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Facioscapulohumeral muscular dystrophy

March 16, 2024

Facioscapulohumeral muscular dystrophy (FSHD) is a type of muscular dystrophy, a group of heritable diseases that cause degeneration of muscle and progressive weakness. Per the name, FSHD tends to sequentially weaken the muscles of the face, those that position the scapula, and those overlying the humerus bone of the upper arm.[2][3] These areas can be spared, and muscles of other areas usually are affected, especially those of the chest, abdomen, spine, and shin. Almost any skeletal muscle can be affected in advanced disease. Abnormally positioned, termed 'winged', scapulas are common, as is the inability to lift the foot, known as foot drop. The two sides of the body are often affected unequally. Weakness typically manifests at ages 15 – 30 years.[4] FSHD can also cause hearing loss and blood vessel abnormalities at the back of the eye.

Facioscapulohumeral muscular dystrophy
Other namesLandouzy–Dejerine muscular dystrophy, FSHMD, FSH
A diagram showing the muscles commonly affected by FSHD
Pronunciation
SpecialtyNeurology, neuromuscular medicine
SymptomsFacial weakness, scapular winging, foot drop
ComplicationsChronic pain, dry eyes, and shoulder instability; less commonly retinal disease, scoliosis, and respiratory insufficiency
Usual onsetAges 15 – 30 years
DurationLifelong
TypesTypically classified by genetic cause (FSHD1, FSHD2). Sometimes classified by disease manifestation (eg, infantile-onset)
CausesGenetic (inherited or new mutation)
Risk factorsMale sex, extent of genetic mutation
Diagnostic methodGenetic testing
Differential diagnosisLimb-girdle muscular dystrophy (especially calpainopathy), Pompe disease, mitochondrial myopathy, polymyositis[2]
ManagementPhysical therapy, bracing, reconstructive surgery
MedicationClinical trials ongoing
PrognosisProgressive, unaffected life expectancy
FrequencyUp to 1/8,333[2]

FSHD is caused by a genetic mutation leading to deregulation of the DUX4 gene.[5] Normally, DUX4 is expressed (i.e., turned on) in cells of the ovary and in very early human development, becoming repressed (i.e., turned off) by the time an embryo is several days old.[6][7] In FSHD, DUX4 is inadequately repressed, allowing sporadic expression throughout life. Deletion of DNA in the region surrounding DUX4 is the causative mutation in 95% of cases, termed "D4Z4 contraction" and defining FSHD type 1 (FSHD1).[8] FSHD caused by other mutations is FSHD type 2 (FSHD2). For disease to develop, also required is a 4qA allele, which is a common variation in the DNA next to DUX4. The chances of a D4Z4 contraction with a 4qA allele being passed on to a child is 50% (autosomal dominant);[2] in 30% of cases, the mutation arose spontaneously.[4] Mutations of FSHD cause inadequate DUX4 repression by unpacking the DNA around DUX4, making it accessible to be copied into messenger RNA (mRNA). The 4qA allele stabilizes this DUX4 mRNA, allowing it to be used for production of DUX4 protein.[9] DUX4 protein is a modulator of hundreds of other genes, many of which are involved in muscle function.[2][5] How this genetic modulation causes muscle damage remains unclear.[2]

Signs, symptoms, and diagnostic tests can suggest FSHD; genetic testing usually provides definitive diagnosis.[2] FSHD can be presumptively diagnosed in an individual with signs/symptoms and an established family history. No intervention has proven effective for slowing progression of weakness.[10] Screening allows for early detection and intervention for various disease complications. Symptoms can be addressed with physical therapy, bracing, and reconstructive surgery such as surgical fixation of the scapula to the thorax.[11] FSHD affects up to 1 in 8,333 people,[2] putting it in the three most common muscular dystrophies with myotonic dystrophy and Duchenne muscular dystrophy.[12][13] Prognosis is variable. Many are not significantly limited in daily activity, whereas a wheel chair or scooter is required in 20% of cases.[14] Life expectancy is not affected, although death can rarely be attributed to respiratory insufficiency due to FSHD.[15]

FSHD was first distinguished as a disease in the 1870s and 1880s when French physicians Louis Théophile Joseph Landouzy and Joseph Jules Dejerine followed a family affected by it, thus the initial name Landouzy–Dejerine muscular dystrophy. Their work is predated by descriptions of probable individual FSHD cases.[16][17][18] The significance of D4Z4 contraction on chromosome 4 was established in the 1990s. The DUX4 gene was discovered in 1999, found to be expressed and toxic in 2007, and in 2010 the genetic mechanism causing its expression was elucidated. In 2012, the gene most frequently mutated in FSHD2 was identified. In 2019, the first drug designed to counteract DUX4 expression entered clinical trials.[19]

Signs and symptoms edit

Classically, weakness develops in the face, then the shoulder girdle, then the upper arm.[10] These muscles can be spared and other muscles usually are affected. The order of muscle involvement can cause the appearance of weakness "descending" from the face to the legs.[10] Distribution and degree of muscle weakness is extremely variable, even between identical twins.[20][21] Musculoskeletal pain is very common, most often described in the neck, shoulders, lower back, and the back of the knee.[22][4] Fatigue is also common.[4] Muscle weakness usually becomes noticeable on one side of the body before the other, a hallmark of the disease.[14] The right shoulder and arm muscles are more often affected than the left upper extremity muscles, independent of handedness.[23]: 139 [24][25][26] Otherwise, neither side of the body has been found to be at more risk. Classically, symptoms appear in those 15 – 30 years of age, although infantile onset, adult onset, and absence of symptoms despite having the causal genetics also occur.[4] FSHD1 with a very large D4Z4 deletion (EcoRI 10-11 kb) is more strongly associated with infantile onset and severe weakness.[27] On average, FSHD2 presents 10 years later than FSHD1.[28] Otherwise, FSHD1 and FSHD2 are indistinguishable on the basis of weakness.[27] Disease progression is slow, and long static phases, in which no progression is apparent, is not uncommon.[29] Less commonly, individual muscles rapidly deteriorate over several months.[2] The symptom burden of FSHD is typically more severe than it is perceived to be by those without the disease.[30][31][32][33]

Face edit

Weakness of the muscles of the face is the most distinguishing sign of FSHD.[4] It is typically the earliest sign, although it is rarely the initial complaint.[4] At least mild facial weakness can be found in 90% or more with FSHD.[29][24] One of the most common deficits is inability to close the eyelids, which can result in sleeping with the eyelids open and dry eyes.[4] The implicated muscle is the orbicularis oculi muscle.[4] Another common deficit is inability to purse the lips, causing inability to pucker, whistle, or blow up a balloon.[4] The implicated muscle is the orbicularis oris muscle.[4] A third common deficit is inability raise the corners of the mouth, causing a "horizontal smile," which looks more like a grin.[4] Responsible is the zygomaticus major muscle.[4]

Weakness of facial muscles contributes to difficulty pronouncing words.[34] Facial expressions can appear diminished, arrogant, grumpy, or fatigued.[4] Muscles used for chewing and moving the eyes are not affected.[24][14] Difficulty swallowing is not typical, although can occur in advanced cases.[35][34] FSHD is generally progressive, but it is not established whether facial weakness is progressive or stable throughout life.[36]

Shoulder, chest, and arm edit

 
Bilateral scapular winging, right moreso than left. Left image showing wall push test, right image showing attempted shoulder flexion.

After the facial weakness, weakness usually develops in the muscles of the chest and those that span from scapula to thorax. Symptoms involving the shoulder, such as difficulty working with the arms overhead, are the initial complaint in 80% of cases.[24][14] Predominantly, the serratus anterior and middle and lower trapezii muscles are affected;[4] the upper trapezius is often spared.[14] Trapezius weakness causes the scapulas to become downwardly rotated and protracted, resulting in winged scapulas, horizontal clavicles, and sloping shoulders; arm abduction is impaired. Serratus anterior weaknesss impairs arm flexion, and worsening of winging can be demonstrated when pushing against a wall. Muscles spanning from the scapula to the arm are generally spared, which include deltoid and the rotator cuff muscles.[37][38] The deltoid can be affected later on, especially the upper portion.[4]

Severe muscle wasting can make bones and spared shoulder muscles very visible, a characteristic example being the "poly-hill" sign elicited by arm elevation.[4] The first "hill" or bump is the upper corner of scapula appearing to "herniate" up and over the rib cage. The second hill is the AC joint, seen between a wasted upper trapezius and wasted upper deltoid. The third hill is the lower deltoid, distinguishable between the wasted upper deltoid and wasted humeral muscles.[4] Shoulder weakness and pain can in turn lead to shoulder instability, such as recurrent dislocation, subluxation, or downward translation of the humeral head.[39]

Also affected is the chest, particularly the parts of the pectoralis major muscle that connect to the sternum and ribs. The part that connects to the clavicle is less often affected. This muscle wasting pattern can contribute to a prominent horizontal anterior axillary fold.[40][4] Beyond this point the disease does not progress further in 30% of familial cases.[24][14] After upper torso weakness, weakness can "descend" to the upper arms (biceps muscle and, particularly, the triceps muscle).[24] The forearms are usually spared, resulting in an appearance some compare to the fictional character Popeye,[4] although when the forearms are affected in advanced disease, the wrist extensors are more often affected.[24]

Lower body and trunk edit

After the upper body, weakness can next appear in either the pelvis, or it "skips" the pelvis and involves the tibialis anterior (shin muscle), causing foot drop. One author considers the pelvic and thigh muscles to be the last group affected.[24] Pelvic weakness can manifest as a Trendelenburg's sign.[4] Weakness of the back of the thigh (hamstrings) is more common than weakness of the front of the thigh (quadriceps).[4] In more severe cases, especially infantile FSHD, there can be anterior pelvic tilt, with associated hyperextension of the knees.[41]

Weakness can also occur in the abdominal muscles and paraspinal muscles, which can manifest as a protuberant abdomen and lumbar hyperlordosis.[2][4] Abdominal weakness can cause inability to do a sit-up or the inability to turn from one side to the other while lying on one's back.[4] Of the rectus abdominis muscle, the lower portion is preferentially affected, manifesting as a positive Beevor's sign.[4][2] In advanced cases, neck extensor weakness can cause the head to lean towards the chest, termed head drop.[24]

Non-muscular edit

 
Funduscopy of the retinal: (A) normal blood vessels (B) tortuous blood vessels, as often seen with FSHD

The most common non-musculoskeletal manifestation of FSHD is abnormalities in the small arteries (arterioles) in the retina. Tortuosity of the arterioles is seen in approximately 50% of those with FSHD. Less common arteriole abnormalities include telangiectasias and microaneurysms.[42][43] These abnormalities of arterioles usually do not affect vision or health, although a severe form of it mimics Coat's disease, a condition found in about 1% of FSHD cases and more frequently associated with large 4q35 deletions.[2][44] High-frequency sensorineural hearing loss can occur in those with large 4q35 deletions, but otherwise is no more common compared to the general population.[2] Large 4q35 deletion can lead to various other rare manifestations.[45]

Scoliosis can occur, thought to result from weakness of abdominal, hip extensor, and spinal muscles.[46][47] Conversely, scoliosis can be viewed as a compensatory mechanism to weakness.[46] Breathing can be affected, associated with kyphoscoliosis and wheelchair use; it is seen in one-third of wheelchair-using patients.[2] However, ventilator support (nocturnal or diurnal) is needed in only 1% of cases.[2][48] Although there are reports of increased risk of cardiac arrhythmias, general consensus is that the heart is not affected.[14]

Genetics edit

 
Structure of DUX4 protein full-length (FL), with short (S) version indicated.

The genetics of FSHD is complex.[2] FSHD and the myotonic dystrophies have unique genetic mechanisms that differ substantially from the rest of genetic myopathies.[49] The DUX4 gene is the focal point of FSHD genetics. Normally, DUX4 is expressed during embryogenesis and later repressed in all tissues except the testes. In FSHD, there is failure of DUX4 repression and continued production of DUX4 protein, which is toxic to muscles.[2][8] The mechanism of failed DUX4 repression is hypomethylation of DUX4 and its surrounding DNA on the tip of chromosome 4 (4q35), allowing transcription of DUX4 into messenger RNA (mRNA). Several mutations can result in disease, upon which FSHD is sub-classified into FSHD type 1 (FSHD1) and FSHD type 2 (FSHD2).[27] Disease can only result when a mutation is present in combination with select, commonly found variations of 4q35, termed haplotype polymorphisms. There are at least 17 4q35 haplotype polymorphisms,[50] roughly dividable into the groups 4qA and 4qB.[50] A 4qA haplotype polymorphism, often referred to as a 4qA allele, is necessary for disease, as it contains a polyadenylation sequence that allows DUX4 mRNA to resist degradation long enough to be translated into DUX4 protein.[8]

DUX4 and the D4Z4 repeat array edit

 
D4Z4 array with three D4Z4 repeats and the 4qA allele.[27]
CEN centromeric end TEL telomeric end
NDE box non-deleted element PAS polyadenylation site
triangle D4Z4 repeat trapezoid partial D4Z4 repeat
white box pLAM gray boxes DUX4 exons 1, 2, 3
arrows
corner promoters straight RNA transcripts
black sense red antisense
blue DBE-T dashes dicing sites

DUX4 resides within the D4Z4 macrosatellite repeat array, a series of tandemly repeated DNA segments in the subtelomeric region (4q35) of chromosome 4.[51] Each D4Z4 repeat is 3.3 kilobase pairs (kb) long and is the site of epigenetic regulation, containing both heterochromatin and euchromatin structures.[52][53] In FSHD, the heterochromatin structure is lost, becoming euchromatin,[52] which consists of less methylation of DNA, and altered methylation of histones.[54] Histone methylation patterns differ slightly between FSHD1 and FSHD2.[54]

The subtelomeric region of chromosome 10q contains a tandem repeat structure highly homologous (99% identical) to 4q35,[8][50] containing "D4Z4-like" repeats with protein-coding regions identical to DUX4 (D10Z10 repeats and DUX4L10, respectively).[8][55] Because 10q usually lacks a polyadenylation sequence, it is usually not implicated in disease. However, chromosomal rearrangements can occur between 4q and 10q repeat arrays, and involvement in disease is possible if a 4q D4Z4 repeat and polyadenylation signal are transferred onto 10q,[56][8][57] or if rearrangement causes FSHD1.

DUX4 consists of three exons. Exons 1 and 2 are in each repeat. Exon 3 is in the pLAM region telomeric to the last partial repeat.[8][7] Multiple RNA transcripts are produced from the D4Z4 repeat array, both sense and antisense. Some transcripts might be degraded in areas to produce si-like small RNAs.[27] Some transcripts that originate centromeric to the D4Z4 repeat array at the non-deleted element (NDE), termed D4Z4 regulatory element transcripts (DBE-T), could play a role in DUX4 derepression.[27][58] One proposed mechanism is that DBE-T leads to the recruitment of the trithorax-group protein Ash1L, an increase in H3K36me2-methylation, and ultimately de-repression of 4q35 genes.[59]

Chromatin profiles[54]
DNA methylation
FSHD1
FSHD2*
*Chromatin profiles not fully
characterized for DNMT3B mutation[54]

FSHD1 edit

FSHD involving deletion of D4Z4 repeats (termed 'D4Z4 contraction') on 4q is classified as FSHD1, which accounts for 95% of FSHD cases.[2] Typically, chromosome 4 includes between 11 and 150 D4Z4 repeats.[52][8] In FSHD1, there are 1–10 D4Z4 repeats.[8] The number of repeats is roughly inversely related to disease severity. Namely, those with 8 - 10 repeats tend to have the mildest presentations, sometimes with no symptoms; those with 4 - 7 repeats have moderate disease that is highly variable; and those with 1 - 3 repeats are more likely to have severe, atypical, and early-onset disease.[60] Deletion of the entire D4Z4 repeat array does not result in FSHD because then there are no complete copies of DUX4 to be expressed, although other birth defects result.[61][8] One contracted D4Z4 repeat array with an adjoining 4qA allele is sufficient to cause disease, so inheritance is autosomal dominant. De novo (new) mutations are implicated in 10 - 30% of cases,[4] up to 40% of which exhibit somatic mosaicism.[14] In an individual with mosaic FSHD, the severity of disease is correlated to the proportion of their cells carrying the mutation.[14]

It has been proposed that FSHD1 undergoes anticipation, a phenomenon primarily associated with trinucleotide repeat disorders in which disease manifestation worsens with each subsequent generation.[62] As of 2019, more detailed studies are needed to definitively show whether or not anticipation occurs.[63] If anticipation does occur in FSHD, the mechanism is different than that of trinucleotide repeat disorders, since D4Z4 repeats are much larger than trinucleotide repeats, an underabundance of repeats (rather than overabundance) causes disease, and the repeat array size in FSHD is stable across generations.[64]

 
D4Z4 array examples, with each D4Z4 repeat represented by a triangle. The circles above the triangles represent DNA methylation, which determine DNA packaging as represented by the circles in line with the triangles.

FSHD2 edit

FSHD without D4Z4 contraction is classified as FSHD2, which constitutes 5% of FSHD cases.[2] Various mutations cause FSHD2, all of chromatin modifier genes that result in D4Z4 hypomethylation, at which the genetic mechanism converges with FSHD1.[65][10] Approximately 80% of FSHD2 cases are due to deactivating mutations in the gene SMCHD1 (structural maintenance of chromosomes flexible hinge domain containing 1) on chromosome 18. SMCHD1 is responsible for DNA methylation, and its deactivation results in hypomethylation of the D4Z4 repeat array.[2] Specific mutations of SMCHD1 are also associated with Bosma arhinia and microphtalmia syndrome.[54] Another cause of FSHD2 is mutation in DNMT3B (DNA methyltransferase 3B), which also plays a role in DNA methylation.[66][67] Mutations in DNMT3B can also cause ICF syndrome.[54] As of 2020, early evidence indicates that a third cause of FSHD2 is mutation in both copies of the LRIF1 gene, which encodes the protein ligand-dependent nuclear receptor-interacting factor 1 (LRIF1).[68] LRIF1 is known to interact with the SMCHD1 protein.[68] As of 2019, there are presumably additional mutations at other unidentified genetic locations that can cause FSHD2.[2]

Mutation of a single allele of SMCHD1 or DNMT3B can cause disease. Mutation of both copies LRIF1 has been tentatively shown to cause disease in a single person as of 2020.[68] As in FSHD1, a 4qA allele must be present for disease to result. However, unlike the D4Z4 array, the genes implicated in FSHD2 are not in proximity with the 4qA allele, and so they are inherited independently from the 4qA allele, resulting in a digenic inheritance pattern. For example, one parent without FSHD can pass on an SMCHD1 mutation, and the other parent, also without FSHD, can pass on a 4qA allele, bearing a child with FSHD2.[65][67]

Two ends of a disease spectrum edit

FSHD1 and FSHD2 have been traditionally viewed as separate entities with distinct genetic causes (albeit, the downstream genetic mechanisms merge).[69] Alternatively, the genetic causes of FSHD1 and FSHD2 can be viewed as risk factors, each contributing to an FSHD disease spectrum.[69] Not rarely, an affected individual seems to have contributions from both.[60] For example, in those with FSHD2, although they have do not have a 4qA allele with D4Z4 repeat number less than 11, they still often have one less than 17 (relatively short compared to the general population), suggesting that a large number of D4Z4 repeats can prevent the effects of an SMCHD1 mutation.[60] Further studies are needed to determine the upper limit of D4Z4 repeats in FSHD2.[60]

In those with FSHD1 and FSHD2, that is, having 10 or fewer repeats with an adjacent 4qA allele and an SMCHD1 mutation, the disease manifests more severely, illustrating that the effects of each mutation are additive.[70] A combined FSHD1/FSHD2 presentation is most common in those with 9 - 10 repeats. A possible explanation is that a sizable portion of the general population has 9 - 10 repeats with difficult to detect or no disease, yet with the additive effect of an SMCHD1 mutation, symptoms are severe enough for a diagnosis to be made.[60] The 9 - 10 repeat size can be considered as an overlap zone between FSHD1 and FSDH2.[60]

Pathophysiology edit

Molecular edit

 
DUX4 signaling in FSHD-affected skeletal muscle.

As of 2020, there seems to be a consensus that aberrant expression of DUX4 in muscle is the cause of FSHD.[71] DUX4 is expressed in extremely small amounts, detectable in 1 out of every 1000 immature muscle cells (myoblast), which appears to increase after myoblast maturation, in part because the cells fuse as they mature, and a single nucleus expressing DUX4 can provide DUX4 protein to neighboring nuclei from fused cells.[72]

It remains an area of active research how DUX4 protein causes muscle damage.[73] DUX4 protein is a transcription factor that regulates many other genes. Some of these genes are involved in apoptosis, such as p53, p21, MYC, and β-catenin, and indeed it seems that DUX4 protein makes muscle cells more prone to apoptosis. Other DUX4 protein-regulated genes are involved in oxidative stress, and indeed it seems that DUX4 expression lowers muscle cell tolerance of oxidative stress. Variation in the ability of individual muscles to handle oxidative stress could partially explain the muscle involvement patterns of FSHD. DUX4 protein downregulates many genes involved in muscle development, including MyoD, myogenin, desmin, and PAX7, and indeed DUX4 expression has shown to reduce muscle cell proliferation, differentiation, and fusion. DUX4 protein regulates a few genes that are involved in RNA quality control, and indeed DUX4 expression has been shown to cause accumulation of RNA with subsequent apoptosis.[71] Estrogen seems to play a role in modifying DUX4 protein effects on muscle differentiation, which could explain why females are lesser affected than males, although it remains unproven.[74]

The cellular hypoxia response has been reported in a single study to be the main driver of DUX4 protein-induced muscle cell death. The hypoxia-inducible factors (HIFs) are upregulated by DUX4 protein, possibly causing pathologic signaling leading to cell death.[75]

Another study found that DUX4 expression in muscle cells led to the recruitment and alteration of fibrous/fat progenitor cells, which helps explain why muscles become replaced by fat and fibrous tissue.[72]

A single study implicated RIPK3 in DUX4-mediated cell death.[76]

Muscle histology edit

 
Microscopic cross-sectional views of FSHD-affected muscle fibers. Visible is inflammation and fibrosis, as well as muscle fiber shape change, death, and regeneration.

Unlike other muscular dystrophies, early muscle biopsies show only mild degrees of fibrosis, muscle fiber hypertrophy, and displacement of nuclei from myofiber peripheries (central nucleation).[27] More often found is inflammation.[27] There can be endomysial inflammation, primarily composed of CD8+ T-cells, although these cells do not seem to directly cause muscle fiber death.[27] Endomysial blood vessels can be surrounded by inflammation, which is relatively unique to FSHD, and this inflammation contains CD4+ T-cells.[27] Inflammation is succeeded by deposition of fat (fatty infiltration), then fibrosis.[77][27] Individual muscle fibers can appear whorled, moth-eaten, and, especially, lobulated.[78]

Muscle involvement pattern edit

Why certain muscles are preferentially affected in FSHD remains unknown. There are multiple trends of involvement seen in FSHD, possibly hinting at underlying pathophysiology. Individual muscles can weaken while adjacent muscles remain strong.[79] The right shoulder and arm muscles are more often affected than the left upper extremity muscles, a pattern also seen in Poland syndrome and hereditary neuralgic amyotrophy; this could reflect a genetic, developmental/anatomic, or functional-related mechanism.[24][25] The deltoid is often spared, which is not seen in any other condition that affects the muscles around the scapula.[36]

 
Examples of MRI imaging in FSHD. The white within the muscles of the STIR (T2) image represents muscle edema. The white within the muscles of the T1 images represents fatty infiltration.

Medical imaging (CT and MRI) have shown muscle involvement not readily apparent otherwise[37]

Retinopathy edit

Tortuosity of the retinal arterioles, and less often microaneurysms and telangiectasia, are commonly found in FSHD.[42] Abnormalities of the capillaries and venules are not observed.[42] One theory for why the arterioles are selectively affected is that they contain smooth muscle.[42] The degree of D4Z4 contraction correlates to the severity of tortuosity of arterioles.[42] It has been hypothesized that retinopathy is due to DUX4-protein-induced modulation of the CXCR4SDF1 axis, which has a role in endothelial tip cell morphology and vascular branching.[42]

Diagnosis edit

 
American Academy of Neurology (ANN) guidelines for genetic testing for suspected FSHD. Not all laboratories follow this workflow.

FSHD can be presumptively diagnosed in many cases based on signs, symptoms, and/or non-genetic medical tests, especially if a first-degree relative has genetically confirmed FSHD.[10] Genetic testing can provide definitive diagnosis.[4] In the absence of an established family history of FSHD, diagnosis can be difficult due to the variability in how FSHD manifests.[82]

Genetic testing edit

Genetic testing is the gold standard for FSHD diagnosis, as it is the most sensitive and specific test available.[2] Commonly, FSHD1 is tested for first.[2] A shortened D4Z4 array length (EcoRI length of 10 kb to 38 kb) with an adjacent 4qA allele supports FSHD1.[2] If FSHD1 is not present, commonly FSHD2 is tested for next by assessing methylation at 4q35.[2] Low methylation (less than 20%) in the context of a 4qA allele is sufficient for diagnosis.[2] The specific mutation, usually one of various SMCHD1 mutations, can be identified with next-generation sequencing (NGS).[83]

Assessing D4Z4 length edit

Measuring D4Z4 length is technically challenging due to the D4Z4 repeat array consisting of long, repetitive elements.[84] For example, NGS is not useful for assessing D4Z4 length, because it breaks DNA into fragments before reading them, and it is unclear from which D4Z4 repeat each sequenced fragment came.[4] In 2020, optical mapping became available for measuring D4Z4 array length, which is more precise and less labor-intensive than southern blot.[85]Molecular combing is also available for assessing D4Z4 array length.[86] These methods, which physical measure the size of the D4Z4 repeat array, require specially prepared high quality and high molecular weight genomic DNA (gDNA) from serum, increasing cost and reducing accessibility to testing.[87]

 
Diagram showing restriction enzyme sites used to differentiate between D4Z4 repeat arrays of 4q and 10q.

Restriction fragment length polymorphism (RFLP) analysis was the first genetic test developed and is still used as of 2020, although it is being phased out by newer methods. It involves dicing the DNA with restriction enzymes and sorting the resulting restriction fragments by size using southern blot. The restriction enzymes EcoRI and BlnI are commonly used. EcoRI isolates the 4q and 10q repeat arrays, and BlnI dices the 10q sequence into small pieces, allowing 4q to be distinguished.[4][50] The EcoRI restriction fragment is composed of three parts: 1) 5.7 kb proximal part, 2) the central, variable size D4Z4 repeat array, and 3) the distal part, usually 1.25 kb.[88] The proximal portion has a sequence of DNA stainable by the probe p13E-11, which is commonly used to visualize the EcoRI fragment during southern blot.[50] The name "p13E-11" reflects that it is a subclone of a DNA sequence designated as cosmid 13E during the human genome project.[89][90] Considering that each D4Z4 repeat is 3.3 kb, and the EcoRI fragment contains about 5 kb of DNA that is not part of the D4Z4 repeat array, the number of D4Z4 units can be calculated.[74]

D4Z4 repeats = (EcoRI length - 5) / 3.3

Sometimes 4q or 10q will have a combination of D4Z4 and D4Z4-like repeats due to DNA exchange between 4q and 10q, which can yield erroneous results, requiring more detailed workup.[50] Sometimes D4Z4 repeat array deletions can include the p13E-11 binding site, warranting use of alternate probes.[50][91]

Assessing methylation status edit

Methylation status of 4q35 is traditionally assessed after FSHD1 testing is negative. Methylation sensitive restriction enzyme (MSRE) digestion showing hypomethylation has long been considered diagnostic of FSHD2.[87] Other methylation assays have been proposed or used in research settings, including methylated DNA immunoprecipitation and bisulfite sequencing, but are not routinely used in clinical practice.[92][87] Bisulfite sequencing, if validated, would be valuable due to it being able to use lower quality DNA sources, such as those found in saliva.[87]

Auxiliary testing edit

 
MRI showing asymmetrical involvement of various muscles in FSHD

Other tests can support the diagnosis of FSHD, although they are all less sensitive and less specific than genetic testing.[93][4] Nonetheless, they can rule out similar-appearing conditions.[14]

  • Creatine kinase (CK) blood level is often ordered when muscle damage is suspected. CK is an enzyme found in muscle, leaking into the blood when muscles become damaged. In FSHD, CK level is normal to mildly elevated,[2] never exceeding five times the upper limit of normal.[4]
  • Electromyogram (EMG) measures the electrical activity in the muscle. EMG can show nonspecific signs of muscle damage or irritability.[2]
  • Nerve conduction velocity (NCV) measures the how fast signals travel along a nerve. The nerve signals are measured with surface electrodes (similar to those used for an electrocardiogram) or needle electrodes.
  • Muscle biopsy is the surgical removal and examination of a small piece of muscle, usually from the arm or leg. Microscopy and a variety of biochemical tests are used for examination. Findings in FSHD are nonspecific, such as presence of white blood cells or variation in muscle fiber size. This test is rarely indicated.[2]
  • Muscle MRI is sensitive for detecting muscle damage, even in mild cases. T1-weighted MRI imaging can visualize fatty infiltration of muscles, and T2-weighted MRI imaging can visualize muscle edema.[citation needed] Because of the particular muscle involvement patterns of FSHD, MRI can help differentiate FSHD from other muscle diseases, directing genetic testing.[37][38]

Differential diagnosis edit

Included in the differential diagnosis of FSHD are limb-girdle muscular dystrophy (especially calpainopathy),[2] scapuloperoneal myopathy,[94] mitochondrial myopathy,[2] Pompe disease,[2] and polymyositis.[2] Calpainopathy and scapuloperoneal myopathy, like FSHD, present with scapular winging.[94] Features that suggest FSHD are facial weakness, asymmetric weakness, and lack of benefit from immunosuppression medications.[2] Features the suggest an alternative diagnosis are contractures, respiratory insufficiency, weakness of muscles controlling eye movement, and weakness of the tongue or throat.[14]

Management edit

No pharmacologic treatment has proven to significantly slow progression of weakness or meaningfully improve strength.[95][2][10]

Screening and monitoring of complications edit

The American Academy of Neurology (AAN) recommends several medical tests to detect complications of FSHD.[95] A dilated eye exam to look for retinal abnormalities is recommended in those newly diagnosed with FSHD; for those with large D4Z4 deletions, an evaluation by a retinal specialist is recommended yearly.[96][2] A hearing test is recommended for individuals with early-onset FSHD prior to starting school, or for any other FSHD-affected individual with symptoms of hearing loss.[96][2] Pulmonary function testing (PFT) is recommended in those newly diagnosed to establish baseline pulmonary function,[2] and recurrently for those with pulmonary insufficiency symptoms or risks.[96][2] Routine screening for heart conditions, such as through an electrocardiogram (EKG) or echocardiogram (echo), is considered unnecessary in those without symptoms of heart disease.[95]

Physical and occupational therapy edit

Aerobic exercise has been shown to reduce chronic fatigue and decelerate fatty infiltration of muscle in FSHD.[97][98] Physical activity in general might slow disease progression in the legs.[10] The AAN recommends that people with FSHD engage in low-intensity aerobic exercise to promote energy levels, muscle health, and bone health.[2] Moderate-intensity strength training appears to do no harm, although it has not been shown to be beneficial.[99] Physical therapy can address specific symptoms; there is no standardized protocol for FSHD. Anecdotal reports suggest that appropriately applied kinesiology tape can reduce pain.[100] Occupational therapy can be used for training in activities of daily living (ADLs) and to help adapt to new assistive devices. Cognitive behavioral therapy (CBT) has been shown to reduce chronic fatigue in FSHD, and it also decelerates fatty infiltration of muscle when directed towards increasing daily activity.[97][98]

Braces are often used to address muscle weakness. Scapular bracing can improve scapular positioning, which improves shoulder function, although it is often deemed as ineffective or impractical.[101] Ankle-foot orthoses can improve walking, balance, and quality of life.[102]

Pharmacologic management edit

No pharmaceuticals have definitively proven effective for altering the disease course.[95] Although a few pharmaceuticals have shown improved muscle mass in limited respects, they did not improve quality of life, and the AAN recommends against their use for FSHD.[95]

Reconstructive surgery edit

Scapular winging is amenable to surgical correction, namely operative scapular fixation. Scapular fixation is restriction and stabilization of the position of the scapula, putting it in closer apposition to the rib cage and reducing winging. Absolute restriction of scapular motion by fixation of the scapula to the ribs is most commonly reported.[103] This procedure often involves inducing bony fusion, called arthrodesis, between the scapula and ribs. Names for this include scapulothoracic fusion, scapular fusion, and scapulodesis. This procedure increases arm active range of motion, improves arm function, decreases pain, and improves cosmetic appearance.[104][105] Active range of motion of the arm increases most in the setting of severe scapular winging with an unaffected deltoid muscle;[11] however, passive range of motion decreases. In other words, the patient gains the ability to slowly raise their arms to 90+ degrees, but they lose the ability to "throw" their arm up to a full 180 degrees.[2] The AAN states that scapular fixation can be offered cautiously to select patients after balancing these benefits against the adverse consequences of surgery and prolonged immobilization.[95][10]

Another form of operative scapular fixation is scapulopexy. "Scapulo-" refers to the scapula bone, and "-pexy" is derived from the Greek root "to bind." Some versions of scapulopexy accomplish essentially the same result as scapulothoracic fusion, but instead of inducing bony fusion, the scapula is secured to the ribs with only wire, tendon grafts, or other material. Some versions of scapulopexy do not completely restrict scapular motion, examples including tethering the scapula to the ribs, vertebrae, or other scapula.[103][106] Scapulopexy is considered to be more conservative than scapulothoracic fusion, with reduced recovery time and less effect on breathing.[103] However, they also seem more susceptible to long-term failure.[103] Another form of scapular fixation, although not commonly done in FSHD, is tendon transfer, which involves surgically rearranging the attachments of muscles to bone.[103][107][108] Examples include pectoralis major transfer and the Eden-Lange procedure.

Various other surgical reconstructions have been described. Upper eyelid gold implants have been used for those unable to close their eyes.[109] Drooping lower lip has been addressed with plastic surgery.[110] Select cases of foot drop can be surgically corrected with tendon transfer, in which the tibialis posterior muscle is repurposed as a tibialis anterior muscle, a version of this being called the Bridle procedure.[111][112][100] Severe scoliosis caused by FSHD can be corrected with spinal fusion; however, since scoliosis might be a compensatory change in response to muscle weakness, correction of spinal alignment can result in further impaired muscle function.

  • Scapular winging management
  •  
    Kinesiology tape applied across the scapulas.
  •  
    A cloth brace to hold the scapulas in retraction to reduce shoulder symptoms, such as collarbone pain.
  •  
    Scapula-to-scapula scapulopexy, pre- and post-operation. The scapulas are tethered together into a retracted position with an Achilles tendon graft, which, in this case, rendered the rhomboid major muscles distinguishable.

Prognosis edit

Genetics partially predicts prognosis.[95] Those with large D4Z4 repeat deletions (with a remaining D4Z4 repeat array size of 10-20 kbp, or 1-4 repeats) are more likely to have severe and early disease, as well as non-muscular symptoms.[95] Those who have the genetic mutations of both FSHD1 and FSHD2 are more likely to have severe disease.[70] It has also been observed that D4Z4 shortening is less and disease manifestation is milder when a prominent family history is present, as opposed to a new mutation.[113] In some large families, 30% of those with the mutation had no noticeable symptoms, and 30% of those with symptoms did not progress beyond facial and shoulder weakness.[24] Women tend to develop symptoms later in life and have less severe disease courses.[108]

Remaining variations in disease course are attributed to unknown environmental factors. A single study found that disease course is not worsened by tobacco smoking or alcohol consumption, common risk factors for other diseases.[114]

Pregnancy edit

Pregnancy outcomes are overall good in mothers with FSHD; there is no difference in rate of preterm labor, rate of miscarriage, and infant outcomes.[115] However, weakness can increase the need for assisted delivery.[115]

A single review found that weakness worsens, without recovery, in 12% of mothers with FSHD during pregnancy, although this might be due to weight gain or deconditioning.[115]

Epidemiology edit

The prevalence of FSHD ranges from 1 in 8,333 to 1 in 15,000.[2] The Netherlands reports a prevalence of 1 in 8,333, after accounting for the undiagnosed.[116] The prevalence in the United States is commonly quoted as 1 in 15,000.[15]

After genetic testing became possible in 1992, average prevalence was found to be around 1 in 20,000, a large increase compared to before 1992.[117][24][116] However, 1 in 20,000 is likely an underestimation, since many with FSHD have mild symptoms and are never diagnosed, or they are siblings of affected individuals and never seek definitive diagnosis.[116]

Race and ethnicity have not been shown to affect FSHD incidence or severity.[15]

Although the inheritance of FSHD shows no predilection for biological sex, the disease manifests less often in women, and even when it manifests in women, they on average are less severely affected than affected males.[15] Estrogen has been suspected to be a protective factor that accounts for this discrepancy. One study found that estrogen reduced DUX4 activity.[118] However, another study found no association between disease severity and lifetime estrogen exposure in females. The same study found that disease progression was not different through periods of hormonal changes, such as menarche, pregnancy, and menopause.[119]

History edit

The first description of a person with FSHD in medical literature appears in an autopsy report by Jean Cruveilhier in 1852.[16][17] In 1868, Duchenne published his seminal work on Duchenne muscular dystrophy, and as part of its differential was a description of FSHD.[120][17] First in 1874, then with a more commonly cited publication in 1884, and again with pictures in 1885, the French physicians Louis Landouzy and Joseph Dejerine published details of the disease, recognizing it as a distinct clinical entity, and thus FSHD is sometimes referred to as Landouzy Dejerine disease.[18][17] In their paper of 1886, Landouzy and Dejerine drew attention to the familial nature of the disorder and mentioned that four generations were affected in the kindred that they had investigated.[121] Formal definition of FSHD's clinical features did not occur until 1952 when a large Utah family with FSHD was studied. Beginning about 1980 an increasing interest in FSHD led to increased understanding of the great variability in the disease and a growing understanding of the genetic and pathophysiological complexities. By the late 1990s, researchers were finally beginning to understand the regions of chromosome 4 associated with FSHD.[52]

Since the publication of the unifying theory in 2010, researchers continued to refine their understanding of DUX4. With increasing confidence in this work, researchers proposed the first a consensus view in 2014 of the pathophysiology of the disease and potential approaches to therapeutic intervention based on that model.[27]

Alternate and historical names for FSHD include the following:

Chronology of important FSHD-related genetic research edit

1861 Person with muscular dystrophy depicted by Duchenne. Based on the muscles involved, this person could have had FSHD.
 
1884 Landouzy and Dejerine describe a form of childhood progressive muscle atrophy with a characteristic involvement of facial muscles and distinct from pseudohypertrophic (Duchenne's MD) and spinal muscle atrophy in adults.[122]
Two brothers with FSHD followed by Landouzy and Dejerine
 
Photograph of one brother at age 21. The right scapula is protracted, downwardly rotated, and laterally displaced.
 
Drawing of another brother at age 17. Visible is lumbar hyperlordosis. The upper arm and pectoral muscles appear atrophied.
1886 Landouzy and Dejerine describe progressive muscular atrophy of the scapulo-humeral type.[123]
1950 Tyler and Stephens study 1249 individuals from a single kindred with FSHD traced to a single ancestor and describe a typical Mendelian inheritance pattern with complete penetrance and highly variable expression. The term facioscapulohumeral dystrophy is introduced.[124]
1982 Padberg provides the first linkage studies to determine the genetic locus for FSHD in his seminal thesis "Facioscapulohumeral disease."[23]
1987 The complete sequence of the Dystrophin gene (Duchenne's MD) is determined.[125]
1991 The genetic defect in FSHD is linked to a region (4q35) near the tip of the long arm of chromosome 4.[126]
1992 FSHD, in both familial and de novo cases, is found to be linked to a recombination event that reduces the size of 4q EcoR1 fragment to < 28 kb (50–300 kb normally).[89]
1993 4q EcoR1 fragments are found to contain tandem arrangement of multiple 3.3-kb units (D4Z4), and FSHD is associated with the presence of < 11 D4Z4 units.[88]

A study of seven families with FSHD reveals evidence of genetic heterogeneity in FSHD.[127]

1994 The heterochromatic structure of 4q35 is recognized as a factor that may affect the expression of FSHD, possibly via position-effect variegation.[128]

DNA sequencing within D4Z4 units shows they contain an open reading frame corresponding to two homeobox domains, but investigators conclude that D4Z4 is unlikely to code for a functional transcript.[128][129]

1995 The terms FSHD1A and FSHD1B are introduced to describe 4q-linked and non-4q-linked forms of the disease.[130]
1996 FSHD Region Gene1 (FRG1) is discovered 100 kb proximal to D4Z4.[131]
1998 Monozygotic twins with vastly different clinical expression of FSHD are described.[20]
1999 Complete sequencing of 4q35 D4Z4 units reveals a promoter region located 149 bp 5' from the open reading frame for the two homeobox domains, indicating a gene that encodes a protein of 391 amino acid protein (later corrected to 424 aa[132]), given the name DUX4.[133]
2001 Investigators assessed the methylation state (heterochromatin is more highly methylated than euchromatin) of DNA in 4q35 D4Z4. An examination of SmaI, MluI, SacII, and EagI restriction fragments from multiple cell types, including skeletal muscle, revealed no evidence for hypomethylation in cells from FSHD1 patients relative to D4Z4 from unaffected control cells or relative to homologous D4Z4 sites on chromosome 10. However, in all instances, D4Z4 from sperm was hypomethylated relative to D4Z4 from somatic tissues.[134]
2002 A polymorphic segment of 10 kb directly distal to D4Z4 is found to exist in two allelic forms, designated 4qA and 4qB. FSHD1 is associated solely with the 4qA allele.[135]

Three genes (FRG1, FRG2, ANT1) located in the region just centromeric to D4Z4 on chromosome 4 are found in isolated muscle cells from individuals with FSHD at levels 10 to 60 times greater than normal, showing a linkage between D4Z4 contractions and altered expression of 4q35 genes.[136]

2003 A further examination of DNA methylation in different 4q35 D4Z4 restriction fragments (BsaAI and FseI) showed significant hypomethylation at both sites for individuals with FSHD1, non-FSHD-expressing gene carriers, and individuals with phenotypic FSHD relative to unaffected controls.[137]
2004 Contraction of the D4Z4 region on the 4qB allele to < 38 kb does not cause FSHD.[138]
2006 Transgenic mice overexpressing FRG1 are shown to develop severe myopathy.[139]
2007 The DUX4 open reading frame is found to have been conserved in the genome of primates for over 100 million years, supporting the likelihood that it encodes a required protein.[140]

Researchers identify DUX4 mRNA in primary FSHD myoblasts and identify in D4Z4-transfected cells a DUX4 protein, the overexpression of which induces cell death.[132]

DUX4 mRNA and protein expression are reported to increase in myoblasts from FSHD patients, compared to unaffected controls. Stable DUX4 mRNA is transcribed only from the most distal D4Z4 unit, which uses an intron and a polyadenylation signal provided by the flanking pLAM region. DUX4 protein is identified as a transcription factor, and evidence suggests overexpression of DUX4 is linked to an increase in the target paired-like homeodomain transcription factor 1 (PITX1).[141]

2009 The terms FSHD1 and FSHD2 are introduced to describe D4Z4-deletion-linked and non-D4Z4-deletion-linked genetic forms, respectively. In FSHD1, hypomethylation is restricted to the short 4q allele, whereas FSHD2 is characterized by hypomethylation of both 4q and both 10q alleles.[142]

Splicing and cleavage of the terminal (most telomeric) 4q D4Z4 DUX4 transcript in primary myoblasts and fibroblasts from FSHD patients is found to result in the generation of multiple RNAs, including small noncoding RNAs, antisense RNAs and capped mRNAs as new candidates for the pathophysiology of FSHD.[143]

Mechanism proposed of DBE-T (D4Z4 Regulatory Element transcript) leading to de-repression of 4q35 genes.[59]

2010 A unifying genetic model of FSHD is established: D4Z4 contractions only cause FSHD when in the context of a 4qA allele due to stabilization of DUX4 RNA transcript, allowing DUX4 expression.[8] Several organizations including The New York Times highlighted this research[144] (See ).

Dr. Francis Collins, who oversaw the first sequencing of the Human Genome with the National Institutes of Health stated:[144]

"If we were thinking of a collection of the genome's greatest hits, this would go on the list,"

Daniel Perez, co-founder of the FSHD Society, hailed the new findings saying:[145]

"This is a long-sought explanation of the exact biological workings of [FSHD]"

The MDA stated that:[citation needed]

"Now, the hunt is on for which proteins or genetic instructions (RNA) cause the problem for muscle tissue in FSHD."

One of the report's co-authors, Silvère van der Maarel of the University of Leiden, stated that[citation needed]

"It is amazing to realize that a long and frustrating journey of almost two decades now culminates in the identification of a single small DNA variant that differs between patients and people without the disease. We finally have a target that we can go after."

DUX4 is found actively transcribed in skeletal muscle biopsies and primary myoblasts. FSHD-affected cells produce a full-length transcript, DUX4-fl, whereas alternative splicing in unaffected individuals results in the production of a shorter, 3'-truncated transcript (DUX4-s). The low overall expression of both transcripts in muscle is attributed to relatively high expression in a small number of nuclei (~ 1 in 1000). Higher levels of DUX4 expression in human testis (~100 fold higher than skeletal muscle) suggest a developmental role for DUX4 in human development. Higher levels of DUX4-s (vs DUX4-fl) are shown to correlate with a greater degree of DUX-4 H3K9me3-methylation.[7]

2012 Some instances of FSHD2 are linked to mutations in the SMCHD1 gene on chromosome 18, and a genetic/mechanistic intersection of FSHD1 and FSHD2 is established.[65]

The prevalence of FSHD-like D4Z4 deletions on permissive alleles is significantly higher than the prevalence of FSHD in the general population, challenging the criteria for molecular diagnosis of FSHD.[146]

When expressed in primary myoblasts, DUX4-fl acted as a transcriptional activator, producing a > 3-fold change in the expression of 710 genes.[147] A subsequent study using a larger number of samples identified DUX4-fl expression in myogenic cells and muscle tissue from unaffected relatives of FSHD patients, per se, is not sufficient to cause pathology, and that additional modifiers are determinants of disease progression.[148]

2013 Mutations in SMCHD1 are shown to increase the severity of FSHD1.[70]

Transgenic mice carrying D4Z4 arrays from an FSHD1 allele (with 2.5 D4Z4 units), although lacking an obvious FSHD-like skeletal muscle phenotype, are found to recapitulate important genetic expression patterns and epigenetic features of FSHD.[149]

2014 DUX4-fl and downstream target genes are expressed in skeletal muscle biopsies and biopsy-derived cells of fetuses with FSHD-like D4Z4 arrays, indicating that molecular markers of FSHD are already expressed during fetal development.[150]

Researchers "review how the contributions from many labs over many years led to an understanding of a fundamentally new mechanism of human disease" and articulate how the unifying genetic model and subsequent research represent a "pivot-point in FSHD research, transitioning the field from discovery-oriented studies to translational studies aimed at developing therapies based on a sound model of disease pathophysiology." They describe the consensus mechanism of pathophysiology for FSHD as an "inefficient repeat-mediated epigenetic repression of the D4Z4 macrosatellite repeat array on chromosome 4, resulting in the variegated expression of the DUX4 retrogene, encoding a double-homeobox transcription factor, in skeletal muscle."[27]

2020 Voice of the Patient Report released documenting FSHD's impacts on daily life as conveyed by about 400 patients during an FDA externally led Patient-Focused Drug Development meeting, which was held on June 29, 2020.[32][30][31][33]

Past pharmaceutical development edit

Early drug trials, before the pathogenesis involving DUX4 was discovered, were untargeted and largely unsuccessful.[19] Compounds were trialed with goals of increasing muscle mass, decreasing inflammation, or addressing provisional theories of disease mechanism.[19] The following drugs failed to show efficacy:

  • Prednisone, a steroid, based on its antiinflammatory properties and therapeutic effect in Duchenne muscular dystrophy.[151]
  • Oral albuterol, a β2 agonist, on the basis of its anabolic properties. Although it improved muscle mass and certain measures of strength in those with FSHD, it did not improve global strength or function.[152][153][154] Interestingly, β2 agonists were later shown to reduce DUX4 expression.[155]
  • Diltiazem, a calcium channel blocker, on the bases of anecdotal reports of benefit and the theory that calcium dysregulation played a part in muscle cell death.[156]
  • MYO-029 (Stamulumab), an antibody that inhibits myostatin, was developed to promote muscle growth. Myostatin is a protein that inhibits the growth of muscle tissue.[157]
  • ACE-083, a TGF-β inhibitor, was developed to promote muscle growth.[158]

Society and culture edit

Media edit

Patient and research organizations edit

  • The FSHD Society (named "FSH Society" until 2019)[164] was founded in 1991 on the East Coast by two individuals with FSHD, Daniel Perez and Stephen Jacobsen.[165][166] The FSHD Society claims to have advocated for the standardization of the disease name facioscapulohumeral muscular dystrophy and its abbreviation FSHD.[164] The FSHD Society claims to have raised funding for seed grants for FSHD research and co-wrote the MD-CARE Act of 2001, which provided federal funding for all muscular dystrophies.[165][166] The FSHD Society has grown into the world's largest grassroots organization advocating for patient education and scientific and medical research for FSHD.[167][168] One notable spokesperson for FSHD Society has been Max Adler, an actor on the TV series Glee.[169]
  • Friends of FSH Research is a research-oriented nonprofit organization founded in 2004 by Terry and Rick Colella from Kirkland, Washington after their son was diagnosed with FSHD.[170][171][172][173]
  • The FSHD Global Research Foundation was founded in 2007 by Bill Moss in Australia, a former Macquarie Bank executive affected by FSHD.[174][175][176] It is currently directed by Moss's daughter.[175] It was named Australian charity of the year for 2017.[175] It is the largest funder of FSHD medical research outside of the United States as of 2018.[176]
  • FSHD EUROPE was founded in 2010.[177] Spanning multiple countries in Europe, it has launched the European Trial Network.[177]

Notable cases edit

  • Chip Wilson is a Canadian billionaire and founder of Lululemon. He has pledged 100 million Canadian dollars to research through the venture 'Solve FSHD'.[178]
  • Chris Carrino is the radio voice of the Brooklyn Nets. He founded the 'Chris Carrino Foundation for FSHD', oriented towards research funding.[179]
  • Madison Ferris is an American actress with FSHD who was the first wheelchair user to play a lead on Broadway.[180][181]
  • Morgan Hoffmann is an American professional golfer. He started the Morgan Hoffmann Foundation, oriented towards research funding.[182]
  • Dr. Arnold Gold (1925-2024) was a pediatric neurologist, founder of the Arnold P. Gold Foundation, and creator of white coat ceremonies. Dr. Gold focused on patient-centered care and humanism.[183]

Research directions edit

Pharmaceutical development edit

Timelapse of DUX4 expression in FSHD muscle cells[184]

After achieving consensus on FSHD pathophysiology in 2014, researchers proposed four approaches for therapeutic intervention:[27]

  1. enhance the epigenetic repression of the D4Z4
  2. target the DUX4 mRNA, including altering splicing or polyadenylation;
  3. block the activity of the DUX4 protein
  4. inhibit the DUX4-induced process, or processes, that leads to pathology.

Small molecule drugs

Most drugs used in medicine are "small molecule drugs," as opposed to biologic medical products that include proteins, vaccines, and nucleic acids. Small molecule drugs can typically be taken by ingestion, rather than injection.

  • Losmapimod, a selective inhibitor of p38α/β mitogen-activated protein kinases, was identified by Fulcrum Therapeutics as a potent suppressor of DUX4 in vitro.[185] Results of a phase IIb clinical trial, revealed in June 2021, showed statistically significant slowing of muscle function deterioration. Further trials are pending.[186][187]
  • Casein kinase 1 (CK1) inhibition has been identified by Facio Therapies, a Dutch pharmaceutical company, to repress DUX4 expression and is in preclinical development. Facio Therapies claims that CK1 inhibition leaves myotube fusion intact, unlike BET inhibitors, p38 MAPK inhibitors, and β2 agonists.[188][189]

Gene therapy

Gene therapy is the administration of nucleotides to treat disease. Multiple types of gene therapy are in the preclinical stage of development for the treatment of FSHD.

  • Antisense therapy utilizes antisense oligonucleotides that bind to DUX4 messenger RNA, inducing its degradation and preventing DUX4 protein production. Phosphorodiamidate morpholinos, an oligonucleotide modified to increase its stability, have been shown to selectively reduce DUX4 and its effects; however, these antisense nucleotides have poor ability to penetrate muscle.[2]
  • MicroRNAs (miRNAs) directed against DUX4, delivered by viral vectors, have shown to reduce DUX4, protect against muscle pathology, and prevent loss of grip strength in mouse FSHD models.[2] Arrowhead pharmaceuticals is developing an RNA interference therapeutic against DUX4, named ARO-DUX4, and intends to file for regulatory clearance in third quarter of 2021 to begin clinical trials.[190][191][192]
  • Genome editing, the permanent alteration of genetic code, is being researched. One study tried to use CRISPR-Cas9 to knockout the polyadenylation signal in lab dish models, but was unable to show therapeutic results.[193]

Potential drug targets

  • Inhibition of the hyaluronic acid (HA) pathway is a potential therapy. One study found that many DUX4-induced molecular pathologies are mediated by HA signaling, and inhibition of HA biosynthesis with 4-methylumbelliferone prevented these molecular pathologies.[194]
  • P300 inhibition has shown to inhibit the deleterious effects of DUX4[195]
  • BET inhibitors have been shown to reduce DUX4 expression.[155]
  • Antioxidants could potentially reduce the effects of FSHD. One study found that vitamin C, vitamin E, zinc gluconate, and selenomethionine supplementation increased endurance and strength of the quadriceps, but had no significant benefit on walking performance.[196] Further study is warranted.[2]

Outcome measures edit

Ways of measuring the disease are important for studying disease progression and assessing the efficacy of drugs in clinical trials.

  • Reachable workspace uses the Kinect motion sensing system to compare range of reach before and after a therapeutic clinical trial.[197]
  • Quality of life can be measured with questionnaires, such as the FSHD Health Index.[198][2]
  • How the disease affects daily activities can measured with questionnaires, such as the FSHD‐Rasch‐built overall disability scale (FSHD-RODS)[199] or FSHD composite outcome measure (FSHD-COM).[200]
  • Electrical impedance myography is being studied as a way to measure muscle damage.[2]
  • Muscle MRI is useful for assessment of all the muscles in the body. Muscles can be scored based on the degree of fat infiltration.[2]

References edit

  1. ^ The sources listed below differ on pronunciation of the 'u' in 'scapulo'. A 'long u' sound in an unstressed nonfinal syllable is often reduced to a schwa and varies by speaker.
    • "Facioscapulohumeral". Merriam-Webster.com Dictionary.
    • "Facioscapulohumeral". Medical Dictionary, Farlex and Partners, 2009.
  2. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj ak al am an ao ap aq ar as at au av aw ax Wagner, Kathryn R. (December 2019). "Facioscapulohumeral Muscular Dystrophies". CONTINUUM: Lifelong Learning in Neurology. 25 (6): 1662–1681. doi:10.1212/CON.0000000000000801. PMID 31794465. S2CID 208531681.
  3. ^ Stedman, Thomas (1987). Webster's New World/Stedman's Concise Medical Dictionary (1 ed.). Baltimore: Williams & Wilkins. p. 230. ISBN 0139481427.
  4. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae Mul, Karlien; Lassche, Saskia; Voermans, Nicol C; Padberg, George W; Horlings, Corinne GC; van Engelen, Baziel GM (June 2016). "What's in a name? The clinical features of facioscapulohumeral muscular dystrophy". Practical Neurology. 16 (3): 201–207. doi:10.1136/practneurol-2015-001353. PMID 26862222. S2CID 4481678.
  5. ^ a b Kumar, Vinay; Abbas, Abul; Aster, Jon, eds. (2018). Robbins Basic Pathology (Tenth ed.). Philadelphia, Pennsylvania: Elsevier. p. 844. ISBN 978-0-323-35317-5.
  6. ^ De Iaco, A; Planet, E; Coluccio, A; Verp, S; Duc, J; Trono, D (June 2017). "DUX-family transcription factors regulate zygotic genome activation in placental mammals". Nature Genetics. 49 (6): 941–945. doi:10.1038/ng.3858. PMC 5446900. PMID 28459456.
  7. ^ a b c Snider, L; Geng, LN; Lemmers, RJ; Kyba, M; Ware, CB; Nelson, AM; Tawil, R; Filippova, GN; van der Maarel, SM; Tapscott, SJ; Miller, DG (28 October 2010). "Facioscapulohumeral dystrophy: incomplete suppression of a retrotransposed gene". PLOS Genetics. 6 (10): e1001181. doi:10.1371/journal.pgen.1001181. PMC 2965761. PMID 21060811.
  8. ^ a b c d e f g h i j k Lemmers RJ, van der Vliet PJ, Klooster R, Sacconi S, Camaño P, Dauwerse JG, Snider L, Straasheijm KR, van Ommen GJ, Padberg GW, Miller DG, Tapscott SJ, Tawil R, Frants RR, van der Maarel SM (19 August 2010). (PDF). Science. 329 (5999): 1650–3. Bibcode:2010Sci...329.1650L. doi:10.1126/science.1189044. hdl:1887/117104. PMC 4677822. PMID 20724583. Archived from the original (PDF) on 2014-06-05.
  9. ^ Lemmers RJ, Wohlgemuth M, van der Gaag KJ, et al. (November 2007). "Specific sequence variations within the 4q35 region are associated with facioscapulohumeral muscular dystrophy". Am. J. Hum. Genet. 81 (5): 884–94. doi:10.1086/521986. PMC 2265642. PMID 17924332.
  10. ^ a b c d e f g h Mul, K (1 December 2022). "Facioscapulohumeral Muscular Dystrophy". Continuum (Minneapolis, Minn.). 28 (6): 1735–1751. doi:10.1212/CON.0000000000001155. PMID 36537978. S2CID 254883066.
  11. ^ a b Eren, İlker; Birsel, Olgar; Öztop Çakmak, Özgür; Aslanger, Ayça; Gürsoy Özdemir, Yasemin; Eraslan, Serpil; Kayserili, Hülya; Oflazer, Piraye; Demirhan, Mehmet (May 2020). "A novel shoulder disability staging system for scapulothoracic arthrodesis in patients with facioscapulohumeral dystrophy". Orthopaedics & Traumatology: Surgery & Research. 106 (4): 701–707. doi:10.1016/j.otsr.2020.03.002. PMID 32430271.
  12. ^ Theadom, A; Rodrigues, M; Roxburgh, R; Balalla, S; Higgins, C; Bhattacharjee, R; Jones, K; Krishnamurthi, R; Feigin, V (2014). "Prevalence of muscular dystrophies: a systematic literature review". Neuroepidemiology. 43 (3–4): 259–68. doi:10.1159/000369343. hdl:10292/13206. PMID 25532075. S2CID 2426923.
  13. ^ Mah, JK; Korngut, L; Fiest, KM; Dykeman, J; Day, LJ; Pringsheim, T; Jette, N (January 2016). "A Systematic Review and Meta-analysis on the Epidemiology of the Muscular Dystrophies". The Canadian Journal of Neurological Sciences. Le Journal Canadien des Sciences Neurologiques. 43 (1): 163–77. doi:10.1017/cjn.2015.311. PMID 26786644. S2CID 24936950.
  14. ^ a b c d e f g h i j k Tawil, R; Van Der Maarel, SM (July 2006). "Facioscapulohumeral muscular dystrophy" (PDF). Muscle & Nerve. 34 (1): 1–15. doi:10.1002/mus.20522. PMID 16508966. S2CID 43304086.
  15. ^ a b c d Statland, JM; Tawil, R (December 2016). "Facioscapulohumeral Muscular Dystrophy". Continuum (Minneapolis, Minn.). 22 (6, Muscle and Neuromuscular Junction Disorders): 1916–1931. doi:10.1212/CON.0000000000000399. PMC 5898965. PMID 27922500.
  16. ^ a b Cruveilhiers, J. (1852–1853). "Mémoire sur la paralysie musculaire atrophique". Bulletins de l'Académie de Médecine. 18: 490–502, 546–583.
  17. ^ a b c d Rogers, Mark T. (2004). "Facioscapulohumeral muscular dystrophy: historical background and literature review". In Upadhyaya, Meena; Cooper, David N. (eds.). FSHD facioscapulohumeral muscular dystrophy : clinical medicine and molecular cell biology. BIOS Scientific Publishers. ISBN 1-85996-244-0.
  18. ^ a b Landouzy, L.; Dejerine, J. (1885). Landouzy, L.; Lépine, R. (eds.). "De la myopathie atrophique progressive (myopathie sans neuropathie débutant d'ordinaire dans l'enfance par la face)". Revue de Médecine (in French). Felix Alcan. 5: 253–366. Retrieved 19 May 2020.
  19. ^ a b c Cohen, Justin; DeSimone, Alec; Lek, Monkol; Lek, Angela (October 2020). "Therapeutic Approaches in Facioscapulohumeral Muscular Dystrophy". Trends in Molecular Medicine. 27 (2): 123–137. doi:10.1016/j.molmed.2020.09.008. PMC 8048701. PMID 33092966.
  20. ^ a b Tupler, R; Barbierato, L; et al. (Sep 1998). "Identical de novo mutation at the D4F104S1 locus in monozygotic male twins affected by facioscapulohumeral muscular dystrophy (FSHD) with different clinical expression". Journal of Medical Genetics. 35 (9): 778–783. doi:10.1136/jmg.35.9.778. PMC 1051435. PMID 9733041.
  21. ^ Tawil, R; Storvick, D; Feasby, TE; Weiffenbach, B; Griggs, RC (February 1993). "Extreme variability of expression in monozygotic twins with FSH muscular dystrophy". Neurology. 43 (2): 345–8. doi:10.1212/wnl.43.2.345. PMID 8094896. S2CID 44422140.
  22. ^ Pandya, Shree; Eichinger, Kate. (PDF). FSHD Society. Archived from the original (PDF) on 14 April 2020. Retrieved 14 April 2020.
  23. ^ a b c d e Padberg, GW (1982-10-13). Facioscapulohumeral disease (Thesis). Leiden University.
  24. ^ a b c d e f g h i j k l Padberg, George W. (2004). "Facioscapulohumeral muscular dystrophy: a clinician's experience". In Upadhyaya, Meena; Cooper, David N. (eds.). FSHD Facioscapulohumeral Muscular Dystrophy: Clinical Medicine and Molecular Cell Biology. BIOS Scientific Publishers. ISBN 1-85996-244-0.
  25. ^ a b c Rijken, NH; van der Kooi, EL; Hendriks, JC; van Asseldonk, RJ; Padberg, GW; Geurts, AC; van Engelen, BG (December 2014). "Skeletal muscle imaging in facioscapulohumeral muscular dystrophy, pattern and asymmetry of individual muscle involvement". Neuromuscular Disorders. 24 (12): 1087–96. doi:10.1016/j.nmd.2014.05.012. PMID 25176503. S2CID 101093.
  26. ^ Bergsma, A; Cup, EH; Janssen, MM; Geurts, AC; de Groot, IJ (February 2017). "Upper limb function and activity in people with facioscapulohumeral muscular dystrophy: a web-based survey". Disability and Rehabilitation. 39 (3): 236–243. doi:10.3109/09638288.2016.1140834. PMID 26942834. S2CID 4237308.
  27. ^ a b c d e f g h i j k l m n Tawil, Rabi; van der Maarel, SM; Tapscott, SJ (10 June 2014). "Facioscapulohumeral dystrophy: the path to consensus on pathophysiology". Skeletal Muscle. 4 (1): 12. doi:10.1186/2044-5040-4-12. PMC 4060068. PMID 24940479.
  28. ^ Jia, FF; Drew, AP; Nicholson, GA; Corbett, A; Kumar, KR (2 October 2021). "Facioscapulohumeral muscular dystrophy type 2: an update on the clinical, genetic, and molecular findings". Neuromuscular Disorders. 31 (11): 1101–1112. doi:10.1016/j.nmd.2021.09.010. PMID 34711481. S2CID 238246093.
  29. ^ a b Upadhyaya, Meena; Cooper, David, eds. (March 2004). FSHD Facioscapulohumeral Muscular Dystrophy : Clinical Medicine and Molecular Cell Biology. BIOS Scientific Publishers. ISBN 0203483677.
  30. ^ a b The FDA held an externally-led Patient-Focused Drug Development meeting with about 400 FSHD patients on June 29, 2020, resulting in a seminal document called the "Voice of the Patient Report." The report captures the impact of FSHD on the daily lives of those with the disease as conveyed by the patients themselves. While FSHD is often perceived to be "mild," the report shows that over 80% of patients report being "moderately" or "severely" limited in daily activities.
    • Society, FSHD. "FSHD Society releases Voice of the Patient Report on FSH muscular dystrophy". www.prweb.com. Retrieved 2024-01-31.
  31. ^ a b Society, FSHD. "Facioscapulohumeral muscular dystrophy community speaks to the FDA". www.prweb.com. Retrieved 2024-01-31.
  32. ^ a b Voice of the Patient Forum - Patient-Focused Drug Development Meeting, retrieved 2024-01-31
  33. ^ a b Overman, Debbie (2020-11-13). "People Living with FSHD Tell Their Stories in New Report". Rehab Management. Retrieved 2024-01-31.
  34. ^ a b Mul, K; Berggren, KN; Sills, MY; McCalley, A; van Engelen, BGM; Johnson, NE; Statland, JM (26 February 2019). "Effects of weakness of orofacial muscles on swallowing and communication in FSHD". Neurology. 92 (9): e957–e963. doi:10.1212/WNL.0000000000007013. PMC 6404471. PMID 30804066.
  35. ^ Wohlgemuth, M; de Swart, BJ; Kalf, JG; Joosten, FB; Van der Vliet, AM; Padberg, GW (27 June 2006). "Dysphagia in facioscapulohumeral muscular dystrophy". Neurology. 66 (12): 1926–8. doi:10.1212/01.wnl.0000219760.76441.f8. PMID 16801662. S2CID 7695047.
  36. ^ a b . FSHD Society. Way Back Machine. 30 September 2020. Archived from the original on 24 October 2020. Retrieved 11 March 2021. Another striking aspect of FSHD is that muscles weakness seems to vary so much from patient to patient. Nonetheless, "there is a highly characteristic pattern of muscle weakness, otherwise we would never have been able to recognize FSHD as a specific disease," Padberg said. "Strong deltoid muscle does not occur in any other condition that involves weakness of scapular stabilizers. No other muscle disease with shoulder girdle involvement has this pattern." Unfortunately, "an explanation is beyond our grasp as we don't know how muscle are laid down" during the early stages of human gestation.
  37. ^ a b c Tasca, G; Monforte, M; Iannaccone, E; Laschena, F; Ottaviani, P; Leoncini, E; Boccia, S; Galluzzi, G; Pelliccioni, M; Masciullo, M; Frusciante, R; Mercuri, E; Ricci, E (2014). "Upper girdle imaging in facioscapulohumeral muscular dystrophy". PLOS ONE. 9 (6): e100292. Bibcode:2014PLoSO...9j0292T. doi:10.1371/journal.pone.0100292. PMC 4059711. PMID 24932477.
  38. ^ a b c Gerevini, S; Scarlato, M; Maggi, L; Cava, M; Caliendo, G; Pasanisi, B; Falini, A; Previtali, SC; Morandi, L (March 2016). "Muscle MRI findings in facioscapulohumeral muscular dystrophy". European Radiology. 26 (3): 693–705. doi:10.1007/s00330-015-3890-1. PMID 26115655. S2CID 24650482.
  39. ^ Faux-Nightingale, Alice; Kulshrestha, Richa; Emery, Nicholas; Pandyan, Anand; Willis, Tracey; Philp, Fraser (September 2021). "Upper limb rehabilitation in fascioscapularhumeral dystrophy (FSHD): a patients' perspective". Archives of Rehabilitation Research and Clinical Translation. 3 (4): 100157. doi:10.1016/j.arrct.2021.100157. ISSN 2590-1095. PMC 8683863. PMID 34977539.
  40. ^ Pandya, Shree; King, Wendy M; Tawil, Rabi (1 January 2008). "Facioscapulohumeral Dystrophy". Physical Therapy. 88 (1): 105–113. doi:10.2522/ptj.20070104. PMID 17986494.
  41. ^ Liew, Wendy K.M.; van der Maarel, Silvère M.; Tawil, Rabi (2015). "Facioscapulohumeral Dystrophy". Neuromuscular Disorders of Infancy, Childhood, and Adolescence. pp. 620–630. doi:10.1016/B978-0-12-417044-5.00032-9. ISBN 9780124170445.
  42. ^ a b c d e f Goselink, RJM; Schreur, V; van Kernebeek, CR; Padberg, GW; van der Maarel, SM; van Engelen, BGM; Erasmus, CE; Theelen, T (2019). "Ophthalmological findings in facioscapulohumeral dystrophy". Brain Communications. 1 (1): fcz023. doi:10.1093/braincomms/fcz023. PMC 7425335. PMID 32954265.
  43. ^ Padberg, G. W.; Brouwer, O. F.; de Keizer, R. J. W.; Dijkman, G.; Wijmenga, C.; Grote, J. J.; Frants, R. R. (1995). "On the significance of retinal vascular disease and hearing loss in facioscapulohumeral muscular dystrophy". Muscle & Nerve. 18 (S13): S73–S80. doi:10.1002/mus.880181314. hdl:2066/20764. S2CID 27523889.
  44. ^ Lindner, Moritz; Holz, Frank G; Charbel Issa, Peter (2016-04-27). "Spontaneous resolution of retinal vascular abnormalities and macular oedema in facioscapulohumeral muscular dystrophy". Clinical & Experimental Ophthalmology. 44 (7): 627–628. doi:10.1111/ceo.12735. ISSN 1442-6404. PMID 26933772. S2CID 204996841.
  45. ^ Trevisan, CP; Pastorello, E; Tomelleri, G; Vercelli, L; Bruno, C; Scapolan, S; Siciliano, G; Comacchio, F (December 2008). "Facioscapulohumeral muscular dystrophy: hearing loss and other atypical features of patients with large 4q35 deletions". European Journal of Neurology. 15 (12): 1353–8. doi:10.1111/j.1468-1331.2008.02314.x. PMID 19049553. S2CID 26276887.
  46. ^ a b Eren, İ; Abay, B; Günerbüyük, C; Çakmak, ÖÖ; Şar, C; Demirhan, M (February 2020). "Spinal fusion in facioscapulohumeral dystrophy for hyperlordosis: A case report". Medicine. 99 (8): e18787. doi:10.1097/MD.0000000000018787. PMC 7034682. PMID 32080072.
  47. ^ Huml, Raymond A.; Perez, Daniel P. (2015). "FSHD: The Most Common Type of Muscular Dystrophy?". Muscular Dystrophy. pp. 9–19. doi:10.1007/978-3-319-17362-7_3. ISBN 978-3-319-17361-0.
  48. ^ Wohlgemuth M, van der Kooi EL, van Kesteren RG, van der Maarel SM, Padberg GW (2004). "Ventilatory support in facioscapulohumeral muscular dystrophy". Neurology. 63 (1): 176–8. CiteSeerX 10.1.1.543.2968. doi:10.1212/01.wnl.0000133126.86377.e8. PMID 15249635. S2CID 31335126.
  49. ^ Dowling, JJ; Weihl, CC; Spencer, MJ (November 2021). "Molecular and cellular basis of genetically inherited skeletal muscle disorders". Nature Reviews. Molecular Cell Biology. 22 (11): 713–732. doi:10.1038/s41580-021-00389-z. PMC 9686310. PMID 34257452. S2CID 235822532.
  50. ^ a b c d e f g Lemmers, Richard J.L.F.; O'Shea, Suzanne; Padberg, George W.; Lunt, Peter W.; van der Maarel, Silvère M. (May 2012). "Best practice guidelines on genetic diagnostics of Facioscapulohumeral muscular dystrophy: Workshop 9th June 2010, LUMC, Leiden, The Netherlands". Neuromuscular Disorders. 22 (5): 463–470. doi:10.1016/j.nmd.2011.09.004. PMID 22177830. S2CID 39898514.
  51. ^ The name "D4Z4" is derived from an obsolete nomenclature system used for DNA segments of unknown significance during the human genome project: D for DNA, 4 for chromosome 4, Z indicates it is a repetitive sequence, and 4 is a serial number assigned based on the order of submission.
    • White, J.A.; McAlpine, P.J.; Antonarakis, S.; Cann, H.; Eppig, J.T.; Frazer, K.; Frezal, J.; Lancet, D.; Nahmias, J.; Pearson, P.; Peters, J.; Scott, A.; Scott, H.; Spurr, N.; Talbot, C.; Povey, S. (October 1997). "NOMENCLATURE". Genomics. 45 (2): 468–471. doi:10.1006/geno.1997.4979. PMID 9344684.
    • Fasman, KH; Letovsky, SI; Cottingham, RW; Kingsbury, DT (1 January 1996). "Improvements to the GDB Human Genome Data Base". Nucleic Acids Research. 24 (1): 57–63. doi:10.1093/nar/24.1.57. PMC 145602. PMID 8594601.
  52. ^ a b c d , Margaret Wahl, MDA, Quest magazine, Vol 14, No 2, March–April 2007
  53. ^ Dixit M, Ansseau E, Tassin A, et al. (November 2007). "DUX4, a candidate gene of facioscapulohumeral muscular dystrophy, encodes a transcriptional activator of PITX1". Proc. Natl. Acad. Sci. U.S.A. 104 (46): 18157–62. Bibcode:2007PNAS..10418157D. doi:10.1073/pnas.0708659104. PMC 2084313. PMID 17984056.
  54. ^ a b c d e f Šikrová, D; Testa, AM; Willemsen, I; van den Heuvel, A; Tapscott, SJ; Daxinger, L; Balog, J; van der Maarel, SM (28 June 2023). "SMCHD1 and LRIF1 converge at the FSHD-associated D4Z4 repeat and LRIF1 promoter yet display different modes of action". Communications Biology. 6 (1): 677. doi:10.1038/s42003-023-05053-0. PMC 10307901. PMID 37380887.
  55. ^ Coppée, Frédérique; Mattéotti, Christel; Anssaeu, Eugénie; Sauvage, Sébastien; Leclercq, India; Leroy, Axelle; Marcowycz, Aline; Gerbaux, Cécile; Figlewicz, Denise; Ding, Hao; Belayew, Belayew (2004). "The DUX gene family and FSHD". In Upadhyaya, Meena; Cooper, David N. (eds.). FSHD facioscapulohumeral muscular dystrophy : clinical medicine and molecular cell biology. BIOS Scientific Publishers. ISBN 1-85996-244-0.
  56. ^ Rossi M, Ricci E, Colantoni L, et al. (2007). "The Facioscapulohumeral muscular dystrophy region on 4qter and the homologous locus on 10qter evolved independently under different evolutionary pressure". BMC Med. Genet. 8: 8. doi:10.1186/1471-2350-8-8. PMC 1821008. PMID 17335567.
  57. ^ Lemmers, RJLF; van der Vliet, PJ; Blatnik, A; Balog, J; Zidar, J; Henderson, D; Goselink, R; Tapscott, SJ; Voermans, NC; Tawil, R; Padberg, GWAM; van Engelen, BG; van der Maarel, SM (12 January 2021). "Chromosome 10q-linked FSHD identifies DUX4 as principal disease gene". Journal of Medical Genetics. 59 (2): jmedgenet-2020-107041. doi:10.1136/jmedgenet-2020-107041. PMC 8273184. PMID 33436523. S2CID 231589589.
  58. ^ Himeda, CL; Jones, PL (31 August 2019). "The Genetics and Epigenetics of Facioscapulohumeral Muscular Dystrophy". Annual Review of Genomics and Human Genetics. 20: 265–291. doi:10.1146/annurev-genom-083118-014933. PMID 31018108. S2CID 131775712.
  59. ^ a b Cabianca, DS; Casa, Casa; Bodega, B; et al. (May 11, 2012). "A long ncRNA links copy number variation to a polycomb/trithorax epigenetic switch in FSHD muscular dystrophy". Cell. 149 (4): 819–831. doi:10.1016/j.cell.2012.03.035. PMC 3350859. PMID 22541069.
  60. ^ a b c d e f Sacconi, S; Briand-Suleau, A; Gros, M; Baudoin, C; Lemmers, RJLF; Rondeau, S; Lagha, N; Nigumann, P; Cambieri, C; Puma, A; Chapon, F; Stojkovic, T; Vial, C; Bouhour, F; Cao, M; Pegoraro, E; Petiot, P; Behin, A; Marc, B; Eymard, B; Echaniz-Laguna, A; Laforet, P; Salviati, L; Jeanpierre, M; Cristofari, G; van der Maarel, SM (7 May 2019). "FSHD1 and FSHD2 form a disease continuum". Neurology. 92 (19): e2273–e2285. doi:10.1212/WNL.0000000000007456. PMC 6537132. PMID 30979860.
  61. ^ Tupler, R; Berardinelli, A; Barbierato, L; Frants, R; Hewitt, JE; Lanzi, G; Maraschio, P; Tiepolo, L (May 1996). "Monosomy of distal 4q does not cause facioscapulohumeral muscular dystrophy". Journal of Medical Genetics. 33 (5): 366–70. doi:10.1136/jmg.33.5.366. PMC 1050603. PMID 8733044.
  62. ^ Tawil, R; Forrester, J; Griggs, RC; Mendell, J; Kissel, J; McDermott, M; King, W; Weiffenbach, B; Figlewicz, D (June 1996). "Evidence for anticipation and association of deletion size with severity in facioscapulohumeral muscular dystrophy. The FSH-DY Group". Annals of Neurology. 39 (6): 744–8. doi:10.1002/ana.410390610. PMID 8651646. S2CID 84518968.
  63. ^ Zernov, N; Skoblov, M (13 March 2019). "Genotype-phenotype correlations in FSHD". BMC Medical Genomics. 12 (Suppl 2): 43. doi:10.1186/s12920-019-0488-5. PMC 6416831. PMID 30871534.
  64. ^ Sacconi, S; Salviati, L; Desnuelle, C (April 2015). "Facioscapulohumeral muscular dystrophy". Biochimica et Biophysica Acta (BBA) - Molecular Basis of Disease. 1852 (4): 607–14. doi:10.1016/j.bbadis.2014.05.021. PMID 24882751.
  65. ^ a b c Lemmers, RJ; Tawil, R; Petek, LM; et al. (Dec 2012). "Digenic inheritance of an SMCHD1 mutation and an FSHD-permissive D4Z4 allele causes facioscapulohumeral muscular dystrophy type 2". Nature Genetics. 44 (12): 1370–1374. doi:10.1038/ng.2454. PMC 3671095. PMID 23143600.
  66. ^ van den Boogaard, ML; Lemmers, RJLF; Balog, J; Wohlgemuth, M; Auranen, M; Mitsuhashi, S; van der Vliet, PJ; Straasheijm, KR; van den Akker, RFP; Kriek, M; Laurense-Bik, MEY; Raz, V; van Ostaijen-Ten Dam, MM; Hansson, KBM; van der Kooi, EL; Kiuru-Enari, S; Udd, B; van Tol, MJD; Nishino, I; Tawil, R; Tapscott, SJ; van Engelen, BGM; van der Maarel, SM (5 May 2016). "Mutations in DNMT3B Modify Epigenetic Repression of the D4Z4 Repeat and the Penetrance of Facioscapulohumeral Dystrophy". American Journal of Human Genetics. 98 (5): 1020–1029. doi:10.1016/j.ajhg.2016.03.013. PMC 4863565. PMID 27153398.
  67. ^ a b Johnson, NE; Statland, JM (7 May 2019). "FSHD1 or FSHD2: That is the question: The answer: It's all just FSHD". Neurology. 92 (19): 881–882. doi:10.1212/WNL.0000000000007446. PMID 30979855. S2CID 111390628.
  68. ^ a b c Hamanaka, Kohei; Šikrová, Darina; Mitsuhashi, Satomi; Masuda, Hiroki; Sekiguchi, Yukari; Sugiyama, Atsuhiko; Shibuya, Kazumoto; Lemmers, Richard J.L.F.; Goossens, Remko; Ogawa, Megumu; Nagao, Koji; Obuse, Chikashi; Noguchi, Satoru; Hayashi, Yukiko K.; Kuwabara, Satoshi; Balog, Judit; Nishino, Ichizo; van der Maarel, Silvère M. (28 May 2020). "Homozygous nonsense variant in associated with facioscapulohumeral muscular dystrophy". Neurology. 94 (23): e2441–e2447. doi:10.1212/WNL.0000000000009617. PMC 7455367. PMID 32467133. S2CID 218982743.
  69. ^ a b Caputo, V; Megalizzi, D; Fabrizio, C; Termine, A; Colantoni, L; Caltagirone, C; Giardina, E; Cascella, R; Strafella, C (29 August 2022). "Update on the Molecular Aspects and Methods Underlying the Complex Architecture of FSHD". Cells. 11 (17): 2687. doi:10.3390/cells11172687. PMC 9454908. PMID 36078093.
  70. ^ a b c Sacconi, S; Lemmers, RJ; Balog, J; et al. (Oct 3, 2013). "The FSHD2 gene SMCHD1 is a modifier of disease severity in families affected by FSHD1". The American Journal of Human Genetics. 93 (4): 744–751. doi:10.1016/j.ajhg.2013.08.004. PMC 3791262. PMID 24075187.
  71. ^ a b Lim, KRQ; Nguyen, Q; Yokota, T (22 January 2020). "DUX4 Signalling in the Pathogenesis of Facioscapulohumeral Muscular Dystrophy". International Journal of Molecular Sciences. 21 (3): 729. doi:10.3390/ijms21030729. PMC 7037115. PMID 31979100.
  72. ^ a b Bosnakovski, Darko; Shams, Ahmed S.; Yuan, Ce; da Silva, Meiricris T.; Ener, Elizabeth T.; Baumann, Cory W.; Lindsay, Angus J.; Verma, Mayank; Asakura, Atsushi; Lowe, Dawn A.; Kyba, Michael (6 April 2020). "Transcriptional and cytopathological hallmarks of FSHD in chronic DUX4-expressing mice". Journal of Clinical Investigation. 130 (5): 2465–2477. doi:10.1172/JCI133303. PMC 7190912. PMID 32250341.
  73. ^ Mocciaro, Emanuele; Runfola, Valeria; Ghezzi, Paola; Pannese, Maria; Gabellini, Davide (26 November 2021). "DUX4 Role in Normal Physiology and in FSHD Muscular Dystrophy". Cells. 10 (12): 3322. doi:10.3390/cells10123322. PMC 8699294. PMID 34943834.
  74. ^ a b Schätzl, T; Kaiser, L; Deigner, HP (12 March 2021). "Facioscapulohumeral muscular dystrophy: genetics, gene activation and downstream signalling with regard to recent therapeutic approaches: an update". Orphanet Journal of Rare Diseases. 16 (1): 129. doi:10.1186/s13023-021-01760-1. PMC 7953708. PMID 33712050. S2CID 232202360.
  75. ^ Lek, Angela; Zhang, Yuanfan; Woodman, Keryn G.; Huang, Shushu; DeSimone, Alec M.; Cohen, Justin; Ho, Vincent; Conner, James; Mead, Lillian; Kodani, Andrew; Pakula, Anna; Sanjana, Neville; King, Oliver D.; Jones, Peter L.; Wagner, Kathryn R.; Lek, Monkol; Kunkel, Louis M. (25 March 2020). "Applying genome-wide CRISPR-Cas9 screens for therapeutic discovery in facioscapulohumeral muscular dystrophy". Science Translational Medicine. 12 (536): eaay0271. doi:10.1126/scitranslmed.aay0271. PMC 7304480. PMID 32213627.
  76. ^ Mariot, Virginie; Joubert, Romain; Le Gall, Laura; Sidlauskaite, Eva; Hourde, Christophe; Duddy, William; Voit, Thomas; Bencze, Maximilien; Dumonceaux, Julie (22 October 2021). "RIPK3-mediated cell death is involved in DUX4-mediated toxicity in facioscapulohumeral dystrophy". Journal of Cachexia, Sarcopenia and Muscle. 12 (6): 2079–2090. doi:10.1002/jcsm.12813. PMC 8718031. PMID 34687171. S2CID 239471655.
  77. ^ Wang, LH; Friedman, SD; Shaw, D; Snider, L; Wong, CJ; Budech, CB; Poliachik, SL; Gove, NE; Lewis, LM; Campbell, AE; Lemmers, RJFL; Maarel, SM; Tapscott, SJ; Tawil, RN (2019-02-01). "MRI-informed muscle biopsies correlate MRI with pathology and DUX4 target gene expression in FSHD". Human Molecular Genetics. 28 (3): 476–486. doi:10.1093/hmg/ddy364. PMC 6337697. PMID 30312408.
  78. ^ Gherardi, Romain; Amato, Anthony A.; Lidov, Hart G.; Girolami, Umberto De (Nov 2018). "Pathology of Skeletal Muscle". In Gray, Francoise; Duyckaerts, Charles; Girolami, Umberto de (eds.). Escourolle and Poirier's manual of basic neuropathology (Sixth ed.). New York, NY: Oxford University Press. doi:10.1093/med/9780190675011.001.0001. ISBN 9780190675011.
  79. ^ van der Maarel, SM; Miller, DG; Tawil, R; Filippova, GN; Tapscott, SJ (October 2012). "Facioscapulohumeral muscular dystrophy: consequences of chromatin relaxation". Current Opinion in Neurology. 25 (5): 614–20. doi:10.1097/WCO.0b013e328357f22d. PMC 3653067. PMID 22892954.
  80. ^ a b c Mair, D; Huegens-Penzel, M; Kress, W; Roth, C; Ferbert, A (2017). "Leg Muscle Involvement in Facioscapulohumeral Muscular Dystrophy: Comparison between Facioscapulohumeral Muscular Dystrophy Types 1 and 2". European Neurology. 77 (1–2): 32–39. doi:10.1159/000452763. PMID 27855411. S2CID 25005883.
  81. ^ a b c Olsen, DB; Gideon, P; Jeppesen, TD; Vissing, J (November 2006). "Leg muscle involvement in facioscapulohumeral muscular dystrophy assessed by MRI". Journal of Neurology. 253 (11): 1437–41. doi:10.1007/s00415-006-0230-z. PMID 16773269. S2CID 19421344.
  82. ^ Sacconi, S; Salviati, L; Bourget, I; Figarella, D; Péréon, Y; Lemmers, R; van der Maarel, S; Desnuelle, C (2006-10-24). "Diagnostic challenges in facioscapulohumeral muscular dystrophy". Neurology. 67 (8): 1464–6. doi:10.1212/01.wnl.0000240071.62540.6f. hdl:11577/1565214. PMID 17060574. S2CID 25693278.
  83. ^ Strafella, Claudia; Caputo, Valerio; Galota, Rosaria Maria; Campoli, Giulia; Bax, Cristina; Colantoni, Luca; Minozzi, Giulietta; Orsini, Chiara; Politano, Luisa; Tasca, Giorgio; Novelli, Giuseppe; Ricci, Enzo; Giardina, Emiliano; Cascella, Raffaella (1 December 2019). "The variability of SMCHD1 gene in FSHD patients: evidence of new mutations". Human Molecular Genetics. 28 (23): 3912–3920. doi:10.1093/hmg/ddz239. PMC 6969370. PMID 31600781.
  84. ^ Zampatti, S; Colantoni, L; Strafella, C; Galota, RM; Caputo, V; Campoli, G; Pagliaroli, G; Carboni, S; Mela, J; Peconi, C; Gambardella, S; Cascella, R; Giardina, E (May 2019). "Facioscapulohumeral muscular dystrophy (FSHD) molecular diagnosis: from traditional technology to the NGS era". Neurogenetics. 20 (2): 57–64. doi:10.1007/s10048-019-00575-4. PMID 30911870. S2CID 85495566.
  85. ^ Kinoshita, June (11 March 2020). . FSHD Society. Archived from the original on 8 April 2020. Retrieved 8 April 2020.
  86. ^ Vasale, J; Boyar, F; Jocson, M; Sulcova, V; Chan, P; Liaquat, K; Hoffman, C; Meservey, M; Chang, I; Tsao, D; Hensley, K; Liu, Y; Owen, R; Braastad, C; Sun, W; Walrafen, P; Komatsu, J; Wang, JC; Bensimon, A; Anguiano, A; Jaremko, M; Wang, Z; Batish, S; Strom, C; Higgins, J (December 2015). "Molecular combing compared to Southern blot for measuring D4Z4 contractions in FSHD". Neuromuscular Disorders. 25 (12): 945–51. doi:10.1016/j.nmd.2015.08.008. PMID 26420234. S2CID 6871094.
  87. ^ a b c d Gould, T; Jones, TI; Jones, PL (13 August 2021). "Precise Epigenetic Analysis Using Targeted Bisulfite Genomic Sequencing Distinguishes FSHD1, FSHD2, and Healthy Subjects". Diagnostics (Basel, Switzerland). 11 (8): 1469. doi:10.3390/diagnostics11081469. PMC 8393475. PMID 34441403.
  88. ^ a b van Deutekom, JC; Wijmenga, C; van Tienhoven, EA; et al. (Dec 1993). "FSHD associated DNA rearrangements are due to deletions of integral copies of a 3.2 kb tandemly repeated unit". Human Molecular Genetics. 2 (12): 2037–2042. doi:10.1093/hmg/2.12.2037. PMID 8111371.
  89. ^ a b Wijmenga, C; Hewitt, JE; Sandkuijl, LA; et al. (Sep 1992). "Chromosome 4q DNA rearrangements associated with facioscapulohumeral muscular dystrophy". Nature Genetics. 2 (1): 26–30. doi:10.1038/ng0992-26. PMID 1363881. S2CID 21940164.
  90. ^ Frants, Rune R.; Sandkuijl, Lodewijk A.; van der Maarel, Silvere M.; Padberg, George W. (2004). "Mapping of the FSHD gene and the discovery of the pathognomonic deletion". In Upadhyaya, Meena; Cooper, David N. (eds.). FSHD Facioscapulohumeral Muscular Dystrophy: Clinical Medicine and Molecular Cell Biology. BIOS Scientific Publishers. ISBN 1-85996-244-0.
  91. ^ Lemmers, Richard J L F; Vliet, Patrick J; Granado, David San Leon; Stoep, Nienke; Buermans, Henk; Schendel, Robin; Schimmel, Joost; Visser, Marianne; Coster, Rudy; Jeanpierre, Marc; Laforet, Pascal; Upadhyaya, Meena; Engelen, Baziel; Sacconi, Sabrina; Tawil, Rabi; Voermans, Nicol C; Rogers, Mark; van der Maarel, Silvère M (24 September 2021). "High resolution breakpoint junction mapping of proximally extended D4Z4 deletions in FSHD1 reveals evidence for a founder effect". Human Molecular Genetics. 31 (5): 748–760. doi:10.1093/hmg/ddab250. PMC 8895739. PMID 34559225.
  92. ^ Gaillard, MC; Roche, S; Dion, C; Tasmadjian, A; Bouget, G; Salort-Campana, E; Vovan, C; Chaix, C; Broucqsault, N; Morere, J; Puppo, F; Bartoli, M; Levy, N; Bernard, R; Attarian, S; Nguyen, K; Magdinier, F (19 August 2014). "Differential DNA methylation of the D4Z4 repeat in patients with FSHD and asymptomatic carriers" (PDF). Neurology. 83 (8): 733–42. doi:10.1212/WNL.0000000000000708. PMID 25031281. S2CID 10002229.
  93. ^ FSHD Fact Sheet 2006-03-06 at the Wayback Machine, MDA, 11/1/2001
  94. ^ a b Preston, MK; Tawil, R; Wang, LH; Adam, MP; Ardinger, HH; Pagon, RA; Wallace, SE; Bean, LJH; Mirzaa, G; Amemiya, A (1993). "Facioscapulohumeral Muscular Dystrophy". PMID 20301616. {{cite journal}}: Cite journal requires |journal= (help)
  95. ^ a b c d e f g h Tawil, R; Kissel, JT; Heatwole, C; Pandya, S; Gronseth, G; Benatar, M; Guideline Development, Dissemination, and Implementation Subcommittee of the American Academy of, Neurology.; Practice Issues Review Panel of the American Association of Neuromuscular & Electrodiagnostic, Medicine. (28 July 2015). "Evidence-based guideline summary: Evaluation, diagnosis, and management of facioscapulohumeral muscular dystrophy: Report of the Guideline Development, Dissemination, and Implementation Subcommittee of the American Academy of Neurology and the Practice Issues Review Panel of the American Association of Neuromuscular & Electrodiagnostic Medicine". Neurology. 85 (4): 357–64. doi:10.1212/WNL.0000000000001783. PMC 4520817. PMID 26215877.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  96. ^ a b c Tawil, R; van der Maarel, S; Padberg, GW; van Engelen, BG (July 2010). "171st ENMC international workshop: Standards of care and management of facioscapulohumeral muscular dystrophy". Neuromuscular Disorders. 20 (7): 471–5. doi:10.1016/j.nmd.2010.04.007. PMID 20554202. S2CID 18448196.
  97. ^ a b Voet, N; Bleijenberg, G; Hendriks, J; de Groot, I; Padberg, G; van Engelen, B; Geurts, A (18 November 2014). "Both aerobic exercise and cognitive-behavioral therapy reduce chronic fatigue in FSHD: an RCT". Neurology. 83 (21): 1914–22. doi:10.1212/WNL.0000000000001008. PMID 25339206. S2CID 25382403.
  98. ^ a b Janssen, B; Voet, N; Geurts, A; van Engelen, B; Heerschap, A (3 May 2016). "Quantitative MRI reveals decelerated fatty infiltration in muscles of active FSHD patients". Neurology. 86 (18): 1700–7. doi:10.1212/WNL.0000000000002640. PMID 27037227. S2CID 11617226.
  99. ^ Voet, Nicoline Bm; van der Kooi, Elly L.; van Engelen, Baziel Gm; Geurts, Alexander Ch (6 December 2019). "Strength training and aerobic exercise training for muscle disease". The Cochrane Database of Systematic Reviews. 2019 (12): CD003907. doi:10.1002/14651858.CD003907.pub5. ISSN 1469-493X. PMC 6953420. PMID 31808555.
  100. ^ a b Tawil, R; Mah, JK; Baker, S; Wagner, KR; Ryan, MM; Sydney Workshop, Participants. (July 2016). "Clinical practice considerations in facioscapulohumeral muscular dystrophy Sydney, Australia, 21 September 2015". Neuromuscular Disorders. 26 (7): 462–71. doi:10.1016/j.nmd.2016.03.007. PMID 27185458.
  101. ^ . www.urmc.rochester.edu. Archived from the original on 14 November 2019. Retrieved 14 April 2020.
  102. ^ Aprile, I; Bordieri, C; Gilardi, A; Lainieri Milazzo, M; Russo, G; De Santis, F; Frusciante, R; Iannaccone, E; Erra, C; Ricci, E; Padua, L (April 2013). "Balance and walking involvement in facioscapulohumeral dystrophy: a pilot study on the effects of custom lower limb orthoses". European Journal of Physical and Rehabilitation Medicine. 49 (2): 169–78. PMID 23138679.
  103. ^ a b c d e Orrell, Richard W; Copeland, Stephen; Rose, Michael R (20 January 2010). "Scapular fixation in muscular dystrophy". Cochrane Database of Systematic Reviews. 2010 (1): CD003278. doi:10.1002/14651858.CD003278.pub2. PMC 7144827. PMID 20091543.
  104. ^ Demirhan, Mehmet; Uysal, Ozgur; Atalar, Ata Can; Kilicoglu, Onder; Serdaroglu, Piraye (31 March 2009). "Scapulothoracic Arthrodesis in Facioscapulohumeral Dystrophy with Multifilament Cable". Clinical Orthopaedics and Related Research. 467 (8): 2090–2097. doi:10.1007/s11999-009-0815-9. PMC 2706357. PMID 19333668.
  105. ^ DeFranco, Michael J.; Nho, Shane; Romeo, Anthony A. (April 2010). "Scapulothoracic Fusion". Journal of the American Academy of Orthopaedic Surgeons. 18 (4): 236–42. doi:10.5435/00124635-201004000-00006. PMID 20357232. S2CID 27456684.
  106. ^ Heller, KD; Prescher, A; Forst, J; Stadtmüller, A; Forst, R (1996). "Anatomo-experimental study for lace fixation of winged scapula in muscular dystrophy". Surgical and Radiologic Anatomy. 18 (2): 75–9. doi:10.1007/BF01795222. PMID 8782311. S2CID 20162712.
  107. ^ Abrams, Jeffrey S.; Bell, Robert H.; Tokish, John M. (2018). ADVANCED RECONSTRUCTION OF SHOULDER. AMER ACAD OF ORTHOPAEDIC. ISBN 9781975123475.
  108. ^ a b Upadhyaya, Meena; Cooper, David N. (2004). "Introduction and overview of FSHD". In Upadhyaya, Meena; Cooper, David N. (eds.). FSHD Facioscapulohumeral Muscular Dystrophy: Clinical Medicine and Molecular Cell Biology. BIOS Scientific Publishers. ISBN 1-85996-244-0.
  109. ^ Sansone, V; Boynton, J; Palenski, C (June 1997). "Use of gold weights to correct lagophthalmos in neuromuscular disease". Neurology. 48 (6): 1500–3. doi:10.1212/wnl.48.6.1500. hdl:2434/210652. PMID 9191754. S2CID 16251273.
  110. ^ Matsumoto, M; Onoda, S; Uehara, H; Miura, Y; Katayama, Y; Kimata, Y (September 2016). "Correction of the Lower Lip With a Cartilage Graft and Lip Resection in Patients With Facioscapulohumeral Muscular Dystrophy". The Journal of Craniofacial Surgery. 27 (6): 1427–9. doi:10.1097/SCS.0000000000002720. PMID 27300465. S2CID 16343571.
  111. ^ Krishnamurthy, S; Ibrahim, M (January 2019). "Tendon Transfers in Foot Drop". Indian Journal of Plastic Surgery. 52 (1): 100–108. doi:10.1055/s-0039-1688105. PMC 6664842. PMID 31456618.
  112. ^ Chiodo, Chris; Bluman, Eric M. (2011-10-21). Tendon transfers in the foot and ankle. Saunders. p. 421. ISBN 9781455709243. Retrieved 1 January 2020.
  113. ^ Lunt, Peter; Upadhyaya, Meena; Koch, Manuela C. (2004). "Genotype-phenotype relationships in FSHD". In Upadhyaya, Meena; Cooper, David N. (eds.). FSHD Facioscapulohumeral Muscular Dystrophy: Clinical Medidne and Molecular Cell Biology. BIOS Scientific Publishers Limited. p. 157.
  114. ^ Vincenten, Sanne C.C.; Mul, Karlien; Schreuder, Tim H.A.; Voermans, Nicol C.; Horlings, Corinne G.C.; van Engelen, Baziel G.M. (July 2021). "nnExploring the influence of smoking and alcohol consumption on clinical severity in patients with facioscapulohumeral muscular dystrophy". Neuromuscular Disorders. 31 (9): 824–828. doi:10.1016/j.nmd.2021.07.005. hdl:2066/239258. ISSN 0960-8966. PMID 34407911.
  115. ^ a b c Massey, JM; Gable, KL (1 February 2022). "Neuromuscular Disorders and Pregnancy". Continuum (Minneapolis, Minn.). 28 (1): 55–71. doi:10.1212/CON.0000000000001069. PMID 35133311. S2CID 246651681.
  116. ^ a b c Deenen JC, Arnts H, van der Maarel SM, Padberg GW, Verschuuren JJ, Bakker E, Weinreich SS, Verbeek AL, van Engelen BG (2014). "Population-based incidence and prevalence of facioscapulohumeral dystrophy". Neurology. 83 (12): 1056–9. doi:10.1212/WNL.0000000000000797. PMC 4166358. PMID 25122204.
  117. ^ Deenen, JC; Horlings, CG; Verschuuren, JJ; Verbeek, AL; van Engelen, BG (2015). "The Epidemiology of Neuromuscular Disorders: A Comprehensive Overview of the Literature". Journal of Neuromuscular Diseases. 2 (1): 73–85. doi:10.3233/JND-140045. PMID 28198707.
  118. ^ Teveroni, E; Pellegrino, M; Sacconi, S; Calandra, P; Cascino, I; Farioli-Vecchioli, S; Puma, A; Garibaldi, M; Morosetti, R; Tasca, G; Ricci, E; Trevisan, CP; Galluzzi, G; Pontecorvi, A; Crescenzi, M; Deidda, G; Moretti, F (3 April 2017). "Estrogens enhance myoblast differentiation in facioscapulohumeral muscular dystrophy by antagonizing DUX4 activity". The Journal of Clinical Investigation. 127 (4): 1531–1545. doi:10.1172/JCI89401. PMC 5373881. PMID 28263188.
  119. ^ Mul, K; Horlings, CGC; Voermans, NC; Schreuder, THA; van Engelen, BGM (June 2018). "Lifetime endogenous estrogen exposure and disease severity in female patients with facioscapulohumeral muscular dystrophy". Neuromuscular Disorders. 28 (6): 508–511. doi:10.1016/j.nmd.2018.02.012. hdl:2066/194350. PMID 29655530.
  120. ^ Duchenne, Guillaume-Benjamin (1868). "De la paralysie musculaire pseudo-hypertrophique, ou paralysie myo-sclérosique". Arch. Gen. Med. (in French). Bibliothèque nationale de France. 11: 5–25, 179–209, 305–321, 421–443, 552–588. Retrieved 18 May 2020.
  121. ^ a b Landouzy-Dejerine syndrome, whonamedit.com, date accessed March 11, 2007
  122. ^ Landouzy; Dejerine (1884). "De la myopathie atrophique progressive (myopathie héréditaire, débutant dans l'enfance par la face, sans altération du système nerveux)". Comptes Rendus de l'Académie des Sciences. 98: 53–55.
  123. ^ Landouzy; Dejerine (1886). "Contribution à l'étude de la myopathie atrophique progressive (myopathie atrophique progressive, à type scapulo-huméral)". Comptes Rendus des Séances de la Société de Biologie. 38: 478–481.
  124. ^ Tyler, Frank; Stephens, FE (April 1950). "Studies in disorders of muscle. II Clinical manifestations and inheritance of facioscapulohumeral dystrophy in a large family". Annals of Internal Medicine. 32 (4): 640–660. doi:10.7326/0003-4819-32-4-640. PMID 15411118.
  125. ^ Koenig, M; Hoffman, EP; Bertelson, CJ; Monaco, AP; Feener, C; Kunkel, LM (Jul 31, 1987). "Complete cloning of the Duchenne muscular dystrophy (DMD) cDNA and preliminary genomic organization of the DMD gene in normal and affected individuals". Cell. 50 (3): 509–517. doi:10.1016/0092-8674(87)90504-6. PMID 3607877. S2CID 35668717.
  126. ^ Wijmenga, C; Padberg, GW; Moerer, P; et al. (April 1991). "Mapping of facioscapulohumeral muscular dystrophy gene to chromosome 4q35-qter by multipoint linkage analysis and in situ hybridization". Genomics. 9 (4): 570–575. doi:10.1016/0888-7543(91)90348-I. PMID 2037288.
  127. ^ Gilbert, JR; Stajich, JM; Wall, S; et al. (Aug 1993). "Evidence for heterogeneity in facioscapulohumeral muscular dystrophy (FSHD)". American Journal of Human Genetics. 53 (2): 401–408. PMC 1682358. PMID 8328457.
  128. ^ a b Winokur, ST; Bengtsson, U; Feddersen, J; et al. (May 1994). "The DNA rearrangement associated with facioscapulohumeral muscular dystrophy involves a heterochromatin-associated repetitive element: implications for a role of chromatin structure in the pathogenesis of the disease". Chromosome Research. 2 (3): 225–234. doi:10.1007/bf01553323. PMID 8069466. S2CID 6933736.
  129. ^ Hewitt, JE; Lyle, R; Clark, LN; et al. (Aug 1994). "Analysis of the tandem repeat locus D4Z4 associated with facioscapulohumeral muscular dystrophy". Human Molecular Genetics. 3 (8): 1287–1295. doi:10.1093/hmg/3.8.1287. PMID 7987304.
  130. ^ Gilbert, JR; Speer, MC; Stajich, J; et al. (Oct 1995). "Exclusion mapping of chromosomal regions which cross hybridise to FSHD1A associated markers in FSHD1B". Journal of Medical Genetics. 32 (10): 770–773. doi:10.1136/jmg.32.10.770. PMC 1051697. PMID 8558552.
  131. ^ van Deutekom, JC; Lemmers, RJ; Grewal, PK; et al. (May 1996). "Identification of the first gene (FRG1) from the FSHD region on human chromosome 4q35". Human Molecular Genetics. 5 (5): 581–590. doi:10.1093/hmg/5.5.581. PMID 8733123.
  132. ^ a b Kowaljow, V; Marcowycz, A; Ansseau, E; et al. (Aug 2007). "The DUX4 gene at the FSHD1A locus encodes a pro-apoptotic protein". Neuromuscular Disorders. 17 (8): 611–623. doi:10.1016/j.nmd.2007.04.002. PMID 17588759. S2CID 25926418.
  133. ^ Gabriels, J; Beckers, MC; Ding, H; et al. (Aug 5, 1999). "Nucleotide sequence of the partially deleted D4Z4 locus in a patient with FSHD identifies a putative gene within each 3.3 kb element". Gene. 236 (1): 25–32. doi:10.1016/S0378-1119(99)00267-X. PMID 10433963.
  134. ^ Tsien, F; Sun, B; Hopkins, NE; et al. (Nov 2001). "Methylation of the FSHD syndrome-linked subtelomeric repeat in normal and FSHD cell cultures and tissues". Molecular Genetics and Metabolism. 74 (3): 322–331. doi:10.1006/mgme.2001.3219. PMID 11708861.
  135. ^ Lemmers, RJ; de Kievit, P; Sandkuijl, L; et al. (Oct 2002). "Facioscapulohumeral muscular dystrophy is uniquely associated with one of the two variants of the 4q subtelomere". Nature Genetics. 32 (2): 235–236. doi:10.1038/ng999. PMID 12355084. S2CID 28107557.
  136. ^ Gabellini, D; Green, MR; Tupler, R (Aug 9, 2002). "Inappropriate gene activation in FSHD: a repressor complex binds a chromosomal repeat deleted in dystrophic muscle". Cell. 110 (3): 339–348. doi:10.1016/S0092-8674(02)00826-7. hdl:11380/459475. PMID 12176321. S2CID 16396883.
  137. ^ van Overveld, PG; Lemmers, RJ; Sandkuijl, LA; et al. (Dec 2003). "Hypomethylation of D4Z4 in 4q-linked and non-4q-linked facioscapulohumeral muscular dystrophy". Nature Genetics. 35 (4): 315–317. doi:10.1038/ng1262. PMID 14634647. S2CID 28696708.
  138. ^ Lemmers, RJ; Wohlgemuth, M; Frants, RR; Padberg, GW; Morava, E; van der Maarel, SM (Dec 2004). "Contractions of D4Z4 on 4qB subtelomeres do not cause facioscapulohumeral muscular dystrophy". The American Journal of Human Genetics. 75 (6): 1124–1130. doi:10.1086/426035. PMC 1182148. PMID 15467981.
  139. ^ Gabellini, D; D'Antona, G; Moggio, M; et al. (Feb 23, 2006). "Facioscapulohumeral muscular dystrophy in mice overexpressing FRG1". Nature. 439 (7079): 973–977. Bibcode:2006Natur.439..973G. doi:10.1038/nature04422. PMID 16341202. S2CID 4427465.
  140. ^ Clapp, J; Mitchell, LM; Bolland, DJ; et al. (Aug 2007). "Evolutionary conservation of a coding function for D4Z4, the tandem DNA repeat mutated in facioscapulohumeral muscular dystrophy". The American Journal of Human Genetics. 81 (2): 264–279. doi:10.1086/519311. PMC 1950813. PMID 17668377.
  141. ^ Dixit, M; Ansseau, E; Tassin, A; et al. (Nov 13, 2007). "DUX4, a candidate gene of facioscapulohumeral muscular dystrophy, encodes a transcriptional activator of PITX1". Proceedings of the National Academy of Sciences of the USA. 104 (46): 18157–18162. Bibcode:2007PNAS..10418157D. doi:10.1073/pnas.0708659104. PMC 2084313. PMID 17984056.
  142. ^ de Greef, JC; Lemmers, RJ; van Engelen, BG; et al. (Oct 2009). "Common epigenetic changes of D4Z4 in contraction-dependent and contraction-independent FSHD". Human Mutation. 30 (10): 1449–1459. CiteSeerX 10.1.1.325.8388. doi:10.1002/humu.21091. PMID 19728363. S2CID 14517505.
  143. ^ Snider, L; Asawachaicharn, A; Tyler, AE; et al. (Jul 1, 2009). "RNA transcripts, miRNA-sized fragments and proteins produced from D4Z4 units: new candidates for the pathophysiology of facioscapulohumeral dystrophy". Human Molecular Genetics. 18 (13): 2414–2430. doi:10.1093/hmg/ddp180. PMC 2694690. PMID 19359275.
  144. ^ a b Kolata, Gina (19 August 2010). "Reanimated 'Junk' DNA Is Found to Cause Disease". The New York Times. Retrieved 29 August 2010.
  145. ^ . 2010-08-23. Archived from the original on 2010-08-23. Retrieved 2024-02-21.
  146. ^ Scionti, I; Greco, F; Ricci, G; et al. (Apr 6, 2012). "Large-scale population analysis challenges the current criteria for the molecular diagnosis of fascioscapulohumeral muscular dystrophy". The American Journal of Human Genetics. 90 (4): 628–635. doi:10.1016/j.ajhg.2012.02.019. PMC 3322229. PMID 22482803.
  147. ^ Geng, LN; Yao, Z; Snider, L; et al. (Jan 17, 2012). "DUX4 activates germline genes, retroelements, and immune mediators: implications for facioscapulohumeral dystrophy". Developmental Cell. 22 (1): 38–51. doi:10.1016/j.devcel.2011.11.013. PMC 3264808. PMID 22209328.
  148. ^ Jones, TI; Chen, JC; Rahimov, F; et al. (Oct 15, 2012). "Facioscapulohumeral muscular dystrophy family studies of DUX4 expression: evidence for disease modifiers and a quantitative model of pathogenesis". Human Molecular Genetics. 21 (20): 4419–4430. doi:10.1093/hmg/dds284. PMC 3459465. PMID 22798623.
  149. ^ Krom, YD; Thijssen, PE; Young, JM; et al. (Apr 2013). "Intrinsic Epigenetic Regulation of the D4Z4 Macrosatellite Repeat in a Transgenic Mouse Model for FSHD". PLOS Genetics. 9 (4): e1003415. doi:10.1371/journal.pgen.1003415. PMC 3616921. PMID 23593020.
  150. ^ Ferreboeuf, M; Mariot, V; Bessieres, B; et al. (Jan 1, 2014). "DUX4 and DUX4 downstream target genes are expressed in fetal FSHD muscles". Human Molecular Genetics. 23 (1): 171–181. doi:10.1093/hmg/ddt409. PMID 23966205.
  151. ^ Tawil, R; McDermott, MP; Pandya, S; King, W; Kissel, J; Mendell, JR; Griggs, RC (January 1997). "A pilot trial of prednisone in facioscapulohumeral muscular dystrophy. FSH-DY Group". Neurology. 48 (1): 46–9. doi:10.1212/wnl.48.1.46. PMID 9008492. S2CID 729275.
  152. ^ Kissel, JT; McDermott, MP; Natarajan, R; Mendell, JR; Pandya, S; King, WM; Griggs, RC; Tawil, R (May 1998). "Pilot trial of albuterol in facioscapulohumeral muscular dystrophy. FSH-DY Group". Neurology. 50 (5): 1402–6. doi:10.1212/wnl.50.5.1402. PMID 9595995. S2CID 24848310.
  153. ^ Kissel, JT; McDermott, MP; Mendell, JR; King, WM; Pandya, S; Griggs, RC; Tawil, R; FSH-DY, Group. (23 October 2001). "Randomized, double-blind, placebo-controlled trial of albuterol in facioscapulohumeral dystrophy". Neurology. 57 (8): 1434–40. doi:10.1212/wnl.57.8.1434. PMID 11673585. S2CID 28093111.
  154. ^ van der Kooi, EL; Vogels, OJ; van Asseldonk, RJ; Lindeman, E; Hendriks, JC; Wohlgemuth, M; van der Maarel, SM; Padberg, GW (24 August 2004). "Strength training and albuterol in facioscapulohumeral muscular dystrophy". Neurology. 63 (4): 702–8. doi:10.1212/01.wnl.0000134660.30793.1f. PMID 15326246. S2CID 22778327.
  155. ^ a b Campbell, AE; Oliva, J; Yates, MP; Zhong, JW; Shadle, SC; Snider, L; Singh, N; Tai, S; Hiramuki, Y; Tawil, R; van der Maarel, SM; Tapscott, SJ; Sverdrup, FM (4 September 2017). "BET bromodomain inhibitors and agonists of the beta-2 adrenergic receptor identified in screens for compounds that inhibit DUX4 expression in FSHD muscle cells". Skeletal Muscle. 7 (1): 16. doi:10.1186/s13395-017-0134-x. PMC 5584331. PMID 28870238.
  156. ^ Elsheikh, BH; Bollman, E; Peruggia, M; King, W; Galloway, G; Kissel, JT (24 April 2007). "Pilot trial of diltiazem in facioscapulohumeral muscular dystrophy". Neurology. 68 (17): 1428–9. doi:10.1212/01.wnl.0000264017.08217.39. PMID 17452589. S2CID 361422.
  157. ^ Wyeth Initiates Clinical Trial with Investigational Muscular Dystrophy Therapy MYO-029
  158. ^ Malcolm, Emily (18 June 2019). "ACE-083". Muscular Dystrophy News. Retrieved 19 December 2019.
  159. ^ Vultaggio, Maria (5 October 2018). . Newsweek. Archived from the original on 6 November 2018. Retrieved 12 April 2022.
  160. ^ Kakutani, Michiko (9 June 2006). . The New York Times. Archived from the original on 16 January 2018.
  161. ^ White, Abbey (2023-12-19). "'Ramy' Star Steve Way Boards Indie Drama 'Good Bad Things' as Executive Producer (Exclusive)". The Hollywood Reporter. Retrieved 2024-01-31.
  162. ^ jkinoshita (2022-08-25). "New movie will feature man with FSHD". FSHD Society. Retrieved 2024-01-31.
  163. ^ "A disability advocate preserves his voice with iPhone". Apple Newsroom. Retrieved 2024-02-21.
  164. ^ a b Kinoshita, June (16 August 2019). . FSHD Society. Archived from the original on 12 April 2022. Retrieved 18 August 2019.
  165. ^ a b . FSHD Society. Archived from the original on 27 February 2022.
  166. ^ a b Bartlett, Jessica (19 August 2014). Boston Business Journal . Archived from the original on 12 April 2022. Retrieved 12 April 2022. {{cite news}}: Missing or empty |title= (help)
  167. ^ . NORD (National Organization for Rare Disorders). Archived from the original on 2022-05-13. Retrieved 2022-04-12.
  168. ^ . Prweb. 26 April 2022. Archived from the original on 29 April 2022. Retrieved 29 April 2022.
  169. ^ . HuffPost. 16 July 2014. Archived from the original on 2 August 2019. Retrieved 12 April 2022.
  170. ^ Krummey, Catherine (30 March 2017). . Kirkland Reporter. Archived from the original on 16 June 2017. Retrieved 9 April 2022.
  171. ^ . Friends of FSH Research. Archived from the original on 17 February 2020. Retrieved 9 April 2022.
  172. ^ AMRA Medical (13 Oct 2021). . Cision PR Newswire. Archived from the original on 1 November 2021. Retrieved 9 April 2022.
  173. ^ Avidity Biosciences, Inc. (16 August 2021). . Cision PR Newswire. Archived from the original on 16 August 2021.
  174. ^ Overington, Caroline (24 September 2016). "He's physically wasting but his brain is sharp. Former Macquarie banker Bill Moss is back in business". The Australian.
  175. ^ a b c Chancellor, Jonathan (7 September 2020). "Buyer swoops on Brett Whiteley's corella". The Australian. Retrieved 9 April 2022.
  176. ^ a b Tasker, Sarah-Jane (26 May 2018). "Bill Moss, the single-minded biotech and a search for a cure". The Australian. Retrieved 9 April 2022.
  177. ^ a b Voermans, NC; Vriens-Munoz Bravo, M; Padberg, GW; Laforêt, P; FSHD European Trial Network workshop study, group. (September 2021). "1st FSHD European Trial Network workshop:Working towards trial readiness across Europe". Neuromuscular Disorders. 31 (9): 907–918. doi:10.1016/j.nmd.2021.07.013. hdl:1887/3505452. PMID 34404575. S2CID 236217036.
  178. ^ Judd, Amy (8 March 2022). "Lululemon founder Chip Wilson donates $100M to find cure for his illness, 30 years after diagnosis | Globalnews.ca". Global News. Retrieved 9 April 2022.
  179. ^ Isola, Frank (23 April 2019). "'You're not going to quit': One step at a time, Nets radio voice Chris Carrino continues to walk tall". The Athletic. Retrieved 9 April 2022.
  180. ^ "Actress Breaking Barriers as Broadway's First Lead Actor in Wheelchair". NBC News. Retrieved 2024-02-21.
  181. ^ "Community Profiles: Actress Madison Ferris". Audioboom. Retrieved 2024-02-21.
  182. ^ Shedloski, Dave (24 February 2020). . Golf Digest. Archived from the original on 5 March 2022. Retrieved 12 April 2022.
  183. ^ Sandomir, Richard (2018-02-03). "Dr. Arnold Gold, 92, Dies; Made Compassionate Care a Cause". The New York Times. ISSN 0362-4331. Retrieved 2024-02-21.
  184. ^ Rickard, Amanda; Petek, Lisa; Miller, Daniel (August 5, 2015). "Endogenous DUX4 expression in FSHD myotubes is sufficient to cause cell death and disrupts RNA splicing and cell migration pathways". Hum. Mol. Genet. 24 (20): 5901–14. doi:10.1093/hmg/ddv315.
March 16, 2024
facioscapulohumeral, muscular, dystrophy, fshd, type, muscular, dystrophy, group, heritable, diseases, that, cause, degeneration, muscle, progressive, weakness, name, fshd, tends, sequentially, weaken, muscles, face, those, that, position, scapula, those, over. Facioscapulohumeral muscular dystrophy FSHD is a type of muscular dystrophy a group of heritable diseases that cause degeneration of muscle and progressive weakness Per the name FSHD tends to sequentially weaken the muscles of the face those that position the scapula and those overlying the humerus bone of the upper arm 2 3 These areas can be spared and muscles of other areas usually are affected especially those of the chest abdomen spine and shin Almost any skeletal muscle can be affected in advanced disease Abnormally positioned termed winged scapulas are common as is the inability to lift the foot known as foot drop The two sides of the body are often affected unequally Weakness typically manifests at ages 15 30 years 4 FSHD can also cause hearing loss and blood vessel abnormalities at the back of the eye Facioscapulohumeral muscular dystrophyOther namesLandouzy Dejerine muscular dystrophy FSHMD FSHA diagram showing the muscles commonly affected by FSHDPronunciation ˌ f eɪ ʃ iː oʊ ˌ s k ae p j e l oʊ ˈ h juː m er el fay shee oh skap ye low HEW mer el 1 alt f eɪ s f ɑː ʃ f ɑː s SpecialtyNeurology neuromuscular medicineSymptomsFacial weakness scapular winging foot dropComplicationsChronic pain dry eyes and shoulder instability less commonly retinal disease scoliosis and respiratory insufficiencyUsual onsetAges 15 30 yearsDurationLifelongTypesTypically classified by genetic cause FSHD1 FSHD2 Sometimes classified by disease manifestation eg infantile onset CausesGenetic inherited or new mutation Risk factorsMale sex extent of genetic mutationDiagnostic methodGenetic testingDifferential diagnosisLimb girdle muscular dystrophy especially calpainopathy Pompe disease mitochondrial myopathy polymyositis 2 ManagementPhysical therapy bracing reconstructive surgeryMedicationClinical trials ongoingPrognosisProgressive unaffected life expectancyFrequencyUp to 1 8 333 2 FSHD is caused by a genetic mutation leading to deregulation of the DUX4 gene 5 Normally DUX4 is expressed i e turned on in cells of the ovary and in very early human development becoming repressed i e turned off by the time an embryo is several days old 6 7 In FSHD DUX4 is inadequately repressed allowing sporadic expression throughout life Deletion of DNA in the region surrounding DUX4 is the causative mutation in 95 of cases termed D4Z4 contraction and defining FSHD type 1 FSHD1 8 FSHD caused by other mutations is FSHD type 2 FSHD2 For disease to develop also required is a 4qA allele which is a common variation in the DNA next to DUX4 The chances of a D4Z4 contraction with a 4qA allele being passed on to a child is 50 autosomal dominant 2 in 30 of cases the mutation arose spontaneously 4 Mutations of FSHD cause inadequate DUX4 repression by unpacking the DNA around DUX4 making it accessible to be copied into messenger RNA mRNA The 4qA allele stabilizes this DUX4 mRNA allowing it to be used for production of DUX4 protein 9 DUX4 protein is a modulator of hundreds of other genes many of which are involved in muscle function 2 5 How this genetic modulation causes muscle damage remains unclear 2 Signs symptoms and diagnostic tests can suggest FSHD genetic testing usually provides definitive diagnosis 2 FSHD can be presumptively diagnosed in an individual with signs symptoms and an established family history No intervention has proven effective for slowing progression of weakness 10 Screening allows for early detection and intervention for various disease complications Symptoms can be addressed with physical therapy bracing and reconstructive surgery such as surgical fixation of the scapula to the thorax 11 FSHD affects up to 1 in 8 333 people 2 putting it in the three most common muscular dystrophies with myotonic dystrophy and Duchenne muscular dystrophy 12 13 Prognosis is variable Many are not significantly limited in daily activity whereas a wheel chair or scooter is required in 20 of cases 14 Life expectancy is not affected although death can rarely be attributed to respiratory insufficiency due to FSHD 15 FSHD was first distinguished as a disease in the 1870s and 1880s when French physicians Louis Theophile Joseph Landouzy and Joseph Jules Dejerine followed a family affected by it thus the initial name Landouzy Dejerine muscular dystrophy Their work is predated by descriptions of probable individual FSHD cases 16 17 18 The significance of D4Z4 contraction on chromosome 4 was established in the 1990s The DUX4 gene was discovered in 1999 found to be expressed and toxic in 2007 and in 2010 the genetic mechanism causing its expression was elucidated In 2012 the gene most frequently mutated in FSHD2 was identified In 2019 the first drug designed to counteract DUX4 expression entered clinical trials 19 Contents 1 Signs and symptoms 1 1 Face 1 2 Shoulder chest and arm 1 3 Lower body and trunk 1 4 Non muscular 2 Genetics 2 1 DUX4 and the D4Z4 repeat array 2 2 FSHD1 2 3 FSHD2 2 4 Two ends of a disease spectrum 3 Pathophysiology 3 1 Molecular 3 2 Muscle histology 3 3 Muscle involvement pattern 3 4 Retinopathy 4 Diagnosis 4 1 Genetic testing 4 1 1 Assessing D4Z4 length 4 1 2 Assessing methylation status 4 2 Auxiliary testing 4 3 Differential diagnosis 5 Management 5 1 Screening and monitoring of complications 5 2 Physical and occupational therapy 5 3 Pharmacologic management 5 4 Reconstructive surgery 6 Prognosis 6 1 Pregnancy 7 Epidemiology 8 History 8 1 Chronology of important FSHD related genetic research 8 2 Past pharmaceutical development 9 Society and culture 9 1 Media 9 2 Patient and research organizations 9 3 Notable cases 10 Research directions 10 1 Pharmaceutical development 10 2 Outcome measures 11 References 12 External linksSigns and symptoms editClassically weakness develops in the face then the shoulder girdle then the upper arm 10 These muscles can be spared and other muscles usually are affected The order of muscle involvement can cause the appearance of weakness descending from the face to the legs 10 Distribution and degree of muscle weakness is extremely variable even between identical twins 20 21 Musculoskeletal pain is very common most often described in the neck shoulders lower back and the back of the knee 22 4 Fatigue is also common 4 Muscle weakness usually becomes noticeable on one side of the body before the other a hallmark of the disease 14 The right shoulder and arm muscles are more often affected than the left upper extremity muscles independent of handedness 23 139 24 25 26 Otherwise neither side of the body has been found to be at more risk Classically symptoms appear in those 15 30 years of age although infantile onset adult onset and absence of symptoms despite having the causal genetics also occur 4 FSHD1 with a very large D4Z4 deletion EcoRI 10 11 kb is more strongly associated with infantile onset and severe weakness 27 On average FSHD2 presents 10 years later than FSHD1 28 Otherwise FSHD1 and FSHD2 are indistinguishable on the basis of weakness 27 Disease progression is slow and long static phases in which no progression is apparent is not uncommon 29 Less commonly individual muscles rapidly deteriorate over several months 2 The symptom burden of FSHD is typically more severe than it is perceived to be by those without the disease 30 31 32 33 Face edit Weakness of the muscles of the face is the most distinguishing sign of FSHD 4 It is typically the earliest sign although it is rarely the initial complaint 4 At least mild facial weakness can be found in 90 or more with FSHD 29 24 One of the most common deficits is inability to close the eyelids which can result in sleeping with the eyelids open and dry eyes 4 The implicated muscle is the orbicularis oculi muscle 4 Another common deficit is inability to purse the lips causing inability to pucker whistle or blow up a balloon 4 The implicated muscle is the orbicularis oris muscle 4 A third common deficit is inability raise the corners of the mouth causing a horizontal smile which looks more like a grin 4 Responsible is the zygomaticus major muscle 4 Weakness of facial muscles contributes to difficulty pronouncing words 34 Facial expressions can appear diminished arrogant grumpy or fatigued 4 Muscles used for chewing and moving the eyes are not affected 24 14 Difficulty swallowing is not typical although can occur in advanced cases 35 34 FSHD is generally progressive but it is not established whether facial weakness is progressive or stable throughout life 36 Shoulder chest and arm edit nbsp Bilateral scapular winging right moreso than left Left image showing wall push test right image showing attempted shoulder flexion After the facial weakness weakness usually develops in the muscles of the chest and those that span from scapula to thorax Symptoms involving the shoulder such as difficulty working with the arms overhead are the initial complaint in 80 of cases 24 14 Predominantly the serratus anterior and middle and lower trapezii muscles are affected 4 the upper trapezius is often spared 14 Trapezius weakness causes the scapulas to become downwardly rotated and protracted resulting in winged scapulas horizontal clavicles and sloping shoulders arm abduction is impaired Serratus anterior weaknesss impairs arm flexion and worsening of winging can be demonstrated when pushing against a wall Muscles spanning from the scapula to the arm are generally spared which include deltoid and the rotator cuff muscles 37 38 The deltoid can be affected later on especially the upper portion 4 Severe muscle wasting can make bones and spared shoulder muscles very visible a characteristic example being the poly hill sign elicited by arm elevation 4 The first hill or bump is the upper corner of scapula appearing to herniate up and over the rib cage The second hill is the AC joint seen between a wasted upper trapezius and wasted upper deltoid The third hill is the lower deltoid distinguishable between the wasted upper deltoid and wasted humeral muscles 4 Shoulder weakness and pain can in turn lead to shoulder instability such as recurrent dislocation subluxation or downward translation of the humeral head 39 Also affected is the chest particularly the parts of the pectoralis major muscle that connect to the sternum and ribs The part that connects to the clavicle is less often affected This muscle wasting pattern can contribute to a prominent horizontal anterior axillary fold 40 4 Beyond this point the disease does not progress further in 30 of familial cases 24 14 After upper torso weakness weakness can descend to the upper arms biceps muscle and particularly the triceps muscle 24 The forearms are usually spared resulting in an appearance some compare to the fictional character Popeye 4 although when the forearms are affected in advanced disease the wrist extensors are more often affected 24 Lower body and trunk edit After the upper body weakness can next appear in either the pelvis or it skips the pelvis and involves the tibialis anterior shin muscle causing foot drop One author considers the pelvic and thigh muscles to be the last group affected 24 Pelvic weakness can manifest as a Trendelenburg s sign 4 Weakness of the back of the thigh hamstrings is more common than weakness of the front of the thigh quadriceps 4 In more severe cases especially infantile FSHD there can be anterior pelvic tilt with associated hyperextension of the knees 41 Weakness can also occur in the abdominal muscles and paraspinal muscles which can manifest as a protuberant abdomen and lumbar hyperlordosis 2 4 Abdominal weakness can cause inability to do a sit up or the inability to turn from one side to the other while lying on one s back 4 Of the rectus abdominis muscle the lower portion is preferentially affected manifesting as a positive Beevor s sign 4 2 In advanced cases neck extensor weakness can cause the head to lean towards the chest termed head drop 24 Non muscular edit nbsp Funduscopy of the retinal A normal blood vessels B tortuous blood vessels as often seen with FSHDThe most common non musculoskeletal manifestation of FSHD is abnormalities in the small arteries arterioles in the retina Tortuosity of the arterioles is seen in approximately 50 of those with FSHD Less common arteriole abnormalities include telangiectasias and microaneurysms 42 43 These abnormalities of arterioles usually do not affect vision or health although a severe form of it mimics Coat s disease a condition found in about 1 of FSHD cases and more frequently associated with large 4q35 deletions 2 44 High frequency sensorineural hearing loss can occur in those with large 4q35 deletions but otherwise is no more common compared to the general population 2 Large 4q35 deletion can lead to various other rare manifestations 45 Scoliosis can occur thought to result from weakness of abdominal hip extensor and spinal muscles 46 47 Conversely scoliosis can be viewed as a compensatory mechanism to weakness 46 Breathing can be affected associated with kyphoscoliosis and wheelchair use it is seen in one third of wheelchair using patients 2 However ventilator support nocturnal or diurnal is needed in only 1 of cases 2 48 Although there are reports of increased risk of cardiac arrhythmias general consensus is that the heart is not affected 14 Genetics edit nbsp Structure of DUX4 protein full length FL with short S version indicated The genetics of FSHD is complex 2 FSHD and the myotonic dystrophies have unique genetic mechanisms that differ substantially from the rest of genetic myopathies 49 The DUX4 gene is the focal point of FSHD genetics Normally DUX4 is expressed during embryogenesis and later repressed in all tissues except the testes In FSHD there is failure of DUX4 repression and continued production of DUX4 protein which is toxic to muscles 2 8 The mechanism of failed DUX4 repression is hypomethylation of DUX4 and its surrounding DNA on the tip of chromosome 4 4q35 allowing transcription of DUX4 into messenger RNA mRNA Several mutations can result in disease upon which FSHD is sub classified into FSHD type 1 FSHD1 and FSHD type 2 FSHD2 27 Disease can only result when a mutation is present in combination with select commonly found variations of 4q35 termed haplotype polymorphisms There are at least 17 4q35 haplotype polymorphisms 50 roughly dividable into the groups 4qA and 4qB 50 A 4qA haplotype polymorphism often referred to as a 4qA allele is necessary for disease as it contains a polyadenylation sequence that allows DUX4 mRNA to resist degradation long enough to be translated into DUX4 protein 8 DUX4 and the D4Z4 repeat array edit nbsp D4Z4 array with three D4Z4 repeats and the 4qA allele 27 CEN centromeric end TEL telomeric end NDE box non deleted element PAS polyadenylation site triangle D4Z4 repeat trapezoid partial D4Z4 repeat white box pLAM gray boxes DUX4 exons 1 2 3 arrows corner promoters straight RNA transcripts black sense red antisense blue DBE T dashes dicing sitesDUX4 resides within the D4Z4 macrosatellite repeat array a series of tandemly repeated DNA segments in the subtelomeric region 4q35 of chromosome 4 51 Each D4Z4 repeat is 3 3 kilobase pairs kb long and is the site of epigenetic regulation containing both heterochromatin and euchromatin structures 52 53 In FSHD the heterochromatin structure is lost becoming euchromatin 52 which consists of less methylation of DNA and altered methylation of histones 54 Histone methylation patterns differ slightly between FSHD1 and FSHD2 54 The subtelomeric region of chromosome 10q contains a tandem repeat structure highly homologous 99 identical to 4q35 8 50 containing D4Z4 like repeats with protein coding regions identical to DUX4 D10Z10 repeats and DUX4L10 respectively 8 55 Because 10q usually lacks a polyadenylation sequence it is usually not implicated in disease However chromosomal rearrangements can occur between 4q and 10q repeat arrays and involvement in disease is possible if a 4q D4Z4 repeat and polyadenylation signal are transferred onto 10q 56 8 57 or if rearrangement causes FSHD1 DUX4 consists of three exons Exons 1 and 2 are in each repeat Exon 3 is in the pLAM region telomeric to the last partial repeat 8 7 Multiple RNA transcripts are produced from the D4Z4 repeat array both sense and antisense Some transcripts might be degraded in areas to produce si like small RNAs 27 Some transcripts that originate centromeric to the D4Z4 repeat array at the non deleted element NDE termed D4Z4 regulatory element transcripts DBE T could play a role in DUX4 derepression 27 58 One proposed mechanism is that DBE T leads to the recruitment of the trithorax group protein Ash1L an increase in H3K36me2 methylation and ultimately de repression of 4q35 genes 59 Chromatin profiles 54 DNA methylation H3K4me2 H3K9me3 H3K27me3FSHD1 FSHD2 Chromatin profiles not fully characterized for DNMT3B mutation 54 FSHD1 edit FSHD involving deletion of D4Z4 repeats termed D4Z4 contraction on 4q is classified as FSHD1 which accounts for 95 of FSHD cases 2 Typically chromosome 4 includes between 11 and 150 D4Z4 repeats 52 8 In FSHD1 there are 1 10 D4Z4 repeats 8 The number of repeats is roughly inversely related to disease severity Namely those with 8 10 repeats tend to have the mildest presentations sometimes with no symptoms those with 4 7 repeats have moderate disease that is highly variable and those with 1 3 repeats are more likely to have severe atypical and early onset disease 60 Deletion of the entire D4Z4 repeat array does not result in FSHD because then there are no complete copies of DUX4 to be expressed although other birth defects result 61 8 One contracted D4Z4 repeat array with an adjoining 4qA allele is sufficient to cause disease so inheritance is autosomal dominant De novo new mutations are implicated in 10 30 of cases 4 up to 40 of which exhibit somatic mosaicism 14 In an individual with mosaic FSHD the severity of disease is correlated to the proportion of their cells carrying the mutation 14 It has been proposed that FSHD1 undergoes anticipation a phenomenon primarily associated with trinucleotide repeat disorders in which disease manifestation worsens with each subsequent generation 62 As of 2019 more detailed studies are needed to definitively show whether or not anticipation occurs 63 If anticipation does occur in FSHD the mechanism is different than that of trinucleotide repeat disorders since D4Z4 repeats are much larger than trinucleotide repeats an underabundance of repeats rather than overabundance causes disease and the repeat array size in FSHD is stable across generations 64 nbsp D4Z4 array examples with each D4Z4 repeat represented by a triangle The circles above the triangles represent DNA methylation which determine DNA packaging as represented by the circles in line with the triangles FSHD2 edit FSHD without D4Z4 contraction is classified as FSHD2 which constitutes 5 of FSHD cases 2 Various mutations cause FSHD2 all of chromatin modifier genes that result in D4Z4 hypomethylation at which the genetic mechanism converges with FSHD1 65 10 Approximately 80 of FSHD2 cases are due to deactivating mutations in the gene SMCHD1 structural maintenance of chromosomes flexible hinge domain containing 1 on chromosome 18 SMCHD1 is responsible for DNA methylation and its deactivation results in hypomethylation of the D4Z4 repeat array 2 Specific mutations of SMCHD1 are also associated with Bosma arhinia and microphtalmia syndrome 54 Another cause of FSHD2 is mutation in DNMT3B DNA methyltransferase 3B which also plays a role in DNA methylation 66 67 Mutations in DNMT3B can also cause ICF syndrome 54 As of 2020 early evidence indicates that a third cause of FSHD2 is mutation in both copies of the LRIF1 gene which encodes the protein ligand dependent nuclear receptor interacting factor 1 LRIF1 68 LRIF1 is known to interact with the SMCHD1 protein 68 As of 2019 there are presumably additional mutations at other unidentified genetic locations that can cause FSHD2 2 Mutation of a single allele of SMCHD1 or DNMT3B can cause disease Mutation of both copies LRIF1 has been tentatively shown to cause disease in a single person as of 2020 68 As in FSHD1 a 4qA allele must be present for disease to result However unlike the D4Z4 array the genes implicated in FSHD2 are not in proximity with the 4qA allele and so they are inherited independently from the 4qA allele resulting in a digenic inheritance pattern For example one parent without FSHD can pass on an SMCHD1 mutation and the other parent also without FSHD can pass on a 4qA allele bearing a child with FSHD2 65 67 Two ends of a disease spectrum edit FSHD1 and FSHD2 have been traditionally viewed as separate entities with distinct genetic causes albeit the downstream genetic mechanisms merge 69 Alternatively the genetic causes of FSHD1 and FSHD2 can be viewed as risk factors each contributing to an FSHD disease spectrum 69 Not rarely an affected individual seems to have contributions from both 60 For example in those with FSHD2 although they have do not have a 4qA allele with D4Z4 repeat number less than 11 they still often have one less than 17 relatively short compared to the general population suggesting that a large number of D4Z4 repeats can prevent the effects of an SMCHD1 mutation 60 Further studies are needed to determine the upper limit of D4Z4 repeats in FSHD2 60 In those with FSHD1 and FSHD2 that is having 10 or fewer repeats with an adjacent 4qA allele and an SMCHD1 mutation the disease manifests more severely illustrating that the effects of each mutation are additive 70 A combined FSHD1 FSHD2 presentation is most common in those with 9 10 repeats A possible explanation is that a sizable portion of the general population has 9 10 repeats with difficult to detect or no disease yet with the additive effect of an SMCHD1 mutation symptoms are severe enough for a diagnosis to be made 60 The 9 10 repeat size can be considered as an overlap zone between FSHD1 and FSDH2 60 Pathophysiology editMolecular edit nbsp DUX4 signaling in FSHD affected skeletal muscle As of 2020 there seems to be a consensus that aberrant expression of DUX4 in muscle is the cause of FSHD 71 DUX4 is expressed in extremely small amounts detectable in 1 out of every 1000 immature muscle cells myoblast which appears to increase after myoblast maturation in part because the cells fuse as they mature and a single nucleus expressing DUX4 can provide DUX4 protein to neighboring nuclei from fused cells 72 It remains an area of active research how DUX4 protein causes muscle damage 73 DUX4 protein is a transcription factor that regulates many other genes Some of these genes are involved in apoptosis such as p53 p21 MYC and b catenin and indeed it seems that DUX4 protein makes muscle cells more prone to apoptosis Other DUX4 protein regulated genes are involved in oxidative stress and indeed it seems that DUX4 expression lowers muscle cell tolerance of oxidative stress Variation in the ability of individual muscles to handle oxidative stress could partially explain the muscle involvement patterns of FSHD DUX4 protein downregulates many genes involved in muscle development including MyoD myogenin desmin and PAX7 and indeed DUX4 expression has shown to reduce muscle cell proliferation differentiation and fusion DUX4 protein regulates a few genes that are involved in RNA quality control and indeed DUX4 expression has been shown to cause accumulation of RNA with subsequent apoptosis 71 Estrogen seems to play a role in modifying DUX4 protein effects on muscle differentiation which could explain why females are lesser affected than males although it remains unproven 74 The cellular hypoxia response has been reported in a single study to be the main driver of DUX4 protein induced muscle cell death The hypoxia inducible factors HIFs are upregulated by DUX4 protein possibly causing pathologic signaling leading to cell death 75 Another study found that DUX4 expression in muscle cells led to the recruitment and alteration of fibrous fat progenitor cells which helps explain why muscles become replaced by fat and fibrous tissue 72 A single study implicated RIPK3 in DUX4 mediated cell death 76 Muscle histology edit nbsp Microscopic cross sectional views of FSHD affected muscle fibers Visible is inflammation and fibrosis as well as muscle fiber shape change death and regeneration Unlike other muscular dystrophies early muscle biopsies show only mild degrees of fibrosis muscle fiber hypertrophy and displacement of nuclei from myofiber peripheries central nucleation 27 More often found is inflammation 27 There can be endomysial inflammation primarily composed of CD8 T cells although these cells do not seem to directly cause muscle fiber death 27 Endomysial blood vessels can be surrounded by inflammation which is relatively unique to FSHD and this inflammation contains CD4 T cells 27 Inflammation is succeeded by deposition of fat fatty infiltration then fibrosis 77 27 Individual muscle fibers can appear whorled moth eaten and especially lobulated 78 Muscle involvement pattern edit Why certain muscles are preferentially affected in FSHD remains unknown There are multiple trends of involvement seen in FSHD possibly hinting at underlying pathophysiology Individual muscles can weaken while adjacent muscles remain strong 79 The right shoulder and arm muscles are more often affected than the left upper extremity muscles a pattern also seen in Poland syndrome and hereditary neuralgic amyotrophy this could reflect a genetic developmental anatomic or functional related mechanism 24 25 The deltoid is often spared which is not seen in any other condition that affects the muscles around the scapula 36 nbsp Examples of MRI imaging in FSHD The white within the muscles of the STIR T2 image represents muscle edema The white within the muscles of the T1 images represents fatty infiltration Medical imaging CT and MRI have shown muscle involvement not readily apparent otherwise 37 A single MRI study shows the teres major muscle to be commonly affected 38 The semimembranosus muscle part of the hamstrings is commonly affected 25 80 81 deemed by one author to be the most frequently and severely affected muscle 2 Of the quadriceps muscles the rectus femoris is preferentially affected 80 Of the gastrocnemius the medial section is preferentially affected 80 81 The iliopsoas a hip flexor muscle is very often spared 81 2 Retinopathy edit Tortuosity of the retinal arterioles and less often microaneurysms and telangiectasia are commonly found in FSHD 42 Abnormalities of the capillaries and venules are not observed 42 One theory for why the arterioles are selectively affected is that they contain smooth muscle 42 The degree of D4Z4 contraction correlates to the severity of tortuosity of arterioles 42 It has been hypothesized that retinopathy is due to DUX4 protein induced modulation of the CXCR4 SDF1 axis which has a role in endothelial tip cell morphology and vascular branching 42 Diagnosis edit nbsp American Academy of Neurology ANN guidelines for genetic testing for suspected FSHD Not all laboratories follow this workflow FSHD can be presumptively diagnosed in many cases based on signs symptoms and or non genetic medical tests especially if a first degree relative has genetically confirmed FSHD 10 Genetic testing can provide definitive diagnosis 4 In the absence of an established family history of FSHD diagnosis can be difficult due to the variability in how FSHD manifests 82 Genetic testing edit Genetic testing is the gold standard for FSHD diagnosis as it is the most sensitive and specific test available 2 Commonly FSHD1 is tested for first 2 A shortened D4Z4 array length EcoRI length of 10 kb to 38 kb with an adjacent 4qA allele supports FSHD1 2 If FSHD1 is not present commonly FSHD2 is tested for next by assessing methylation at 4q35 2 Low methylation less than 20 in the context of a 4qA allele is sufficient for diagnosis 2 The specific mutation usually one of various SMCHD1 mutations can be identified with next generation sequencing NGS 83 Assessing D4Z4 length edit Measuring D4Z4 length is technically challenging due to the D4Z4 repeat array consisting of long repetitive elements 84 For example NGS is not useful for assessing D4Z4 length because it breaks DNA into fragments before reading them and it is unclear from which D4Z4 repeat each sequenced fragment came 4 In 2020 optical mapping became available for measuring D4Z4 array length which is more precise and less labor intensive than southern blot 85 Molecular combing is also available for assessing D4Z4 array length 86 These methods which physical measure the size of the D4Z4 repeat array require specially prepared high quality and high molecular weight genomic DNA gDNA from serum increasing cost and reducing accessibility to testing 87 nbsp Diagram showing restriction enzyme sites used to differentiate between D4Z4 repeat arrays of 4q and 10q Restriction fragment length polymorphism RFLP analysis was the first genetic test developed and is still used as of 2020 although it is being phased out by newer methods It involves dicing the DNA with restriction enzymes and sorting the resulting restriction fragments by size using southern blot The restriction enzymes EcoRI and BlnI are commonly used EcoRI isolates the 4q and 10q repeat arrays and BlnI dices the 10q sequence into small pieces allowing 4q to be distinguished 4 50 The EcoRI restriction fragment is composed of three parts 1 5 7 kb proximal part 2 the central variable size D4Z4 repeat array and 3 the distal part usually 1 25 kb 88 The proximal portion has a sequence of DNA stainable by the probe p13E 11 which is commonly used to visualize the EcoRI fragment during southern blot 50 The name p13E 11 reflects that it is a subclone of a DNA sequence designated as cosmid 13E during the human genome project 89 90 Considering that each D4Z4 repeat is 3 3 kb and the EcoRI fragment contains about 5 kb of DNA that is not part of the D4Z4 repeat array the number of D4Z4 units can be calculated 74 D4Z4 repeats EcoRI length 5 3 3Sometimes 4q or 10q will have a combination of D4Z4 and D4Z4 like repeats due to DNA exchange between 4q and 10q which can yield erroneous results requiring more detailed workup 50 Sometimes D4Z4 repeat array deletions can include the p13E 11 binding site warranting use of alternate probes 50 91 Assessing methylation status edit Methylation status of 4q35 is traditionally assessed after FSHD1 testing is negative Methylation sensitive restriction enzyme MSRE digestion showing hypomethylation has long been considered diagnostic of FSHD2 87 Other methylation assays have been proposed or used in research settings including methylated DNA immunoprecipitation and bisulfite sequencing but are not routinely used in clinical practice 92 87 Bisulfite sequencing if validated would be valuable due to it being able to use lower quality DNA sources such as those found in saliva 87 Auxiliary testing edit nbsp MRI showing asymmetrical involvement of various muscles in FSHDOther tests can support the diagnosis of FSHD although they are all less sensitive and less specific than genetic testing 93 4 Nonetheless they can rule out similar appearing conditions 14 Creatine kinase CK blood level is often ordered when muscle damage is suspected CK is an enzyme found in muscle leaking into the blood when muscles become damaged In FSHD CK level is normal to mildly elevated 2 never exceeding five times the upper limit of normal 4 Electromyogram EMG measures the electrical activity in the muscle EMG can show nonspecific signs of muscle damage or irritability 2 Nerve conduction velocity NCV measures the how fast signals travel along a nerve The nerve signals are measured with surface electrodes similar to those used for an electrocardiogram or needle electrodes Muscle biopsy is the surgical removal and examination of a small piece of muscle usually from the arm or leg Microscopy and a variety of biochemical tests are used for examination Findings in FSHD are nonspecific such as presence of white blood cells or variation in muscle fiber size This test is rarely indicated 2 Muscle MRI is sensitive for detecting muscle damage even in mild cases T1 weighted MRI imaging can visualize fatty infiltration of muscles and T2 weighted MRI imaging can visualize muscle edema citation needed Because of the particular muscle involvement patterns of FSHD MRI can help differentiate FSHD from other muscle diseases directing genetic testing 37 38 Differential diagnosis edit Included in the differential diagnosis of FSHD are limb girdle muscular dystrophy especially calpainopathy 2 scapuloperoneal myopathy 94 mitochondrial myopathy 2 Pompe disease 2 and polymyositis 2 Calpainopathy and scapuloperoneal myopathy like FSHD present with scapular winging 94 Features that suggest FSHD are facial weakness asymmetric weakness and lack of benefit from immunosuppression medications 2 Features the suggest an alternative diagnosis are contractures respiratory insufficiency weakness of muscles controlling eye movement and weakness of the tongue or throat 14 Management editNo pharmacologic treatment has proven to significantly slow progression of weakness or meaningfully improve strength 95 2 10 Screening and monitoring of complications edit The American Academy of Neurology AAN recommends several medical tests to detect complications of FSHD 95 A dilated eye exam to look for retinal abnormalities is recommended in those newly diagnosed with FSHD for those with large D4Z4 deletions an evaluation by a retinal specialist is recommended yearly 96 2 A hearing test is recommended for individuals with early onset FSHD prior to starting school or for any other FSHD affected individual with symptoms of hearing loss 96 2 Pulmonary function testing PFT is recommended in those newly diagnosed to establish baseline pulmonary function 2 and recurrently for those with pulmonary insufficiency symptoms or risks 96 2 Routine screening for heart conditions such as through an electrocardiogram EKG or echocardiogram echo is considered unnecessary in those without symptoms of heart disease 95 Physical and occupational therapy edit Aerobic exercise has been shown to reduce chronic fatigue and decelerate fatty infiltration of muscle in FSHD 97 98 Physical activity in general might slow disease progression in the legs 10 The AAN recommends that people with FSHD engage in low intensity aerobic exercise to promote energy levels muscle health and bone health 2 Moderate intensity strength training appears to do no harm although it has not been shown to be beneficial 99 Physical therapy can address specific symptoms there is no standardized protocol for FSHD Anecdotal reports suggest that appropriately applied kinesiology tape can reduce pain 100 Occupational therapy can be used for training in activities of daily living ADLs and to help adapt to new assistive devices Cognitive behavioral therapy CBT has been shown to reduce chronic fatigue in FSHD and it also decelerates fatty infiltration of muscle when directed towards increasing daily activity 97 98 Braces are often used to address muscle weakness Scapular bracing can improve scapular positioning which improves shoulder function although it is often deemed as ineffective or impractical 101 Ankle foot orthoses can improve walking balance and quality of life 102 Pharmacologic management edit No pharmaceuticals have definitively proven effective for altering the disease course 95 Although a few pharmaceuticals have shown improved muscle mass in limited respects they did not improve quality of life and the AAN recommends against their use for FSHD 95 Reconstructive surgery edit Scapular winging is amenable to surgical correction namely operative scapular fixation Scapular fixation is restriction and stabilization of the position of the scapula putting it in closer apposition to the rib cage and reducing winging Absolute restriction of scapular motion by fixation of the scapula to the ribs is most commonly reported 103 This procedure often involves inducing bony fusion called arthrodesis between the scapula and ribs Names for this include scapulothoracic fusion scapular fusion and scapulodesis This procedure increases arm active range of motion improves arm function decreases pain and improves cosmetic appearance 104 105 Active range of motion of the arm increases most in the setting of severe scapular winging with an unaffected deltoid muscle 11 however passive range of motion decreases In other words the patient gains the ability to slowly raise their arms to 90 degrees but they lose the ability to throw their arm up to a full 180 degrees 2 The AAN states that scapular fixation can be offered cautiously to select patients after balancing these benefits against the adverse consequences of surgery and prolonged immobilization 95 10 Another form of operative scapular fixation is scapulopexy Scapulo refers to the scapula bone and pexy is derived from the Greek root to bind Some versions of scapulopexy accomplish essentially the same result as scapulothoracic fusion but instead of inducing bony fusion the scapula is secured to the ribs with only wire tendon grafts or other material Some versions of scapulopexy do not completely restrict scapular motion examples including tethering the scapula to the ribs vertebrae or other scapula 103 106 Scapulopexy is considered to be more conservative than scapulothoracic fusion with reduced recovery time and less effect on breathing 103 However they also seem more susceptible to long term failure 103 Another form of scapular fixation although not commonly done in FSHD is tendon transfer which involves surgically rearranging the attachments of muscles to bone 103 107 108 Examples include pectoralis major transfer and the Eden Lange procedure Various other surgical reconstructions have been described Upper eyelid gold implants have been used for those unable to close their eyes 109 Drooping lower lip has been addressed with plastic surgery 110 Select cases of foot drop can be surgically corrected with tendon transfer in which the tibialis posterior muscle is repurposed as a tibialis anterior muscle a version of this being called the Bridle procedure 111 112 100 Severe scoliosis caused by FSHD can be corrected with spinal fusion however since scoliosis might be a compensatory change in response to muscle weakness correction of spinal alignment can result in further impaired muscle function Scapular winging management nbsp Kinesiology tape applied across the scapulas nbsp A cloth brace to hold the scapulas in retraction to reduce shoulder symptoms such as collarbone pain nbsp Scapula to scapula scapulopexy pre and post operation The scapulas are tethered together into a retracted position with an Achilles tendon graft which in this case rendered the rhomboid major muscles distinguishable Prognosis editGenetics partially predicts prognosis 95 Those with large D4Z4 repeat deletions with a remaining D4Z4 repeat array size of 10 20 kbp or 1 4 repeats are more likely to have severe and early disease as well as non muscular symptoms 95 Those who have the genetic mutations of both FSHD1 and FSHD2 are more likely to have severe disease 70 It has also been observed that D4Z4 shortening is less and disease manifestation is milder when a prominent family history is present as opposed to a new mutation 113 In some large families 30 of those with the mutation had no noticeable symptoms and 30 of those with symptoms did not progress beyond facial and shoulder weakness 24 Women tend to develop symptoms later in life and have less severe disease courses 108 Remaining variations in disease course are attributed to unknown environmental factors A single study found that disease course is not worsened by tobacco smoking or alcohol consumption common risk factors for other diseases 114 Pregnancy edit Pregnancy outcomes are overall good in mothers with FSHD there is no difference in rate of preterm labor rate of miscarriage and infant outcomes 115 However weakness can increase the need for assisted delivery 115 A single review found that weakness worsens without recovery in 12 of mothers with FSHD during pregnancy although this might be due to weight gain or deconditioning 115 Epidemiology editThe prevalence of FSHD ranges from 1 in 8 333 to 1 in 15 000 2 The Netherlands reports a prevalence of 1 in 8 333 after accounting for the undiagnosed 116 The prevalence in the United States is commonly quoted as 1 in 15 000 15 After genetic testing became possible in 1992 average prevalence was found to be around 1 in 20 000 a large increase compared to before 1992 117 24 116 However 1 in 20 000 is likely an underestimation since many with FSHD have mild symptoms and are never diagnosed or they are siblings of affected individuals and never seek definitive diagnosis 116 Race and ethnicity have not been shown to affect FSHD incidence or severity 15 Although the inheritance of FSHD shows no predilection for biological sex the disease manifests less often in women and even when it manifests in women they on average are less severely affected than affected males 15 Estrogen has been suspected to be a protective factor that accounts for this discrepancy One study found that estrogen reduced DUX4 activity 118 However another study found no association between disease severity and lifetime estrogen exposure in females The same study found that disease progression was not different through periods of hormonal changes such as menarche pregnancy and menopause 119 History editThe first description of a person with FSHD in medical literature appears in an autopsy report by Jean Cruveilhier in 1852 16 17 In 1868 Duchenne published his seminal work on Duchenne muscular dystrophy and as part of its differential was a description of FSHD 120 17 First in 1874 then with a more commonly cited publication in 1884 and again with pictures in 1885 the French physicians Louis Landouzy and Joseph Dejerine published details of the disease recognizing it as a distinct clinical entity and thus FSHD is sometimes referred to as Landouzy Dejerine disease 18 17 In their paper of 1886 Landouzy and Dejerine drew attention to the familial nature of the disorder and mentioned that four generations were affected in the kindred that they had investigated 121 Formal definition of FSHD s clinical features did not occur until 1952 when a large Utah family with FSHD was studied Beginning about 1980 an increasing interest in FSHD led to increased understanding of the great variability in the disease and a growing understanding of the genetic and pathophysiological complexities By the late 1990s researchers were finally beginning to understand the regions of chromosome 4 associated with FSHD 52 Since the publication of the unifying theory in 2010 researchers continued to refine their understanding of DUX4 With increasing confidence in this work researchers proposed the first a consensus view in 2014 of the pathophysiology of the disease and potential approaches to therapeutic intervention based on that model 27 Alternate and historical names for FSHD include the following facioscapulohumeral disease 23 faciohumeroscapular citation needed Landouzy Dejerine disease 23 or syndrome 121 or type of muscular dystrophy 23 Erb Landouzy Dejerine syndrome citation needed Chronology of important FSHD related genetic research edit 1861 Person with muscular dystrophy depicted by Duchenne Based on the muscles involved this person could have had FSHD nbsp 1884 Landouzy and Dejerine describe a form of childhood progressive muscle atrophy with a characteristic involvement of facial muscles and distinct from pseudohypertrophic Duchenne s MD and spinal muscle atrophy in adults 122 Two brothers with FSHD followed by Landouzy and Dejerine nbsp Photograph of one brother at age 21 The right scapula is protracted downwardly rotated and laterally displaced nbsp Drawing of another brother at age 17 Visible is lumbar hyperlordosis The upper arm and pectoral muscles appear atrophied 1886 Landouzy and Dejerine describe progressive muscular atrophy of the scapulo humeral type 123 1950 Tyler and Stephens study 1249 individuals from a single kindred with FSHD traced to a single ancestor and describe a typical Mendelian inheritance pattern with complete penetrance and highly variable expression The term facioscapulohumeral dystrophy is introduced 124 1982 Padberg provides the first linkage studies to determine the genetic locus for FSHD in his seminal thesis Facioscapulohumeral disease 23 1987 The complete sequence of the Dystrophin gene Duchenne s MD is determined 125 1991 The genetic defect in FSHD is linked to a region 4q35 near the tip of the long arm of chromosome 4 126 1992 FSHD in both familial and de novo cases is found to be linked to a recombination event that reduces the size of 4q EcoR1 fragment to lt 28 kb 50 300 kb normally 89 1993 4q EcoR1 fragments are found to contain tandem arrangement of multiple 3 3 kb units D4Z4 and FSHD is associated with the presence of lt 11 D4Z4 units 88 A study of seven families with FSHD reveals evidence of genetic heterogeneity in FSHD 127 1994 The heterochromatic structure of 4q35 is recognized as a factor that may affect the expression of FSHD possibly via position effect variegation 128 DNA sequencing within D4Z4 units shows they contain an open reading frame corresponding to two homeobox domains but investigators conclude that D4Z4 is unlikely to code for a functional transcript 128 129 1995 The terms FSHD1A and FSHD1B are introduced to describe 4q linked and non 4q linked forms of the disease 130 1996 FSHD Region Gene1 FRG1 is discovered 100 kb proximal to D4Z4 131 1998 Monozygotic twins with vastly different clinical expression of FSHD are described 20 1999 Complete sequencing of 4q35 D4Z4 units reveals a promoter region located 149 bp 5 from the open reading frame for the two homeobox domains indicating a gene that encodes a protein of 391 amino acid protein later corrected to 424 aa 132 given the name DUX4 133 2001 Investigators assessed the methylation state heterochromatin is more highly methylated than euchromatin of DNA in 4q35 D4Z4 An examination of SmaI MluI SacII and EagI restriction fragments from multiple cell types including skeletal muscle revealed no evidence for hypomethylation in cells from FSHD1 patients relative to D4Z4 from unaffected control cells or relative to homologous D4Z4 sites on chromosome 10 However in all instances D4Z4 from sperm was hypomethylated relative to D4Z4 from somatic tissues 134 2002 A polymorphic segment of 10 kb directly distal to D4Z4 is found to exist in two allelic forms designated 4qA and 4qB FSHD1 is associated solely with the 4qA allele 135 Three genes FRG1 FRG2 ANT1 located in the region just centromeric to D4Z4 on chromosome 4 are found in isolated muscle cells from individuals with FSHD at levels 10 to 60 times greater than normal showing a linkage between D4Z4 contractions and altered expression of 4q35 genes 136 2003 A further examination of DNA methylation in different 4q35 D4Z4 restriction fragments BsaAI and FseI showed significant hypomethylation at both sites for individuals with FSHD1 non FSHD expressing gene carriers and individuals with phenotypic FSHD relative to unaffected controls 137 2004 Contraction of the D4Z4 region on the 4qB allele to lt 38 kb does not cause FSHD 138 2006 Transgenic mice overexpressing FRG1 are shown to develop severe myopathy 139 2007 The DUX4 open reading frame is found to have been conserved in the genome of primates for over 100 million years supporting the likelihood that it encodes a required protein 140 Researchers identify DUX4 mRNA in primary FSHD myoblasts and identify in D4Z4 transfected cells a DUX4 protein the overexpression of which induces cell death 132 DUX4 mRNA and protein expression are reported to increase in myoblasts from FSHD patients compared to unaffected controls Stable DUX4 mRNA is transcribed only from the most distal D4Z4 unit which uses an intron and a polyadenylation signal provided by the flanking pLAM region DUX4 protein is identified as a transcription factor and evidence suggests overexpression of DUX4 is linked to an increase in the target paired like homeodomain transcription factor 1 PITX1 141 2009 The terms FSHD1 and FSHD2 are introduced to describe D4Z4 deletion linked and non D4Z4 deletion linked genetic forms respectively In FSHD1 hypomethylation is restricted to the short 4q allele whereas FSHD2 is characterized by hypomethylation of both 4q and both 10q alleles 142 Splicing and cleavage of the terminal most telomeric 4q D4Z4 DUX4 transcript in primary myoblasts and fibroblasts from FSHD patients is found to result in the generation of multiple RNAs including small noncoding RNAs antisense RNAs and capped mRNAs as new candidates for the pathophysiology of FSHD 143 Mechanism proposed of DBE T D4Z4 Regulatory Element transcript leading to de repression of 4q35 genes 59 2010 A unifying genetic model of FSHD is established D4Z4 contractions only cause FSHD when in the context of a 4qA allele due to stabilization of DUX4 RNA transcript allowing DUX4 expression 8 Several organizations including The New York Times highlighted this research 144 See FSHD Society Dr Francis Collins who oversaw the first sequencing of the Human Genome with the National Institutes of Health stated 144 If we were thinking of a collection of the genome s greatest hits this would go on the list Daniel Perez co founder of the FSHD Society hailed the new findings saying 145 This is a long sought explanation of the exact biological workings of FSHD The MDA stated that citation needed Now the hunt is on for which proteins or genetic instructions RNA cause the problem for muscle tissue in FSHD One of the report s co authors Silvere van der Maarel of the University of Leiden stated that citation needed It is amazing to realize that a long and frustrating journey of almost two decades now culminates in the identification of a single small DNA variant that differs between patients and people without the disease We finally have a target that we can go after DUX4 is found actively transcribed in skeletal muscle biopsies and primary myoblasts FSHD affected cells produce a full length transcript DUX4 fl whereas alternative splicing in unaffected individuals results in the production of a shorter 3 truncated transcript DUX4 s The low overall expression of both transcripts in muscle is attributed to relatively high expression in a small number of nuclei 1 in 1000 Higher levels of DUX4 expression in human testis 100 fold higher than skeletal muscle suggest a developmental role for DUX4 in human development Higher levels of DUX4 s vs DUX4 fl are shown to correlate with a greater degree of DUX 4 H3K9me3 methylation 7 2012 Some instances of FSHD2 are linked to mutations in the SMCHD1 gene on chromosome 18 and a genetic mechanistic intersection of FSHD1 and FSHD2 is established 65 The prevalence of FSHD like D4Z4 deletions on permissive alleles is significantly higher than the prevalence of FSHD in the general population challenging the criteria for molecular diagnosis of FSHD 146 When expressed in primary myoblasts DUX4 fl acted as a transcriptional activator producing a gt 3 fold change in the expression of 710 genes 147 A subsequent study using a larger number of samples identified DUX4 fl expression in myogenic cells and muscle tissue from unaffected relatives of FSHD patients per se is not sufficient to cause pathology and that additional modifiers are determinants of disease progression 148 2013 Mutations in SMCHD1 are shown to increase the severity of FSHD1 70 Transgenic mice carrying D4Z4 arrays from an FSHD1 allele with 2 5 D4Z4 units although lacking an obvious FSHD like skeletal muscle phenotype are found to recapitulate important genetic expression patterns and epigenetic features of FSHD 149 2014 DUX4 fl and downstream target genes are expressed in skeletal muscle biopsies and biopsy derived cells of fetuses with FSHD like D4Z4 arrays indicating that molecular markers of FSHD are already expressed during fetal development 150 Researchers review how the contributions from many labs over many years led to an understanding of a fundamentally new mechanism of human disease and articulate how the unifying genetic model and subsequent research represent a pivot point in FSHD research transitioning the field from discovery oriented studies to translational studies aimed at developing therapies based on a sound model of disease pathophysiology They describe the consensus mechanism of pathophysiology for FSHD as an inefficient repeat mediated epigenetic repression of the D4Z4 macrosatellite repeat array on chromosome 4 resulting in the variegated expression of the DUX4 retrogene encoding a double homeobox transcription factor in skeletal muscle 27 2020 Voice of the Patient Report released documenting FSHD s impacts on daily life as conveyed by about 400 patients during an FDA externally led Patient Focused Drug Development meeting which was held on June 29 2020 32 30 31 33 Past pharmaceutical development edit Early drug trials before the pathogenesis involving DUX4 was discovered were untargeted and largely unsuccessful 19 Compounds were trialed with goals of increasing muscle mass decreasing inflammation or addressing provisional theories of disease mechanism 19 The following drugs failed to show efficacy Prednisone a steroid based on its antiinflammatory properties and therapeutic effect in Duchenne muscular dystrophy 151 Oral albuterol a b2 agonist on the basis of its anabolic properties Although it improved muscle mass and certain measures of strength in those with FSHD it did not improve global strength or function 152 153 154 Interestingly b2 agonists were later shown to reduce DUX4 expression 155 Diltiazem a calcium channel blocker on the bases of anecdotal reports of benefit and the theory that calcium dysregulation played a part in muscle cell death 156 MYO 029 Stamulumab an antibody that inhibits myostatin was developed to promote muscle growth Myostatin is a protein that inhibits the growth of muscle tissue 157 ACE 083 a TGF b inhibitor was developed to promote muscle growth 158 Society and culture editMedia edit In the Amazon Video series The Man in the High Castle Obergruppenfuhrer John Smith s son Thomas is diagnosed with Landouzy Dejerine syndrome 159 In the biography Stuart A Life Backwards the protagonist was affected by muscular dystrophy 160 presumably FSHD citation needed Good Bad Things a independent film about an entrepreneur afflicted with FSHD and his journey of transformation self acceptance and discovery The movie premiered at the 2024 Slamdance Film Festival 161 162 The Lost Voice a short film featuring Dr Tristram Ingham who lives with FSHD Dr Ingham used Apple s Personal Voice feature to recreate his voice and use it to read a children s book titled The Lost Voice for International Day of Persons with Disabilities in 2023 163 Patient and research organizations edit The FSHD Society named FSH Society until 2019 164 was founded in 1991 on the East Coast by two individuals with FSHD Daniel Perez and Stephen Jacobsen 165 166 The FSHD Society claims to have advocated for the standardization of the disease name facioscapulohumeral muscular dystrophy and its abbreviation FSHD 164 The FSHD Society claims to have raised funding for seed grants for FSHD research and co wrote the MD CARE Act of 2001 which provided federal funding for all muscular dystrophies 165 166 The FSHD Society has grown into the world s largest grassroots organization advocating for patient education and scientific and medical research for FSHD 167 168 One notable spokesperson for FSHD Society has been Max Adler an actor on the TV series Glee 169 Friends of FSH Research is a research oriented nonprofit organization founded in 2004 by Terry and Rick Colella from Kirkland Washington after their son was diagnosed with FSHD 170 171 172 173 The FSHD Global Research Foundation was founded in 2007 by Bill Moss in Australia a former Macquarie Bank executive affected by FSHD 174 175 176 It is currently directed by Moss s daughter 175 It was named Australian charity of the year for 2017 175 It is the largest funder of FSHD medical research outside of the United States as of 2018 176 FSHD EUROPE was founded in 2010 177 Spanning multiple countries in Europe it has launched the European Trial Network 177 Notable cases edit Chip Wilson is a Canadian billionaire and founder of Lululemon He has pledged 100 million Canadian dollars to research through the venture Solve FSHD 178 Chris Carrino is the radio voice of the Brooklyn Nets He founded the Chris Carrino Foundation for FSHD oriented towards research funding 179 Madison Ferris is an American actress with FSHD who was the first wheelchair user to play a lead on Broadway 180 181 Morgan Hoffmann is an American professional golfer He started the Morgan Hoffmann Foundation oriented towards research funding 182 Dr Arnold Gold 1925 2024 was a pediatric neurologist founder of the Arnold P Gold Foundation and creator of white coat ceremonies Dr Gold focused on patient centered care and humanism 183 Research directions editPharmaceutical development edit source source source source source source source Timelapse of DUX4 expression in FSHD muscle cells 184 After achieving consensus on FSHD pathophysiology in 2014 researchers proposed four approaches for therapeutic intervention 27 enhance the epigenetic repression of the D4Z4 target the DUX4 mRNA including altering splicing or polyadenylation block the activity of the DUX4 protein inhibit the DUX4 induced process or processes that leads to pathology Small molecule drugsMost drugs used in medicine are small molecule drugs as opposed to biologic medical products that include proteins vaccines and nucleic acids Small molecule drugs can typically be taken by ingestion rather than injection Losmapimod a selective inhibitor of p38a b mitogen activated protein kinases was identified by Fulcrum Therapeutics as a potent suppressor of DUX4 in vitro 185 Results of a phase IIb clinical trial revealed in June 2021 showed statistically significant slowing of muscle function deterioration Further trials are pending 186 187 Casein kinase 1 CK1 inhibition has been identified by Facio Therapies a Dutch pharmaceutical company to repress DUX4 expression and is in preclinical development Facio Therapies claims that CK1 inhibition leaves myotube fusion intact unlike BET inhibitors p38 MAPK inhibitors and b2 agonists 188 189 Gene therapyGene therapy is the administration of nucleotides to treat disease Multiple types of gene therapy are in the preclinical stage of development for the treatment of FSHD Antisense therapy utilizes antisense oligonucleotides that bind to DUX4 messenger RNA inducing its degradation and preventing DUX4 protein production Phosphorodiamidate morpholinos an oligonucleotide modified to increase its stability have been shown to selectively reduce DUX4 and its effects however these antisense nucleotides have poor ability to penetrate muscle 2 MicroRNAs miRNAs directed against DUX4 delivered by viral vectors have shown to reduce DUX4 protect against muscle pathology and prevent loss of grip strength in mouse FSHD models 2 Arrowhead pharmaceuticals is developing an RNA interference therapeutic against DUX4 named ARO DUX4 and intends to file for regulatory clearance in third quarter of 2021 to begin clinical trials 190 191 192 Genome editing the permanent alteration of genetic code is being researched One study tried to use CRISPR Cas9 to knockout the polyadenylation signal in lab dish models but was unable to show therapeutic results 193 Potential drug targets Inhibition of the hyaluronic acid HA pathway is a potential therapy One study found that many DUX4 induced molecular pathologies are mediated by HA signaling and inhibition of HA biosynthesis with 4 methylumbelliferone prevented these molecular pathologies 194 P300 inhibition has shown to inhibit the deleterious effects of DUX4 195 BET inhibitors have been shown to reduce DUX4 expression 155 Antioxidants could potentially reduce the effects of FSHD One study found that vitamin C vitamin E zinc gluconate and selenomethionine supplementation increased endurance and strength of the quadriceps but had no significant benefit on walking performance 196 Further study is warranted 2 Outcome measures edit Ways of measuring the disease are important for studying disease progression and assessing the efficacy of drugs in clinical trials Reachable workspace uses the Kinect motion sensing system to compare range of reach before and after a therapeutic clinical trial 197 Quality of life can be measured with questionnaires such as the FSHD Health Index 198 2 How the disease affects daily activities can measured with questionnaires such as the FSHD Rasch built overall disability scale FSHD RODS 199 or FSHD composite outcome measure FSHD COM 200 Electrical impedance myography is being studied as a way to measure muscle damage 2 Muscle MRI is useful for assessment of all the muscles in the body Muscles can be scored based on the degree of fat infiltration 2 References edit The sources listed below differ on pronunciation of the u in scapulo A long u sound in an unstressed nonfinal syllable is often reduced to a schwa and varies by speaker Facioscapulohumeral Merriam Webster com Dictionary Facioscapulohumeral Medical Dictionary Farlex and Partners 2009 a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj ak al am an ao ap aq ar as at au av aw ax Wagner Kathryn R December 2019 Facioscapulohumeral Muscular Dystrophies CONTINUUM Lifelong Learning in Neurology 25 6 1662 1681 doi 10 1212 CON 0000000000000801 PMID 31794465 S2CID 208531681 Stedman Thomas 1987 Webster s New World Stedman s Concise Medical Dictionary 1 ed Baltimore Williams amp Wilkins p 230 ISBN 0139481427 a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae Mul Karlien Lassche Saskia Voermans Nicol C Padberg George W Horlings Corinne GC van Engelen Baziel GM June 2016 What s in a name The clinical features of facioscapulohumeral muscular dystrophy Practical Neurology 16 3 201 207 doi 10 1136 practneurol 2015 001353 PMID 26862222 S2CID 4481678 a b Kumar Vinay Abbas Abul Aster Jon eds 2018 Robbins Basic Pathology Tenth ed Philadelphia Pennsylvania Elsevier p 844 ISBN 978 0 323 35317 5 De Iaco A Planet E Coluccio A Verp S Duc J Trono D June 2017 DUX family transcription factors regulate zygotic genome activation in placental mammals Nature Genetics 49 6 941 945 doi 10 1038 ng 3858 PMC 5446900 PMID 28459456 a b c Snider L Geng LN Lemmers RJ Kyba M Ware CB Nelson AM Tawil R Filippova GN van der Maarel SM Tapscott SJ Miller DG 28 October 2010 Facioscapulohumeral dystrophy incomplete suppression of a retrotransposed gene PLOS Genetics 6 10 e1001181 doi 10 1371 journal pgen 1001181 PMC 2965761 PMID 21060811 a b c d e f g h i j k Lemmers RJ van der Vliet PJ Klooster R Sacconi S Camano P Dauwerse JG Snider L Straasheijm KR van Ommen GJ Padberg GW Miller DG Tapscott SJ Tawil R Frants RR van der Maarel SM 19 August 2010 A Unifying Genetic Model for Facioscapulohumeral Muscular Dystrophy PDF Science 329 5999 1650 3 Bibcode 2010Sci 329 1650L doi 10 1126 science 1189044 hdl 1887 117104 PMC 4677822 PMID 20724583 Archived from the original PDF on 2014 06 05 Lemmers RJ Wohlgemuth M van der Gaag KJ et al November 2007 Specific sequence variations within the 4q35 region are associated with facioscapulohumeral muscular dystrophy Am J Hum Genet 81 5 884 94 doi 10 1086 521986 PMC 2265642 PMID 17924332 a b c d e f g h Mul K 1 December 2022 Facioscapulohumeral Muscular Dystrophy Continuum Minneapolis Minn 28 6 1735 1751 doi 10 1212 CON 0000000000001155 PMID 36537978 S2CID 254883066 a b Eren Ilker Birsel Olgar Oztop Cakmak Ozgur Aslanger Ayca Gursoy Ozdemir Yasemin Eraslan Serpil Kayserili Hulya Oflazer Piraye Demirhan Mehmet May 2020 A novel shoulder disability staging system for scapulothoracic arthrodesis in patients with facioscapulohumeral dystrophy Orthopaedics amp Traumatology Surgery amp Research 106 4 701 707 doi 10 1016 j otsr 2020 03 002 PMID 32430271 Theadom A Rodrigues M Roxburgh R Balalla S Higgins C Bhattacharjee R Jones K Krishnamurthi R Feigin V 2014 Prevalence of muscular dystrophies a systematic literature review Neuroepidemiology 43 3 4 259 68 doi 10 1159 000369343 hdl 10292 13206 PMID 25532075 S2CID 2426923 Mah JK Korngut L Fiest KM Dykeman J Day LJ Pringsheim T Jette N January 2016 A Systematic Review and Meta analysis on the Epidemiology of the Muscular Dystrophies The Canadian Journal of Neurological Sciences Le Journal Canadien des Sciences Neurologiques 43 1 163 77 doi 10 1017 cjn 2015 311 PMID 26786644 S2CID 24936950 a b c d e f g h i j k Tawil R Van Der Maarel SM July 2006 Facioscapulohumeral muscular dystrophy PDF Muscle amp Nerve 34 1 1 15 doi 10 1002 mus 20522 PMID 16508966 S2CID 43304086 a b c d Statland JM Tawil R December 2016 Facioscapulohumeral Muscular Dystrophy Continuum Minneapolis Minn 22 6 Muscle and Neuromuscular Junction Disorders 1916 1931 doi 10 1212 CON 0000000000000399 PMC 5898965 PMID 27922500 a b Cruveilhiers J 1852 1853 Memoire sur la paralysie musculaire atrophique Bulletins de l Academie de Medecine 18 490 502 546 583 a b c d Rogers Mark T 2004 Facioscapulohumeral muscular dystrophy historical background and literature review In Upadhyaya Meena Cooper David N eds FSHD facioscapulohumeral muscular dystrophy clinical medicine and molecular cell biology BIOS Scientific Publishers ISBN 1 85996 244 0 a b Landouzy L Dejerine J 1885 Landouzy L Lepine R eds De la myopathie atrophique progressive myopathie sans neuropathie debutant d ordinaire dans l enfance par la face Revue de Medecine in French Felix Alcan 5 253 366 Retrieved 19 May 2020 a b c Cohen Justin DeSimone Alec Lek Monkol Lek Angela October 2020 Therapeutic Approaches in Facioscapulohumeral Muscular Dystrophy Trends in Molecular Medicine 27 2 123 137 doi 10 1016 j molmed 2020 09 008 PMC 8048701 PMID 33092966 a b Tupler R Barbierato L et al Sep 1998 Identical de novo mutation at the D4F104S1 locus in monozygotic male twins affected by facioscapulohumeral muscular dystrophy FSHD with different clinical expression Journal of Medical Genetics 35 9 778 783 doi 10 1136 jmg 35 9 778 PMC 1051435 PMID 9733041 Tawil R Storvick D Feasby TE Weiffenbach B Griggs RC February 1993 Extreme variability of expression in monozygotic twins with FSH muscular dystrophy Neurology 43 2 345 8 doi 10 1212 wnl 43 2 345 PMID 8094896 S2CID 44422140 Pandya Shree Eichinger Kate Physical Therapy for Facioscapulohumeral Muscular Dystrophy PDF FSHD Society Archived from the original PDF on 14 April 2020 Retrieved 14 April 2020 a b c d e Padberg GW 1982 10 13 Facioscapulohumeral disease Thesis Leiden University a b c d e f g h i j k l Padberg George W 2004 Facioscapulohumeral muscular dystrophy a clinician s experience In Upadhyaya Meena Cooper David N eds FSHD Facioscapulohumeral Muscular Dystrophy Clinical Medicine and Molecular Cell Biology BIOS Scientific Publishers ISBN 1 85996 244 0 a b c Rijken NH van der Kooi EL Hendriks JC van Asseldonk RJ Padberg GW Geurts AC van Engelen BG December 2014 Skeletal muscle imaging in facioscapulohumeral muscular dystrophy pattern and asymmetry of individual muscle involvement Neuromuscular Disorders 24 12 1087 96 doi 10 1016 j nmd 2014 05 012 PMID 25176503 S2CID 101093 Bergsma A Cup EH Janssen MM Geurts AC de Groot IJ February 2017 Upper limb function and activity in people with facioscapulohumeral muscular dystrophy a web based survey Disability and Rehabilitation 39 3 236 243 doi 10 3109 09638288 2016 1140834 PMID 26942834 S2CID 4237308 a b c d e f g h i j k l m n Tawil Rabi van der Maarel SM Tapscott SJ 10 June 2014 Facioscapulohumeral dystrophy the path to consensus on pathophysiology Skeletal Muscle 4 1 12 doi 10 1186 2044 5040 4 12 PMC 4060068 PMID 24940479 Jia FF Drew AP Nicholson GA Corbett A Kumar KR 2 October 2021 Facioscapulohumeral muscular dystrophy type 2 an update on the clinical genetic and molecular findings Neuromuscular Disorders 31 11 1101 1112 doi 10 1016 j nmd 2021 09 010 PMID 34711481 S2CID 238246093 a b Upadhyaya Meena Cooper David eds March 2004 FSHD Facioscapulohumeral Muscular Dystrophy Clinical Medicine and Molecular Cell Biology BIOS Scientific Publishers ISBN 0203483677 a b The FDA held an externally led Patient Focused Drug Development meeting with about 400 FSHD patients on June 29 2020 resulting in a seminal document called the Voice of the Patient Report The report captures the impact of FSHD on the daily lives of those with the disease as conveyed by the patients themselves While FSHD is often perceived to be mild the report shows that over 80 of patients report being moderately or severely limited in daily activities Society FSHD FSHD Society releases Voice of the Patient Report on FSH muscular dystrophy www prweb com Retrieved 2024 01 31 a b Society FSHD Facioscapulohumeral muscular dystrophy community speaks to the FDA www prweb com Retrieved 2024 01 31 a b Voice of the Patient Forum Patient Focused Drug Development Meeting retrieved 2024 01 31 a b Overman Debbie 2020 11 13 People Living with FSHD Tell Their Stories in New Report Rehab Management Retrieved 2024 01 31 a b Mul K Berggren KN Sills MY McCalley A van Engelen BGM Johnson NE Statland JM 26 February 2019 Effects of weakness of orofacial muscles on swallowing and communication in FSHD Neurology 92 9 e957 e963 doi 10 1212 WNL 0000000000007013 PMC 6404471 PMID 30804066 Wohlgemuth M de Swart BJ Kalf JG Joosten FB Van der Vliet AM Padberg GW 27 June 2006 Dysphagia in facioscapulohumeral muscular dystrophy Neurology 66 12 1926 8 doi 10 1212 01 wnl 0000219760 76441 f8 PMID 16801662 S2CID 7695047 a b A giant of FSHD research shares his regrets FSHD Society Way Back Machine 30 September 2020 Archived from the original on 24 October 2020 Retrieved 11 March 2021 Another striking aspect of FSHD is that muscles weakness seems to vary so much from patient to patient Nonetheless there is a highly characteristic pattern of muscle weakness otherwise we would never have been able to recognize FSHD as a specific disease Padberg said Strong deltoid muscle does not occur in any other condition that involves weakness of scapular stabilizers No other muscle disease with shoulder girdle involvement has this pattern Unfortunately an explanation is beyond our grasp as we don t know how muscle are laid down during the early stages of human gestation a b c Tasca G Monforte M Iannaccone E Laschena F Ottaviani P Leoncini E Boccia S Galluzzi G Pelliccioni M Masciullo M Frusciante R Mercuri E Ricci E 2014 Upper girdle imaging in facioscapulohumeral muscular dystrophy PLOS ONE 9 6 e100292 Bibcode 2014PLoSO 9j0292T doi 10 1371 journal pone 0100292 PMC 4059711 PMID 24932477 a b c Gerevini S Scarlato M Maggi L Cava M Caliendo G Pasanisi B Falini A Previtali SC Morandi L March 2016 Muscle MRI findings in facioscapulohumeral muscular dystrophy European Radiology 26 3 693 705 doi 10 1007 s00330 015 3890 1 PMID 26115655 S2CID 24650482 Faux Nightingale Alice Kulshrestha Richa Emery Nicholas Pandyan Anand Willis Tracey Philp Fraser September 2021 Upper limb rehabilitation in fascioscapularhumeral dystrophy FSHD a patients perspective Archives of Rehabilitation Research and Clinical Translation 3 4 100157 doi 10 1016 j arrct 2021 100157 ISSN 2590 1095 PMC 8683863 PMID 34977539 Pandya Shree King Wendy M Tawil Rabi 1 January 2008 Facioscapulohumeral Dystrophy Physical Therapy 88 1 105 113 doi 10 2522 ptj 20070104 PMID 17986494 Liew Wendy K M van der Maarel Silvere M Tawil Rabi 2015 Facioscapulohumeral Dystrophy Neuromuscular Disorders of Infancy Childhood and Adolescence pp 620 630 doi 10 1016 B978 0 12 417044 5 00032 9 ISBN 9780124170445 a b c d e f Goselink RJM Schreur V van Kernebeek CR Padberg GW van der Maarel SM van Engelen BGM Erasmus CE Theelen T 2019 Ophthalmological findings in facioscapulohumeral dystrophy Brain Communications 1 1 fcz023 doi 10 1093 braincomms fcz023 PMC 7425335 PMID 32954265 Padberg G W Brouwer O F de Keizer R J W Dijkman G Wijmenga C Grote J J Frants R R 1995 On the significance of retinal vascular disease and hearing loss in facioscapulohumeral muscular dystrophy Muscle amp Nerve 18 S13 S73 S80 doi 10 1002 mus 880181314 hdl 2066 20764 S2CID 27523889 Lindner Moritz Holz Frank G Charbel Issa Peter 2016 04 27 Spontaneous resolution of retinal vascular abnormalities and macular oedema in facioscapulohumeral muscular dystrophy Clinical amp Experimental Ophthalmology 44 7 627 628 doi 10 1111 ceo 12735 ISSN 1442 6404 PMID 26933772 S2CID 204996841 Trevisan CP Pastorello E Tomelleri G Vercelli L Bruno C Scapolan S Siciliano G Comacchio F December 2008 Facioscapulohumeral muscular dystrophy hearing loss and other atypical features of patients with large 4q35 deletions European Journal of Neurology 15 12 1353 8 doi 10 1111 j 1468 1331 2008 02314 x PMID 19049553 S2CID 26276887 a b Eren I Abay B Gunerbuyuk C Cakmak OO Sar C Demirhan M February 2020 Spinal fusion in facioscapulohumeral dystrophy for hyperlordosis A case report Medicine 99 8 e18787 doi 10 1097 MD 0000000000018787 PMC 7034682 PMID 32080072 Huml Raymond A Perez Daniel P 2015 FSHD The Most Common Type of Muscular Dystrophy Muscular Dystrophy pp 9 19 doi 10 1007 978 3 319 17362 7 3 ISBN 978 3 319 17361 0 Wohlgemuth M van der Kooi EL van Kesteren RG van der Maarel SM Padberg GW 2004 Ventilatory support in facioscapulohumeral muscular dystrophy Neurology 63 1 176 8 CiteSeerX 10 1 1 543 2968 doi 10 1212 01 wnl 0000133126 86377 e8 PMID 15249635 S2CID 31335126 Dowling JJ Weihl CC Spencer MJ November 2021 Molecular and cellular basis of genetically inherited skeletal muscle disorders Nature Reviews Molecular Cell Biology 22 11 713 732 doi 10 1038 s41580 021 00389 z PMC 9686310 PMID 34257452 S2CID 235822532 a b c d e f g Lemmers Richard J L F O Shea Suzanne Padberg George W Lunt Peter W van der Maarel Silvere M May 2012 Best practice guidelines on genetic diagnostics of Facioscapulohumeral muscular dystrophy Workshop 9th June 2010 LUMC Leiden The Netherlands Neuromuscular Disorders 22 5 463 470 doi 10 1016 j nmd 2011 09 004 PMID 22177830 S2CID 39898514 The name D4Z4 is derived from an obsolete nomenclature system used for DNA segments of unknown significance during the human genome project D for DNA 4 for chromosome 4 Z indicates it is a repetitive sequence and 4 is a serial number assigned based on the order of submission White J A McAlpine P J Antonarakis S Cann H Eppig J T Frazer K Frezal J Lancet D Nahmias J Pearson P Peters J Scott A Scott H Spurr N Talbot C Povey S October 1997 NOMENCLATURE Genomics 45 2 468 471 doi 10 1006 geno 1997 4979 PMID 9344684 Fasman KH Letovsky SI Cottingham RW Kingsbury DT 1 January 1996 Improvements to the GDB Human Genome Data Base Nucleic Acids Research 24 1 57 63 doi 10 1093 nar 24 1 57 PMC 145602 PMID 8594601 a b c d Impossible Things Through the looking glass with FSH Dystrophy Researchers Margaret Wahl MDA Quest magazine Vol 14 No 2 March April 2007 Dixit M Ansseau E Tassin A et al November 2007 DUX4 a candidate gene of facioscapulohumeral muscular dystrophy encodes a transcriptional activator of PITX1 Proc Natl Acad Sci U S A 104 46 18157 62 Bibcode 2007PNAS 10418157D doi 10 1073 pnas 0708659104 PMC 2084313 PMID 17984056 a b c d e f Sikrova D Testa AM Willemsen I van den Heuvel A Tapscott SJ Daxinger L Balog J van der Maarel SM 28 June 2023 SMCHD1 and LRIF1 converge at the FSHD associated D4Z4 repeat and LRIF1 promoter yet display different modes of action Communications Biology 6 1 677 doi 10 1038 s42003 023 05053 0 PMC 10307901 PMID 37380887 Coppee Frederique Matteotti Christel Anssaeu Eugenie Sauvage Sebastien Leclercq India Leroy Axelle Marcowycz Aline Gerbaux Cecile Figlewicz Denise Ding Hao Belayew Belayew 2004 The DUX gene family and FSHD In Upadhyaya Meena Cooper David N eds FSHD facioscapulohumeral muscular dystrophy clinical medicine and molecular cell biology BIOS Scientific Publishers ISBN 1 85996 244 0 Rossi M Ricci E Colantoni L et al 2007 The Facioscapulohumeral muscular dystrophy region on 4qter and the homologous locus on 10qter evolved independently under different evolutionary pressure BMC Med Genet 8 8 doi 10 1186 1471 2350 8 8 PMC 1821008 PMID 17335567 Lemmers RJLF van der Vliet PJ Blatnik A Balog J Zidar J Henderson D Goselink R Tapscott SJ Voermans NC Tawil R Padberg GWAM van Engelen BG van der Maarel SM 12 January 2021 Chromosome 10q linked FSHD identifies DUX4 as principal disease gene Journal of Medical Genetics 59 2 jmedgenet 2020 107041 doi 10 1136 jmedgenet 2020 107041 PMC 8273184 PMID 33436523 S2CID 231589589 Himeda CL Jones PL 31 August 2019 The Genetics and Epigenetics of Facioscapulohumeral Muscular Dystrophy Annual Review of Genomics and Human Genetics 20 265 291 doi 10 1146 annurev genom 083118 014933 PMID 31018108 S2CID 131775712 a b Cabianca DS Casa Casa Bodega B et al May 11 2012 A long ncRNA links copy number variation to a polycomb trithorax epigenetic switch in FSHD muscular dystrophy Cell 149 4 819 831 doi 10 1016 j cell 2012 03 035 PMC 3350859 PMID 22541069 a b c d e f Sacconi S Briand Suleau A Gros M Baudoin C Lemmers RJLF Rondeau S Lagha N Nigumann P Cambieri C Puma A Chapon F Stojkovic T Vial C Bouhour F Cao M Pegoraro E Petiot P Behin A Marc B Eymard B Echaniz Laguna A Laforet P Salviati L Jeanpierre M Cristofari G van der Maarel SM 7 May 2019 FSHD1 and FSHD2 form a disease continuum Neurology 92 19 e2273 e2285 doi 10 1212 WNL 0000000000007456 PMC 6537132 PMID 30979860 Tupler R Berardinelli A Barbierato L Frants R Hewitt JE Lanzi G Maraschio P Tiepolo L May 1996 Monosomy of distal 4q does not cause facioscapulohumeral muscular dystrophy Journal of Medical Genetics 33 5 366 70 doi 10 1136 jmg 33 5 366 PMC 1050603 PMID 8733044 Tawil R Forrester J Griggs RC Mendell J Kissel J McDermott M King W Weiffenbach B Figlewicz D June 1996 Evidence for anticipation and association of deletion size with severity in facioscapulohumeral muscular dystrophy The FSH DY Group Annals of Neurology 39 6 744 8 doi 10 1002 ana 410390610 PMID 8651646 S2CID 84518968 Zernov N Skoblov M 13 March 2019 Genotype phenotype correlations in FSHD BMC Medical Genomics 12 Suppl 2 43 doi 10 1186 s12920 019 0488 5 PMC 6416831 PMID 30871534 Sacconi S Salviati L Desnuelle C April 2015 Facioscapulohumeral muscular dystrophy Biochimica et Biophysica Acta BBA Molecular Basis of Disease 1852 4 607 14 doi 10 1016 j bbadis 2014 05 021 PMID 24882751 a b c Lemmers RJ Tawil R Petek LM et al Dec 2012 Digenic inheritance of an SMCHD1 mutation and an FSHD permissive D4Z4 allele causes facioscapulohumeral muscular dystrophy type 2 Nature Genetics 44 12 1370 1374 doi 10 1038 ng 2454 PMC 3671095 PMID 23143600 van den Boogaard ML Lemmers RJLF Balog J Wohlgemuth M Auranen M Mitsuhashi S van der Vliet PJ Straasheijm KR van den Akker RFP Kriek M Laurense Bik MEY Raz V van Ostaijen Ten Dam MM Hansson KBM van der Kooi EL Kiuru Enari S Udd B van Tol MJD Nishino I Tawil R Tapscott SJ van Engelen BGM van der Maarel SM 5 May 2016 Mutations in DNMT3B Modify Epigenetic Repression of the D4Z4 Repeat and the Penetrance of Facioscapulohumeral Dystrophy American Journal of Human Genetics 98 5 1020 1029 doi 10 1016 j ajhg 2016 03 013 PMC 4863565 PMID 27153398 a b Johnson NE Statland JM 7 May 2019 FSHD1 or FSHD2 That is the question The answer It s all just FSHD Neurology 92 19 881 882 doi 10 1212 WNL 0000000000007446 PMID 30979855 S2CID 111390628 a b c Hamanaka Kohei Sikrova Darina Mitsuhashi Satomi Masuda Hiroki Sekiguchi Yukari Sugiyama Atsuhiko Shibuya Kazumoto Lemmers Richard J L F Goossens Remko Ogawa Megumu Nagao Koji Obuse Chikashi Noguchi Satoru Hayashi Yukiko K Kuwabara Satoshi Balog Judit Nishino Ichizo van der Maarel Silvere M 28 May 2020 Homozygous nonsense variant in associated with facioscapulohumeral muscular dystrophy Neurology 94 23 e2441 e2447 doi 10 1212 WNL 0000000000009617 PMC 7455367 PMID 32467133 S2CID 218982743 a b Caputo V Megalizzi D Fabrizio C Termine A Colantoni L Caltagirone C Giardina E Cascella R Strafella C 29 August 2022 Update on the Molecular Aspects and Methods Underlying the Complex Architecture of FSHD Cells 11 17 2687 doi 10 3390 cells11172687 PMC 9454908 PMID 36078093 a b c Sacconi S Lemmers RJ Balog J et al Oct 3 2013 The FSHD2 gene SMCHD1 is a modifier of disease severity in families affected by FSHD1 The American Journal of Human Genetics 93 4 744 751 doi 10 1016 j ajhg 2013 08 004 PMC 3791262 PMID 24075187 a b Lim KRQ Nguyen Q Yokota T 22 January 2020 DUX4 Signalling in the Pathogenesis of Facioscapulohumeral Muscular Dystrophy International Journal of Molecular Sciences 21 3 729 doi 10 3390 ijms21030729 PMC 7037115 PMID 31979100 a b Bosnakovski Darko Shams Ahmed S Yuan Ce da Silva Meiricris T Ener Elizabeth T Baumann Cory W Lindsay Angus J Verma Mayank Asakura Atsushi Lowe Dawn A Kyba Michael 6 April 2020 Transcriptional and cytopathological hallmarks of FSHD in chronic DUX4 expressing mice Journal of Clinical Investigation 130 5 2465 2477 doi 10 1172 JCI133303 PMC 7190912 PMID 32250341 Mocciaro Emanuele Runfola Valeria Ghezzi Paola Pannese Maria Gabellini Davide 26 November 2021 DUX4 Role in Normal Physiology and in FSHD Muscular Dystrophy Cells 10 12 3322 doi 10 3390 cells10123322 PMC 8699294 PMID 34943834 a b Schatzl T Kaiser L Deigner HP 12 March 2021 Facioscapulohumeral muscular dystrophy genetics gene activation and downstream signalling with regard to recent therapeutic approaches an update Orphanet Journal of Rare Diseases 16 1 129 doi 10 1186 s13023 021 01760 1 PMC 7953708 PMID 33712050 S2CID 232202360 Lek Angela Zhang Yuanfan Woodman Keryn G Huang Shushu DeSimone Alec M Cohen Justin Ho Vincent Conner James Mead Lillian Kodani Andrew Pakula Anna Sanjana Neville King Oliver D Jones Peter L Wagner Kathryn R Lek Monkol Kunkel Louis M 25 March 2020 Applying genome wide CRISPR Cas9 screens for therapeutic discovery in facioscapulohumeral muscular dystrophy Science Translational Medicine 12 536 eaay0271 doi 10 1126 scitranslmed aay0271 PMC 7304480 PMID 32213627 Mariot Virginie Joubert Romain Le Gall Laura Sidlauskaite Eva Hourde Christophe Duddy William Voit Thomas Bencze Maximilien Dumonceaux Julie 22 October 2021 RIPK3 mediated cell death is involved in DUX4 mediated toxicity in facioscapulohumeral dystrophy Journal of Cachexia Sarcopenia and Muscle 12 6 2079 2090 doi 10 1002 jcsm 12813 PMC 8718031 PMID 34687171 S2CID 239471655 Wang LH Friedman SD Shaw D Snider L Wong CJ Budech CB Poliachik SL Gove NE Lewis LM Campbell AE Lemmers RJFL Maarel SM Tapscott SJ Tawil RN 2019 02 01 MRI informed muscle biopsies correlate MRI with pathology and DUX4 target gene expression in FSHD Human Molecular Genetics 28 3 476 486 doi 10 1093 hmg ddy364 PMC 6337697 PMID 30312408 Gherardi Romain Amato Anthony A Lidov Hart G Girolami Umberto De Nov 2018 Pathology of Skeletal Muscle In Gray Francoise Duyckaerts Charles Girolami Umberto de eds Escourolle and Poirier s manual of basic neuropathology Sixth ed New York NY Oxford University Press doi 10 1093 med 9780190675011 001 0001 ISBN 9780190675011 van der Maarel SM Miller DG Tawil R Filippova GN Tapscott SJ October 2012 Facioscapulohumeral muscular dystrophy consequences of chromatin relaxation Current Opinion in Neurology 25 5 614 20 doi 10 1097 WCO 0b013e328357f22d PMC 3653067 PMID 22892954 a b c Mair D Huegens Penzel M Kress W Roth C Ferbert A 2017 Leg Muscle Involvement in Facioscapulohumeral Muscular Dystrophy Comparison between Facioscapulohumeral Muscular Dystrophy Types 1 and 2 European Neurology 77 1 2 32 39 doi 10 1159 000452763 PMID 27855411 S2CID 25005883 a b c Olsen DB Gideon P Jeppesen TD Vissing J November 2006 Leg muscle involvement in facioscapulohumeral muscular dystrophy assessed by MRI Journal of Neurology 253 11 1437 41 doi 10 1007 s00415 006 0230 z PMID 16773269 S2CID 19421344 Sacconi S Salviati L Bourget I Figarella D Pereon Y Lemmers R van der Maarel S Desnuelle C 2006 10 24 Diagnostic challenges in facioscapulohumeral muscular dystrophy Neurology 67 8 1464 6 doi 10 1212 01 wnl 0000240071 62540 6f hdl 11577 1565214 PMID 17060574 S2CID 25693278 Strafella Claudia Caputo Valerio Galota Rosaria Maria Campoli Giulia Bax Cristina Colantoni Luca Minozzi Giulietta Orsini Chiara Politano Luisa Tasca Giorgio Novelli Giuseppe Ricci Enzo Giardina Emiliano Cascella Raffaella 1 December 2019 The variability of SMCHD1 gene in FSHD patients evidence of new mutations Human Molecular Genetics 28 23 3912 3920 doi 10 1093 hmg ddz239 PMC 6969370 PMID 31600781 Zampatti S Colantoni L Strafella C Galota RM Caputo V Campoli G Pagliaroli G Carboni S Mela J Peconi C Gambardella S Cascella R Giardina E May 2019 Facioscapulohumeral muscular dystrophy FSHD molecular diagnosis from traditional technology to the NGS era Neurogenetics 20 2 57 64 doi 10 1007 s10048 019 00575 4 PMID 30911870 S2CID 85495566 Kinoshita June 11 March 2020 Genetic testing for FSHD a new frontier FSHD Society Archived from the original on 8 April 2020 Retrieved 8 April 2020 Vasale J Boyar F Jocson M Sulcova V Chan P Liaquat K Hoffman C Meservey M Chang I Tsao D Hensley K Liu Y Owen R Braastad C Sun W Walrafen P Komatsu J Wang JC Bensimon A Anguiano A Jaremko M Wang Z Batish S Strom C Higgins J December 2015 Molecular combing compared to Southern blot for measuring D4Z4 contractions in FSHD Neuromuscular Disorders 25 12 945 51 doi 10 1016 j nmd 2015 08 008 PMID 26420234 S2CID 6871094 a b c d Gould T Jones TI Jones PL 13 August 2021 Precise Epigenetic Analysis Using Targeted Bisulfite Genomic Sequencing Distinguishes FSHD1 FSHD2 and Healthy Subjects Diagnostics Basel Switzerland 11 8 1469 doi 10 3390 diagnostics11081469 PMC 8393475 PMID 34441403 a b van Deutekom JC Wijmenga C van Tienhoven EA et al Dec 1993 FSHD associated DNA rearrangements are due to deletions of integral copies of a 3 2 kb tandemly repeated unit Human Molecular Genetics 2 12 2037 2042 doi 10 1093 hmg 2 12 2037 PMID 8111371 a b Wijmenga C Hewitt JE Sandkuijl LA et al Sep 1992 Chromosome 4q DNA rearrangements associated with facioscapulohumeral muscular dystrophy Nature Genetics 2 1 26 30 doi 10 1038 ng0992 26 PMID 1363881 S2CID 21940164 Frants Rune R Sandkuijl Lodewijk A van der Maarel Silvere M Padberg George W 2004 Mapping of the FSHD gene and the discovery of the pathognomonic deletion In Upadhyaya Meena Cooper David N eds FSHD Facioscapulohumeral Muscular Dystrophy Clinical Medicine and Molecular Cell Biology BIOS Scientific Publishers ISBN 1 85996 244 0 Lemmers Richard J L F Vliet Patrick J Granado David San Leon Stoep Nienke Buermans Henk Schendel Robin Schimmel Joost Visser Marianne Coster Rudy Jeanpierre Marc Laforet Pascal Upadhyaya Meena Engelen Baziel Sacconi Sabrina Tawil Rabi Voermans Nicol C Rogers Mark van der Maarel Silvere M 24 September 2021 High resolution breakpoint junction mapping of proximally extended D4Z4 deletions in FSHD1 reveals evidence for a founder effect Human Molecular Genetics 31 5 748 760 doi 10 1093 hmg ddab250 PMC 8895739 PMID 34559225 Gaillard MC Roche S Dion C Tasmadjian A Bouget G Salort Campana E Vovan C Chaix C Broucqsault N Morere J Puppo F Bartoli M Levy N Bernard R Attarian S Nguyen K Magdinier F 19 August 2014 Differential DNA methylation of the D4Z4 repeat in patients with FSHD and asymptomatic carriers PDF Neurology 83 8 733 42 doi 10 1212 WNL 0000000000000708 PMID 25031281 S2CID 10002229 FSHD Fact Sheet Archived 2006 03 06 at the Wayback Machine MDA 11 1 2001 a b Preston MK Tawil R Wang LH Adam MP Ardinger HH Pagon RA Wallace SE Bean LJH Mirzaa G Amemiya A 1993 Facioscapulohumeral Muscular Dystrophy PMID 20301616 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help a b c d e f g h Tawil R Kissel JT Heatwole C Pandya S Gronseth G Benatar M Guideline Development Dissemination and Implementation Subcommittee of the American Academy of Neurology Practice Issues Review Panel of the American Association of Neuromuscular amp Electrodiagnostic Medicine 28 July 2015 Evidence based guideline summary Evaluation diagnosis and management of facioscapulohumeral muscular dystrophy Report of the Guideline Development Dissemination and Implementation Subcommittee of the American Academy of Neurology and the Practice Issues Review Panel of the American Association of Neuromuscular amp Electrodiagnostic Medicine Neurology 85 4 357 64 doi 10 1212 WNL 0000000000001783 PMC 4520817 PMID 26215877 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b c Tawil R van der Maarel S Padberg GW van Engelen BG July 2010 171st ENMC international workshop Standards of care and management of facioscapulohumeral muscular dystrophy Neuromuscular Disorders 20 7 471 5 doi 10 1016 j nmd 2010 04 007 PMID 20554202 S2CID 18448196 a b Voet N Bleijenberg G Hendriks J de Groot I Padberg G van Engelen B Geurts A 18 November 2014 Both aerobic exercise and cognitive behavioral therapy reduce chronic fatigue in FSHD an RCT Neurology 83 21 1914 22 doi 10 1212 WNL 0000000000001008 PMID 25339206 S2CID 25382403 a b Janssen B Voet N Geurts A van Engelen B Heerschap A 3 May 2016 Quantitative MRI reveals decelerated fatty infiltration in muscles of active FSHD patients Neurology 86 18 1700 7 doi 10 1212 WNL 0000000000002640 PMID 27037227 S2CID 11617226 Voet Nicoline Bm van der Kooi Elly L van Engelen Baziel Gm Geurts Alexander Ch 6 December 2019 Strength training and aerobic exercise training for muscle disease The Cochrane Database of Systematic Reviews 2019 12 CD003907 doi 10 1002 14651858 CD003907 pub5 ISSN 1469 493X PMC 6953420 PMID 31808555 a b Tawil R Mah JK Baker S Wagner KR Ryan MM Sydney Workshop Participants July 2016 Clinical practice considerations in facioscapulohumeral muscular dystrophy Sydney Australia 21 September 2015 Neuromuscular Disorders 26 7 462 71 doi 10 1016 j nmd 2016 03 007 PMID 27185458 Information for Patients and Families The Richard Fields Center for FSH Dystrophy FSHD amp Neuromuscular Research University of Rochester Medical Center www urmc rochester edu Archived from the original on 14 November 2019 Retrieved 14 April 2020 Aprile I Bordieri C Gilardi A Lainieri Milazzo M Russo G De Santis F Frusciante R Iannaccone E Erra C Ricci E Padua L April 2013 Balance and walking involvement in facioscapulohumeral dystrophy a pilot study on the effects of custom lower limb orthoses European Journal of Physical and Rehabilitation Medicine 49 2 169 78 PMID 23138679 a b c d e Orrell Richard W Copeland Stephen Rose Michael R 20 January 2010 Scapular fixation in muscular dystrophy Cochrane Database of Systematic Reviews 2010 1 CD003278 doi 10 1002 14651858 CD003278 pub2 PMC 7144827 PMID 20091543 Demirhan Mehmet Uysal Ozgur Atalar Ata Can Kilicoglu Onder Serdaroglu Piraye 31 March 2009 Scapulothoracic Arthrodesis in Facioscapulohumeral Dystrophy with Multifilament Cable Clinical Orthopaedics and Related Research 467 8 2090 2097 doi 10 1007 s11999 009 0815 9 PMC 2706357 PMID 19333668 DeFranco Michael J Nho Shane Romeo Anthony A April 2010 Scapulothoracic Fusion Journal of the American Academy of Orthopaedic Surgeons 18 4 236 42 doi 10 5435 00124635 201004000 00006 PMID 20357232 S2CID 27456684 Heller KD Prescher A Forst J Stadtmuller A Forst R 1996 Anatomo experimental study for lace fixation of winged scapula in muscular dystrophy Surgical and Radiologic Anatomy 18 2 75 9 doi 10 1007 BF01795222 PMID 8782311 S2CID 20162712 Abrams Jeffrey S Bell Robert H Tokish John M 2018 ADVANCED RECONSTRUCTION OF SHOULDER AMER ACAD OF ORTHOPAEDIC ISBN 9781975123475 a b Upadhyaya Meena Cooper David N 2004 Introduction and overview of FSHD In Upadhyaya Meena Cooper David N eds FSHD Facioscapulohumeral Muscular Dystrophy Clinical Medicine and Molecular Cell Biology BIOS Scientific Publishers ISBN 1 85996 244 0 Sansone V Boynton J Palenski C June 1997 Use of gold weights to correct lagophthalmos in neuromuscular disease Neurology 48 6 1500 3 doi 10 1212 wnl 48 6 1500 hdl 2434 210652 PMID 9191754 S2CID 16251273 Matsumoto M Onoda S Uehara H Miura Y Katayama Y Kimata Y September 2016 Correction of the Lower Lip With a Cartilage Graft and Lip Resection in Patients With Facioscapulohumeral Muscular Dystrophy The Journal of Craniofacial Surgery 27 6 1427 9 doi 10 1097 SCS 0000000000002720 PMID 27300465 S2CID 16343571 Krishnamurthy S Ibrahim M January 2019 Tendon Transfers in Foot Drop Indian Journal of Plastic Surgery 52 1 100 108 doi 10 1055 s 0039 1688105 PMC 6664842 PMID 31456618 Chiodo Chris Bluman Eric M 2011 10 21 Tendon transfers in the foot and ankle Saunders p 421 ISBN 9781455709243 Retrieved 1 January 2020 Lunt Peter Upadhyaya Meena Koch Manuela C 2004 Genotype phenotype relationships in FSHD In Upadhyaya Meena Cooper David N eds FSHD Facioscapulohumeral Muscular Dystrophy Clinical Medidne and Molecular Cell Biology BIOS Scientific Publishers Limited p 157 Vincenten Sanne C C Mul Karlien Schreuder Tim H A Voermans Nicol C Horlings Corinne G C van Engelen Baziel G M July 2021 nnExploring the influence of smoking and alcohol consumption on clinical severity in patients with facioscapulohumeral muscular dystrophy Neuromuscular Disorders 31 9 824 828 doi 10 1016 j nmd 2021 07 005 hdl 2066 239258 ISSN 0960 8966 PMID 34407911 a b c Massey JM Gable KL 1 February 2022 Neuromuscular Disorders and Pregnancy Continuum Minneapolis Minn 28 1 55 71 doi 10 1212 CON 0000000000001069 PMID 35133311 S2CID 246651681 a b c Deenen JC Arnts H van der Maarel SM Padberg GW Verschuuren JJ Bakker E Weinreich SS Verbeek AL van Engelen BG 2014 Population based incidence and prevalence of facioscapulohumeral dystrophy Neurology 83 12 1056 9 doi 10 1212 WNL 0000000000000797 PMC 4166358 PMID 25122204 Deenen JC Horlings CG Verschuuren JJ Verbeek AL van Engelen BG 2015 The Epidemiology of Neuromuscular Disorders A Comprehensive Overview of the Literature Journal of Neuromuscular Diseases 2 1 73 85 doi 10 3233 JND 140045 PMID 28198707 Teveroni E Pellegrino M Sacconi S Calandra P Cascino I Farioli Vecchioli S Puma A Garibaldi M Morosetti R Tasca G Ricci E Trevisan CP Galluzzi G Pontecorvi A Crescenzi M Deidda G Moretti F 3 April 2017 Estrogens enhance myoblast differentiation in facioscapulohumeral muscular dystrophy by antagonizing DUX4 activity The Journal of Clinical Investigation 127 4 1531 1545 doi 10 1172 JCI89401 PMC 5373881 PMID 28263188 Mul K Horlings CGC Voermans NC Schreuder THA van Engelen BGM June 2018 Lifetime endogenous estrogen exposure and disease severity in female patients with facioscapulohumeral muscular dystrophy Neuromuscular Disorders 28 6 508 511 doi 10 1016 j nmd 2018 02 012 hdl 2066 194350 PMID 29655530 Duchenne Guillaume Benjamin 1868 De la paralysie musculaire pseudo hypertrophique ou paralysie myo sclerosique Arch Gen Med in French Bibliotheque nationale de France 11 5 25 179 209 305 321 421 443 552 588 Retrieved 18 May 2020 a b Landouzy Dejerine syndrome whonamedit com date accessed March 11 2007 Landouzy Dejerine 1884 De la myopathie atrophique progressive myopathie hereditaire debutant dans l enfance par la face sans alteration du systeme nerveux Comptes Rendus de l Academie des Sciences 98 53 55 Landouzy Dejerine 1886 Contribution a l etude de la myopathie atrophique progressive myopathie atrophique progressive a type scapulo humeral Comptes Rendus des Seances de la Societe de Biologie 38 478 481 Tyler Frank Stephens FE April 1950 Studies in disorders of muscle II Clinical manifestations and inheritance of facioscapulohumeral dystrophy in a large family Annals of Internal Medicine 32 4 640 660 doi 10 7326 0003 4819 32 4 640 PMID 15411118 Koenig M Hoffman EP Bertelson CJ Monaco AP Feener C Kunkel LM Jul 31 1987 Complete cloning of the Duchenne muscular dystrophy DMD cDNA and preliminary genomic organization of the DMD gene in normal and affected individuals Cell 50 3 509 517 doi 10 1016 0092 8674 87 90504 6 PMID 3607877 S2CID 35668717 Wijmenga C Padberg GW Moerer P et al April 1991 Mapping of facioscapulohumeral muscular dystrophy gene to chromosome 4q35 qter by multipoint linkage analysis and in situ hybridization Genomics 9 4 570 575 doi 10 1016 0888 7543 91 90348 I PMID 2037288 Gilbert JR Stajich JM Wall S et al Aug 1993 Evidence for heterogeneity in facioscapulohumeral muscular dystrophy FSHD American Journal of Human Genetics 53 2 401 408 PMC 1682358 PMID 8328457 a b Winokur ST Bengtsson U Feddersen J et al May 1994 The DNA rearrangement associated with facioscapulohumeral muscular dystrophy involves a heterochromatin associated repetitive element implications for a role of chromatin structure in the pathogenesis of the disease Chromosome Research 2 3 225 234 doi 10 1007 bf01553323 PMID 8069466 S2CID 6933736 Hewitt JE Lyle R Clark LN et al Aug 1994 Analysis of the tandem repeat locus D4Z4 associated with facioscapulohumeral muscular dystrophy Human Molecular Genetics 3 8 1287 1295 doi 10 1093 hmg 3 8 1287 PMID 7987304 Gilbert JR Speer MC Stajich J et al Oct 1995 Exclusion mapping of chromosomal regions which cross hybridise to FSHD1A associated markers in FSHD1B Journal of Medical Genetics 32 10 770 773 doi 10 1136 jmg 32 10 770 PMC 1051697 PMID 8558552 van Deutekom JC Lemmers RJ Grewal PK et al May 1996 Identification of the first gene FRG1 from the FSHD region on human chromosome 4q35 Human Molecular Genetics 5 5 581 590 doi 10 1093 hmg 5 5 581 PMID 8733123 a b Kowaljow V Marcowycz A Ansseau E et al Aug 2007 The DUX4 gene at the FSHD1A locus encodes a pro apoptotic protein Neuromuscular Disorders 17 8 611 623 doi 10 1016 j nmd 2007 04 002 PMID 17588759 S2CID 25926418 Gabriels J Beckers MC Ding H et al Aug 5 1999 Nucleotide sequence of the partially deleted D4Z4 locus in a patient with FSHD identifies a putative gene within each 3 3 kb element Gene 236 1 25 32 doi 10 1016 S0378 1119 99 00267 X PMID 10433963 Tsien F Sun B Hopkins NE et al Nov 2001 Methylation of the FSHD syndrome linked subtelomeric repeat in normal and FSHD cell cultures and tissues Molecular Genetics and Metabolism 74 3 322 331 doi 10 1006 mgme 2001 3219 PMID 11708861 Lemmers RJ de Kievit P Sandkuijl L et al Oct 2002 Facioscapulohumeral muscular dystrophy is uniquely associated with one of the two variants of the 4q subtelomere Nature Genetics 32 2 235 236 doi 10 1038 ng999 PMID 12355084 S2CID 28107557 Gabellini D Green MR Tupler R Aug 9 2002 Inappropriate gene activation in FSHD a repressor complex binds a chromosomal repeat deleted in dystrophic muscle Cell 110 3 339 348 doi 10 1016 S0092 8674 02 00826 7 hdl 11380 459475 PMID 12176321 S2CID 16396883 van Overveld PG Lemmers RJ Sandkuijl LA et al Dec 2003 Hypomethylation of D4Z4 in 4q linked and non 4q linked facioscapulohumeral muscular dystrophy Nature Genetics 35 4 315 317 doi 10 1038 ng1262 PMID 14634647 S2CID 28696708 Lemmers RJ Wohlgemuth M Frants RR Padberg GW Morava E van der Maarel SM Dec 2004 Contractions of D4Z4 on 4qB subtelomeres do not cause facioscapulohumeral muscular dystrophy The American Journal of Human Genetics 75 6 1124 1130 doi 10 1086 426035 PMC 1182148 PMID 15467981 Gabellini D D Antona G Moggio M et al Feb 23 2006 Facioscapulohumeral muscular dystrophy in mice overexpressing FRG1 Nature 439 7079 973 977 Bibcode 2006Natur 439 973G doi 10 1038 nature04422 PMID 16341202 S2CID 4427465 Clapp J Mitchell LM Bolland DJ et al Aug 2007 Evolutionary conservation of a coding function for D4Z4 the tandem DNA repeat mutated in facioscapulohumeral muscular dystrophy The American Journal of Human Genetics 81 2 264 279 doi 10 1086 519311 PMC 1950813 PMID 17668377 Dixit M Ansseau E Tassin A et al Nov 13 2007 DUX4 a candidate gene of facioscapulohumeral muscular dystrophy encodes a transcriptional activator of PITX1 Proceedings of the National Academy of Sciences of the USA 104 46 18157 18162 Bibcode 2007PNAS 10418157D doi 10 1073 pnas 0708659104 PMC 2084313 PMID 17984056 de Greef JC Lemmers RJ van Engelen BG et al Oct 2009 Common epigenetic changes of D4Z4 in contraction dependent and contraction independent FSHD Human Mutation 30 10 1449 1459 CiteSeerX 10 1 1 325 8388 doi 10 1002 humu 21091 PMID 19728363 S2CID 14517505 Snider L Asawachaicharn A Tyler AE et al Jul 1 2009 RNA transcripts miRNA sized fragments and proteins produced from D4Z4 units new candidates for the pathophysiology of facioscapulohumeral dystrophy Human Molecular Genetics 18 13 2414 2430 doi 10 1093 hmg ddp180 PMC 2694690 PMID 19359275 a b Kolata Gina 19 August 2010 Reanimated Junk DNA Is Found to Cause Disease The New York Times Retrieved 29 August 2010 FSH Society 2010 08 23 Archived from the original on 2010 08 23 Retrieved 2024 02 21 Scionti I Greco F Ricci G et al Apr 6 2012 Large scale population analysis challenges the current criteria for the molecular diagnosis of fascioscapulohumeral muscular dystrophy The American Journal of Human Genetics 90 4 628 635 doi 10 1016 j ajhg 2012 02 019 PMC 3322229 PMID 22482803 Geng LN Yao Z Snider L et al Jan 17 2012 DUX4 activates germline genes retroelements and immune mediators implications for facioscapulohumeral dystrophy Developmental Cell 22 1 38 51 doi 10 1016 j devcel 2011 11 013 PMC 3264808 PMID 22209328 Jones TI Chen JC Rahimov F et al Oct 15 2012 Facioscapulohumeral muscular dystrophy family studies of DUX4 expression evidence for disease modifiers and a quantitative model of pathogenesis Human Molecular Genetics 21 20 4419 4430 doi 10 1093 hmg dds284 PMC 3459465 PMID 22798623 Krom YD Thijssen PE Young JM et al Apr 2013 Intrinsic Epigenetic Regulation of the D4Z4 Macrosatellite Repeat in a Transgenic Mouse Model for FSHD PLOS Genetics 9 4 e1003415 doi 10 1371 journal pgen 1003415 PMC 3616921 PMID 23593020 Ferreboeuf M Mariot V Bessieres B et al Jan 1 2014 DUX4 and DUX4 downstream target genes are expressed in fetal FSHD muscles Human Molecular Genetics 23 1 171 181 doi 10 1093 hmg ddt409 PMID 23966205 Tawil R McDermott MP Pandya S King W Kissel J Mendell JR Griggs RC January 1997 A pilot trial of prednisone in facioscapulohumeral muscular dystrophy FSH DY Group Neurology 48 1 46 9 doi 10 1212 wnl 48 1 46 PMID 9008492 S2CID 729275 Kissel JT McDermott MP Natarajan R Mendell JR Pandya S King WM Griggs RC Tawil R May 1998 Pilot trial of albuterol in facioscapulohumeral muscular dystrophy FSH DY Group Neurology 50 5 1402 6 doi 10 1212 wnl 50 5 1402 PMID 9595995 S2CID 24848310 Kissel JT McDermott MP Mendell JR King WM Pandya S Griggs RC Tawil R FSH DY Group 23 October 2001 Randomized double blind placebo controlled trial of albuterol in facioscapulohumeral dystrophy Neurology 57 8 1434 40 doi 10 1212 wnl 57 8 1434 PMID 11673585 S2CID 28093111 van der Kooi EL Vogels OJ van Asseldonk RJ Lindeman E Hendriks JC Wohlgemuth M van der Maarel SM Padberg GW 24 August 2004 Strength training and albuterol in facioscapulohumeral muscular dystrophy Neurology 63 4 702 8 doi 10 1212 01 wnl 0000134660 30793 1f PMID 15326246 S2CID 22778327 a b Campbell AE Oliva J Yates MP Zhong JW Shadle SC Snider L Singh N Tai S Hiramuki Y Tawil R van der Maarel SM Tapscott SJ Sverdrup FM 4 September 2017 BET bromodomain inhibitors and agonists of the beta 2 adrenergic receptor identified in screens for compounds that inhibit DUX4 expression in FSHD muscle cells Skeletal Muscle 7 1 16 doi 10 1186 s13395 017 0134 x PMC 5584331 PMID 28870238 Elsheikh BH Bollman E Peruggia M King W Galloway G Kissel JT 24 April 2007 Pilot trial of diltiazem in facioscapulohumeral muscular dystrophy Neurology 68 17 1428 9 doi 10 1212 01 wnl 0000264017 08217 39 PMID 17452589 S2CID 361422 Wyeth Initiates Clinical Trial with Investigational Muscular Dystrophy Therapy MYO 029 Malcolm Emily 18 June 2019 ACE 083 Muscular Dystrophy News Retrieved 19 December 2019 Vultaggio Maria 5 October 2018 Why Rufus Sewell wanted to play Man in the High Castle villain John Smith Newsweek Archived from the original on 6 November 2018 Retrieved 12 April 2022 Kakutani Michiko 9 June 2006 Stuart A Life Backwards by Alexander Masters a Portrait of a Homeless Man The New York Times Archived from the original on 16 January 2018 White Abbey 2023 12 19 Ramy Star Steve Way Boards Indie Drama Good Bad Things as Executive Producer Exclusive The Hollywood Reporter Retrieved 2024 01 31 jkinoshita 2022 08 25 New movie will feature man with FSHD FSHD Society Retrieved 2024 01 31 A disability advocate preserves his voice with iPhone Apple Newsroom Retrieved 2024 02 21 a b Kinoshita June 16 August 2019 What s in a name FSHD Society FSHD Society Archived from the original on 12 April 2022 Retrieved 18 August 2019 a b Our History FSHD Society Archived from the original on 27 February 2022 a b Bartlett Jessica 19 August 2014 Boston Business Journal https web archive org web 20220412220102 https www bizjournals com boston blog health care 2014 08 dan perez living with and fighting against a html Archived from the original on 12 April 2022 Retrieved 12 April 2022 a href Template Cite news html title Template Cite news cite news a Missing or empty title help FSHD Society NORD National Organization for Rare Disorders Archived from the original on 2022 05 13 Retrieved 2022 04 12 FSHD Society Achieves Accreditation from BBB Wise Giving Alliance Prweb 26 April 2022 Archived from the original on 29 April 2022 Retrieved 29 April 2022 This Is FSHD HuffPost 16 July 2014 Archived from the original on 2 August 2019 Retrieved 12 April 2022 Krummey Catherine 30 March 2017 Kirkland couple raises 3 2 million for FSH muscular dystrophy research Kirkland Reporter Archived from the original on 16 June 2017 Retrieved 9 April 2022 About Us Friends of FSH Research Friends of FSH Research Archived from the original on 17 February 2020 Retrieved 9 April 2022 AMRA Medical 13 Oct 2021 AMRA Medical s Whole body MRI Analysis Used in FSHD Clinical Trial Research Network Study for Biomarker Development Cision PR Newswire Archived from the original on 1 November 2021 Retrieved 9 April 2022 Avidity Biosciences Inc 16 August 2021 Avidity Biosciences Enters Into Collaboration with FSHD Clinical Trial Network to Support Development of Biomarkers for Future Clinical Trial Use Cision PR Newswire Archived from the original on 16 August 2021 Overington Caroline 24 September 2016 He s physically wasting but his brain is sharp Former Macquarie banker Bill Moss is back in business The Australian a b c Chancellor Jonathan 7 September 2020 Buyer swoops on Brett Whiteley s corella The Australian Retrieved 9 April 2022 a b Tasker Sarah Jane 26 May 2018 Bill Moss the single minded biotech and a search for a cure The Australian Retrieved 9 April 2022 a b Voermans NC Vriens Munoz Bravo M Padberg GW Laforet P FSHD European Trial Network workshop study group September 2021 1st FSHD European Trial Network workshop Working towards trial readiness across Europe Neuromuscular Disorders 31 9 907 918 doi 10 1016 j nmd 2021 07 013 hdl 1887 3505452 PMID 34404575 S2CID 236217036 Judd Amy 8 March 2022 Lululemon founder Chip Wilson donates 100M to find cure for his illness 30 years after diagnosis Globalnews ca Global News Retrieved 9 April 2022 Isola Frank 23 April 2019 You re not going to quit One step at a time Nets radio voice Chris Carrino continues to walk tall The Athletic Retrieved 9 April 2022 Actress Breaking Barriers as Broadway s First Lead Actor in Wheelchair NBC News Retrieved 2024 02 21 Community Profiles Actress Madison Ferris Audioboom Retrieved 2024 02 21 Shedloski Dave 24 February 2020 There s no stopping Morgan Hoffmann in his fight against muscular dystrophy Golf Digest Archived from the original on 5 March 2022 Retrieved 12 April 2022 Sandomir Richard 2018 02 03 Dr Arnold Gold 92 Dies Made Compassionate Care a Cause The New York Times ISSN 0362 4331 Retrieved 2024 02 21 Rickard Amanda Petek Lisa Miller Daniel August 5 2015 Endogenous DUX4 expression in FSHD myotubes is sufficient to cause cell death and disrupts RNA splicing and cell migration pathways Hum Mol Genet 24 20 5901 14 doi 10 1093 hmg ddv315 a, wikipedia, wiki, book, books, library,

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