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Neurodegenerative disease

February 15, 2024

For the medical journal, see Experimental Neurology.

A neurodegenerative disease is caused by the progressive loss of structure or function of neurons, in the process known as neurodegeneration. Such neuronal damage may ultimately involve cell death. Neurodegenerative diseases include amyotrophic lateral sclerosis, multiple sclerosis, Parkinson's disease, Alzheimer's disease, Huntington's disease, multiple system atrophy, tauopathies, and prion diseases. Neurodegeneration can be found in the brain at many different levels of neuronal circuitry, ranging from molecular to systemic. Because there is no known way to reverse the progressive degeneration of neurons, these diseases are considered to be incurable; however research has shown that the two major contributing factors to neurodegeneration are oxidative stress and inflammation.[2][3][4][5] Biomedical research has revealed many similarities between these diseases at the subcellular level, including atypical protein assemblies (like proteinopathy) and induced cell death.[6][7] These similarities suggest that therapeutic advances against one neurodegenerative disease might ameliorate other diseases as well.

Neurodegenerative disease
Normal brain on left contrasted with structural changes shown in brain on right of person with Alzheimer's disease, the most common neurodegenerative disease[1]
SpecialtyNeurology, Psychiatry

Within neurodegenerative diseases, it is estimated that 55 million people worldwide had dementia in 2019, and that by 2050 this figure will increase to 139 million people.[8]

Specific disorders edit

The consequences of neurodegeneration can vary widely depending on the specific region affected, ranging from issues related to movement to the development of dementia.[9][10]

Alzheimer's disease edit

 
Comparison of brain tissue between healthy individual and Alzheimer's disease patient, demonstrating extent of neuronal death
Main article: Alzheimer's disease

Alzheimer's disease (AD) is a chronic neurodegenerative disease that results in the loss of neurons and synapses in the cerebral cortex and certain subcortical structures, resulting in gross atrophy of the temporal lobe, parietal lobe, and parts of the frontal cortex and cingulate gyrus.[11] It is the most common neurodegenerative disease.[1] Even with billions of dollars being used to find a treatment for Alzheimer's disease, no effective treatments have been found.[12] However, clinical trials have developed certain compounds that could potentially change the future of Alzheimer's disease treatments.[13] Within clinical trials stable and effective AD therapeutic strategies have a 99.5% failure rate.[14] Reasons for this failure rate include inappropriate drug doses, invalid target and participant selection, and inadequate knowledge of pathophysiology of AD. Currently, diagnoses of Alzheimer's is subpar, and better methods need to be utilized for various aspects of clinical diagnoses.[15] Alzheimer's has a 20% misdiagnosis rate.[15]

AD pathology is primarily characterized by the presence of amyloid plaques and neurofibrillary tangles. Plaques are made up of small peptides, typically 39–43 amino acids in length, called amyloid beta (also written as A-beta or Aβ). Amyloid beta is a fragment from a larger protein called amyloid precursor protein (APP), a transmembrane protein that penetrates through the neuron's membrane. APP appears to play roles in normal neuron growth, survival and post-injury repair.[16][17] APP is cleaved into smaller fragments by enzymes such as gamma secretase and beta secretase.[18] One of these fragments gives rise to fibrils of amyloid beta which can self-assemble into the dense extracellular amyloid plaques.[19][20]

Parkinson's disease edit

Main article: Parkinson's disease

Parkinson's disease (PD) is the second most common neurodegenerative disorder.[21] It typically manifests as bradykinesia, rigidity, resting tremor and posture instability. The crude prevalence rate of PD has been reported to range from 15 per 100,000 to 12,500 per 100,000, and the incidence of PD from 15 per 100,000 to 328 per 100,000, with the disease being less common in Asian countries.

PD is primarily characterized by death of dopaminergic neurons in the substantia nigra, a region of the midbrain. The cause of this selective cell death is unknown. Notably, alpha-synuclein-ubiquitin complexes and aggregates are observed to accumulate in Lewy bodies within affected neurons. It is thought that defects in protein transport machinery and regulation, such as RAB1, may play a role in this disease mechanism.[22] Impaired axonal transport of alpha-synuclein may also lead to its accumulation in Lewy bodies. Experiments have revealed reduced transport rates of both wild-type and two familial Parkinson's disease-associated mutant alpha-synucleins through axons of cultured neurons.[23] Membrane damage by alpha-synuclein could be another Parkinson's disease mechanism.[24]

The main known risk factor is age. Mutations in genes such as α-synuclein (SNCA), leucine-rich repeat kinase 2 (LRRK2), glucocerebrosidase (GBA), and tau protein (MAPT) can also cause hereditary PD or increase PD risk.[25] While PD is the second most common neurodegenerative disorder, problems with diagnoses still persist.[26] Problems with the sense of smell is a widespread symptom of Parkinson's disease (PD), however, some neurologists question its efficacy.[26] This assessment method is a source of controversy among medical professionals.[26] The gut microbiome might play a role in the diagnosis of PD, and research suggests various ways that could revolutionize the future of PD treatment.[27]

Huntington's disease edit

Main article: Huntington's disease

Huntington's disease (HD) is a rare autosomal dominant neurodegenerative disorder caused by mutations in the huntingtin gene (HTT). HD is characterized by loss of medium spiny neurons and astrogliosis.[28][29][30] The first brain region to be substantially affected is the striatum, followed by degeneration of the frontal and temporal cortices.[31] The striatum's subthalamic nuclei send control signals to the globus pallidus, which initiates and modulates motion. The weaker signals from subthalamic nuclei thus cause reduced initiation and modulation of movement, resulting in the characteristic movements of the disorder, notably chorea.[32] Huntington's disease presents itself later in life even though the proteins that cause the disease works towards manifestation from their early stages in the humans affected by the proteins.[33] Along with being a neurodegenerative disorder, HD has links to problems with neurodevelopment.[33]

HD is caused by polyglutamine tract expansion in the huntingtin gene, resulting in the mutant huntingtin. Aggregates of mutant huntingtin form as inclusion bodies in neurons, and may be directly toxic. Additionally, they may damage molecular motors and microtubules to interfere with normal axonal transport, leading to impaired transport of important cargoes such as BDNF.[23] Huntington's disease currently has no effective treatments that would modify the disease.[34]

Multiple sclerosis edit

Main article: Multiple sclerosis

Multiple sclerosis (MS) is a chronic debilitating demyelinating disease of the central nervous system, caused by an autoimmune attack resulting in the progressive loss of myelin sheath on neuronal axons.[35] The resultant decrease in the speed of signal transduction leads to a loss of functionality that includes both cognitive and motor impairment depending on the location of the lesion.[35] The progression of MS occurs due to episodes of increasing inflammation, which is proposed to be due to the release of antigens such as myelin oligodendrocyte glycoprotein, myelin basic protein, and proteolipid protein, causing an autoimmune response.[36] This sets off a cascade of signaling molecules that result in T cells, B cells, and Macrophages to cross the blood-brain barrier and attack myelin on neuronal axons leading to inflammation.[37] Further release of antigens drives subsequent degeneration causing increased inflammation.[38] Multiple sclerosis presents itself as a spectrum based on the degree of inflammation, a majority of patients experience early relapsing and remitting episodes of neuronal deterioration following a period of recovery. Some of these individuals may transition to a more linear progression of the disease, while about 15% of others begin with a progressive course on the onset of Multiple sclerosis. The inflammatory response contributes to the loss of the grey matter, and as a result current literature devotes itself to combatting the auto-inflammatory aspect of the disease.[37] While there are several proposed causal links between EBV and the HLA-DRB1*15:01 allele to the onset of MS – they may contribute to the degree of autoimmune attack and the resultant inflammation – they do not determine the onset of MS.[37]

Amyotrophic lateral sclerosis edit

Main article: Amyotrophic lateral sclerosis

Amyotrophic lateral sclerosis (ALS) or Lou Gehrig's disease is a disease in which motor neurons are selectively targeted for degeneration. Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disorder that negatively impacts the upper motor neurons (UMNs) and lower motor neurons (LMNs).[39] In 1993, missense mutations in the gene encoding the antioxidant enzyme Cu/Zn superoxide dismutase 1 (SOD1) were discovered in a subsets of patients with familial ALS. This discovery led researchers to focus on unlocking the mechanisms for SOD1-mediated diseases. However, the pathogenic mechanism underlying SOD1 mutant toxicity has yet to be resolved. More recently, TDP-43 and FUS protein aggregates have been implicated in some cases of the disease, and a mutation in chromosome 9 (C9orf72) is thought to be the most common known cause of sporadic ALS. It is diagnosed by skeletal muscle weakness that progresses gradually.[39] Early diagnosis of ALS is harder than with other neurodegenerative diseases as there are no highly effective means of determining its early onset.[39] Currently, there is research being done regarding the diagnosis of ALS through upper motor neuron tests.[40] The Penn Upper Motor Neuron Score (PUMNS) consists of 28 criteria with a score range of 0–32.[40] A higher score indicates a higher level of burden present on the upper motor neurons.[40] The PUMNS has proven quite effective in determining the burden that exists on upper motor neurons in affected patients.[40]

Independent research provided in vitro evidence that the primary cellular sites where SOD1 mutations act are located on astrocytes.[41][42] Astrocytes then cause the toxic effects on the motor neurons. The specific mechanism of toxicity still needs to be investigated, but the findings are significant because they implicate cells other than neuron cells in neurodegeneration.[43]

Batten disease edit

Main article: Batten disease

Batten disease is a rare and fatal recessive neurodegenerative disorder that begins in childhood.[44] Batten disease is the common name for a group of lysosomal storage disorders known as neuronal ceroid lipofuscinoses (NCLs) – each caused by a specific gene mutation,[44] of which there are thirteen.[45] Since Batten disease is quite rare, its worldwide prevalence is about 1 in every 100,000 live births.[46] In North America, CLN3 disease (juvenile NCL) typically manifests between the ages of 4 and 7.[47] Batten disease is characterized by motor impairment, epilepsy, dementia, vision loss, and shortened lifespan.[48] A loss of vision is common first sign of Batten disease.[47] Loss of vision is typically preceded by cognitive and behavioral changes, seizures, and loss of the ability to walk.[47] It is common for people to establish cardiac arrhythmias and difficulties eating food as the disease progresses.[47] Batten disease diagnosis depends on a conflation of many criteria: clinical signs and symptoms, evaluations of the eye, electroencephalograms (EEG), and brain magnetic resonance imaging (MRI) results.[46] The diagnosis provided by these results are corroborated by genetic and biochemical testing.[46] No effective treatments were available to prevent the disease from being widespread before the past few years.[46] In recent years, more models have been created to expedite the research process for methods to treat Batten disease.[46]

Creutzfeldt–Jakob disease edit

Main article: Creutzfeldt-Jakob disease

Creutzfeldt–Jakob disease (CJD) is a prion disease that is characterized by rapidly progressive dementia.[49] Misfolded proteins called prions aggregate in brain tissue leading to nerve cell death.[50] Variant Creutzfeldt–Jakob disease (vCJD) is the infectious form that comes from the meat of a cow that was infected with bovine spongiform encephalopathy, also called mad cow disease.[51]

Risk factor edit

Further information: Aging brain

The greatest risk factor for neurodegenerative diseases is aging. Mitochondrial DNA mutations as well as oxidative stress both contribute to aging.[52] Many of these diseases are late-onset, meaning there is some factor that changes as a person ages for each disease.[6] One constant factor is that in each disease, neurons gradually lose function as the disease progresses with age. It has been proposed that DNA damage accumulation provides the underlying causative link between aging and neurodegenerative disease.[53][54] About 20–40% of healthy people between 60 and 78 years old experience discernable decrements in cognitive performance in several domains including working, spatial, and episodic memory, and processing speed.[55]

 
Risks from viral exposures according to one biobank study[56]

A study using electronic health records indicates that 45 (with 22 of these being replicated with the UK Biobank) viral exposures can significantly elevate risks of neurodegenerative disease, including up to 15 years after infection.[56][additional citation(s) needed]

Mechanisms edit

Genetics edit

See also: Trinucleotide repeat disorder and Epigenetics of neurodegenerative diseases

Many neurodegenerative diseases are caused by genetic mutations, most of which are located in completely unrelated genes. In many of the different diseases, the mutated gene has a common feature: a repeat of the CAG nucleotide triplet. CAG codes for the amino acid glutamine. A repeat of CAG results in a polyglutamine (polyQ) tract. Diseases associated with such mutations are known as trinucleotide repeat disorders.[57][58]

Polyglutamine repeats typically cause dominant pathogenesis. Extra glutamine residues can acquire toxic properties through a variety of ways, including irregular protein folding and degradation pathways, altered subcellular localization, and abnormal interactions with other cellular proteins.[57] PolyQ studies often use a variety of animal models because there is such a clearly defined trigger – repeat expansion. Extensive research has been done using the models of nematode (C. elegans), and fruit fly (Drosophila), mice, and non-human primates.[58][59]

Nine inherited neurodegenerative diseases are caused by the expansion of the CAG trinucleotide and polyQ tract, including Huntington's disease and the spinocerebellar ataxias.[60]

Epigenetics edit

The presence of epigenetic modifications for certain genes has been demonstrated in this type of pathology. An example is FKBP5 gene, which progressively increases its expression with age and has been related to Braak staging and increased tau pathology both in vitro and in mouse models of AD.[61]

Protein misfolding edit

See also: Stress granule

Several neurodegenerative diseases are classified as proteopathies as they are associated with the aggregation of misfolded proteins. Protein toxicity is one of the key mechanisms of many neurodegenrative diseases.[62]

Intracellular mechanisms edit

Protein degradation pathways edit

Parkinson's disease and Huntington's disease are both late-onset and associated with the accumulation of intracellular toxic proteins. Diseases caused by the aggregation of proteins are known as proteopathies, and they are primarily caused by aggregates in the following structures:[6]

  • cytosol, e.g. Parkinson's and Huntington's
  • nucleus, e.g. Spinocerebellar ataxia type 1 (SCA1)
  • endoplasmic reticulum (ER), (as seen with neuroserpin mutations that cause familial encephalopathy with neuroserpin inclusion bodies)
  • extracellularly excreted proteins, amyloid-beta in Alzheimer's disease

There are two main avenues eukaryotic cells use to remove troublesome proteins or organelles:

  • ubiquitin–proteasome: protein ubiquitin along with enzymes is key for the degradation of many proteins that cause proteopathies including polyQ expansions and alpha-synucleins. Research indicates proteasome enzymes may not be able to correctly cleave these irregular proteins, which could possibly result in a more toxic species. This is the primary route cells use to degrade proteins.[6]
    • Decreased proteasome activity is consistent with models in which intracellular protein aggregates form. It is still unknown whether or not these aggregates are a cause or a result of neurodegeneration.[6]
  • autophagy–lysosome pathways: a form of programmed cell death (PCD), this becomes the favorable route when a protein is aggregate-prone meaning it is a poor proteasome substrate. This can be split into two forms of autophagy: macroautophagy and chaperone-mediated autophagy (CMA).[6]
    • macroautophagy is involved with nutrient recycling of macromolecules under conditions of starvation, certain apoptotic pathways, and if absent, leads to the formation of ubiquinated inclusions. Experiments in mice with neuronally confined macroautophagy-gene knockouts develop intraneuronal aggregates leading to neurodegeneration.[6]
    • chaperone-mediated autophagy defects may also lead to neurodegeneration. Research has shown that mutant proteins bind to the CMA-pathway receptors on lysosomal membrane and in doing so block their own degradation as well as the degradation of other substrates.[6]

Membrane damage edit

Damage to the membranes of organelles by monomeric or oligomeric proteins could also contribute to these diseases. Alpha-synuclein can damage membranes by inducing membrane curvature,[24] and cause extensive tubulation and vesiculation when incubated with artificial phospholipid vesicles.[24]The tubes formed from these lipid vesicles consist of both micellar as well as bilayer tubes. Extensive induction of membrane curvature is deleterious to the cell and would eventually lead to cell death. Apart from tubular structures, alpha-synuclein can also form lipoprotein nanoparticles similar to apolipoproteins.

Mitochondrial dysfunction edit

The most common form of cell death in neurodegeneration is through the intrinsic mitochondrial apoptotic pathway. This pathway controls the activation of caspase-9 by regulating the release of cytochrome c from the mitochondrial intermembrane space. Reactive oxygen species (ROS) are normal byproducts of mitochondrial respiratory chain activity. ROS concentration is mediated by mitochondrial antioxidants such as manganese superoxide dismutase (SOD2) and glutathione peroxidase. Over production of ROS (oxidative stress) is a central feature of all neurodegenerative disorders. In addition to the generation of ROS, mitochondria are also involved with life-sustaining functions including calcium homeostasis, PCD, mitochondrial fission and fusion, lipid concentration of the mitochondrial membranes, and the mitochondrial permeability transition. Mitochondrial disease leading to neurodegeneration is likely, at least on some level, to involve all of these functions.[63]

There is strong evidence that mitochondrial dysfunction and oxidative stress play a causal role in neurodegenerative disease pathogenesis, including in four of the more well known diseases Alzheimer's, Parkinson's, Huntington's, and amyotrophic lateral sclerosis.[52]

Neurons are particularly vulnerable to oxidative damage due to their strong metabolic activity associated with high transcription levels, high oxygen consumption, and weak antioxidant defense.[64][65]

DNA damage edit

The brain metabolizes as much as a fifth of consumed oxygen, and reactive oxygen species produced by oxidative metabolism are a major source of DNA damage in the brain. Damage to a cell's DNA is particularly harmful because DNA is the blueprint for protein production and unlike other molecules it cannot simply be replaced by re-synthesis. The vulnerability of post-mitotic neurons to DNA damage (such as oxidative lesions or certain types of DNA strand breaks), coupled with a gradual decline in the activities of repair mechanisms, could lead to accumulation of DNA damage with age and contribute to brain aging and neurodegeneration.[66] DNA single-strand breaks are common and are associated with the neurodegenerative disease ataxia-oculomotor apraxia.[67][65] Increased oxidative DNA damage in the brain is associated with Alzheimer's disease and Parkinson's disease.[67] Defective DNA repair has been linked to neurodegenerative disorders such as Alzheimer's disease, amyotrophic lateral sclerosis, ataxia telangiectasia, Cockayne syndrome, Parkinson's disease and xeroderma pigmentosum.[67][66]

Axonal transport edit

Main article: Axonal transport

Axonal swelling, and axonal spheroids have been observed in many different neurodegenerative diseases. This suggests that defective axons are not only present in diseased neurons, but also that they may cause certain pathological insult due to accumulation of organelles. Axonal transport can be disrupted by a variety of mechanisms including damage to: kinesin and cytoplasmic dynein, microtubules, cargoes, and mitochondria.[23] When axonal transport is severely disrupted a degenerative pathway known as Wallerian-like degeneration is often triggered.[68]

Programmed cell death edit

Programmed cell death (PCD) is death of a cell in any form, mediated by an intracellular program.[69] This process can be activated in neurodegenerative diseases including Parkinson's disease, amytrophic lateral sclerosis, Alzheimer's disease and Huntington's disease.[70] PCD observed in neurodegenerative diseases may be directly pathogenic; alternatively, PCD may occur in response to other injury or disease processes.[7]

Apoptosis (type I) edit

Apoptosis is a form of programmed cell death in multicellular organisms. It is one of the main types of programmed cell death (PCD) and involves a series of biochemical events leading to a characteristic cell morphology and death.

  • Extrinsic apoptotic pathways: Occur when factors outside the cell activate cell surface death receptors (e.g., Fas) that result in the activation of caspases-8 or -10.[7]
  • Intrinsic apoptotic pathways: Result from mitochondrial release of cytochrome c or endoplasmic reticulum malfunctions, each leading to the activation of caspase-9. The nucleus and Golgi apparatus are other organelles that have damage sensors, which can lead the cells down apoptotic pathways.[7][71]

Caspases (cysteine-aspartic acid proteases) cleave at very specific amino acid residues. There are two types of caspases: initiators and effectors. Initiator caspases cleave inactive forms of effector caspases. This activates the effectors that in turn cleave other proteins resulting in apoptotic initiation.[7]

Autophagic (type II) edit

Autophagy is a form of intracellular phagocytosis in which a cell actively consumes damaged organelles or misfolded proteins by encapsulating them into an autophagosome, which fuses with a lysosome to destroy the contents of the autophagosome. Because many neurodegenerative diseases show unusual protein aggregates, it is hypothesized that defects in autophagy could be a common mechanism of neurodegeneration.[7]

Cytoplasmic (type III) edit

PCD can also occur via non-apoptotic processes, also known as Type III or cytoplasmic cell death. For example, type III PCD might be caused by trophotoxicity, or hyperactivation of trophic factor receptors. Cytotoxins that induce PCD can cause necrosis at low concentrations, or aponecrosis (combination of apoptosis and necrosis) at higher concentrations. It is still unclear exactly what combination of apoptosis, non-apoptosis, and necrosis causes different kinds of aponecrosis.[7]

Transglutaminase edit

Transglutaminases are human enzymes ubiquitously present in the human body and in the brain in particular.[72]

The main function of transglutaminases is bind proteins and peptides intra- and intermolecularly, by a type of covalent bonds termed isopeptide bonds, in a reaction termed transamidation or crosslinking.[72]

Transglutaminase binding of these proteins and peptides make them clump together. The resulting structures are turned extremely resistant to chemical and mechanical disruption.[72]

Most relevant human neurodegenerative diseases share the property of having abnormal structures made up of proteins and peptides.[72]

Each of these neurodegenerative diseases have one (or several) specific main protein or peptide. In Alzheimer's disease, these are amyloid-beta and tau. In Parkinson's disease, it is alpha-synuclein. In Huntington's disease, it is huntingtin.[72]

Transglutaminase substrates: Amyloid-beta, tau, alpha-synuclein and huntingtin have been proved to be substrates of transglutaminases in vitro or in vivo, that is, they can be bonded by trasglutaminases by covalent bonds to each other and potentially to any other transglutaminase substrate in the brain.[72]

Transglutaminase augmented expression: It has been proved that in these neurodegenerative diseases (Alzheimer's disease, Parkinson's disease, and Huntington's disease) the expression of the transglutaminase enzyme is increased.[72]

Presence of isopeptide bonds in these structures: The presence of isopeptide bonds (the result of the transglutaminase reaction) have been detected in the abnormal structures that are characteristic of these neurodegenerative diseases.[72]

Co-localization: Co-localization of transglutaminase mediated isopeptide bonds with these abnormal structures has been detected in the autopsy of brains of patients with these diseases.[72]

Management edit

The process of neurodegeneration is not well understood, so the diseases that stem from it have, as yet, no cures.

Animal models in research edit

In the search for effective treatments (as opposed to palliative care), investigators employ animal models of disease to test potential therapeutic agents. Model organisms provide an inexpensive and relatively quick means to perform two main functions: target identification and target validation. Together, these help show the value of any specific therapeutic strategies and drugs when attempting to ameliorate disease severity. An example is the drug Dimebon by Medivation, Inc. In 2009 this drug was in phase III clinical trials for use in Alzheimer's disease, and also phase II clinical trials for use in Huntington's disease.[58] In March 2010, the results of a clinical trial phase III were released; the investigational Alzheimer's disease drug Dimebon failed in the pivotal CONNECTION trial of patients with mild-to-moderate disease.[73] With CONCERT, the remaining Pfizer and Medivation Phase III trial for Dimebon (latrepirdine) in Alzheimer's disease failed in 2012, effectively ending the development in this indication.[74]

In another experiment using a rat model of Alzheimer's disease, it was demonstrated that systemic administration of hypothalamic proline-rich peptide (PRP)-1 offers neuroprotective effects and can prevent neurodegeneration in hippocampus amyloid-beta 25–35. This suggests that there could be therapeutic value to PRP-1.[75]

Other avenues of investigation edit

Protein degradation offers therapeutic options both in preventing the synthesis and degradation of irregular proteins. There is also interest in upregulating autophagy to help clear protein aggregates implicated in neurodegeneration. Both of these options involve very complex pathways that we are only beginning to understand.[6]

The goal of immunotherapy is to enhance aspects of the immune system. Both active and passive vaccinations have been proposed for Alzheimer's disease and other conditions; however, more research must be done to prove safety and efficacy in humans.[76]

A current therapeutic target for the treatment of Alzheimer's disease is the protease β-secretase[77][non-primary source needed], which is involved in the amyloidogenic processing pathway that leads to the pathological accumulation of proteins in the brain. When the gene that encodes for amyloid precursor protein (APP) is spliced by α-secretase[78][non-primary source needed] rather than β-secretase, the toxic protein β amyloid is not produced. Targeted inhibition[79] of β-secretase can potentially prevent the neuronal death that is responsible for the symptoms of Alzheimer's disease.

Dr. Antonio Barbera a former obstetrics and gynaecology doctor is prescribing table tennis for patients who are suffering from a serious Neurological disorder.[80]

See also edit

References edit

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February 15, 2024
neurodegenerative, disease, medical, journal, experimental, neurology, neurodegenerative, disease, caused, progressive, loss, structure, function, neurons, process, known, neurodegeneration, such, neuronal, damage, ultimately, involve, cell, death, include, am. For the medical journal see Experimental Neurology A neurodegenerative disease is caused by the progressive loss of structure or function of neurons in the process known as neurodegeneration Such neuronal damage may ultimately involve cell death Neurodegenerative diseases include amyotrophic lateral sclerosis multiple sclerosis Parkinson s disease Alzheimer s disease Huntington s disease multiple system atrophy tauopathies and prion diseases Neurodegeneration can be found in the brain at many different levels of neuronal circuitry ranging from molecular to systemic Because there is no known way to reverse the progressive degeneration of neurons these diseases are considered to be incurable however research has shown that the two major contributing factors to neurodegeneration are oxidative stress and inflammation 2 3 4 5 Biomedical research has revealed many similarities between these diseases at the subcellular level including atypical protein assemblies like proteinopathy and induced cell death 6 7 These similarities suggest that therapeutic advances against one neurodegenerative disease might ameliorate other diseases as well Neurodegenerative diseaseNormal brain on left contrasted with structural changes shown in brain on right of person with Alzheimer s disease the most common neurodegenerative disease 1 SpecialtyNeurology PsychiatryWithin neurodegenerative diseases it is estimated that 55 million people worldwide had dementia in 2019 and that by 2050 this figure will increase to 139 million people 8 Contents 1 Specific disorders 1 1 Alzheimer s disease 1 2 Parkinson s disease 1 3 Huntington s disease 1 4 Multiple sclerosis 1 5 Amyotrophic lateral sclerosis 1 6 Batten disease 1 7 Creutzfeldt Jakob disease 2 Risk factor 3 Mechanisms 3 1 Genetics 3 2 Epigenetics 3 3 Protein misfolding 3 4 Intracellular mechanisms 3 4 1 Protein degradation pathways 3 4 2 Membrane damage 3 4 3 Mitochondrial dysfunction 3 4 4 DNA damage 3 4 5 Axonal transport 3 5 Programmed cell death 3 5 1 Apoptosis type I 3 5 2 Autophagic type II 3 5 3 Cytoplasmic type III 3 6 Transglutaminase 4 Management 4 1 Animal models in research 4 2 Other avenues of investigation 5 See also 6 ReferencesSpecific disorders editThe consequences of neurodegeneration can vary widely depending on the specific region affected ranging from issues related to movement to the development of dementia 9 10 Alzheimer s disease edit nbsp Comparison of brain tissue between healthy individual and Alzheimer s disease patient demonstrating extent of neuronal deathMain article Alzheimer s disease Alzheimer s disease AD is a chronic neurodegenerative disease that results in the loss of neurons and synapses in the cerebral cortex and certain subcortical structures resulting in gross atrophy of the temporal lobe parietal lobe and parts of the frontal cortex and cingulate gyrus 11 It is the most common neurodegenerative disease 1 Even with billions of dollars being used to find a treatment for Alzheimer s disease no effective treatments have been found 12 However clinical trials have developed certain compounds that could potentially change the future of Alzheimer s disease treatments 13 Within clinical trials stable and effective AD therapeutic strategies have a 99 5 failure rate 14 Reasons for this failure rate include inappropriate drug doses invalid target and participant selection and inadequate knowledge of pathophysiology of AD Currently diagnoses of Alzheimer s is subpar and better methods need to be utilized for various aspects of clinical diagnoses 15 Alzheimer s has a 20 misdiagnosis rate 15 AD pathology is primarily characterized by the presence of amyloid plaques and neurofibrillary tangles Plaques are made up of small peptides typically 39 43 amino acids in length called amyloid beta also written as A beta or Ab Amyloid beta is a fragment from a larger protein called amyloid precursor protein APP a transmembrane protein that penetrates through the neuron s membrane APP appears to play roles in normal neuron growth survival and post injury repair 16 17 APP is cleaved into smaller fragments by enzymes such as gamma secretase and beta secretase 18 One of these fragments gives rise to fibrils of amyloid beta which can self assemble into the dense extracellular amyloid plaques 19 20 Parkinson s disease edit Main article Parkinson s disease Parkinson s disease PD is the second most common neurodegenerative disorder 21 It typically manifests as bradykinesia rigidity resting tremor and posture instability The crude prevalence rate of PD has been reported to range from 15 per 100 000 to 12 500 per 100 000 and the incidence of PD from 15 per 100 000 to 328 per 100 000 with the disease being less common in Asian countries PD is primarily characterized by death of dopaminergic neurons in the substantia nigra a region of the midbrain The cause of this selective cell death is unknown Notably alpha synuclein ubiquitin complexes and aggregates are observed to accumulate in Lewy bodies within affected neurons It is thought that defects in protein transport machinery and regulation such as RAB1 may play a role in this disease mechanism 22 Impaired axonal transport of alpha synuclein may also lead to its accumulation in Lewy bodies Experiments have revealed reduced transport rates of both wild type and two familial Parkinson s disease associated mutant alpha synucleins through axons of cultured neurons 23 Membrane damage by alpha synuclein could be another Parkinson s disease mechanism 24 The main known risk factor is age Mutations in genes such as a synuclein SNCA leucine rich repeat kinase 2 LRRK2 glucocerebrosidase GBA and tau protein MAPT can also cause hereditary PD or increase PD risk 25 While PD is the second most common neurodegenerative disorder problems with diagnoses still persist 26 Problems with the sense of smell is a widespread symptom of Parkinson s disease PD however some neurologists question its efficacy 26 This assessment method is a source of controversy among medical professionals 26 The gut microbiome might play a role in the diagnosis of PD and research suggests various ways that could revolutionize the future of PD treatment 27 Huntington s disease edit Main article Huntington s disease Huntington s disease HD is a rare autosomal dominant neurodegenerative disorder caused by mutations in the huntingtin gene HTT HD is characterized by loss of medium spiny neurons and astrogliosis 28 29 30 The first brain region to be substantially affected is the striatum followed by degeneration of the frontal and temporal cortices 31 The striatum s subthalamic nuclei send control signals to the globus pallidus which initiates and modulates motion The weaker signals from subthalamic nuclei thus cause reduced initiation and modulation of movement resulting in the characteristic movements of the disorder notably chorea 32 Huntington s disease presents itself later in life even though the proteins that cause the disease works towards manifestation from their early stages in the humans affected by the proteins 33 Along with being a neurodegenerative disorder HD has links to problems with neurodevelopment 33 HD is caused by polyglutamine tract expansion in the huntingtin gene resulting in the mutant huntingtin Aggregates of mutant huntingtin form as inclusion bodies in neurons and may be directly toxic Additionally they may damage molecular motors and microtubules to interfere with normal axonal transport leading to impaired transport of important cargoes such as BDNF 23 Huntington s disease currently has no effective treatments that would modify the disease 34 Multiple sclerosis edit Main article Multiple sclerosis Multiple sclerosis MS is a chronic debilitating demyelinating disease of the central nervous system caused by an autoimmune attack resulting in the progressive loss of myelin sheath on neuronal axons 35 The resultant decrease in the speed of signal transduction leads to a loss of functionality that includes both cognitive and motor impairment depending on the location of the lesion 35 The progression of MS occurs due to episodes of increasing inflammation which is proposed to be due to the release of antigens such as myelin oligodendrocyte glycoprotein myelin basic protein and proteolipid protein causing an autoimmune response 36 This sets off a cascade of signaling molecules that result in T cells B cells and Macrophages to cross the blood brain barrier and attack myelin on neuronal axons leading to inflammation 37 Further release of antigens drives subsequent degeneration causing increased inflammation 38 Multiple sclerosis presents itself as a spectrum based on the degree of inflammation a majority of patients experience early relapsing and remitting episodes of neuronal deterioration following a period of recovery Some of these individuals may transition to a more linear progression of the disease while about 15 of others begin with a progressive course on the onset of Multiple sclerosis The inflammatory response contributes to the loss of the grey matter and as a result current literature devotes itself to combatting the auto inflammatory aspect of the disease 37 While there are several proposed causal links between EBV and the HLA DRB1 15 01 allele to the onset of MS they may contribute to the degree of autoimmune attack and the resultant inflammation they do not determine the onset of MS 37 Amyotrophic lateral sclerosis edit Main article Amyotrophic lateral sclerosis Amyotrophic lateral sclerosis ALS or Lou Gehrig s disease is a disease in which motor neurons are selectively targeted for degeneration Amyotrophic lateral sclerosis ALS is a neurodegenerative disorder that negatively impacts the upper motor neurons UMNs and lower motor neurons LMNs 39 In 1993 missense mutations in the gene encoding the antioxidant enzyme Cu Zn superoxide dismutase 1 SOD1 were discovered in a subsets of patients with familial ALS This discovery led researchers to focus on unlocking the mechanisms for SOD1 mediated diseases However the pathogenic mechanism underlying SOD1 mutant toxicity has yet to be resolved More recently TDP 43 and FUS protein aggregates have been implicated in some cases of the disease and a mutation in chromosome 9 C9orf72 is thought to be the most common known cause of sporadic ALS It is diagnosed by skeletal muscle weakness that progresses gradually 39 Early diagnosis of ALS is harder than with other neurodegenerative diseases as there are no highly effective means of determining its early onset 39 Currently there is research being done regarding the diagnosis of ALS through upper motor neuron tests 40 The Penn Upper Motor Neuron Score PUMNS consists of 28 criteria with a score range of 0 32 40 A higher score indicates a higher level of burden present on the upper motor neurons 40 The PUMNS has proven quite effective in determining the burden that exists on upper motor neurons in affected patients 40 Independent research provided in vitro evidence that the primary cellular sites where SOD1 mutations act are located on astrocytes 41 42 Astrocytes then cause the toxic effects on the motor neurons The specific mechanism of toxicity still needs to be investigated but the findings are significant because they implicate cells other than neuron cells in neurodegeneration 43 Batten disease edit Main article Batten disease Batten disease is a rare and fatal recessive neurodegenerative disorder that begins in childhood 44 Batten disease is the common name for a group of lysosomal storage disorders known as neuronal ceroid lipofuscinoses NCLs each caused by a specific gene mutation 44 of which there are thirteen 45 Since Batten disease is quite rare its worldwide prevalence is about 1 in every 100 000 live births 46 In North America CLN3 disease juvenile NCL typically manifests between the ages of 4 and 7 47 Batten disease is characterized by motor impairment epilepsy dementia vision loss and shortened lifespan 48 A loss of vision is common first sign of Batten disease 47 Loss of vision is typically preceded by cognitive and behavioral changes seizures and loss of the ability to walk 47 It is common for people to establish cardiac arrhythmias and difficulties eating food as the disease progresses 47 Batten disease diagnosis depends on a conflation of many criteria clinical signs and symptoms evaluations of the eye electroencephalograms EEG and brain magnetic resonance imaging MRI results 46 The diagnosis provided by these results are corroborated by genetic and biochemical testing 46 No effective treatments were available to prevent the disease from being widespread before the past few years 46 In recent years more models have been created to expedite the research process for methods to treat Batten disease 46 Creutzfeldt Jakob disease edit Main article Creutzfeldt Jakob disease Creutzfeldt Jakob disease CJD is a prion disease that is characterized by rapidly progressive dementia 49 Misfolded proteins called prions aggregate in brain tissue leading to nerve cell death 50 Variant Creutzfeldt Jakob disease vCJD is the infectious form that comes from the meat of a cow that was infected with bovine spongiform encephalopathy also called mad cow disease 51 Risk factor editFurther information Aging brain The greatest risk factor for neurodegenerative diseases is aging Mitochondrial DNA mutations as well as oxidative stress both contribute to aging 52 Many of these diseases are late onset meaning there is some factor that changes as a person ages for each disease 6 One constant factor is that in each disease neurons gradually lose function as the disease progresses with age It has been proposed that DNA damage accumulation provides the underlying causative link between aging and neurodegenerative disease 53 54 About 20 40 of healthy people between 60 and 78 years old experience discernable decrements in cognitive performance in several domains including working spatial and episodic memory and processing speed 55 nbsp Risks from viral exposures according to one biobank study 56 A study using electronic health records indicates that 45 with 22 of these being replicated with the UK Biobank viral exposures can significantly elevate risks of neurodegenerative disease including up to 15 years after infection 56 additional citation s needed Mechanisms editGenetics edit See also Trinucleotide repeat disorder and Epigenetics of neurodegenerative diseases Many neurodegenerative diseases are caused by genetic mutations most of which are located in completely unrelated genes In many of the different diseases the mutated gene has a common feature a repeat of the CAG nucleotide triplet CAG codes for the amino acid glutamine A repeat of CAG results in a polyglutamine polyQ tract Diseases associated with such mutations are known as trinucleotide repeat disorders 57 58 Polyglutamine repeats typically cause dominant pathogenesis Extra glutamine residues can acquire toxic properties through a variety of ways including irregular protein folding and degradation pathways altered subcellular localization and abnormal interactions with other cellular proteins 57 PolyQ studies often use a variety of animal models because there is such a clearly defined trigger repeat expansion Extensive research has been done using the models of nematode C elegans and fruit fly Drosophila mice and non human primates 58 59 Nine inherited neurodegenerative diseases are caused by the expansion of the CAG trinucleotide and polyQ tract including Huntington s disease and the spinocerebellar ataxias 60 Epigenetics edit The presence of epigenetic modifications for certain genes has been demonstrated in this type of pathology An example is FKBP5 gene which progressively increases its expression with age and has been related to Braak staging and increased tau pathology both in vitro and in mouse models of AD 61 Protein misfolding edit See also Stress granule Several neurodegenerative diseases are classified as proteopathies as they are associated with the aggregation of misfolded proteins Protein toxicity is one of the key mechanisms of many neurodegenrative diseases 62 alpha synuclein can aggregate to form insoluble fibrils in pathological conditions characterized by Lewy bodies such as Parkinson s disease dementia with Lewy bodies and multiple system atrophy Alpha synuclein is the primary structural component of Lewy body fibrils In addition an alpha synuclein fragment known as the non Abeta component NAC is found in amyloid plaques in Alzheimer s disease tau hyperphosphorylated tau protein is the main component of neurofibrillary tangles in Alzheimer s disease tau fibrils are the main component of Pick bodies found in behavioral variant frontotemporal dementia amyloid beta the major component of amyloid plaques in Alzheimer s disease prion main component of prion diseases and transmissible spongiform encephalopathy Intracellular mechanisms edit Protein degradation pathways edit Parkinson s disease and Huntington s disease are both late onset and associated with the accumulation of intracellular toxic proteins Diseases caused by the aggregation of proteins are known as proteopathies and they are primarily caused by aggregates in the following structures 6 cytosol e g Parkinson s and Huntington s nucleus e g Spinocerebellar ataxia type 1 SCA1 endoplasmic reticulum ER as seen with neuroserpin mutations that cause familial encephalopathy with neuroserpin inclusion bodies extracellularly excreted proteins amyloid beta in Alzheimer s diseaseThere are two main avenues eukaryotic cells use to remove troublesome proteins or organelles ubiquitin proteasome protein ubiquitin along with enzymes is key for the degradation of many proteins that cause proteopathies including polyQ expansions and alpha synucleins Research indicates proteasome enzymes may not be able to correctly cleave these irregular proteins which could possibly result in a more toxic species This is the primary route cells use to degrade proteins 6 Decreased proteasome activity is consistent with models in which intracellular protein aggregates form It is still unknown whether or not these aggregates are a cause or a result of neurodegeneration 6 autophagy lysosome pathways a form of programmed cell death PCD this becomes the favorable route when a protein is aggregate prone meaning it is a poor proteasome substrate This can be split into two forms of autophagy macroautophagy and chaperone mediated autophagy CMA 6 macroautophagy is involved with nutrient recycling of macromolecules under conditions of starvation certain apoptotic pathways and if absent leads to the formation of ubiquinated inclusions Experiments in mice with neuronally confined macroautophagy gene knockouts develop intraneuronal aggregates leading to neurodegeneration 6 chaperone mediated autophagy defects may also lead to neurodegeneration Research has shown that mutant proteins bind to the CMA pathway receptors on lysosomal membrane and in doing so block their own degradation as well as the degradation of other substrates 6 Membrane damage edit Damage to the membranes of organelles by monomeric or oligomeric proteins could also contribute to these diseases Alpha synuclein can damage membranes by inducing membrane curvature 24 and cause extensive tubulation and vesiculation when incubated with artificial phospholipid vesicles 24 The tubes formed from these lipid vesicles consist of both micellar as well as bilayer tubes Extensive induction of membrane curvature is deleterious to the cell and would eventually lead to cell death Apart from tubular structures alpha synuclein can also form lipoprotein nanoparticles similar to apolipoproteins Mitochondrial dysfunction edit The most common form of cell death in neurodegeneration is through the intrinsic mitochondrial apoptotic pathway This pathway controls the activation of caspase 9 by regulating the release of cytochrome c from the mitochondrial intermembrane space Reactive oxygen species ROS are normal byproducts of mitochondrial respiratory chain activity ROS concentration is mediated by mitochondrial antioxidants such as manganese superoxide dismutase SOD2 and glutathione peroxidase Over production of ROS oxidative stress is a central feature of all neurodegenerative disorders In addition to the generation of ROS mitochondria are also involved with life sustaining functions including calcium homeostasis PCD mitochondrial fission and fusion lipid concentration of the mitochondrial membranes and the mitochondrial permeability transition Mitochondrial disease leading to neurodegeneration is likely at least on some level to involve all of these functions 63 There is strong evidence that mitochondrial dysfunction and oxidative stress play a causal role in neurodegenerative disease pathogenesis including in four of the more well known diseases Alzheimer s Parkinson s Huntington s and amyotrophic lateral sclerosis 52 Neurons are particularly vulnerable to oxidative damage due to their strong metabolic activity associated with high transcription levels high oxygen consumption and weak antioxidant defense 64 65 DNA damage edit The brain metabolizes as much as a fifth of consumed oxygen and reactive oxygen species produced by oxidative metabolism are a major source of DNA damage in the brain Damage to a cell s DNA is particularly harmful because DNA is the blueprint for protein production and unlike other molecules it cannot simply be replaced by re synthesis The vulnerability of post mitotic neurons to DNA damage such as oxidative lesions or certain types of DNA strand breaks coupled with a gradual decline in the activities of repair mechanisms could lead to accumulation of DNA damage with age and contribute to brain aging and neurodegeneration 66 DNA single strand breaks are common and are associated with the neurodegenerative disease ataxia oculomotor apraxia 67 65 Increased oxidative DNA damage in the brain is associated with Alzheimer s disease and Parkinson s disease 67 Defective DNA repair has been linked to neurodegenerative disorders such as Alzheimer s disease amyotrophic lateral sclerosis ataxia telangiectasia Cockayne syndrome Parkinson s disease and xeroderma pigmentosum 67 66 Axonal transport edit Main article Axonal transport Axonal swelling and axonal spheroids have been observed in many different neurodegenerative diseases This suggests that defective axons are not only present in diseased neurons but also that they may cause certain pathological insult due to accumulation of organelles Axonal transport can be disrupted by a variety of mechanisms including damage to kinesin and cytoplasmic dynein microtubules cargoes and mitochondria 23 When axonal transport is severely disrupted a degenerative pathway known as Wallerian like degeneration is often triggered 68 Programmed cell death edit Programmed cell death PCD is death of a cell in any form mediated by an intracellular program 69 This process can be activated in neurodegenerative diseases including Parkinson s disease amytrophic lateral sclerosis Alzheimer s disease and Huntington s disease 70 PCD observed in neurodegenerative diseases may be directly pathogenic alternatively PCD may occur in response to other injury or disease processes 7 Apoptosis type I edit Apoptosis is a form of programmed cell death in multicellular organisms It is one of the main types of programmed cell death PCD and involves a series of biochemical events leading to a characteristic cell morphology and death Extrinsic apoptotic pathways Occur when factors outside the cell activate cell surface death receptors e g Fas that result in the activation of caspases 8 or 10 7 Intrinsic apoptotic pathways Result from mitochondrial release of cytochrome c or endoplasmic reticulum malfunctions each leading to the activation of caspase 9 The nucleus and Golgi apparatus are other organelles that have damage sensors which can lead the cells down apoptotic pathways 7 71 Caspases cysteine aspartic acid proteases cleave at very specific amino acid residues There are two types of caspases initiators and effectors Initiator caspases cleave inactive forms of effector caspases This activates the effectors that in turn cleave other proteins resulting in apoptotic initiation 7 Autophagic type II edit Autophagy is a form of intracellular phagocytosis in which a cell actively consumes damaged organelles or misfolded proteins by encapsulating them into an autophagosome which fuses with a lysosome to destroy the contents of the autophagosome Because many neurodegenerative diseases show unusual protein aggregates it is hypothesized that defects in autophagy could be a common mechanism of neurodegeneration 7 Cytoplasmic type III edit PCD can also occur via non apoptotic processes also known as Type III or cytoplasmic cell death For example type III PCD might be caused by trophotoxicity or hyperactivation of trophic factor receptors Cytotoxins that induce PCD can cause necrosis at low concentrations or aponecrosis combination of apoptosis and necrosis at higher concentrations It is still unclear exactly what combination of apoptosis non apoptosis and necrosis causes different kinds of aponecrosis 7 Transglutaminase edit Transglutaminases are human enzymes ubiquitously present in the human body and in the brain in particular 72 The main function of transglutaminases is bind proteins and peptides intra and intermolecularly by a type of covalent bonds termed isopeptide bonds in a reaction termed transamidation or crosslinking 72 Transglutaminase binding of these proteins and peptides make them clump together The resulting structures are turned extremely resistant to chemical and mechanical disruption 72 Most relevant human neurodegenerative diseases share the property of having abnormal structures made up of proteins and peptides 72 Each of these neurodegenerative diseases have one or several specific main protein or peptide In Alzheimer s disease these are amyloid beta and tau In Parkinson s disease it is alpha synuclein In Huntington s disease it is huntingtin 72 Transglutaminase substrates Amyloid beta tau alpha synuclein and huntingtin have been proved to be substrates of transglutaminases in vitro or in vivo that is they can be bonded by trasglutaminases by covalent bonds to each other and potentially to any other transglutaminase substrate in the brain 72 Transglutaminase augmented expression It has been proved that in these neurodegenerative diseases Alzheimer s disease Parkinson s disease and Huntington s disease the expression of the transglutaminase enzyme is increased 72 Presence of isopeptide bonds in these structures The presence of isopeptide bonds the result of the transglutaminase reaction have been detected in the abnormal structures that are characteristic of these neurodegenerative diseases 72 Co localization Co localization of transglutaminase mediated isopeptide bonds with these abnormal structures has been detected in the autopsy of brains of patients with these diseases 72 Management editThe process of neurodegeneration is not well understood so the diseases that stem from it have as yet no cures Animal models in research edit In the search for effective treatments as opposed to palliative care investigators employ animal models of disease to test potential therapeutic agents Model organisms provide an inexpensive and relatively quick means to perform two main functions target identification and target validation Together these help show the value of any specific therapeutic strategies and drugs when attempting to ameliorate disease severity An example is the drug Dimebon by Medivation Inc In 2009 this drug was in phase III clinical trials for use in Alzheimer s disease and also phase II clinical trials for use in Huntington s disease 58 In March 2010 the results of a clinical trial phase III were released the investigational Alzheimer s disease drug Dimebon failed in the pivotal CONNECTION trial of patients with mild to moderate disease 73 With CONCERT the remaining Pfizer and Medivation Phase III trial for Dimebon latrepirdine in Alzheimer s disease failed in 2012 effectively ending the development in this indication 74 In another experiment using a rat model of Alzheimer s disease it was demonstrated that systemic administration of hypothalamic proline rich peptide PRP 1 offers neuroprotective effects and can prevent neurodegeneration in hippocampus amyloid beta 25 35 This suggests that there could be therapeutic value to PRP 1 75 Other avenues of investigation edit Protein degradation offers therapeutic options both in preventing the synthesis and degradation of irregular proteins There is also interest in upregulating autophagy to help clear protein aggregates implicated in neurodegeneration Both of these options involve very complex pathways that we are only beginning to understand 6 The goal of immunotherapy is to enhance aspects of the immune system Both active and passive vaccinations have been proposed for Alzheimer s disease and other conditions however more research must be done to prove safety and efficacy in humans 76 A current therapeutic target for the treatment of Alzheimer s disease is the protease b secretase 77 non primary source needed which is involved in the amyloidogenic processing pathway that leads to the pathological accumulation of proteins in the brain When the gene that encodes for amyloid precursor protein APP is spliced by a secretase 78 non primary source needed rather than b secretase the toxic protein b amyloid is not produced Targeted inhibition 79 of b secretase can potentially prevent the neuronal death that is responsible for the symptoms of Alzheimer s disease Dr Antonio Barbera a former obstetrics and gynaecology doctor is prescribing table tennis for patients who are suffering from a serious Neurological disorder 80 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