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Congenital adrenal hyperplasia

May 08, 2024

"Adrenal hyperplasia" redirects here. See also primary aldosteronism or Cushing's syndrome.

Congenital adrenal hyperplasia (CAH) is a group of autosomal recessive disorders characterized by impaired cortisol synthesis.[1][2] It results from the deficiency of one of the five enzymes required for the synthesis of cortisol in the adrenal cortex.[3] Most of these disorders involve excessive or deficient production of hormones such as glucocorticoids, mineralocorticoids, or sex steroids,[4][2] and can alter development of primary or secondary sex characteristics in some affected infants, children, or adults.[5] It is one of the most common autosomal recessive disorders in humans.[6][7][8]

Congenital adrenal hyperplasia
Congenital adrenal hyperplasia enzymes.
SpecialtyEndocrinology 
SymptomsExcessive urination of sodium, virilism, early, delayed, or absent puberty, hyperandrogenism
Usual onsetBefore birth
DurationLifetime
CausesVariants in genes responsible the enzymes required for the synthesis of cortisol in the adrenal cortex

Types edit

CAH can occur in various forms. The clinical presentation of each form is different and depends to a large extent on the underlying enzyme defect, its precursor retention, and deficient products.[9] Classical forms appear in infancy, and nonclassical forms appear in late childhood. The presentation in patients with classic CAH can be further subdivided into three forms: salt-wasting, simple-virilizing, and non-classic (NC) depending on whether mineralocorticoid deficiency presents or absents, respectively.[10][11][12] This subtyping is often not clinically meaningful, though, because all patients lose salt to some degree, and clinical presentations may overlap.[13]

Classic edit

Salt-wasting edit

In 75% of cases of severe enzyme deficiency, insufficient aldosterone production can lead to salt wasting, failure to thrive, and potentially fatal hypovolemia and shock. A missed diagnosis of salt-loss CAH is related to the increased risk of early neonatal morbidity and death.[2]

Simple-virilizing edit

The main feature of CAH in newborn females is the abnormal development of the external genitalia, which has varying degrees of virilization. According to clinical practice guidelines, for newborns found to have bilateral inaccessible gonads, CAH evaluation should be considered. If virilizing CAH cannot be identified and treated, both boys and girls may undergo rapid postnatal growth and virilization.[2]

Nonclassic edit

Main article: Late onset congenital adrenal hyperplasia

In addition to the salt-wasting and simple-virilizing forms of CAH diagnosed in infancy, a mild or "nonclassic" form exists, which is characterized by varying degrees of postnatal androgen excess, but is sometimes asymptomatic.[14] The nonclassic form may be noticed in late childhood and may lead to signs of hyperandrogenism such as accelerated growth, acne, hirsutism, premature pubarche, menstrual irregularities,[14] and secondary polycystic ovary syndrome.[15] In adult males, early balding[14] and infertility may suggest the diagnosis. The nonclassic form is characterized by mild subclinical impairment of cortisol synthesis[14] serum cortisol concentration is usually normal.[14]

Signs and symptoms edit

The symptoms of CAH vary depending upon the form of CAH and the sex of the patient. Symptoms can include:

Due to inadequate mineralocorticoids:[citation needed]

Due to excess androgens:

Due to insufficient androgens and estrogens:[citation needed]

Genetics edit

CAH results from mutations of genes for enzymes mediating the biochemical steps of production of mineralocorticoids, glucocorticoids, or sex steroids from cholesterol by the adrenal glands (steroidogenesis).[20]

Each form of CAH is associated with a specific defective gene. The most common type (95% of cases)[2][11]involves the gene for 21-hydroxylase, which is found on 6p21.3 as part of the HLA complex; 21-hydroxylase deficiency results from a unique mutation with two highly homologous near-copies in series consisting of an active gene (CYP21A2) and an inactive pseudogene (CYP21A1P).[21][22][23] Mutant alleles result from recombination between the active and pseudogenes (gene conversion).[24] About 5% of cases of CAH are due to defects in the gene encoding 11β-hydroxylase and consequent 11β-hydroxylase deficiency. Other, more rare forms of CAH are caused by mutations in genes, including HSD3B2 (3β-hydroxysteroid dehydrogenase 2), CYP17A1 (17α-hydroxylase/17,20-lyase),[25] CYP11A1 (P450scc; cholesterol side-chain cleavage enzyme), STAR (steroidogenic acute regulatory protein; StAR), CYB5A (cytochrome b5), and CYPOR (cytochrome P450 oxidoreductase; POR).[citation needed]

Expressivity edit

Further variability is introduced by the degree of enzyme inefficiency produced by the specific alleles each patient has. Some alleles result in more severe degrees of enzyme inefficiency. In general, severe degrees of inefficiency produce changes in the fetus and problems in prenatal or perinatal life. Milder degrees of inefficiency are usually associated with excessive or deficient sex hormone effects in childhood or adolescence, while the mildest forms of CAH interfere with ovulation and fertility in adults.[citation needed]

Diagnosis edit

Clinical evaluation edit

Female infants with classic CAH have ambiguous genitalia due to exposure to high concentrations of androgens in utero.[26] CAH due to 21-hydroxylase deficiency is the most common cause of ambiguous genitalia in genotypically normal female infants (46XX). Less severely affected females may present with early pubarche. Young women may present with symptoms of polycystic ovarian syndrome (oligomenorrhea, polycystic ovaries, hirsutism).[medical citation needed]

Males with classic CAH generally have no signs of CAH at birth. Some may present with hyperpigmentation, due to co-secretion with melanocyte-stimulating hormone, and possible penile enlargement. Age of diagnosis of males with CAH varies and depends on the severity of aldosterone deficiency. Boys with salt-wasting disease present early with symptoms of hyponatremia and hypovolemia. Boys with non-salt-wasting disease present later with signs of virilization.[24]

In rarer forms of CAH, males are undermasculinized[27] and females generally have no signs or symptoms at birth.[medical citation needed]

Laboratory studies edit

Genetic analysis can be helpful to confirm a diagnosis of CAH, but it is not necessary if classic clinical and laboratory findings are present.

In classic 21-hydroxylase deficiency, laboratory studies will show:

  • Hypoglycemia (due to hypocortisolism) - One of cortisol's many functions is to increase blood glucose levels. This occurs via a combination of several mechanisms, including (a) the stimulation of gluconeogesis (i.e. the creation of new glucose) in the liver, (b) the promotion of glycogenolysis (i.e. the breakdown of glycogen into glucose), and (c) the prevention of glucose leaving the bloodstream via the downregulation of GLUT-4 receptors (which normally promote movement of glucose from the bloodstream into adipose and muscle tissues). Therefore, when cortisol is deficient, these processes (effectively) occur in the reverse direction. Although there are compensatory mechanisms that mitigate the impact of hypocortisolism, they are limited in their extent and the net effect is still hypoglycemia.
  • Hyponatremia (due to hypoaldosteronism) - Aldosterone is the end product of the renin-angiotensin-aldosterone system that regulates blood pressure via blood pressure surveillance in the Kidney Juxtaglomerular apparatus. Aldosterone normally functions to increase sodium retention (which brings water as well) in exchange for potassium. Thus, lack of aldosterone causes hyperkalemia and hyponatremia. In fact, this is a distinguishing point from 11-hydroxylase deficiency, in which one of the increased products is 11-deoxycorticosterone that has weak mineralocorticoid activity. In 11-hydroxylase deficiency, 11-deoxycorticosterone is produced in such excess that it acts to retain sodium at the expense of potassium. It is this reason that patients with 11-hydroxylase deficiency do not show salt wasting (although sometimes they do in infancy), and instead have hypertension/water retention and sometimes hypokalemia.
  • Hyperkalemia (due to hypoaldosteronism)
  • Elevated 17α-hydroxyprogesterone

Classic 21-hydroxylase deficiency typically causes 17α-hydroxyprogesterone blood levels >242 nmol/L.[medical citation needed] (For comparison, a full-term infant at three days of age should have <3 nmol/L. Many neonatal screening programs have specific reference ranges by weight and gestational age because high levels may be seen in premature infants without CAH.) Salt-wasting patients tend to have higher 17α-hydroxyprogesterone levels than non-salt-wasting patients. In mild cases, 17α-hydroxyprogesterone may not be elevated in a particular random blood sample, but it will rise during a corticotropin stimulation test.

Classification edit

Cortisol is an adrenal steroid hormone required for normal endocrine function. Production begins in the second month of fetal life. Poor cortisol production is a hallmark of most forms of CAH. Inefficient cortisol production results in rising levels of ACTH, because cortisol feeds back to inhibit ACTH production, so loss of cortisol results in increased ACTH.[28] This increased ACTH stimulation induces overgrowth (hyperplasia) and overactivity of the steroid-producing cells of the adrenal cortex. The defects causing adrenal hyperplasia are congenital (i.e. present at birth).

 
Steroidogenesis: The enzymes affected in CAH are represented by one red and four green bars on the top half of the diagram (for example, "21α-hydroxylase" is visible near the top center. "17α-hydroxylase" and "17,20 lyase" are carried out by a single enzyme).[29] Depending upon which enzyme is unavailable, production of androgens (lower left) or mineralocorticoids (upper right) is reduced. This, in turn, can lead to increased production of other molecules, due to a buildup of precursors.

Cortisol deficiency in CAH is usually partial, and not the most serious problem for an affected person. Synthesis of cortisol shares steps with synthesis of mineralocorticoids such as aldosterone, androgens such as testosterone, and estrogens such as estradiol. The resulting excessive or deficient production of these three classes of hormones produce the most important problems for people with CAH. Specific enzyme inefficiencies are associated with characteristic patterns of over- or underproduction of mineralocorticoids or sex steroids.

Since the 1960s, most endocrinologists have referred to the forms of CAH by the traditional names in the left column, which generally correspond to the deficient enzyme activity. As exact structures and genes for the enzymes were identified in the 1980s, most of the enzymes were found to be cytochrome P450 oxidases and were renamed to reflect this. In some cases, more than one enzyme was found to participate in a reaction, and in other cases, a single enzyme mediated in more than one reaction. Variation in different tissues and mammalian species also was found.

In all its forms, congenital adrenal hyperplasia due to 21-hydroxylase deficiency accounts for about 95% of diagnosed cases of CAH.[2] Unless another specific enzyme is mentioned, "CAH" in nearly all contexts refers to 21-hydroxylase deficiency. (The terms "salt-wasting CAH", and "simple virilizing CAH" usually refer to subtypes of this condition.) CAH due to deficiencies of enzymes other than 21-hydroxylase present many of the same management challenges, as 21-hydroxylase deficiency, but some involve mineralocorticoid excess or sex steroid deficiency.

Common medical term % OMIM Enzyme(s) Locus Substrate(s) Product(s) Mineralocorticoids Androgens
21-Hydroxylase CAH 95%[2] 201910 P450c21 6p21.3 17-OH-Progesterone
Progesterone		 11-Deoxycortisol
DOC
11β-Hydroxylase CAH 5% 202010 P450c11β 8q21-22 11-Deoxycortisol→
DOC→ 		Cortisol
Corticosterone
3β-HSD CAH Very rare 201810 3βHSD2 1p13 Pregnenolone
17-OH-Pregnenolone
DHEA		 Progesterone
17-OH-Progesterone
Androstenedione
17α-Hydroxylase CAH Very rare 202110 CYP17A1 10q24.3 Pregnenolone
Progesterone
17-OH-Pregnenolone→ 		17-OH-Pregnenolone
17-OH-Progesterone
DHEA
Lipoid CAH
(20,22-desmolase) 		Very rare 201710 StAR
P450scc 		8p11.2
15q23-q24 		Transport of cholesterol
Cholesterol		 Into mitochondria
Pregnenolone

Screening edit

Currently, in the United States and over 40 other countries, every child born is screened for 21-hydroxylase CAH at birth. This test detects elevated levels of 17α-hydroxyprogesterone (17-OHP). Detecting high levels of 17-OHP enables early detection of CAH. Newborns detected early enough can be placed on medication and live relatively normal lives.[citation needed]

The screening process, however, is characterized by a high false-positive rate. In one study,[30] CAH screening had the lowest positive predictive value (111 true-positive cases among 20,647 abnormal screening results in a 2-year period, or 0.53%, compared with 6.36% for biotinidase deficiency, 1.84% for congenital hypo-thyroidism, 0.56% for classic galactosemia, and 2.9% for phenylketonuria). According to this estimate, 200 unaffected newborns required clinical and laboratory follow-up for every true case of CAH.[non-primary source needed]

In 2020, Wael AbdAlmageed from USC Information Sciences Institute and Mimi Kim from USC Keck School Of Medicine led a joint study in which they used deep learning technology to analyze the facial morphology and features of CAH patients compared to control. In this cross-sectional study[31] of 102 patients with CAH and 144 control participants, deep learning methods achieved a mean area under the receiver operating characteristic curve of 92% for predicting CAH from facial images. Facial features distinguished patients with CAH from controls, and analyses of facial regions found that the nose and upper face were most contributory. The findings suggest that facial morphologic features, as analyzed by deep neural network techniques, can be used as a phenotypic biomarker to predict CAH.

Treatment edit

Since the clinical manifestations of each form of CAH are unique and depend to a large extent on the underlying enzyme defects, their precursor retention and defective products, the therapeutic goal of CAH is to replenish insufficient adrenal hormones and suppress excess of precursors.[9]

Treatment of all forms of CAH may include any of:

  1. Supplying enough glucocorticoid to reduce hyperplasia and overproduction of androgens or mineralocorticoids[citation needed]
  2. Providing replacement mineralocorticoid and extra salt if the person is deficient[2]
  3. Providing replacement testosterone or estrogens at puberty if the person is deficient[citation needed]
  4. Additional treatments to optimize growth by delaying puberty or delaying bone maturation[citation needed]

If CAH is caused by the deficiency of the 21-hydroxylase enzyme, then treatment aims to normalize levels of androstenedione, but normalization of 17α-hydroxyprogesterone is a sign of overtreatment.[32] Treatment can be monitored by measuring androstenedione and 17α-hydroxyprogesterone levels in blood or saliva[32].

See also: Congenital adrenal hyperplasia due to 21-hydroxylase deficiency § Treatment

Epidemiology edit

The incidence varies ethnically. In the United States, congenital adrenal hyperplasia in its classic form is particularly common in Native Americans and Yupik Inuit (incidence 1280). Among American Caucasians, the incidence of the classic form is about 115,000).[24]

Continued treatment and wellness are enhanced by education and follow up.[33]

History edit

Before 20th century edit

An Italian anatomist, Luigi De Crecchio (1832-1894) provided the earliest known description of a case of probable CAH.

I propose in this narrative that it is sometimes extremely difficult and even impossible to determine sex during life. In one of the anatomical theaters of the hospital..., there arrived toward the end of January a cadaver which in life was the body of a certain Joseph Marzo... The general physiognomy was decidedly male in all respects. There were no feminine curves to the body. There was a heavy beard. There was some delicacy of structure with muscles that were not very well developed... The distribution of pubic hair was typical of the male. Perhaps the lower extremities were somewhat delicate, resembling the female, and were covered with hair... The penis was curved posteriorly and measured 6 cm, or with stretching, 10 cm. The corona was 3 cm long and 8 cm in circumference. There was an ample prepuce. There was a first grade hypospadias... There were two folds of skin coming from the top of the penis and encircling it on either side. These were somewhat loose and resembled labia majora.

De Crecchio then described the internal organs, which included a normal vagina, uterus, fallopian tubes, and ovaries.

It was of the greatest importance to determine the habits, tendencies, passions, and general character of this individual... I was determined to get as complete a story as possible, determined to get at the base of the facts and to avoid undue exaggeration which was rampant in the conversation of many of the people present at the time of the dissection.

He interviewed many people and satisfied himself that Joseph Marzo "conducted himself within the sexual area exclusively as a male", even to the point of contracting the "French disease" on two occasions. The cause of death was another in a series of episodes of vomiting and diarrhea.[34]

This account was translated by Alfred Bongiovanni from De Crecchio ("Sopra un caso di apparenzi virili in una donna". Morgagni 7:154–188, 1865) in 1963 for an article in The New England Journal of Medicine.

20th and 21st centuries edit

The association of excessive sex steroid effects with diseases of the adrenal cortex have been recognized for over a century. The term "adrenogenital syndrome" was applied to both sex-steroid producing tumors and severe forms of CAH for much of the 20th century, before some of the forms of CAH were understood. Congenital adrenal hyperplasia, which also dates to the first half of the century, has become the preferred term to reduce ambiguity and to emphasize the underlying pathophysiology of the disorders.

Much modern understanding and treatment of CAH comes from research conducted at Johns Hopkins Medical School in Baltimore in the middle of the 20th century. Lawson Wilkins, "founder" of pediatric endocrinology, worked out the apparently paradoxical pathophysiology: that hyperplasia and overproduction of adrenal androgens resulted from impaired capacity for making cortisol. He reported use of adrenal cortical extracts to treat children with CAH in 1950. Genital reconstructive surgery was also pioneered at Hopkins. After application of karyotyping to CAH and other intersex disorders in the 1950s, John Money, JL Hampson, and JG Hampson persuaded both the scientific community and the public [citation needed] that sex assignment should not be based on any single biological criterion, and gender identity was largely learned and has no simple relationship with chromosomes or hormones. See Intersex for a fuller history, including recent controversies over reconstructive surgery.

Hydrocortisone, fludrocortisone, and prednisone were available by the late 1950s. By 1980, all of the relevant steroids could be measured in blood by reference laboratories for patient care. By 1990, nearly all specific genes and enzymes had been identified. The last decade, though, has seen a number of new developments, discussed more extensively in congenital adrenal hyperplasia due to 21-hydroxylase deficiency:

  1. Debate over the value of genital reconstructive surgery and changing standards
  2. Debate over sex assignment of severely virilized XX infants
  3. New treatments to improve height outcomes
  4. Newborn screening programs to detect CAH at birth
  5. Increasing attempts to treat CAH before birth

Society and culture edit

People with CAH edit

Notable people with CAH include:

See also edit

References edit

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Further reading edit

  • Han, Thang S.; Walker, Brian R.; Arlt, Wiebke; Ross, Richard J. (17 December 2013). "Treatment and health outcomes in adults with congenital adrenal hyperplasia". Nature Reviews Endocrinology. 10 (2): 115–124. doi:10.1038/nrendo.2013.239. PMID 24342885. S2CID 6090764Figure 2: The adrenal steroidogenesis pathway.{{cite journal}}: CS1 maint: postscript (link)

External links edit

 
Wikimedia Commons has media related to Congenital adrenal hyperplasia.
  • Congenital adrenal hyperplasia at Curlie

May 08, 2024
congenital, adrenal, hyperplasia, adrenal, hyperplasia, redirects, here, also, primary, aldosteronism, cushing, syndrome, group, autosomal, recessive, disorders, characterized, impaired, cortisol, synthesis, results, from, deficiency, five, enzymes, required, . Adrenal hyperplasia redirects here See also primary aldosteronism or Cushing s syndrome Congenital adrenal hyperplasia CAH is a group of autosomal recessive disorders characterized by impaired cortisol synthesis 1 2 It results from the deficiency of one of the five enzymes required for the synthesis of cortisol in the adrenal cortex 3 Most of these disorders involve excessive or deficient production of hormones such as glucocorticoids mineralocorticoids or sex steroids 4 2 and can alter development of primary or secondary sex characteristics in some affected infants children or adults 5 It is one of the most common autosomal recessive disorders in humans 6 7 8 Congenital adrenal hyperplasiaCongenital adrenal hyperplasia enzymes SpecialtyEndocrinology SymptomsExcessive urination of sodium virilism early delayed or absent puberty hyperandrogenismUsual onsetBefore birthDurationLifetimeCausesVariants in genes responsible the enzymes required for the synthesis of cortisol in the adrenal cortexContents 1 Types 1 1 Classic 1 1 1 Salt wasting 1 1 2 Simple virilizing 1 2 Nonclassic 2 Signs and symptoms 3 Genetics 3 1 Expressivity 4 Diagnosis 4 1 Clinical evaluation 4 2 Laboratory studies 4 3 Classification 5 Screening 6 Treatment 7 Epidemiology 8 History 8 1 Before 20th century 8 2 20th and 21st centuries 9 Society and culture 9 1 People with CAH 10 See also 11 References 12 Further reading 13 External linksTypes editCAH can occur in various forms The clinical presentation of each form is different and depends to a large extent on the underlying enzyme defect its precursor retention and deficient products 9 Classical forms appear in infancy and nonclassical forms appear in late childhood The presentation in patients with classic CAH can be further subdivided into three forms salt wasting simple virilizing and non classic NC depending on whether mineralocorticoid deficiency presents or absents respectively 10 11 12 This subtyping is often not clinically meaningful though because all patients lose salt to some degree and clinical presentations may overlap 13 Classic edit Salt wasting edit In 75 of cases of severe enzyme deficiency insufficient aldosterone production can lead to salt wasting failure to thrive and potentially fatal hypovolemia and shock A missed diagnosis of salt loss CAH is related to the increased risk of early neonatal morbidity and death 2 Simple virilizing edit The main feature of CAH in newborn females is the abnormal development of the external genitalia which has varying degrees of virilization According to clinical practice guidelines for newborns found to have bilateral inaccessible gonads CAH evaluation should be considered If virilizing CAH cannot be identified and treated both boys and girls may undergo rapid postnatal growth and virilization 2 Nonclassic edit Main article Late onset congenital adrenal hyperplasiaIn addition to the salt wasting and simple virilizing forms of CAH diagnosed in infancy a mild or nonclassic form exists which is characterized by varying degrees of postnatal androgen excess but is sometimes asymptomatic 14 The nonclassic form may be noticed in late childhood and may lead to signs of hyperandrogenism such as accelerated growth acne hirsutism premature pubarche menstrual irregularities 14 and secondary polycystic ovary syndrome 15 In adult males early balding 14 and infertility may suggest the diagnosis The nonclassic form is characterized by mild subclinical impairment of cortisol synthesis 14 serum cortisol concentration is usually normal 14 Signs and symptoms editThe symptoms of CAH vary depending upon the form of CAH and the sex of the patient Symptoms can include Due to inadequate mineralocorticoids citation needed Vomiting due to salt wasting leading to dehydration and death Due to excess androgens In extreme virilization clitoromegaly elongated clitoris with a phallic like structure is seen 16 17 18 Ambiguous genitalia in some infants occurs such that initially identifying external genitalia as male or female is difficult Early pubic hair and rapid growth occurs in childhood Precocious puberty or failure of puberty to occur sexual infantilism absent or delayed puberty Excessive facial hair virilization and or menstrual irregularity in adolescence Infertility due to anovulation Shallow vagina 19 Due to insufficient androgens and estrogens citation needed Undervirilization in XY males can result in an apparent vulva Ambiguous genitalia in XY males with 3b hydroxysteroid dehydrogenase deficiency 3b HSD2D In females hypogonadism can cause sexual infantilism or abnormal pubertal development infertility and other reproductive system abnormalities Genetics editCAH results from mutations of genes for enzymes mediating the biochemical steps of production of mineralocorticoids glucocorticoids or sex steroids from cholesterol by the adrenal glands steroidogenesis 20 Each form of CAH is associated with a specific defective gene The most common type 95 of cases 2 11 involves the gene for 21 hydroxylase which is found on 6p21 3 as part of the HLA complex 21 hydroxylase deficiency results from a unique mutation with two highly homologous near copies in series consisting of an active gene CYP21A2 and an inactive pseudogene CYP21A1P 21 22 23 Mutant alleles result from recombination between the active and pseudogenes gene conversion 24 About 5 of cases of CAH are due to defects in the gene encoding 11b hydroxylase and consequent 11b hydroxylase deficiency Other more rare forms of CAH are caused by mutations in genes including HSD3B2 3b hydroxysteroid dehydrogenase 2 CYP17A1 17a hydroxylase 17 20 lyase 25 CYP11A1 P450scc cholesterol side chain cleavage enzyme STAR steroidogenic acute regulatory protein StAR CYB5A cytochrome b5 and CYPOR cytochrome P450 oxidoreductase POR citation needed Expressivity edit Further variability is introduced by the degree of enzyme inefficiency produced by the specific alleles each patient has Some alleles result in more severe degrees of enzyme inefficiency In general severe degrees of inefficiency produce changes in the fetus and problems in prenatal or perinatal life Milder degrees of inefficiency are usually associated with excessive or deficient sex hormone effects in childhood or adolescence while the mildest forms of CAH interfere with ovulation and fertility in adults citation needed Diagnosis editThis section needs additional citations for verification Please help improve this article by adding citations to reliable sources in this section Unsourced material may be challenged and removed October 2020 Learn how and when to remove this message Clinical evaluation edit Female infants with classic CAH have ambiguous genitalia due to exposure to high concentrations of androgens in utero 26 CAH due to 21 hydroxylase deficiency is the most common cause of ambiguous genitalia in genotypically normal female infants 46XX Less severely affected females may present with early pubarche Young women may present with symptoms of polycystic ovarian syndrome oligomenorrhea polycystic ovaries hirsutism medical citation needed Males with classic CAH generally have no signs of CAH at birth Some may present with hyperpigmentation due to co secretion with melanocyte stimulating hormone and possible penile enlargement Age of diagnosis of males with CAH varies and depends on the severity of aldosterone deficiency Boys with salt wasting disease present early with symptoms of hyponatremia and hypovolemia Boys with non salt wasting disease present later with signs of virilization 24 In rarer forms of CAH males are undermasculinized 27 and females generally have no signs or symptoms at birth medical citation needed Laboratory studies edit Genetic analysis can be helpful to confirm a diagnosis of CAH but it is not necessary if classic clinical and laboratory findings are present In classic 21 hydroxylase deficiency laboratory studies will show Hypoglycemia due to hypocortisolism One of cortisol s many functions is to increase blood glucose levels This occurs via a combination of several mechanisms including a the stimulation of gluconeogesis i e the creation of new glucose in the liver b the promotion of glycogenolysis i e the breakdown of glycogen into glucose and c the prevention of glucose leaving the bloodstream via the downregulation of GLUT 4 receptors which normally promote movement of glucose from the bloodstream into adipose and muscle tissues Therefore when cortisol is deficient these processes effectively occur in the reverse direction Although there are compensatory mechanisms that mitigate the impact of hypocortisolism they are limited in their extent and the net effect is still hypoglycemia Hyponatremia due to hypoaldosteronism Aldosterone is the end product of the renin angiotensin aldosterone system that regulates blood pressure via blood pressure surveillance in the Kidney Juxtaglomerular apparatus Aldosterone normally functions to increase sodium retention which brings water as well in exchange for potassium Thus lack of aldosterone causes hyperkalemia and hyponatremia In fact this is a distinguishing point from 11 hydroxylase deficiency in which one of the increased products is 11 deoxycorticosterone that has weak mineralocorticoid activity In 11 hydroxylase deficiency 11 deoxycorticosterone is produced in such excess that it acts to retain sodium at the expense of potassium It is this reason that patients with 11 hydroxylase deficiency do not show salt wasting although sometimes they do in infancy and instead have hypertension water retention and sometimes hypokalemia Hyperkalemia due to hypoaldosteronism Elevated 17a hydroxyprogesterone Classic 21 hydroxylase deficiency typically causes 17a hydroxyprogesterone blood levels gt 242 nmol L medical citation needed For comparison a full term infant at three days of age should have lt 3 nmol L Many neonatal screening programs have specific reference ranges by weight and gestational age because high levels may be seen in premature infants without CAH Salt wasting patients tend to have higher 17a hydroxyprogesterone levels than non salt wasting patients In mild cases 17a hydroxyprogesterone may not be elevated in a particular random blood sample but it will rise during a corticotropin stimulation test Classification edit Cortisol is an adrenal steroid hormone required for normal endocrine function Production begins in the second month of fetal life Poor cortisol production is a hallmark of most forms of CAH Inefficient cortisol production results in rising levels of ACTH because cortisol feeds back to inhibit ACTH production so loss of cortisol results in increased ACTH 28 This increased ACTH stimulation induces overgrowth hyperplasia and overactivity of the steroid producing cells of the adrenal cortex The defects causing adrenal hyperplasia are congenital i e present at birth nbsp Steroidogenesis The enzymes affected in CAH are represented by one red and four green bars on the top half of the diagram for example 21a hydroxylase is visible near the top center 17a hydroxylase and 17 20 lyase are carried out by a single enzyme 29 Depending upon which enzyme is unavailable production of androgens lower left or mineralocorticoids upper right is reduced This in turn can lead to increased production of other molecules due to a buildup of precursors Cortisol deficiency in CAH is usually partial and not the most serious problem for an affected person Synthesis of cortisol shares steps with synthesis of mineralocorticoids such as aldosterone androgens such as testosterone and estrogens such as estradiol The resulting excessive or deficient production of these three classes of hormones produce the most important problems for people with CAH Specific enzyme inefficiencies are associated with characteristic patterns of over or underproduction of mineralocorticoids or sex steroids Since the 1960s most endocrinologists have referred to the forms of CAH by the traditional names in the left column which generally correspond to the deficient enzyme activity As exact structures and genes for the enzymes were identified in the 1980s most of the enzymes were found to be cytochrome P450 oxidases and were renamed to reflect this In some cases more than one enzyme was found to participate in a reaction and in other cases a single enzyme mediated in more than one reaction Variation in different tissues and mammalian species also was found In all its forms congenital adrenal hyperplasia due to 21 hydroxylase deficiency accounts for about 95 of diagnosed cases of CAH 2 Unless another specific enzyme is mentioned CAH in nearly all contexts refers to 21 hydroxylase deficiency The terms salt wasting CAH and simple virilizing CAH usually refer to subtypes of this condition CAH due to deficiencies of enzymes other than 21 hydroxylase present many of the same management challenges as 21 hydroxylase deficiency but some involve mineralocorticoid excess or sex steroid deficiency Common medical term OMIM Enzyme s Locus Substrate s Product s Mineralocorticoids Androgens 21 Hydroxylase CAH 95 2 201910 P450c21 6p21 3 17 OH Progesterone Progesterone 11 DeoxycortisolDOC 11b Hydroxylase CAH 5 202010 P450c11b 8q21 22 11 Deoxycortisol DOC CortisolCorticosterone 3b HSD CAH Very rare 201810 3bHSD2 1p13 Pregnenolone 17 OH Pregnenolone DHEA Progesterone17 OH ProgesteroneAndrostenedione 17a Hydroxylase CAH Very rare 202110 CYP17A1 10q24 3 Pregnenolone Progesterone 17 OH Pregnenolone 17 OH Pregnenolone17 OH ProgesteroneDHEA Lipoid CAH 20 22 desmolase Very rare 201710 StARP450scc 8p11 215q23 q24 Transport of cholesterolCholesterol Into mitochondriaPregnenolone Screening editCurrently in the United States and over 40 other countries every child born is screened for 21 hydroxylase CAH at birth This test detects elevated levels of 17a hydroxyprogesterone 17 OHP Detecting high levels of 17 OHP enables early detection of CAH Newborns detected early enough can be placed on medication and live relatively normal lives citation needed The screening process however is characterized by a high false positive rate In one study 30 CAH screening had the lowest positive predictive value 111 true positive cases among 20 647 abnormal screening results in a 2 year period or 0 53 compared with 6 36 for biotinidase deficiency 1 84 for congenital hypo thyroidism 0 56 for classic galactosemia and 2 9 for phenylketonuria According to this estimate 200 unaffected newborns required clinical and laboratory follow up for every true case of CAH non primary source needed In 2020 Wael AbdAlmageed from USC Information Sciences Institute and Mimi Kim from USC Keck School Of Medicine led a joint study in which they used deep learning technology to analyze the facial morphology and features of CAH patients compared to control In this cross sectional study 31 of 102 patients with CAH and 144 control participants deep learning methods achieved a mean area under the receiver operating characteristic curve of 92 for predicting CAH from facial images Facial features distinguished patients with CAH from controls and analyses of facial regions found that the nose and upper face were most contributory The findings suggest that facial morphologic features as analyzed by deep neural network techniques can be used as a phenotypic biomarker to predict CAH Treatment editSince the clinical manifestations of each form of CAH are unique and depend to a large extent on the underlying enzyme defects their precursor retention and defective products the therapeutic goal of CAH is to replenish insufficient adrenal hormones and suppress excess of precursors 9 Treatment of all forms of CAH may include any of Supplying enough glucocorticoid to reduce hyperplasia and overproduction of androgens or mineralocorticoids citation needed Providing replacement mineralocorticoid and extra salt if the person is deficient 2 Providing replacement testosterone or estrogens at puberty if the person is deficient citation needed Additional treatments to optimize growth by delaying puberty or delaying bone maturation citation needed If CAH is caused by the deficiency of the 21 hydroxylase enzyme then treatment aims to normalize levels of androstenedione but normalization of 17a hydroxyprogesterone is a sign of overtreatment 32 Treatment can be monitored by measuring androstenedione and 17a hydroxyprogesterone levels in blood or saliva 32 See also Congenital adrenal hyperplasia due to 21 hydroxylase deficiency TreatmentEpidemiology editThe incidence varies ethnically In the United States congenital adrenal hyperplasia in its classic form is particularly common in Native Americans and Yupik Inuit incidence 1 280 Among American Caucasians the incidence of the classic form is about 1 15 000 24 Continued treatment and wellness are enhanced by education and follow up 33 History editBefore 20th century edit An Italian anatomist Luigi De Crecchio 1832 1894 provided the earliest known description of a case of probable CAH I propose in this narrative that it is sometimes extremely difficult and even impossible to determine sex during life In one of the anatomical theaters of the hospital there arrived toward the end of January a cadaver which in life was the body of a certain Joseph Marzo The general physiognomy was decidedly male in all respects There were no feminine curves to the body There was a heavy beard There was some delicacy of structure with muscles that were not very well developed The distribution of pubic hair was typical of the male Perhaps the lower extremities were somewhat delicate resembling the female and were covered with hair The penis was curved posteriorly and measured 6 cm or with stretching 10 cm The corona was 3 cm long and 8 cm in circumference There was an ample prepuce There was a first grade hypospadias There were two folds of skin coming from the top of the penis and encircling it on either side These were somewhat loose and resembled labia majora De Crecchio then described the internal organs which included a normal vagina uterus fallopian tubes and ovaries It was of the greatest importance to determine the habits tendencies passions and general character of this individual I was determined to get as complete a story as possible determined to get at the base of the facts and to avoid undue exaggeration which was rampant in the conversation of many of the people present at the time of the dissection He interviewed many people and satisfied himself that Joseph Marzo conducted himself within the sexual area exclusively as a male even to the point of contracting the French disease on two occasions The cause of death was another in a series of episodes of vomiting and diarrhea 34 This account was translated by Alfred Bongiovanni from De Crecchio Sopra un caso di apparenzi virili in una donna Morgagni 7 154 188 1865 in 1963 for an article in The New England Journal of Medicine 20th and 21st centuries edit The association of excessive sex steroid effects with diseases of the adrenal cortex have been recognized for over a century The term adrenogenital syndrome was applied to both sex steroid producing tumors and severe forms of CAH for much of the 20th century before some of the forms of CAH were understood Congenital adrenal hyperplasia which also dates to the first half of the century has become the preferred term to reduce ambiguity and to emphasize the underlying pathophysiology of the disorders Much modern understanding and treatment of CAH comes from research conducted at Johns Hopkins Medical School in Baltimore in the middle of the 20th century Lawson Wilkins founder of pediatric endocrinology worked out the apparently paradoxical pathophysiology that hyperplasia and overproduction of adrenal androgens resulted from impaired capacity for making cortisol He reported use of adrenal cortical extracts to treat children with CAH in 1950 Genital reconstructive surgery was also pioneered at Hopkins After application of karyotyping to CAH and other intersex disorders in the 1950s John Money JL Hampson and JG Hampson persuaded both the scientific community and the public citation needed that sex assignment should not be based on any single biological criterion and gender identity was largely learned and has no simple relationship with chromosomes or hormones See Intersex for a fuller history including recent controversies over reconstructive surgery Hydrocortisone fludrocortisone and prednisone were available by the late 1950s By 1980 all of the relevant steroids could be measured in blood by reference laboratories for patient care By 1990 nearly all specific genes and enzymes had been identified The last decade though has seen a number of new developments discussed more extensively in congenital adrenal hyperplasia due to 21 hydroxylase deficiency Debate over the value of genital reconstructive surgery and changing standards Debate over sex assignment of severely virilized XX infants New treatments to improve height outcomes Newborn screening programs to detect CAH at birth Increasing attempts to treat CAH before birthSociety and culture editPeople with CAH edit Notable people with CAH include Jeff Cagandahan is a Filipino who successfully appealed for a change of name and gender on his birth certificate 35 Lisa Lee Dark 36 Betsy Driver 37 Casimir Pulaski hypothesized based on examination of remains 38 See also editDisorders of sex development Inborn errors of steroid metabolism Intersex List of vaginal anomalies 5a Reductase 2 deficiency Androgen insensitivity syndromeReferences edit El Maouche D Arlt W Merke DP November 2017 Congenital adrenal hyperplasia PDF Lancet 390 10108 2194 2210 doi 10 1016 S0140 6736 17 31431 9 PMID 28576284 S2CID 13737960 a b c d e f g h Speiser PW Arlt W Auchus RJ Baskin LS Conway GS Merke DP Meyer Bahlburg HFL Miller WL Murad MH Oberfield SE White PC 2018 Congenital Adrenal Hyperplasia Due to Steroid 21 Hydroxylase Deficiency An Endocrine Society Clinical Practice Guideline The Journal of Clinical Endocrinology and Metabolism 103 11 4043 4088 doi 10 1210 jc 2018 01865 PMC 6456929 PMID 30272171 Speiser PW White PC August 2003 Congenital adrenal hyperplasia The New England Journal of Medicine 349 8 776 88 doi 10 1056 NEJMra021561 PMID 12930931 La Betty Tung Celestine Choi Eugene A Nguyen Ha 1 November 2021 A Gigantic Uterine Leiomyoma and Big Bilateral Adrenal Myelolipomas as a Result of Untreated Congenital Adrenal Hyperplasia AACE Clinical Case Reports 7 6 342 345 doi 10 1016 j aace 2021 05 002 PMC 8573279 PMID 34765728 Aubrey Milunsky Jeff Milunsky 29 January 2010 Genetic Disorders and the Fetus Diagnosis Prevention and Treatment John Wiley and Sons pp 600 ISBN 978 1 4051 9087 9 Retrieved 14 June 2010 Speiser PW Dupont B Rubinstein P Piazza A Kastelan A New MI July 1985 High frequency of nonclassical steroid 21 hydroxylase deficiency American Journal of Human Genetics 37 4 650 67 PMC 1684620 PMID 9556656 Krone N Arlt W April 2009 Genetics of congenital adrenal hyperplasia Best Practice amp Research Clinical Endocrinology amp Metabolism 23 2 181 92 doi 10 1016 j beem 2008 10 014 PMC 5576025 PMID 19500762 Turcu AF Nanba AT Chomic R Upadhyay SK Giordano TJ Shields JJ Merke DP Rainey WE Auchus RJ May 2016 Adrenal derived 11 oxygenated 19 carbon steroids are the dominant androgens in classic 21 hydroxylase deficiency European Journal of Endocrinology 174 5 601 9 doi 10 1530 EJE 15 1181 PMC 4874183 PMID 26865584 a b Feingold KR Anawalt B Boyce A Chrousos G de Herder WW Dungan K Grossman A Hershman JM Hofland HJ Kaltsas G Koch C Kopp P Korbonits M McLachlan R Morley JE New M Purnell J Singer F Stratakis CA Trence DL Wilson DP New M Yau M Lekarev O Lin Su K Parsa A Pina C Yuen T Khattab A 15 March 2017 Congenital Adrenal Hyperplasia MDText com Inc PMID 25905188 Speiser Phyllis W Arlt Wiebke Auchus Richard J Baskin Laurence S Conway Gerard S Merke Deborah P Meyer Bahlburg Heino F L Miller Walter L Murad M Hassan Oberfield Sharon E White Perrin C 1 November 2018 Congenital Adrenal Hyperplasia Due to Steroid 21 Hydroxylase Deficiency An Endocrine Society Clinical Practice Guideline The Journal of Clinical Endocrinology and Metabolism 103 11 4043 4088 doi 10 1210 jc 2018 01865 ISSN 1945 7197 PMC 6456929 PMID 30272171 a b Nordenstrom Anna Lajic Svetlana Falhammar Henrik 8 July 2022 Long Term Outcomes of Congenital Adrenal Hyperplasia Endocrinology and Metabolism 37 4 587 598 doi 10 3803 EnM 2022 1528 ISSN 2093 596X PMC 9449109 PMID 35799332 Dauber A Kellogg M Majzoub JA 2010 Monitoring of therapy in congenital adrenal hyperplasia Clinical Chemistry 56 8 1245 51 doi 10 1373 clinchem 2010 146035 PMID 20558634 Merke DP Auchus RJ September 2020 Congenital Adrenal Hyperplasia Due to 21 Hydroxylase Deficiency The New England Journal of Medicine 383 13 1248 1261 doi 10 1056 NEJMra1909786 PMID 32966723 S2CID 221884108 a b c d e Adriaansen Bas P H Schroder Mariska A M Span Paul N Sweep Fred C G J van Herwaarden Antonius E Claahsen van der Grinten Hedi L 12 December 2022 Challenges in treatment of patients with non classic congenital adrenal hyperplasia Frontiers in Endocrinology 13 doi 10 3389 fendo 2022 1064024 PMC 9791115 PMID 36578966 Yau M et al 2000 Congenital Adrenal Hyperplasia Diagnosis and Emergency Treatment MDText com PMID 25905311 Philadelphia The Children s Hospital of 19 November 2019 Classic congenital Adrenal Hyperplasia Diagnosed in the Newborn Period www chop edu Retrieved 5 September 2020 New Maria Yau Mabel Lekarev Oksana Lin Su Karen Parsa Alan Pina Christian Yuen Tony Khattab Ahmed 15 March 2017 Figure 2 Different degrees of virilization according www ncbi nlm nih gov Retrieved 5 September 2020 Genital Birth Defects Children s Health Issues Merck Manuals Consumer Version Retrieved 5 September 2020 Richard D McAnulty M Michele Burnette 2006 Sex and sexuality Volume 1 Greenwood Publishing Group p 165 David A Warrell 2005 Oxford textbook of medicine Sections 18 33 Oxford University Press pp 261 ISBN 978 0 19 856978 7 Retrieved 14 June 2010 Gidlof Sebastian Falhammar Henrik Thilen Astrid Dobeln Ulrika von Ritzen Martin Wedell Anna Nordenstrom Anna 1 September 2013 One hundred years of congenital adrenal hyperplasia in Sweden a retrospective population based cohort study The Lancet Diabetes amp Endocrinology 1 1 35 42 doi 10 1016 S2213 8587 13 70007 X ISSN 2213 8587 PMID 24622265 Arlt Wiebke Willis Debbie S Wild Sarah H Krone Nils Doherty Emma J Hahner Stefanie Han Thang S Carroll Paul V Conway Gerry S Rees D Aled Stimson Roland H Walker Brian R Connell John M C Ross Richard J 18 August 2010 Health Status of Adults with Congenital Adrenal Hyperplasia A Cohort Study of 203 Patients The Journal of Clinical Endocrinology amp Metabolism 95 11 5110 5121 doi 10 1210 jc 2010 0917 ISSN 0021 972X PMC 3066446 PMID 20719839 Stromer H Cittadini A Douglas P S Morgan J P 12 January 2022 Exogenously administered growth hormone and insulin like growth factor I alter intracellular Ca2 handling and enhance cardiac performance In vitro evaluation in the isolated isovolumic buffer perfused rat heart Circulation Research 79 2 227 236 doi 10 1161 01 res 79 2 227 ISSN 0009 7330 PMID 8755999 a b c Mais Daniel D 2008 Quick compendium of clinical pathology 2nd ed Chicago ASCP Press ISBN 978 0891895671 Miller WL January 2012 The syndrome of 17 20 lyase deficiency The Journal of Clinical Endocrinology and Metabolism 97 1 59 67 doi 10 1210 jc 2011 2161 PMC 3251937 PMID 22072737 White P C Speiser P W 1 June 2000 Congenital adrenal hyperplasia due to 21 hydroxylase deficiency Endocrine Reviews 21 3 245 291 doi 10 1210 edrv 21 3 0398 ISSN 0163 769X PMID 10857554 3 beta hydroxysteroid dehydrogenase deficiency MedlinePlus Archived from the original on 28 September 2020 Retrieved 2 June 2021 Kumar Vinay Abbas Abul K Aster Jon C 2014 Robbins and Cotran pathologic basis of disease Kumar Vinay 1944 Abbas Abul K Aster Jon C Perkins James A Ninth ed Philadelphia PA p 1128 ISBN 9781455726134 OCLC 879416939 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Haggstrom Mikael Richfield David 2014 Diagram of the pathways of human steroidogenesis WikiJournal of Medicine 1 1 doi 10 15347 wjm 2014 005 ISSN 2002 4436 Kenneth A Pass Eurico Carmago Neto 2005 Update Newborn Screening for Endocrinopathies PDF pp 831 834 Archived from the original PDF on 1 January 2014 Retrieved 12 December 2013 AbdAlmageed Wael Mirzaalian Hengameh Guo Xiao Randolph Linda M Tanawattanacharoen Veeraya K Geffner Mitchell E Ross Heather M Kim Mimi S 18 November 2020 Assessment of Facial Morphologic Features in Patients With Congenital Adrenal Hyperplasia Using Deep Learning JAMA Network Open 3 11 e2022199 doi 10 1001 jamanetworkopen 2020 22199 ISSN 2574 3805 PMC 7675110 PMID 33206189 a b Adriaansen Bas P H Kamphuis Johannes S Schroder Mariska A M Olthaar Andre J Bock Carina Brandt Andre Stikkelbroeck Nike M M L Lentjes Eef G W M Span Paul N Sweep Fred C G J Claahsen van der Grinten Hedi L van Herwaarden Antonius E 2022 Diurnal salivary androstenedione and 17 hydroxyprogesterone levels in healthy volunteers for monitoring treatment efficacy of patients with congenital adrenal hyperplasia Clinical Endocrinology 97 1 36 42 doi 10 1111 cen 14690 ISSN 0300 0664 PMC 9542109 PMID 35150157 Kruse B Riepe F G Krone N Bosinski H a G Kloehn S Partsch C J Sippell W G Monig H July 2004 Congenital adrenal hyperplasia how to improve the transition from adolescence to adult life Experimental and Clinical Endocrinology amp Diabetes 112 7 343 355 doi 10 1055 s 2004 821013 ISSN 0947 7349 PMID 15239019 S2CID 260138410 Bongiovanni AM Root AW 1963 The Adrenogenital Syndrome The New England Journal of Medicine 268 23 1283 9 contd doi 10 1056 NEJM196306062682308 PMID 13968788 International Commission of Jurists 2017 Republic of the Philippines v Jennifer Cagandahan Supreme Court of the Philippines Second Division 12 September 2008 International Commission of Jurists Retrieved 19 March 2021 BBC Radio 4 Changing Sex Retrieved 6 August 2008 Mayor Betsy Driver is Promoting Intersex Visibility Through Activism and Politics Yahoo 23 August 2019 Archived from the original on 22 September 2021 Retrieved 10 September 2019 Schoenberg Nara 3 April 2019 It s a woman It s not Pulaski New documentary argues Revolutionary War hero was intersex chicagotribune com Archived from the original on 2 November 2019 Retrieved 28 May 2020 Further reading editHan Thang S Walker Brian R Arlt Wiebke Ross Richard J 17 December 2013 Treatment and health outcomes in adults with congenital adrenal hyperplasia Nature Reviews Endocrinology 10 2 115 124 doi 10 1038 nrendo 2013 239 PMID 24342885 S2CID 6090764Figure 2 The adrenal steroidogenesis pathway a href Template Cite journal html title Template Cite journal cite journal a CS1 maint postscript link External links edit nbsp Wikimedia Commons has media related to Congenital adrenal hyperplasia Congenital adrenal hyperplasia at Curlie Retrieved from https en wikipedia org w index php title Congenital adrenal hyperplasia amp oldid 1216368835, wikipedia, wiki, book, books, library,

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