Utilidad de la hormona anti-Mülleriana (AMH) y la inhibina B en el diagnóstico del hipogonadismo en el niño

Durante la infancia, el eje hipotálamo-hipófiso-testicular se encuentra parcialmente quiescente: bajan los niveles de gonadotrofinas y la secreción de testosterona disminuye siguiendo a la caída de la LH. Por el contrario, las células de Sertoli están activas, como lo demuestran los niveles séricos de hormona anti-mülleriana (AMH) e inhibina B. Por lo tanto, el hipogonadismo en la infancia puede ser puesto en evidencia, sin necesidad de pruebas de estímulo, si se evalúa la función de las células de Sertoli. La AMH sérica es alta desde la vida fetal hasta el inicio de la pubertad. La producción testicular de AMH aumenta en respuesta a la FSH pero es potentemente inhibida por los andrógenos. La inhibina B es alta en los primeros años de la vida, luego disminuye parcialmente aunque permanece claramente más alta que en las mujeres, y aumenta nuevamente en la pubertad. Las concentraciones séricas de AMH e inhibina B son indetectables en pacientes anórquidos. En el hipogonadismo primario que afecta a todo el testículo, establecido durante la vida fetal o la infancia, todos los marcadores testiculares están bajos. Cuando en el hipogonadismo están afectadas sólo las células de Leydig, la AMH y la inhibina B sérica son normales y/o altas, mientras que están bajas cuando se ven afectadas las células de Sertoli. La AMH y la inhibina B están bajas en varones con hipogonadismo central en edad prepuberal y continúan bajas en edad puberal. El tratamiento con FSH induce un aumento en los niveles séricos de los marcadores de la célula de Sertoli. En conclusión, la determinación de los niveles séricos de AMH e inhibina B es útil para evaluar la función testicular, sin necesidad de pruebas de estímulo, y orientar el diagnóstico etiológico en el hipogonadismo masculino en pediatría.

During childhood, the hypothalamic-pituitary-gonadal axis is partially quiescent: gonadotropin and testosterone levels decrease, but Sertoli cells remain active, as shown by serum anti-Müllerian hormone (AMH) and inhibin B levels. Therefore, hypogonadism may be diagnosed during childhood, without the need for stimulation tests, provided Sertoli cell function is assessed. Serum AMH levels are high from fetal life until the onset of puberty. Testicular AMH production increases in response to FSH but is potently inhibited by androgens. Serum inhibin B levels are high until the age of 3-4 years in boys; although they decrease thereafter, they remain clearly higher than in girls of the same age. During the early stage of puberty, serum inhibin B increases again to reach adult values. AMH and inhibin B are undetectable in the serum of anorchid patients. In boys with fetalonset primary hypogonadism affecting the whole testicular parenchyma, AMH and inhibin B are low in serum. Conversely, they are normal or high when only the interstitial tissue of the gonads is impaired. AMH and inhibin B are low in children with central hypogonadism and persist low during pubertal age. FSH treatment induces an increase in both Sertoli cell markers. In conclusion, the determination of serum AMH and inhibin B levels is useful for the assessment of testicular function, without the need for stimulation tests, in pediatric patients.

Spreading the clinical window for diagnosing fetal-onset hypogonadism in boys.

In early fetal development, the testis secretes - independent of pituitary gonadotropins - androgens and anti-Müllerian hormone (AMH) that are essential for male sex differentiation. In the second half of fetal life, the hypothalamic-pituitary axis gains control of testicular hormone secretion. Follicle-stimulating hormone (FSH) controls Sertoli cell proliferation, responsible for testis volume increase and AMH and inhibin B secretion, whereas luteinizing hormone (LH) regulates Leydig cell androgen and INSL3 secretion, involved in the growth and trophism of male external genitalia and in testis descent. This differential regulation of testicular function between early and late fetal periods underlies the distinct clinical presentations of fetal-onset hypogonadism in the newborn male: primary hypogonadism results in ambiguous or female genitalia when early fetal-onset, whereas it becomes clinically undistinguishable from central hypogonadism when established later in fetal life. The assessment of the hypothalamic-pituitary-gonadal axis in male has classically relied on the measurement of gonadotropin and testosterone levels in serum. These hormone levels normally decline 3-6 months after birth, thus constraining the clinical evaluation window for diagnosing male hypogonadism. The advent of new markers of gonadal function has spread this clinical window beyond the first 6 months of life. In this review, we discuss the advantages and limitations of old and new markers used for the functional assessment of the hypothalamic-pituitary-testicular axis in boys suspected of fetal-onset hypogonadism.

Male Central Precocious Puberty: Serum Profile of Anti-Müllerian Hormone and Inhibin B before, during, and after Treatment with GnRH Analogue.

We aimed to describe the functional changes of Sertoli cells, based on the measurement of serum anti-Müllerian hormone (AMH) and inhibin B during treatment with GnRHa and after its withdrawal in boys with central precocious puberty. Six boys aged 0.8 to 5.5 yr were included. AMH was low at diagnosis in patients >1 yr but within the normal range in younger patients. AMH increased to normal prepubertal levels during treatment. After GnRHa withdrawal, AMH declined concomitantly with the rise in serum testosterone. At diagnosis, inhibin B was elevated and decreased throughout therapy, remaining in the upper normal prepubertal range. In patients with testicular volume above 4 mL AMH remained higher in spite of suppressed FSH. After treatment withdrawal, inhibin B rose towards normal pubertal levels. In conclusion, AMH did not decrease in patients <1 yr reflecting the lack of androgen receptor expression in Sertoli cells in early infancy. Serum inhibin B might result from the contribution of two sources: the mass of Sertoli cells and the stimulation exerted by FSH. Sertoli cell markers might provide additional tools for the diagnosis and treatment followup of boys with central precocious puberty.

Sertoli cell markers in the diagnosis of paediatric male hypogonadism.

During childhood, the pituitary-testicular axis is partially dormant: testosterone secretion decreases following a drop in luteinising hormone levels; follicle-stimulating hormone (FSH) levels also go down. Conversely, Sertoli cells are most active, as revealed by the circulating levels of anti-Müllerian hormone (AMH) and inhibin B. Therefore, hypogonadism can best be evidenced, without stimulation tests, if Sertoli cell function is assessed. Serum AMH is high from fetal life until mid-puberty. Testicular AMH production increases in response to FSH and is potently inhibited by androgens. Inhibin B is high in the first years of life, then decreases partially while remaining clearly higher than in females, and increases again at puberty. Serum AMH and inhibin B are undetectable in anorchid patients. In primary or central hypogonadism affecting the whole gonad established in fetal life or childhood, all testicular markers are low. Conversely, when hypogonadism only affects Leydig cells, serum AMH and inhibin B are normal. In males of pubertal age with central hypogonadism, AMH and inhibin B are low. Treatment with FSH provokes an increase in serum levels of both Sertoli cell markers, whereas human chorionic gonadotrophin (hCG) administration increases testosterone levels. In conclusion, measurement of serum AMH and inhibin B is helpful in assessing testicular function, without need for stimulation tests, and orientates the aetiological diagnosis of paediatric male hypogonadism.

Gonadotrophin secretion pattern in anorchid boys from birth to pubertal age: pathophysiological aspects and diagnostic usefulness.

CONTEXT: The biphasic ontogeny of serum gonadotrophins observed in normal children also exists in girls with gonadal dysgenesis, although with higher levels. However, limited data exist in prepubertal boys with anorchia. OBJECTIVE: To investigate whether the existence of testicular tissue is required for gonadotrophin downregulation in boys. Secondarily, we analysed the prevalence of high gonadotrophins and its diagnostic value to assess the presence or absence of testes in childhood. STUDY DESIGN: In a retrospective, semi-longitudinal study, we compared serum gonadotrophin levels in 35 boys with anorchia aged 0-18 years, in 29 bilaterally cryptorchid boys with abdominal testes and in 236 normal boys. RESULTS: In anorchid boys, follicle stimulating hormone (FSH) and luteinizing hormone (LH) were abnormally high in the first months after birth, then decreased progressively. LH decreased more readily than FSH and dropped to normal values in up to 70% of anorchid patients before the usual age of pubertal onset, when both gonadotrophins increased again to very high levels. In cryptorchid boys, FSH was elevated in a significantly (P < 0·0001) lower proportion of cases. Below the age of 6 years, FSH below 2 IU/l ruled out anorchia and LH above 5 IU/l confirmed anorchia with high accuracy. Between 6 and 11 years, FSH or LH levels above 5 IU/l were highly specific for the absence of testes. CONCLUSIONS: The U-shaped pattern of serum gonadotrophins observed in normal males from birth to puberty was also found in anorchid boys, but with gonadotrophin levels considerably elevated. Serum gonadotrophin levels may normalize in anorchid boys during late childhood only to rise again at puberty. The presence of testicular tissue results in restrain of gonadotrophin secretion in most patients, even if the testes are cryptorchid.

Are Klinefelter boys hypogonadal?

UNLABELLED: Male hypogonadism implies decreased function of one or more testicular cell population, i.e. germ, Leydig and/or Sertoli cells. In the normal prepubertal boy, Sertoli cells are very active, as indicated by high anti-Müllerian hormone (AMH) and inhibin B secretion, whereas the functional activity of Leydig cells is minimal, as evidenced by low testosterone production, and germ cells do not undergo the full spermatogenic process. Klinefelter syndrome is the most frequent cause of hypogonadism in the adult male. In this review, we discuss whether the gonadal failure is already established during infancy and childhood. In Klinefelter syndrome, there is increased germ cells degeneration from mid-foetal life - resulting in a decreased number at birth - which persists during infancy and childhood and becomes dramatic during puberty. Controversial results exist in the literature regarding Leydig cell function in Klinefelter boys: while some authors have found normal to low testosterone levels in infancy and childhood, others have reported normal to high values. Sertoli cell products AMH and inhibin B are normal in prepubertal boys and only decline during mid- to late puberty. CONCLUSION: Klinefelter syndrome is a primary hypogonadism affecting all testicular cell populations. Germ cells are affected from foetal life, and a severe depletion occurs at puberty. Leydig cell function may be normal or mildly affected in foetal and early postnatal life. Sertoli cell function is not impaired until mid- to late puberty, as reflected by normal AMH and inhibin B in Klinefelter boys.

Low risk of impaired testicular Sertoli and Leydig cell functions in boys with isolated hypospadias.

CONTEXT: Isolated hypospadias may result from impaired testicular function or androgen end-organ defects or, alternatively, from hormone-independent abnormalities of morphogenetic events responsible for urethral seam. OBJECTIVE: The objective was to evaluate the relative prevalence of hormone-dependent etiologies in boys with isolated hypospadias. DESIGN, PATIENTS, AND MAIN OUTCOME MEASURES: We studied endocrine testicular capacity in 61 patients with isolated hypospadias and 28 with hypospadias associated with micropenis, cryptorchidism, or ambiguous genitalia. Serum anti-Müllerian hormone and inhibin B were used as Sertoli cell markers. A human chorionic gonadotropin test was performed to evaluate Leydig cell function. RESULTS: Testicular dysfunction was observed in 57.1% and androgen end-organ defects in 7.2% of patients with hypospadias associated with cryptorchidism, micropenis, or ambiguous genitalia. In the remaining 35.7%, the disorder was idiopathic. The presence of ambiguous genitalia predicted the existence of testicular or end-organ dysfunction with 81.8% specificity. Isolated hypospadias was associated in 14.8% of patients with testicular dysfunction and in 6.5% of cases with end-organ defects; in 78.7% of cases, the condition was idiopathic. The occurrence of isolated hypospadias ruled out the existence of testicular or end-organ disorders with 80.0% sensitivity. Altogether our data indicate that the risk for the existence of an underlying testicular or end-organ dysfunction is low in patients with isolated hypospadias (odds ratio, 0.13; 95% confidence interval, 0.05-0.36; P < 0.001). CONCLUSIONS: Boys with isolated hypospadias are more likely to have normal endocrine testicular and androgen end-organ functions, suggesting that transient disruption of morphogenetic events in early fetal life may be the predominant underlying cause.