Puberty and Disorders of Pubertal Development PDF

Summary

This chapter details the factors influencing puberty in young girls, including genetic, environmental, nutrition-related factors, and physical activity. The chapter explains the normal sequence of physical signs of puberty in girls, as well as disorders of puberty, such as precocious and delayed puberty.

Full Transcript

CHAPTER

32
Puberty and Disorders
of Pubertal Development
SARA CHURCHILL CAROLYN J. ALEXANDER

CLINICAL KEYS FOR THIS CHAPTER

Both genetic and environmental factors determine the pituitary–ovarian axis. A combination of high sensitivity
onset of pubertal change in young girls. Puberty may be to low levels of estradiol resulting in negative feedback
delayed or may occur earlier, depending on nutrition- on gonadotropin release, and an intrinsic central nervous
related factors and physical activity. Obesity causes system inhibition of gonadotropin-releasing hormone
earlier onset of puberty, and excessive exercise causes secretion, keep gonadotropins at low levels. By age 11
delay. Psychological disorders and chronic isolation may years (the usual onset of pubertal development), there is
also affect the normal onset of puberty. a gradual loss of the negative feedback to low levels of
The Frisch hypothesis states that an invariant mean sex steroids, and pubertal development begins.
weight (48 kg/106 lb) is essential for the initiation of the The usual sequence of physical signs of puberty in girls
first menses (menarche). Leptin (a peptide hormone) is (1) thelarche (breast budding), (2) adrenarche and/or
secreted by adipose tissue may provide the “triggering pubarche (axillary and pubic hair growth), (3) peak
link” for the initiation of menarche. height velocity, (4) menarche (first menses), and (5)
The female fetus has the highest lifetime number of mature sexual hair and breast growth.
oocytes by mid-gestation. Brief follicular maturation and Disorders of puberty include precocious development
negative feedback on gonadotropin release due to fol- and delayed puberty. Precocious puberty refers to the
licular estradiol production also occurs in utero. Peak development of any sign of secondary sexual maturation
serum levels of gonadotropins are seen by 3 months after at an age earlier than 8 years in girls. Failure to undergo
birth and then slowly decline, reaching their nadir at age thelarche by the age of 14 years constitutes significant
4 years. Between the ages of 4 and about 10 years, the delay of pubertal development and requires evaluation.
“gonadostat” is said to regulate the hypothalamic–

Puberty encompasses the development of secondary puberty. It has been proposed that an invariant mean
sexual characteristics and the acquisition of repro- weight of 48 kg (106 lb) is essential for the initiation
ductive capability. During this transition, usually of menarche in healthy girls. Leptin, a peptide secreted
between 10 and 16 years of age, a variety of physical, by adipose tissue, may be the link between weight and
endocrinologic, and psychological changes accom- the initiation of menarche. Psychological factors,
pany the increasing levels of circulating sex steroids. severe neurotic or psychotic disorders, and chronic iso-
The onset of pubertal changes is determined pri- lation may interfere with the normal onset of puberty
marily by genetic factors, including race, and is also through a mechanism similar to adult hypothalamic
influenced by geographic location (girls in metropoli- amenorrhea.
tan areas, at altitudes near sea level, or at latitudes In the United States and Western Europe, a decrease
close to the equator tend to begin puberty at an earlier in the age of menarche (i.e., age at first menses) was
age) and nutritional status (obese children have an noted between 1840 and 1970, from an estimated mean
earlier onset of puberty, and those who are malnour- age of 17 years in 1840 down to a reported mean age of
ished or have chronic illnesses associated with weight 13 years in 1970. This trend has plateaued since then,
loss have a later onset of menses). Excessive exercise and currently the mean age of menarche is approxi-
relative to the caloric intake can also delay the onset of mately 12.4 years in the United States.

370
 CH A PTE R 32 Puberty and Disorders of Pubertal Development 371

FSH and Birth
LH

Number of
oogonia FSH

LH
hCG FSH

LH DHEA
Androstenedione
Estradiol

10 20 30 40 2 4 6 2 4 6 8 10 12 14 16 18
INTRAUTERINE WEEKS NEONATAL YEARS OF PUBERTAL DEVELOPMENT
MONTHS
FIGURE 32-1 Changes in the concentration of gonadotropins (LH and FSH), sex steroids (DHEA, androstenedione, and estradiol), and
the number of oogonia throughout fetal life and pubertal development. DHEA, Dehydroepiandrosterone; FSH, follicle-stimulating hormone;
hCG, human chorionic gonadotropin; LH, luteinizing hormone. Adapted from Speroff L, Fritz MA: Neuroendocrinology. In Speroff L, Fritz
MA, editors: Clinical gynecologic endocrinology and infertility, ed 7, Baltimore, MD, 2005, Lippincott Williams & Wilkins.

Endocrinologic Changes of Puberty ing adult or near-adult concentrations in the early neo-
natal period. In the female infant, peak serum levels
FETAL AND NEWBORN PERIOD of gonadotropins are generally seen by 3 months of
The fetal hypothalamic–pituitary–gonadal axis is age, then they slowly decline until a nadir is reached
capable of producing adult levels of gonadotropins by the age of 4 years. In contrast to gonadotropin
and sex steroids. By 20 weeks’ gestation, levels of levels, sex steroid concentrations decrease rapidly to
gonadotropins—follicle-stimulating hormone (FSH) prepubertal values within 1 week of birth and remain
and luteinizing hormone (LH)—rise dramatically in low until the onset of puberty.
both male and female fetuses (Figure 32-1). Late in During fetal development, the adrenal glands are
gestation, a surge in levels of glucocorticoids in the large in proportion to their size in adult life (similar
fetal circulation occurs. This is essential for normal to the fetal kidneys). Early in gestation, the fetal adrenal
maturation of fetal lungs and critical for the develop- gland produces abundant dehydroepiandrosterone
ment of the fetal thyroid, kidney, brain, and pituitary. sulfate (DHEA-S), which serves as a precursor for estro-
Recently, it has been suggested that excessive exposure gen production by the placenta and is also able to
of the developing fetus to glucocorticoids or exposure convert placental progesterone into cortisol. It is not
at the wrong time may lead to lifelong alterations in the until about 23 weeks’ gestation that the fetal adrenal
function of the hypothalamic–pituitary–adrenal axis. cortex expresses the enzyme to directly synthesize
The female fetus acquires the lifetime peak number cortisol from cholesterol or pregnenolone. In the first
of oocytes (in utero) by mid-gestation and also has a few months of postnatal life, the innermost part of
brief period of follicular maturation and sex steroid the adrenal cortex (the fetal zone) largely regresses,
production in response to elevated gonadotropin levels and there is a rapid decrease in the production of
in utero. This transient increase in serum estradiol (a DHEA-S.
sex steroid) acts on the fetal hypothalamic-pituitary
unit, resulting in a reduction of gonadotropin secretion CHILDHOOD
(a negative feedback effect), which in turn reduces The hypothalamic–pituitary–gonadal axis in the
estradiol production. This indicates that the inhibitory young child is suppressed between the ages of 4 and
effect of sex steroids on gonadotropin release is opera- 10 years. The hypothalamic–pituitary system regulat-
tive before birth. ing gonadotropin release has been termed the gonad-
In both male and female fetuses, serum estradiol ostat. Low levels of gonadotropins and sex steroids
is primarily of maternal and placental origin. With during this prepubertal period are a function of two
birth and the acute loss of maternal and placental mechanisms: (1) maximal sensitivity of the gonad-
sex steroids, the negative feedback action on the ostat to the negative feedback effect of the low circu-
hypothalamic-pituitary axis is lost, and gonadotropins lating levels of estradiol present in prepubertal
are once again released from the pituitary gland, reach- children, and (2) intrinsic central nervous system
372 PAR T 4 Reproductive Endocrinology and Infertility

inhibition of hypothalamic gonadotropin-releasing Serum concentrations of DHEA, DHEA-S, and andro-
hormone (GnRH) secretion. These mechanisms occur stenedione rise between the ages of 8 and 11 years.
independently of the presence of functional gonadal This rise in adrenal androgens induces the growth of
tissue. This is clearly demonstrated in children with both axillary and pubic hair and is known as adre-
gonadal dysgenesis. Agonadal children display elevated narche or pubarche. This increase in adrenal androgen
gonadotropin concentrations during the first 2 to 4 production occurs independently of gonadotropin
years of life, followed by a decline in circulating FSH secretion or gonadal steroid levels, and the mechanism
and LH levels by 6 to 8 years of age. By 10 to 12 years of its initiation is not understood at this time. Some
of age, gonadotropin concentrations spontaneously studies have suggested that the morphologic and func-
rise once again, eventually achieving castration levels. tional changes in the zona reticularis are induced by
This pattern of gonadotropin secretion in early child- increasing cortisol levels. In cellular studies, human
hood is similar to that of children with normal gonadal fetal adrenal cells exposed to cortisol in high concen-
function. These data suggest that an intrinsic central trations produce DHEA, whereas in human studies,
nervous system regulator of GnRH release is the prin- infants treated with high-dose adrenocorticotropic
cipal inhibitor of gonadotropin secretion from 4 hormone for infantile spasms have been noted to have
years of age until the peripubertal period. Further- adrenal androgen production.
more, after regression of the fetal zone of the adrenal Recent studies indicate that girls who undergo pre-
gland (a few months after birth), very low concentra- mature pubarche are more likely than other girls to
tions of adrenal androgen precursors are available, develop polycystic ovarian syndrome (PCOS) as
resulting in decreased adrenal androgen production in adults (see Chapter 33).
early childhood.
PUBERTAL ONSET
LATE PREPUBERTAL PERIOD By approximately the 11th year of life, there is a
In general, androgen production and differentiation gradual loss of sensitivity by the gonadostat to the
by the zona reticularis of the adrenal cortex are the negative feedback of sex steroids (Figure 32-2). As a
initial endocrine changes associated with puberty. consequence, GnRH pulses (with their mirroring pulses

Increase
Maturation of negative
feedback mechanism

Increased
release of GnRH
Increased pituitary
Relative sensitivity of responsiveness to GnRH
the "gonadostat" Gonadotropins
to negative sex Increased gonadal
steroid feedback responsiveness to Activation of positive
gonadotropins, feedback mechanism
rising sex steroid levels
Sleep-associated increase
in LH secretion: Episodic
secretion of LH

Decrease

FETUS INFANCY & CHILDHOOD PUBERTY ADULT
FIGURE 32-2 Changes in set point of the hypothalamic-pituitary unit (gonadostat) (solid lines) and the maturation of the negative and
positive feedback mechanisms from fetal life to adulthood in relation to the normal changes of puberty. This figure does not illustrate
the change in the sex steroid–independent intrinsic central nervous system inhibitory mechanism that is observed from late infancy to
puberty. GnRH, Gonadotropin-releasing hormone; LH, luteinizing hormone. Adapted from Styne DM, Grumbach MM: Disorders of puberty
in the male and female. In Yen SSC, Jaffe RB, editors: Reproductive endocrinology: physiology, pathophysiology and clinical management, ed
2, Philadelphia, Saunders, 1991.
 CH A PTE R 32 Puberty and Disorders of Pubertal Development 373

of FSH and LH) increase in amplitude and frequency. uration of the positive feedback mechanism of estra-
The factors that reduce the sensitivity of the gonad- diol on LH release from the anterior pituitary gland is
ostat are incompletely understood. Some studies indi- complete, and ovulatory cycles are established.
cate that a rise in the concentration of leptin, a
hormone produced by adipocytes (fat cells) that
mediates appetite satiety, precedes and is necessary
Somatic Changes of Puberty
for this change. This, in turn, supports the association Physical changes of puberty involve the development
between minimum weight or total body fat and the of secondary sexual characteristics and the accelera-
onset of puberty. The Frisch hypothesis suggests that a tion of linear growth (gain in height). The Marshall
critical body weight is necessary for pubertal onset. and Tanner classification of breast and pubic hair
Further investigations support the concept that fat development is employed for descriptive and diagnos-
stores might influence pubertal onset through several tic purposes (Figures 32-3 and 32-4). A useful acronym
mechanisms. First, adipocytes secrete adipokines such for remembering the usual chronologic order of the
as leptin. Leptin appears to serve as a signal to the stages of female pubertal development is TAPuP ME
hypothalamic GnRH pulse generator that there are suf- (standing for thelarche, adrenarche, pubarche, peak
ficient energy stores for fertility to commence. Studies growth velocity, and menarche).
have shown that every 1-kg gain in body weight lowers
the onset of menarche by 13 days and that every STAGES OF PUBERTAL DEVELOPMENT
increase of 1 ng/ml in serum leptin lowers the age of The first physical sign of puberty is usually breast
menarche by 1 month. Second, aromatase activity in budding (thelarche), followed by the appearance of
adipocytes is dependent on fat mass, and obesity axillary or pubic hair (adrenarche/pubarche). Unilat-
results in greater peripheral conversion of androstene- eral breast development is not uncommon in early
dione to estrone and of testosterone to estradiol. puberty and may last up to 6 months before the devel-
Last, increasing adipose tissue is related to increasing opment of the contralateral breast. Maximal growth or
insulin resistance, which decreases serum levels of sex peak height velocity is usually the next stage, followed
hormone binding globulin. This leads to an increased by menarche (the onset of menstrual periods). The
level of bioavailable sex hormones. final somatic changes are the appearance of adult
A further decrease in sensitivity of the gonadostat pubic hair distribution and adult-type breasts. In
combined with the loss of intrinsic central nervous approximately 15% of normally developing girls, the
system inhibition of hypothalamic GnRH release is development of pubic hair occurs before breast devel-
heralded by sleep-associated increases in GnRH opment. The sequence of pubertal changes generally
secretion. This nocturnal dominant pattern gradually occurs over a period of 4.5 years, with a normal range
shifts into an adult-type secretory pattern, with GnRH of 1.5 to 6 years (Figure 32-5).
pulses occurring every 90 to 120 minutes throughout Race plays a role in determining the age of the onset
the 24-hour day. of puberty. African American girls begin puberty earlier
The increase in gonadotropin release promotes than girls in other racial groups (on average between
ovarian follicular maturation and sex steroid produc- the ages of 8 and 9 years), followed by Mexican Ameri-
tion, which induces the development of secondary cans and whites (Table 32-1). In African American girls,
sexual characteristics. By middle to late puberty, mat- thelarche and adrenarche can occur as early as 6 years

TABLE 32-1
AGE AT ONSET OF PUBIC HAIR DEVELOPMENT, BREAST DEVELOPMENT, AND MENARCHE FOR THREE RACIAL/ETHNIC
GROUPS OF U.S. GIRLS: NATIONAL HEALTH AND NUTRITION EXAMINATION SURVEY III, 1988-1994
Non-Hispanic White Black Mexican American
Puberty Milestone (mean age*) (mean age*) (mean age*)
Pubic hair† 10.5 9.5 10.3
†
Breast development 10.3 9.5 9.8
Menarche† 12.7 12.1 12.2
Menarche‡ 12.7 12.3 12.5

Modified with permission from Wu T, Mendola P, Buck GM: Ethnic differences in the presence of secondary sex characteristics and menarche among US
girls: the Third National Health and Nutrition Examination Survey, 1988-1994. Pediatrics 110:752–757, 2002.
*Estimated with application of weights for the examination sample of the National Health and Nutrition Examination Survey III (NHANES III).
†
Estimated using probit model for the status quo data of the puberty measurements.
‡
Estimated using failure time model for the recalled age at menarche.
374 PAR T 4 Reproductive Endocrinology and Infertility

Stage 1

Stage 2

Stage 3

Stage 4

Stage 5

FIGURE 32-3 Stages of breast development as defined by Marshall and Tanner. Stage 1, Preadolescent; elevation of papilla only. Stage
2, Breast bud stage; elevation of breast and papilla as a small mound with enlargement of the areolar region. Stage 3, Further enlarge-
ment of breast and areola without separation of their contours. Stage 4, Projection of areola and papilla to form a secondary mound
above the level of the breast. Stage 5, Mature stage; projection of papilla only, resulting from recession of the areola to the general
contour of the breast. Adapted from Marshall WA, Tanner JM: Variations in pattern of pubertal changes in girls. Arch Dis Child 44:291,
1969.
 CH A PTE R 32 Puberty and Disorders of Pubertal Development 375

Stage 1 Stage 2 Stage 3

Stage 4 Stage 5
FIGURE 32-4 Stages of female pubic hair development according to Marshall and Tanner. Stage 1, Preadolescent; absence of pubic hair.
Stage 2, Sparse hair along the labia; hair downy with slight pigmentation. Stage 3, Hair spreads sparsely over the junction of the pubes;
hair is darker and coarser. Stage 4, Adult-type hair; no spread to the medial surface of the thighs. Stage 5, Adult-type hair with spread to
the medial thighs assuming an inverted triangle pattern. Adapted from Marshall WA, Tanner JM: Variations in pattern of pubertal changes
in girls. Arch Dis Child 44:291, 1969.

Adrenarche/ Peak height Mature sexual
Thelarche Menarche
Pubarche velocity hair and breasts

9 10 11 12 13 14 15
AGE IN YEARS
FIGURE 32-5 Sequence of physical changes during pubertal development. The acronym TAPuP ME has been used as a mnemonic device
for Thelarche, Adrenarche/Pubarche, Peak height velocity, and MEnarche, which precede mature sexual hair and breast development.

of age, whereas in whites, they can occur as early 7 estradiol, and insulin-like growth factor 1 (formerly
years of age. somatomedin C) are involved in the adolescent growth
spurt. Peak height velocity occurs approximately 1 year
ADOLESCENT GROWTH SPURT before the onset of menarche. There is limited linear
In general, the growth spurt is seen 2 years earlier in growth after menarche, as gonadal steroid production
pubertal girls than in boys. Growth hormone, accelerates fusion of the long bone epiphyses.
376 PAR T 4 Reproductive Endocrinology and Infertility

BOX 32-1
BODY COMPOSITION AND BONE AGE
CLASSIFICATION OF FEMALE PRECOCIOUS PUBERTY
There are no significant differences in skeletal mass,
lean body mass, or percentage of body fat between pre- Heterosexual Precocious Puberty
pubertal boys and prepubertal girls. After attaining Virilizing neoplasm
sexual maturity, girls generally have less skeletal and Ovarian
lean body mass and a greater percentage of body fat Adrenal
Congenital adrenal hyperplasia (adrenogenital
than boys do.
syndrome)
Bone age correlates well with the onset of second- Exogenous androgen exposure
ary sexual characteristics and menarche. Bone age is
Isosexual Precocious Puberty
determined by obtaining radiographs of the left (or
nondominant) hand and wrist, elbow, or knee and Incomplete Isosexual Precocious Puberty
comparing them with an index population. Osseous Premature thelarche
maturation is particularly useful in the evaluation of Premature adrenarche
Premature pubarche
adolescents with delayed onset of puberty. Bone matu-
ration, chronologic age, and height can also be used to Complete Isosexual Precocious Puberty
predict the final adult stature based on standardized True isosexual precocious puberty
nomograms. Constitutional (idiopathic)
Organic brain disease
Central nervous system tumors
Precocious Puberty Head trauma
Hydrocephalus
Precocious puberty refers to the development of any Central nervous system infection (abscess, enceph-
sign of secondary sexual maturation at an age 2.5 alitis, meningitis)
standard deviations earlier than the expected age of Pseudoisosexual Precocious Puberty
pubertal onset. In North America, these ages are 8
Ovarian neoplasm
years for girls and 9 years for boys. The incidence of Adrenal neoplasm
precocious puberty is 1 in 10,000 children in North Exogenous estrogen exposure
America, and it is approximately five times more Advanced hypothyroidism
common in girls. In 75% of cases of precocious puberty McCune-Albright syndrome
in girls, the cause is idiopathic. A thorough evaluation Peutz-Jeghers syndrome
to eliminate a serious disease process, and to arrest
Adapted from Brenner PF: Precocious puberty in the female. In Mishell DR
potential premature osseous maturation that may Jr, Davajan V, Lobo RA, editors: Infertility, contraception and reproductive
affect the normal growth pattern, is mandatory. endocrinology, ed 3, Cambridge, MA, 1991, Blackwell Scientific, p 349.
The early development of secondary sexual charac-
teristics may promote psychosocial problems for the
child and should be addressed carefully. Typically, or adrenal in origin and are exceedingly rare in child-
these girls are taller than their peers as children but hood. They are diagnosed on the basis of physical and
ultimately are shorter as adults, due to the premature radiologic examinations of the abdomen and are
fusion of the long bone epiphyses. A classification treated by surgical removal.
system for female precocious puberty is shown in Congenital adrenal hyperplasia most commonly
Box 32-1. results from a defect of the adrenal enzyme
Precocious puberty may be divided into two major 21-hydroxylase that leads to excessive androgen pro-
subgroups: heterosexual precocious puberty (devel- duction. More severe forms of this defect cause the
opment of secondary sexual characteristics opposite birth of a female with ambiguous genitalia. If untreated,
those of the anticipated phenotypic sex) and isosex- progressive virilization during childhood and short
ual precocious puberty (premature sexual matura- adult stature will result. The treatment of this disorder
tion that is appropriate for the phenotype of the includes replacement of cortisol with a related gluco-
affected individual). corticoid and surgical correction of any anatomic
Investigations for females with precocious puberty abnormalities in the first few years of life. A less severe
are shown in Box 32-2. form of this defect, referred to as nonclassic (late onset)
adrenal hyperplasia can cause premature pubarche
HETEROSEXUAL PRECOCITY and an adult disorder resembling PCOS.
In females, heterosexual precocity results from viril-
izing neoplasms, congenital adrenal hyperplasia, or ISOSEXUAL PRECOCIOUS PUBERTY
exposure to exogenous androgens. Complete isosexual precocious puberty results in the
Androgen-secreting neoplasms in females are development of the full complement of secondary
either ovarian (most commonly an arrhenoblastoma) sexual characteristics and increased levels of sex
 CH A PTE R 32 Puberty and Disorders of Pubertal Development 377

BOX 32-2
Pseudoisosexual Precocity
LABORATORY TESTS USED SELECTIVELY TO EVALUATE
Pseudoisosexual precocity occurs when estrogen
FEMALE PRECOCIOUS PUBERTY
levels are elevated and cause characteristic sexual
Radiologic maturation without activation of the hypothalamic–
Serial bone age (isosexual precocity) pituitary axis. In these girls, a GnRH stimulation test
Magnetic resonance imaging (MRI) or computed tomog- does not induce pubertal levels of gonadotropins.
raphy (CT) of the brain with optimal visualization of Causes include ovarian tumors and cysts, exogenous
hypothalamic region and sella turcica (true isosexual
estrogenic compound use, McCune-Albright syn-
precocity)
MRI, CT, or ultrasonography of abdomen, pelvis, or drome, severe prolonged hypothyroidism, and Peutz-
adrenal gland (heterosexual precocity, pseudoisosexual Jeghers syndrome. Curiously, when the initial cause of
precocity) pseudoisosexual precocity is eliminated, some girls go
Laboratory on to develop true isosexual precocity.
Some ovarian tumors can be felt on abdominal
Luteinizing hormone (LH) and follicle-stimulating
hormone (FSH) examination and are usually unilateral. Other lesions
Dehydroepiandrosterone sulfate, testosterone (hetero- may require radiologic or ultrasonic imaging for diag-
sexual precocity) nosis. Treatment of these lesions is surgical.
17-hydroxyprogesterone, 11-deoxycortisol (suspected The McCune-Albright syndrome (polyostotic
congenital adrenal hyperplasia causing heterosexual fibrous dysplasia) represents 5% of cases of female
precocity) precocious puberty. This syndrome consists of sexual
Thyroid function tests (thyroid-stimulating hormone, free precocity, multiple cystic bone defects that fracture
thyroxine) (isosexual precocious puberty) easily, café au lait spots with irregular borders (most
Gonadotropin-releasing hormone (GnRH) stimula- frequently on the face, neck, shoulders, and back), and
tion test: LH measurement after 100 μg of GnRH is
adrenal hypercortisolism. Hyperthyroidism and acro-
given intravenously (to differentiate gonadotropin-
dependent from gonadotropin-independent isosexual megaly may also occur in this syndrome. The patho-
precocity) physiology involves a somatic mutation in affected
postzygotic tissues that causes them to function inde-
pendently of their normal stimulating hormones.
Prolonged, severe hypothyroidism has been
steroids. It may arise from premature activation of the hypothesized to cause pituitary gonadotropin release
normal process of pubertal development involving the in response to the persistently elevated secretion
hypothalamic–pituitary–gonadal axis, which is called of thyroid-releasing hormone. Concomitant elevation
true isosexual precocity. Exposure to estrogen, inde- of prolactin may also occur with the development of
pendent of the hypothalamic–pituitary axis (such as galactorrhea. Ovarian cysts may occasionally develop,
from an estrogen-producing tumor), is called pseudo- and bone age may be retarded. This is the only form of
isosexual precocity. precocious puberty associated with delayed bone age.
Treatment is with thyroid replacement therapy.
True Isosexual Precocity The Peutz-Jeghers syndrome has been associated
In females, 75% of cases are constitutional. True iso- with a rare sex cord tumor with annular tubules,
sexual precocity may be diagnosed by the administra- which may secrete estrogen. Because this syndrome of
tion of exogenous GnRH (a GnRH stimulation test) gastrointestinal tract polyposis and mucocutaneous
with a resultant rise in LH levels equivalent to those pigmentation has also been reported in association
seen in older girls who are undergoing normal puberty. with granulosa-theca cell tumors, children with this
In approximately 10% of girls with the true form of disorder should be screened for the development of
precocious puberty, a central nervous system disor- gonadal neoplasms.
der is the underlying cause. This includes tumors, Incomplete isosexual precocity is the early appear-
obstructive lesions (hydrocephalus), granulomatous ance of a single secondary sexual characteristic. These
diseases (sarcoidosis, tuberculosis), infective processes conditions include premature thelarche, the isolated
(meningitis, encephalitis, or brain abscess), neurofi- appearance of breast development before the age of 4
bromatosis, and head trauma. It is postulated that years (unilateral or bilateral) that resolves spontane-
these conditions interfere with the normal inhibition ously within months and that is probably secondary to
of hypothalamic GnRH release. Children with preco- transient estradiol secretion; premature adrenarche,
cious puberty secondary to organic brain disease the isolated appearance of axillary hair before the age
often exhibit neurologic symptoms before the appear- of 7 years that is the result of premature androgen
ance of premature sexual maturation. Evaluation of secretion by the adrenal gland; and premature
true isosexual precocity should include MRI of the pubarche, the isolated appearance of pubic hair in
head for lesions. girls before the age of 8 years.
378 PAR T 4 Reproductive Endocrinology and Infertility

In general, premature thelarche and premature BOX 32-3
adrenarche are associated with appropriate sexual
RADIOLOGIC AND LABORATORY TESTS USED TO
maturation, though they may be associated with the
EVALUATE FEMALE DELAYED PUBERTY
development of nonclassic adrenal hyperplasia and
perhaps PCOS. Therapy for these conditions is not Radiologic
required. Both conditions are more common in girls Magnetic resonance imaging or computed tomography
than in boys. It is not possible to diagnose an incom- of the brain with optimal visualization of hypotha-
plete form of sexual precocity on the basis of a single lamic region and sella turcica (hypogonadotropic
hypogonadism)
evaluation, and interval examinations of bone age are
necessary to rule out true precocious puberty. Laboratory
Follicle-stimulating hormone
TREATMENT OF TRUE ISOSEXUAL Karyotype (delayed puberty, ambiguous genitalia)
PRECOCIOUS PUBERTY Progesterone (delayed puberty secondary to 17-hydroxylase
[P450c17] deficiency)
Approximately 75% of cases of precocious puberty in
Prolactin (hypogonadotropic hypogonadism)
girls prove to have a constitutional or idiopathic
cause, and these patients are candidates for GnRH
agonist therapy (e.g., leuprolide acetate). These girls
require treatment to prevent further sex steroid release
and accelerated epiphyseal fusion. Less than 50% of
girls with idiopathic precocity will attain an adult States begin pubertal maturation by the age of 13 years.
height of 5 feet if the condition is left untreated. If thelarche does not occur by age 14 years, an evalu-
GnRH agonists are the most effective therapy for ation is required. A physiologic delay in the onset of
idiopathic precocity. Long-term GnRH agonist treat- puberty occurs in only 10% of girls with delayed
ment suppresses pituitary release of LH and FSH, puberty, and exclusion of other diagnoses is necessary.
resulting in decline of gonadotropin levels to prepu- Physiologic delay in puberty tends to be familial. A
bertal concentrations and arrest of gonadal sex steroid careful history must be taken, with special attention to
secretion. Clinically, normal gonadotropin release, sex the patient’s past general health, height, dietary habits,
steroid production, and pubertal maturation will and exercise patterns. Details about the pubertal devel-
resume 3 to 12 months after discontinuation of GnRH opment of the patient’s siblings and parents should be
agonist therapy. obtained. Box 32-3 lists tests that should be performed
The final adult stature of girls with GnRH- to evaluate girls with delayed puberty.
dependent causes of precocious puberty is strongly In general, the causes of delayed onset of puberty
influenced by their chronologic age at diagnosis and can be subdivided into two categories: hypogonado-
initiation of treatment. When GnRH agonist treatment tropic hypogonadism and hypergonadotropic hypo-
is initiated before the chronologic age of 6 years, the gonadism. Disorders resulting in hypogonadotropic
final adult height is increased by 2-4%. In contrast, hypogonadism that may cause primary or secondary
the final adult height is usually not affected when the amenorrhea are discussed in Chapter 33. Of note,
chronologic age at diagnosis and treatment is greater anorexia nervosa, which can result in hypogonado-
than 6 years. Many studies have reported good long- tropic hypogonadism and delayed puberty, can affect
term reproductive outcomes in GnRH-dependent pre- 0.5-1.0% of young women. It is important to recognize
cocious puberty after treatment with GnRH agonists this disorder in the evaluation of these patients. Chro-
and have shown no differences between regularity mosomal abnormalities or injury to the ovaries by
of menstrual cycles, pregnancy rates, and live births surgery, chemotherapy, or radiation may cause
compared to a normal population. However, a few hypergonadotropic hypogonadism. When the
studies have suggested a higher prevalence (32% vs. patient’s abnormal karyotype includes the presence of
10%) of PCOS. a Y chromosome or the SRY gene in the sex-determining
The majority of children with sexual precocity have region, gonadectomy is recommended to prevent
few significant behavioral problems, but emotional potential malignant neoplastic transformation.
support is important for these children. Behavioral A growing list of single-gene disorders resulting in
expectations by family members and teachers should delayed or absent female puberty is being docu-
be based on the child’s chronologic age, which deter- mented in the literature.
mines psychosocial development, and not on the Turner syndrome affects approximately 1 in 2500
presence of secondary sexual characteristics. live-born females and is characterized by loss or
structural anomalies of an X chromosome. Its clinical
features vary, and multiple organ systems may be
Delayed Puberty affected. Often these patients present with hypergo-
Although there is wide variation in normal pubertal nadotropic hypogonadism and clinical features such
development, the vast majority of girls in the United as short stature and infertility.
 CH A PTE R 32 Puberty and Disorders of Pubertal Development 379

roids, resulting in deficient or absent pubertal develop-
ment. The accumulation of progesterone before the
block leads to excessive synthesis of the mineralocor-
ticoid 11-deoxycorticosterone, which generally causes
hypertension and hypokalemia.
Mutations of leptin and leptin receptor gene are
associated with retarded pubertal development and
childhood morbid obesity.
Mutations in the steroidogenic acute regulatory
(StAR) gene result in complete loss of adrenal steroido-
genesis and delayed puberty, which is called congeni-
tal lipoid adrenal hyperplasia. The StAR protein is
necessary for the transportation of cholesterol from the
outer mitochondrial membrane to the inner mito-
chondrial membrane, which is the rate-limiting step in
steroidogenesis.
Adolescents who present with permanent hypoes-
trogenism require estrogen therapy to complete the
development of secondary sexual characteristics.
Hormone therapy with estrogen plus a progestin or
with a low-dose oral contraceptive after establishment
of secondary sexual characteristics is required to avoid
menopausal symptoms and to prevent osteoporosis.
To further optimize gradual bone mineral deposition,
1500 mg of elemental calcium and 400 mg of vitamin
D daily are recommended. This should be combined
with regular weight-bearing exercises.

FIGURE 32-6 Kallmann syndrome is a genetic condition that Polycystic Ovarian Syndrome
results in hypogonadotropic hypogonadism caused by a defect in
gonadotropin-releasing hormone (GnRH) production and release and Puberty
from the hypothalamus. Because the area in the hypothalamus
where GnRH is produced is near the olfactory center, the sense of
PCOS is the leading cause of female anovulatory
smell is usually affected, resulting in anosmia. infertility and is characterized by ovulatory dysfunc-
tion and hyperandrogenism. It is associated with
obesity, insulin resistance, and metabolic dysfunc-
tion (see Chapter 33). During the transition from
adrenarche/pubarche (adrenal androgen production
Kallmann syndrome (Figure 32-6) presents with dominance) to menarche, a relatively similar imbal-
hypogonadotropic hypogonadism and anosmia/ ance of hormones leads to irregular menses, polycystic
hyposmia. It may result from a mutation of the KAL ovaries, and a relative androgen excess. Because of
gene on the X chromosome or from autosomal muta- these similar clinical findings, the diagnosis of PCOS in
tions that prevent the embryologic migration of GnRH the adolescent population remains controversial.
neurons into the hypothalamus. Individuals with this Recently, it has been suggested that adolescents
syndrome may have other anomalies of midline struc- with congenital virilization, premature pubarche, or
tures of the head. One in 50,000 females is affected. central precocious puberty are at higher risk of devel-
Mutations of the GnRH receptor gene in females oping PCOS. There is growing support for using a
have resulted in low gonadotropin levels with primary modified Rotterdam system to make a diagnosis of
amenorrhea or delayed puberty. PCOS in adolescents. This requires the presence of all
Mutations of the FSH β-subunit gene and the FSH three of the following criteria (rather than the standard
receptor gene have been associated with primary two of three criteria): oligo-ovulation or anovulation,
amenorrhea and varying degrees of incomplete devel- hyperandrogenism, and polycystic ovaries visualized
opment of secondary sexual characteristics. by pelvic ultrasonography. Adolescent PCOS is associ-
Females with aromatase deficiency present at ated with metabolic syndrome and sleep disorders,
puberty with progressive virilization, absence of thelar- and treatment should include lifestyle modification.
che, and primary amenorrhea. Other treatments commonly used to treat PCOS in an
17-Hydroxylase (P450c17) deficiency interferes older population have not been studied thoroughly in
with production of the androgenic and estrogenic ste- adolescents.