The history in patients with suspected growth hormone deficiency (GHD) should focus on the following issues:
Birth weight and length: Intrauterine growth retardation is an issue in the differential diagnosis and should be apparent from the birth history.
Height of parents
Timing of puberty in parents
Previous growth points
General health of child: Exclusion of chronic disease as the cause of short stature is imperative.
Nutritional history: Malnutrition is the most common cause of short stature worldwide.
Physical
The following items should be targeted:
Height and weight measurement
The best way to evaluate height or weight measurements is to plot the points on a growth chart. A growth chart depicts the child's growth over time, allows comparison of the height or weight to other children, and graphically depicts changes in growth or growth velocity.
Although weight is not difficult to determine, height measurement requires care.
Proportionality: Inspect the child for proportionality of limbs and trunk.
Pubertal status
Evidence of specific syndromes: Many syndromes include short stature as follows:
Turner syndrome
Noonan syndrome
Russell-Silver syndrome
Workup
Laboratory Studies
Laboratory studies in growth hormone deficiency (GHD) include the following:
Thyroxine and thyroid-stimulating hormone: Hypothyroidism should be excluded as a cause of growth failure and short stature.
Serum electrolytes: A low bicarbonate level may indicate renal tubular acidosis, which can result in growth failure. Abnormal electrolytes may indicate renal failure.
CBC count and sedimentation rate: These studies may be helpful if inflammatory bowel disease is suspected.
Insulinlike growth factor 1 (IGF-1) and IGF-binding protein 3 (IGFBP-3)
Karyotype
Celiac panel: Celiac disease may present with growth failure without specific GI complaints
Imaging Studies
Bone age: Radiograph of left hand and wrist is compared to standards and can be used to estimate skeletal maturation.
Patients diagnosed with growth hormone deficiency should undergo an MRI of the head to exclude a brain tumor (eg, craniopharyngioma). Approximately 15% of patients with growth hormone deficiency have an abnormality of the pituitary gland (eg, ectopic bright spot, empty or small sella).
Other Tests
Growth hormone response to insulin is the most reliable test for growth hormone deficiency.
Management
Medical Care
The current practice is a subcutaneous injection of growth hormone and daily administration is now commonly used. Long acting agents are currently still in the investigative phases.
Although growth hormone is normally secreted in multiple peaks during the day and mostly at night, a single daily injection of recombinant growth hormone can provide physiologic replacement. In order for growth hormone replacement to be effective, other pituitary deficiencies should be treated. Response to growth hormone therapy is measured (every 3-6 mo) by sequential height determinations and by occasional bone age determinations.
See Presentation, Workup, Treatment and Medication for more detail.
Many European paintings, particularly those of the Spanish Court, portray people with extremely short stature who may have had growth hormone deficiency (GHD). During the 1800s, General Tom Thumb and his wife, Lavinia Warren, exploited their short stature as part of the Barnum and Bailey Circus. The couple may have had growth hormone deficiency, although such a diagnosis was not recognized until the early 1900s.
In the 1950s, growth hormone isolated from the pituitaries of humans and anthropoid apes was discovered to stimulate growth in children who had growth hormone deficiency. In the United States, human-derived growth hormone was produced and distributed by the National Institute of Health's (NIH’s) National Pituitary Agency. From 1958-1985, a limited supply of this cadaver-derived pituitary growth hormone was used to treat 8000 children who had growth hormone deficiency in the United States. The preparation was in short supply, resulting in lower-than-ideal dosing and frequent drug holidays. Potential recipients were required to participate in a research protocol; in order to ration the cadaveric growth hormone, the diagnosis of growth hormone deficiency required that the patient have a specific peak growth hormone level in response to provocative stimuli. This requirement gradually increased in response to a better supply of cadaveric growth hormone, starting at 5 ng/mL, then 7 ng/mL, and finally 10 ng/mL in the early 1980s.
In 1985, these preparations of cadaver-derived pituitary growth hormone were implicated in several cases of Creutzfeldt-Jakob disease (CJD), and the Food and Drug Administration (FDA) ceased distribution of the cadaver-derived growth hormone. In an analysis of patients treated with cadaver-derived growth hormone, Mills et al have reported 26 subjects in the United States who died from CJD out of 7700 who had received cadaver-derived growth hormone.[1] As of 2013, there have been 29 cases reported in the United States and 226 deaths associated with cadaveric growth hormone worldwide.[2]
Since 1985, recombinant DNA–produced human growth hormone has assured a safe and unlimited supply for uninterrupted therapy at doses adequate to restore normal growth. Growth hormone deficiency may be isolated (isolated growth hormone deficiency) or associated with other pituitary deficiencies. Multiple pituitary hormone deficiency involving growth hormone deficiency is caused by genetic defects in pituitary stem cells or by anatomic problems that may be congenital or acquired (eg, from tumor, trauma, radiation, infection).
Pituitary growth hormone secretion is stimulated by growth hormone–releasing hormone (GHRH) from the hypothalamus and possibly by another signal, which may be stimulated by certain growth hormone–releasing peptides (GHRPs). Receptors for the GHRPs have been identified, and the natural ligand for these receptors has been determined to be ghrelin. Somatostatin secreted by the hypothalamus inhibits growth hormone secretion. When growth hormone pulses are secreted into the systemic circulation, insulinlike growth factor 1 (IGF-1) is released, either locally or at the site of growing bone. Growth hormone binds to a specific growth hormone–binding protein (GHBP) and circulates. This GHBP is the extracellular portion of the growth hormone receptor. IGF-1 binds to one of several IGF-binding proteins (IGFBPs) and circulates almost entirely (>99%) in the bound state. IGFBP-3 accounts for most of the IGF-I binding and this binding protein directly depends on growth hormone.
Growth hormone deficiency may result from disruption of the growth hormone axis in the higher brain, hypothalamus, or pituitary. This dysfunction can be congenital or acquired.
A mutation in a transcription factor (POUF-1, also known as PIT-1) is known to result in familial growth hormone deficiency.[3] As many as 14 different mutations have been described. In addition to growth hormone deficiency, affected individuals have had prolactin deficiencies and variable thyroid-stimulating hormone (TSH) deficiencies. Imaging of the pituitary gland usually reveals a hypoplastic or ectopic posterior pituitary.
Growth hormone deficiency with other hypopituitarism associated with inactivating mutations of the PROP1 (Prophet of PIT-1) transcription factor gene have been documented in reports. Patients with this mutation usually do not produce luteinizing hormone (LH) or follicle-stimulating hormone (FSH), and thus, do not spontaneously progress into puberty. They may also have TSH deficiency. Imaging of the pituitary gland of patients with PROP1 mutations may show either a small anterior pituitary or an intrapituitary mass.
Congenital growth hormone deficiency may be associated with an abnormal pituitary gland (seen on MRI) or may be part of a syndrome such as septooptic dysplasia (SOD) (de Morsier syndrome), which may include other pituitary deficiencies, optic nerve hypoplasia, and absence of the septum pellucidum; it occurs with an incidence of about 1 in 50,000 births. SOD may be associated with a mutation in the gene for another transcription factor, HESX1.
Acquired growth hormone deficiency may result from trauma, infections (eg, encephalitis, meningitis), cranial irradiation (somatotrophs appear to be the most radiation-sensitive cells in the pituitary), and other systemic diseases (particularly histiocytosis). Although most instances of isolated growth hormone deficiency are idiopathic, specific etiologies cause most growth hormone deficiency associated with other pituitary deficiencies. A reported 12-86% of children with apparent isolated growth hormone deficiency have sellar developmental defects.
A study of 80,000 children in Salt Lake City, Utah, reported that 555 children were below the third height percentile and had growth rates less than 5 cm/y; of these children, 33 had growth hormone deficiency, an incidence rate of 1 case per 3,500 children. Of more than 20,000 children receiving growth hormone in the National Cooperative Growth Study (a database of patients receiving growth hormone therapy), approximately 25% of the patients with growth hormone deficiency had an organic etiology. These etiologies included the following[4, 5, 6] :
CNS tumor, including craniopharyngioma - 47%
CNS malformation - 15%
SOD - 14%
Leukemia - 9%
CNS radiation - 9%
CNS trauma - 3%
Histiocytosis - 2%
CNS infection - 1%
International
Frequency of isolated growth hormone deficiency has been reported to range from 1 case per 1,800 children in Sri Lanka (a probable overestimate due to liberal diagnostic criteria) to 1 case per 30,000 children in Newcastle, United Kingdom (a probable underestimate due to its reliance on referral rates to a growth clinic).
Mortality/Morbidity
Mortality in children with growth hormone (GH) deficiency is due almost entirely to other pituitary hormone deficiencies.[1] These children have an increased relative risk of death in adulthood from cardiovascular causes resulting from altered body composition and dyslipidemia.
Most morbidity in children with GH deficiency relates to short stature. Average adult height for untreated patients with severe isolated GH deficiency is 143 cm in men and 130 cm in women. Approximately 5% of children with GH deficiency also have episodes of hypoglycemia, particularly in infancy, which resolve with GH therapy.
Overall, GH has been shown to be a safe hormone when used at recommended doses. There are excellent large databases for evaluation of possible safety signals that occur during treatment with GH. GH adverse events have been carefully documented in a review by Krysiak R et al. Most adverse events have been local injection site reactions, which rarely lead to discontinuation. Headache, nausea, and fever have been generally self-limiting and are well tolerated. Adverse events such as edema or carpal tunnel syndrome are seen more often in adults than children, and they may be the result of fluid retention caused by GH. Adverse events seen particularly in children have included transient idiopathic intracranial hypertension (also known as pseudotumor cerebri), gynecomastia, and slipped capital femoral epiphysis. The idiopathic intracranial hypertension resolved after discontinuation of GH and restarting at a low dose.
There have been concerns about cancer associated with GH administration, and these concerns have stemmed from several observations. First, acromegaly (a condition of GH excess) is known to increase the risk of colorectal cancer. Second, epidemiological studies have shown a relationship between tall statue and cancer risk, between insulinlike growth factor I (IGF-I) levels and the risk of prostate cancer, and an increase in breast cancer associated with levels of free IGF-I. One study has suggested that there may be reason for concern because of cases of Hodgkin disease and colorectal cancer found in long-term follow up of patients who had received human-derived GH. Although the incidence of these diseases was greater than the population at large, it was not outside the confidence ranges.
Further, follow up of patients receiving human-derived GH in the United States has not shown such a correlation. There has been recent concern from analysis of data in French children who were treated with GH between 1985 and 1996, and then followed until 1996 (the SAGhE study).[7] A retrospective analysis of mortality in this population suggests the possibility of increased cardiovascular disease and bone tumors in adults who received GH as children. The cardiovascular disease was primarily attributed to subarachnoid or intracerebral hemorrhages. Overall cancer mortality rates were not higher than the general population, but bone tumor–related deaths were 5 times higher than expected. There appeared to be a dose relationship (risk was highest in patients receiving doses >50 mcg/d).
The study is flawed by not having a control group (data from those who took GH as children were compared to the population at large, which may not be an appropriate comparison). In addition, there was no apparent relationship with duration of GH therapy, which one would expect if the increase in mortality was actually related GH therapy, suggesting that the increase in mortality in this group could be more likely related to the reason they were short and taking GH, rather than an effect of the GH itself.
Similar data from Sweden, The Netherlands, and Belgium[8] have shown no increase in mortality rates, and all of the deaths were attributable to accidents or suicide, further suggesting that the French data could be misleading. Clearly, what is most needed is long-term adult follow up of those patients who received GH as children
Adults with untreated GH deficiency have altered body composition (eg, excess body fat, lower lean body mass), decreased bone mineralization, cardiovascular risk factors (in particular, altered blood lipids), and decreased exercise tolerance. In addition, these patients may be socially isolated.
Race
Although no racial difference in the incidence of growth hormone deficiency is apparent, the rate at which patients receive growth hormone therapy appears to differ by race. Among nearly 9000 patients with idiopathic growth hormone deficiency in a large North American database of patients treated with growth hormone, 85% were white, only 6% were black, and 2% were of Asian descent.[4, 5, 6] An almost identical distribution is seen for patients with organic growth hormone deficiency. The racial difference may reflect a possible ascertainment bias, a notion supported by the observation that patients from other racial groups are shorter than their white counterparts at diagnosis.
Sex
The sex distribution of patients with idiopathic growth hormone deficiency in the National Cooperative Growth Study is 73% male and 27% female.[4, 5, 6] Among patients with organic growth hormone deficiency, in which no sex difference should be present, the ratio is 62% male to 38% female.
When growth hormone deficiency is diagnosed as part of SOD, sex distribution is nearly equal (male-to-female ratio is 1.3:1). Referral bias may explain this distribution (ie, greater concern for short stature in boys). This referral bias is absent when reasons other than stature result in diagnosis (eg, in patients with SOD). However, close examination of the Utah study data reveals twice the number of boys than girls in the group with heights less than the third height percentile and with growth rates less than 5 cm/y.[9] Furthermore, the group diagnosed with growth hormone deficiency had about 3 times the number of boys as girls. Given the approximately equal number of boys and girls in the Utah school system, the observed difference may not be due to referral bias.
However, several studies have tried to determine the point at which gender bias is introduced. Cuttler et al published results of a survey of pediatric endocrinologists that growth hormone treatment was 1.3 times more common in boys than in girls.[10] Furthermore, Grimberg et al examined a large worldwide database of children treated with growth hormone and found a male predominance of treated patients in Asia, the United States, Europe, Australia, and New Zealand, but not in the rest of the world.[11] These authors speculate that the bias may be introduced by parents and referring physicians and is a reflection of the culture in those countries in which the bias is observed.
Age
Although most cases of idiopathic growth hormone deficiency are thought present at birth, diagnosis is often delayed until concern is raised about short stature. Diagnosis of growth hormone deficiency is made during 2 broad age peaks. The first age peak occurs at 5 years, a time when children begin school and the height of short children is probably compared with that of their peers. The second age peak occurs in girls aged 10-13 years and boys aged 12-16 years. This second peak possibly relates to the delay in puberty associated with growth hormone deficiency. Children with growth hormone deficiency may seem to grow at a slower rate than their peers because their peers are in the midst of the pubertal growth spurt, whereas children with growth hormone have not yet entered this phase.
Growth hormone deficiency is a congenital disease no matter when height deficit becomes clinically evident; children with growth hormone deficiency grow in disease-specific percentile channels, with a highly significantly reduced length and weight. This reveals that growth hormone is essential for adequate growth in infancy and early childhood.[12]
The history in patients with suspected growth hormone deficiency (GHD) should focus on the following issues:
Birth weight and length: Intrauterine growth retardation is an issue in the differential diagnosis and should be apparent from the birth history.
Height of parents
Calculation of the sex-adjusted midparental height, also termed the "target height," helps evaluate a child's genetic potential.
For boys, calculate the sex-adjusted midparental height by adding 2.5 in or 6.5 cm from the mean of the parents' heights. For girls, subtract 2.5 in or 6.5 cm from the mean of the parents' heights.
This sex-adjusted midparental height represents the statistically most probable adult height for the child, based on parental contribution.
Timing of puberty in parents
Constitutional delay in growth and maturation may have a family history. Most mothers can remember their age at menarche (average age is 12-12.5 y).
Although pubertal age is more difficult to establish for fathers because no precise landmark is recognized, recall is generally good for development later than other boys, for always looking younger than peers, for continuing to grow after high school, and for delayed beard appearance.
Previous growth points
The child's growth pattern is an important part of the workup for short stature. Previous growth data may be obtained from physicians' offices, schools, or heights plotted on a door at home.
If the growth rate is normal (about 2 in/y [5 cm/y] from age 3 y to puberty), the child's short stature most likely is caused by a normal variant, such as familial short stature or constitutional delay in growth and maturation. If the growth rate is slow, a pathological cause for short stature is more likely.
General health of child: Exclusion of chronic disease as the cause of short stature is imperative.
Nutritional history: Malnutrition is the most common cause of short stature worldwide. Celiac disease may also present with growth decrease/failure and minimal to no gastrointestinal symptoms.[13]
The best way to evaluate height or weight measurements is to plot the points on a growth chart. A growth chart depicts the child's growth over time, allows comparison of the height or weight to other children, and graphically depicts changes in growth or growth velocity.
Although weight is not difficult to determine, height measurement requires care. The following points help provide accurate measurements:
Children should be either barefoot or in stocking feet upon measurement. The heels, buttocks, and shoulders should be in contact with the wall or the measuring device.
Have the child stand with feet slightly spread but with heels together.
Instruct the child to look straight ahead. This positions the head in the Frankfort horizontal plane (ie, the plane represented in the profile by a line between the lowest point on the margin of the orbit and the highest point on the margin of the auditory meatus).
Instruct the child to hold a deep breath at the time of measurement.
Use proper equipment. The ideal device for height measurement is a wall-mounted stadiometer with an arm that moves vertically. The arm is placed on the head; the height can be read from a counter or from a ruler on the wall. If a stadiometer is unavailable, good height measurements may be obtained from a yardstick (or meterstick) attached to the wall, combined with a device creating a right angle with the wall and the child's head. Floppy-arm devices mounted on weight scales are inherently inaccurate and frequently yield poor measurements. A child's height can be determined using this device, but accurate measurement requires even more attention.
For precise height determinations, measure the child 2-3 times and calculate the mean. If the first 2 measurements agree, consider them accurate.
Measure the child at the same time of day to minimize diurnal variation in height.
Proportionality: Inspect the child for proportionality of limbs and trunk. The following measurements may be taken if disproportionality is suspected:
Arm span: Measure outstretched arms from fingertip to fingertip. The arm span should approximate the height, although this depends on genetic background. In comparisons of people of Asian, European, and African heritage, Asians have proportionally shorter arms, Europeans have intermediate arm length, and Africans have significantly longer arms.
Lower segment (LS): Measure from the symphysis pubis to the floor.
Upper segment (US): Calculate by subtracting the lower segment measurement from the height.
US/LS ratio: Calculate by dividing US by LS. For people of European origin, the US/LS ratio at birth is approximately 1.7:1 and decreases to 1:1 at age 10 years, a ratio that lasts throughout adulthood. In comparisons of people of Asian, European, and African heritage, Asians have proportionally shorter legs (and, therefore, larger US/LS ratios), Europeans have intermediate length legs, and Africans have significantly longer legs.
Pubertal status
Calculate stage of puberty using the Tanner staging system.[14]
Constitutional and many other pathological causes of short stature, including growth hormone deficiency, delay puberty.
Evidence of specific syndromes: Many syndromes include short stature as follows:
Laboratory studies in growth hormone deficiency (GHD) include the following:
Thyroxine and thyroid-stimulating hormone: Hypothyroidism should be excluded as a cause of growth failure and short stature.
Serum electrolytes: A low bicarbonate level may indicate renal tubular acidosis, which can result in growth failure. Abnormal electrolytes may indicate renal failure.
CBC count and sedimentation rate: These studies may be helpful if inflammatory bowel disease is suspected.
Insulinlike growth factor 1 (IGF-1) and IGF-binding protein 3 (IGFBP-3)
Both IGF-1 and IGFBP-3 are growth hormone–dependent.
Low values of IGF-1 and IGFBP-3 suggest growth hormone deficiency. However, a low value alone is not diagnostic because IGFs are sensitive to other factors such as nutritional state and chronic systemic disease.
Celiac panel
a small subset of patients with celiac disease may present with minimal to no gastrointestinal (GI) symptoms with growth failure or decreased height velocity. Before modifying gluten exposure, these patients should be referred to GI specialists to confirm the diagnosis.
Karyotype
Girls with otherwise unexplained short stature should have a karyotype study to rule out Turner syndrome.
Although many girls with Turner syndrome are diagnosed from signs upon physical examination, the only recognizable feature of many girls with the condition may be short stature.
In particular, girls with mosaic karyotypes or karyotypes with isochromosomes tend to exhibit fewer signs specific to Turner syndrome.
Many girls with Turner syndrome, and particularly those with mosaic karyotypes and karyotypes other than 45,X, do not demonstrate the striking stigmata associated with Turner syndrome.
Boys in which there is clinical suspicion of a possible genetic etiology of the growth disorder have about the same likelihood of having an abnormal karyotype as is seen in girls being evaluated for Turner syndrome.
Patients diagnosed with growth hormone deficiency should undergo an MRI of the head to exclude a brain tumor (eg, craniopharyngioma). Approximately 15% of patients with growth hormone deficiency have an abnormality of the pituitary gland (eg, ectopic bright spot, empty or small sella).
Comparison of a left hand and wrist radiograph to standards can be used to estimate skeletal maturation. With familial short stature, bone age is comparable to chronological age. Bone age is usually delayed in children with constitutional growth delay, malnutrition, and endocrine causes of short stature (eg, hypothyroidism, cortisol excess, growth hormone deficiency). Bone age also allows determination of growth potential as adult stature may be estimated from the Bayley-Pinneau tables.
Growth hormone response to insulin is the most reliable test for growth hormone deficiency. Before accepting growth hormone deficiency diagnosis, many insurance companies require a documented failure to demonstrate a growth hormone response (with a growth hormone level >10 ng/mL) after presentation of 2 provocative stimuli. Provocative stimuli include insulin-induced hypoglycemia, arginine, levodopa (L-dopa), clonidine, and glucagon.
Initially, growth hormone was injected intramuscularly; however, in the mid 1980s (about the time recombinant human growth hormone [rhGH] became available) it was shown to be as effective when administered as a subcutaneous injection.[15] This is the current practice.
Early in its use, growth hormone was administered twice weekly; this was increased to 3 times weekly when the higher frequency was shown to result in an increased growth response.[16] At about the time of the transition from cadaveric growth hormone to rhGH, daily injections (6-7 injections per week) were shown to yield an even better growth response than administering injections 3 times per week.[17, 18, 19, 20] Thus, daily administration is now commonly used.
A multicenter, randomized, controlled dose-response trial of 35 children in the Netherlands found that final adult height was 4-5 cm less than target height in patients administered growth hormone does of 0.7 mg/m2/d, whereas adult height was 0-2 cm less than target height in patients receiving 1.4 mg/m2/d; however, this difference was not statistical significant, likely due to the limited numbers of patients, variation in growth response, and earlier spontaneous puberty and pubertal induction in children receiving 1.4 mg/m2/d.[21]
Although growth hormone is normally secreted in multiple peaks during the day and mostly at night, a single daily injection of recombinant growth hormone can provide physiologic replacement. In order for growth hormone replacement to be effective, other pituitary deficiencies should be treated. Response to growth hormone therapy is measured (every 3-6 mo) by sequential height determinations and by occasional bone age determinations.
Newer, long acting formulations of GH are currently under investigation. Although none are yet approved in the United States, these agents that rely on various technologies to extend duration of therapy appear promising. [22]
Guidelines on growth disorders and their treatment by the Drug and Therapeutics Committee and Ethics Committee of the Pediatric Endocrine Society[23]
Use growth hormone (GH) to normalize adult height (AH) and avoid extreme shortness in children and adolescents with growth hormone deficiency (GHD).
Suggest against routine cardiac testing, dual x-ray absorptiometry (DXA) scanning, and measurement of lipid profiles in children and adolescents treated with GH.
Establish a diagnosis of GHD without GH provocative testing in patients possessing all of the following 3 conditions: auxological criteria, hypothalamic-pituitary defect (such as major congenital malformation [ectopic posterior pituitary and pituitary hypoplasia with abnormal stalk], tumor, or irradiation), and deficiency of at least one additional pituitary hormone.
GHD due to congenital hypopituitarism should be diagnosed without formal GH provocative testing in a newborn with hypoglycemia who does not attain a serum GH concentration above 5 µg/L and has deficiency of at least one additional pituitary hormone and/or the classical imaging triad (ectopic posterior pituitary and pituitary hypoplasia with abnormal stalk).
Recommend against reliance on GH provocative test results as the sole diagnostic criterion of GHD.
Suggest sex steroid priming prior to provocative GH testing in prepubertal boys older than 11 yr and in prepubertal girls older than 10 yr with AH prognosis within -2 SD of the reference population mean in order to prevent unnecessary GH treatment of children with constitutional delay of growth and puberty.
Recommend against the use of spontaneous GH secretion in the diagnosis of GHD in a clinical setting.
Recommend an initial GH dose of 0.16-0.24 mg/kg/wk (22-35 µg/kg/day) with individualization of subsequent dosing.
Suggest measurement of serum insulin-like growth factor-I (IGF-I) levels as a tool to monitor adherence and IGF-I production in response to GH dose changes. Suggest that the GH dose be lowered if serum IGF-I levels rise above the laboratory-defined normal range for the age of pubertal stage of the patient.
During puberty, recommend against the routine increase in GH dose to 0.7 mg/kg/wk in every child with GHD.
Recommend that GH treatment at pediatric doses not continue beyond attainment of a growth velocity below 2-2.5 cm/yr. The decision to discontinue pediatric dosing prior to attainment of this growth velocity should be individualized.
Recommend that prospective recipients of GH treatment receive anticipatory guidance regarding the potential adverse effects of intracranial hypertension, slipped capital femoral epiphysis (SCFE), and scoliosis progression.
Recommend monitoring of GH recipients for potential development of intracranial hypertension, SCFE, and scoliosis progression by soliciting pertinent history and performing a physical examination at every follow-up clinic visit; further testing should be pursued if indicated.
Recommend re-assessment of both the adrenal and thyroid axes after initiation of GH therapy in patients whose cause of GHD is associated with possible multiple pituitary hormone deficiencies (MPHD).
For GH initiation after completion of tumor therapy with no evidence of ongoing tumor, a standard waiting period of 12 mo to establish “successful therapy” of the primary lesion is reasonable, but can also be altered depending on individual patient circumstances.
Recommend that patients with multiple (≥3) pituitary hormone deficiencies regardless of etiology, or GHD with a documented causal genetic mutation or specific pituitary/hypothalamic structural defect except ectopic posterior pituitary, be diagnosed with persistent GHD.
Recommend re-evaluation of the somatotropic axis for persistent GHD in persons with GHD and deficiency of only one additional pituitary hormone, idiopathic isolated GHD (IGHD), IGHD with or without small pituitary/ectopic posterior pituitary, and after irradiation.
Suggest that measurement of the serum IGF-I concentration be the initial test of the somatotropic axis if re-evaluation of the somatotropic axis is clinically indicated.
Recommend GH provocative testing to evaluate the function of the somatotropic axis in the transition period if indicated by a low IGF-I level.
Suggest that GH treatment be offered to individuals with persistent GHD in the transition period. There is evidence of benefit; however, the specifics of the patient population that benefits, the optimal time to re-initiate treatment, and the optimal dose are not clear.
Because there is overlap in response between dosing groups, suggest initiating GH at a dose of 0.24 mg/kg/wk, with some patients requiring up to 0.47 mg/kg/wk.
Recommend the use of IGF-I therapy to increase height in patients with severe primary IGF-I deficiency (PIGFD).
Recommend a trial of GH therapy before initiating IGF-I for patients with unexplained IGF-I deficiency. Patients with hormone signaling defects known to be unresponsive to GH treatment can start directly on IGF-I replacement; these include patients with very low or undetectable levels of GH-binding protein (GHBP) and/or proven GH receptor (GHR) gene mutations known to be associated with Laron syndrome/GH insensitivity syndrome (GHIS), GH-neutralizing antibodies, STAT5b gene mutations, and IGF1 gene deletion or mutation.
Suggest an IGF-I dose of 80-120 µg/kg BID. Similar short-term outcomes were seen with 80 and 120 µg, but published studies had limitations, and there is no strong evidence supporting superiority of one dose over the other.
Clinical Context:
Purified polypeptide hormone of recombinant DNA origin. In children whose epiphyses are not yet fused, GH replacement usually causes significant increase in growth velocity (averaging 10-11 cm/y during first y of therapy). Response wanes each y, but growth velocity continues at faster than pretreatment rates. A long-acting depot preparation designed for monthly or bimonthly SC injection was available but is not off the market. Other long-acting preparations are currently under investigation.
Most pediatric endocrinologists see patients who are receiving growth hormone therapy 2-4 times per year. The most important reasons for follow-up are to monitor growth progress and to adjust growth hormone dosage. Growth rate usually increases most during the first year of treatment, with an average increase of 8-10 cm/y (often called "catch-up" growth). Progressive growth slows over the next several years (ie, waning effect). A growth rate appearing to slow more than expected should prompt investigation for a medical cause (eg, hypothyroidism) or another diagnosis (eg, inflammatory bowel disease). Follow-up may also be needed to assure patient compliance with the growth hormone injections.
Although few patients experience adverse events from growth hormone therapy, the following complications have been recognized:
Carbohydrate metabolism: Growth hormone has an anti-insulin effect, and carbohydrate metabolism has been monitored in many clinical studies of growth hormone therapy. A review of large databases containing more than 35,000 patients on growth hormone and more than 75,000 patients with years of exposure indicates no greater incidence of type 1 diabetes than would be expected in the general population of age-matched children. One study of an increased incidence of type 2 diabetes in children undergoing growth hormone therapy with risk factors for diabetes suggests that growth hormone may cause earlier expression of this condition.
Benign intracranial hypertension (pseudotumor cerebri): A clear association between intracranial hypertension and growth hormone therapy is observed. The incidence appears to be about 0.001 (21 cases reported out of 19,000 patients receiving growth hormone, or 50,000 patient-years). Usually, severe headache symptoms (occasionally with vomiting) develop during the first 4 months of therapy. The risk of this complication increased in children receiving growth hormone for chronic renal insufficiency. In most cases, cessation of growth hormone therapy resolved the intracranial hypertension; the growth hormone then could be restarted at a lower dose and slowly titrated back to the usual dose.
Fluid homeostasis: Growth hormone affects fluid homeostasis, which may lead to edema and even carpal tunnel syndrome. These problems are more common in adults receiving growth hormone. When these occurrences become sufficiently serious to require action, stopping the growth hormone provides resolution. Restarting the growth hormone at a lower dose and slowly titrating it back to the usual dose is usually possible.
Skeletal and joint problems: Children receiving growth hormone therapy are more susceptible to slipped capital femoral epiphysis (SCFE). Yet children with growth hormone deficiency (GHD), hypothyroidism, or renal disease seem to have increased risk for SCFE, even without growth hormone therapy. When a child receiving growth hormone therapy complains of hip or knee pain, a careful physical examination is vital, and, if warranted, hip radiography. Scoliosis progression is another skeletal-related complication of growth hormone therapy. Scoliosis relates to the rapid growth that occurs with therapy and is not a direct effect of the growth hormone. Patients with scoliosis who are treated with growth hormone should have their scoliosis monitored during therapy.
Prepubertal gynecomastia: Although adolescent gynecomastia is common, prepubertal gynecomastia occurs less frequently. Such cases have been reported in association with growth hormone therapy, although whether the gynecomastia is related to the growth hormone is unclear. Prepubertal gynecomastia is a benign condition that resolves without sequelae.
Leukemia: Several worldwide databases have been examined in response to sporadic reports of leukemia in patients undergoing growth hormone therapy. When patients with other risk factors (eg, previous history of leukemia, radiation, chemotherapy) are excluded, no increased risk of leukemia has been demonstrated. No evidence suggests an association between growth hormone therapy and leukemia in otherwise healthy children.
Since recombinant DNA–derived growth hormone became available, most children with growth hormone deficiency reach normal adult stature. Duration of therapy has the most consistent correlation with growth response to growth hormone. Initiate growth hormone therapy as early as possible and continue therapy through adolescence to ensure the best chance of achieving height potential.
Instruct patients and families regarding subcutaneous injection technique.
For patient education resources, see the Growth Hormone Deficiency Center, as well as Growth Hormone Deficiency, Growth Hormone Deficiency in Children, Understanding Growth Hormone Deficiency Medications, and Growth Hormone Deficiency FAQs.
What is the focus of clinical history for pediatric growth hormone deficiency (GHD)?What is the focus of the physical exam to evaluate pediatric growth hormone deficiency (GHD)?Which lab tests are performed in the workup of pediatric growth hormone deficiency (GHD)?What is the role of imaging studies in the workup of pediatric growth hormone deficiency (GHD)?What is the most reliable test for pediatric growth hormone deficiency (GHD)?What is the role of growth hormone injection in the treatment of pediatric growth hormone deficiency (GHD) treated?What is pediatric growth hormone deficiency (GHD)?What is the pathophysiology of pediatric growth hormone deficiency (GHD)?What is the prevalence of pediatric growth hormone deficiency (GHD) in the US?What is the global prevalence of pediatric growth hormone deficiency (GHD)?What is the morbidity and mortality associated with pediatric growth hormone deficiency (GHD)?What are the racial predilections of pediatric growth hormone deficiency (GHD)?What are the sexual predilections of pediatric growth hormone deficiency (GHD)?At what age is pediatric growth hormone deficiency (GHD) typically diagnosed?Which clinical history findings suggest pediatric growth hormone deficiency (GHD)?How should height and weight be measured in the evaluation of pediatric growth hormone deficiency (GHD)?How is proportionality determined in the evaluation of pediatric growth hormone deficiency (GHD)?How is pubertal status determined in the evaluation of pediatric growth hormone deficiency (GHD)?Which syndromes are associated with pediatric growth hormone deficiency (GHD)?What causes pediatric growth hormone deficiency (GHD)?What are the differential diagnoses for Pediatric Growth Hormone Deficiency?What is the role of lab tests in the workup of pediatric growth hormone deficiency (GHD)?What is the role of imaging studies in the workup of pediatric growth hormone deficiency (GHD)?How is skeletal maturation estimated in the workup of pediatric growth hormone deficiency (GHD)?How is a diagnosis of pediatric growth hormone deficiency (GHD) confirmed?How is pediatric growth hormone deficiency (GHD) treated?Which specialist consultations are beneficial to patients with pediatric growth hormone deficiency (GHD)?What are the Pediatric Endocrine Society treatment guidelines for pediatric growth hormone deficiency (GHD)?What is the role of medications in the treatment of pediatric growth hormone deficiency (GHD)?Which medications in the drug class Growth hormones are used in the treatment of Pediatric Growth Hormone Deficiency?What is included in the long-term monitoring of pediatric growth hormone deficiency (GHD)?What are the possible complications of pediatric growth hormone deficiency (GHD)?What is the prognosis of pediatric growth hormone deficiency (GHD)?What is included in the patient education about pediatric growth hormone deficiency (GHD)?
Vaneeta Bamba, MD, Associate Professor of Clinical Pediatrics, Perelman School of Medicine at the University of Pennsylvania; Attending Physician, Medical Director, Diagnostic and Research Growth Center, Medical Director, Turner Syndrome Program, Children’s Hospital of Philadelphia
Disclosure: Nothing to disclose.
Specialty Editors
Mary L Windle, PharmD, Adjunct Associate Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference
Disclosure: Nothing to disclose.
Barry B Bercu, MD, Professor, Departments of Pediatrics, Molecular Pharmacology and Physiology, University of South Florida College of Medicine, All Children's Hospital
Disclosure: Nothing to disclose.
Chief Editor
Robert P Hoffman, MD, Professor and Program Director, Department of Pediatrics, Ohio State University College of Medicine; Pediatric Endocrinologist, Division of Pediatric, Endocrinology, Diabetes, and Metabolism, Nationwide Children's Hospital
Disclosure: Nothing to disclose.
Additional Contributors
Arlan L Rosenbloom, MD, Adjunct Distinguished Service Professor Emeritus of Pediatrics, University of Florida College of Medicine; Fellow of the American Academy of Pediatrics; Fellow of the American College of Epidemiology
Frindik JP, Kemp SF, Pihoker C. Effective use of magnetic resonance imaging in the assessment of children with possible growth hormone deficiency. Endocrine Practice. 1996. 2:8-12.
Rosenbloom AL, Knuth C, Shulman D. Growth hormone therapy by daily injection in patients previously treated for growth hormone deficiency. South Med J. 1980. 83:653-5.