Pharmacokinetic and pharmacodynamic characteristics of a long-acting growth hormone (GH) preparation (nutropin depot) in GH-deficient children.

Long-term GH replacement therapy is indicated for children with growth failure due to GH deficiency (GHD). We evaluated the feasibility of administering a long-acting GH preparation [Nutropin Depot (somatropin, rDNA origin) for injectable suspension] to prepubertal children with GHD by examining pharmacokinetic and pharmacodynamic response parameters after single or multiple doses. Data were collected from three studies involving 138 children treated with Nutropin Depot 0.75 mg/kg once per month, 0.75 mg/kg twice per month, or 1.5 mg/kg once per month. Twenty-two patients underwent intensive sampling to estimate mean peak serum GH concentrations (C(max)) and time to achieve C(max) for GH and IGF-I. Thereafter, weekly serum concentrations were measured and compared with baseline. C(max) and area under the curve were approximately proportional to the dose administered. Fractional area under the curve data indicate that at least 50% of GH exposure occurs during the first 2 d after administration. Serum GH levels remained above 1 microg/liter for 11-14 d. IGF-I levels remained above baseline for 16-20 d, but increases were not proportional to dose. After multiple doses over a 6-month period, peak and trough concentrations showed no progressive accumulation of GH, IGF-I, or IGF binding protein-3. Nutropin Depot administration once or twice per month provides serum levels of GH and IGF-I expected to promote growth, without accumulation of GH, IGF-I, or IGF binding protein-3, in children with GHD.

The pharmacokinetic and pharmacodynamic characteristics of a long-acting growth hormone (GH) preparation (nutropin depot) in GH-deficient adults.

A pharmacokinetic-pharmacodynamic study of a long-acting GH [Nutropin Depot; somatropin (rDNA origin) for injectable suspension] was performed in 25 patients with adult GH deficiency. Single doses of 0.25 mg/kg and 0.5 mg/kg, based on ideal body weight, were administered sc. After either dose, serum GH concentrations rose rapidly in both sexes. In men, the lower dose maintained serum IGF-I levels within 1 SD of the mean for age and sex for 14-17 d; the higher dose raised IGF-I levels 2 SD above the mean. In most women, all of whom were receiving oral estrogen, the lower dose did not normalize IGF-I levels; the higher dose maintained IGF-I near the mean for approximately 14 d. Increases in IGF binding protein-3 and acid-labile subunit levels were observed in both sexes; however, a sex-related difference was not obvious. Fasting glucose and insulin concentrations were transiently elevated in men receiving the higher dose. Patients tolerated the injections well. We concluded that a single injection of Nutropin Depot at these doses in patients with adult GH deficiency increased serum IGF-I to within normal limits for 14-17 d. Estrogen-treated women required approximately twice the dose needed in men to produce comparable IGF-I concentrations.

Early initiation of growth hormone treatment allows age-appropriate estrogen use in Turner's syndrome.

Because estrogen (E) accelerates skeletal maturation it can decrease final height attainable with GH therapy in girls with Turner's syndrome (TS). Nonetheless, as age-appropriate E administration does have psychobehavioral benefits for such patients, we asked whether E treatment in TS could occur without adverse impact on final adult height if GH therapy were started at an earlier age. Near adult height (NAH) was assessed in 344 girls with TS, who had received both GH and E and were followed in the National Cooperative Growth Study database. The groups were divided into quartiles based on age at initiation of GH (2-10, 10-12, 12-14, and 14-18 yr). The longest total and E-free period of GH treatment occurred in the girls who had started treatment in the youngest quartile (mean age, 8.2 +/- 1.5 (SD) yr); they were also exposed to E at the youngest age (12.7 +/- 1.6 yr). Although the girls in the youngest group received E at an earlier age, they had a significantly greater increase (1.8 +/- 0.8) in Lyon height SD score at NAH over Lyon predicted adult height than those in the oldest GH-treated group (0.8 +/- 0.6), which first received E at 15.9 +/- 1.3 yr. Multiple linear regression equations for gain in Lyon height SD score and in height (cm) showed greater increments with a longer period of E-free GH therapy. All four GH age groups had the same NAH, but the youngest quartile was youngest at NAH and likely still having more growth potential. Comparable data were found in 127 TS girls with spontaneous puberty. In conclusion, girls with TS starting GH at an early age have a greater gain in Lyon SD score at NAH compared with those starting later, even though they received E at a younger age. If GH therapy were started early, E treatment could be initiated at a younger, more age-appropriate time without compromising adult height.

Body mass index (BMI) in Turner Syndrome before and during growth hormone (GH) therapy.

OBJECTIVE: To study whether body mass index (BMI) is different in girls with Turner syndrome (TS) compared to normal girls, and whether BMI in TS is affected by growth hormone (GH) treatment. DESIGN: A retrospective cross-sectional study. SUBJECTS: 2468 girls with TS enrolled in the National Cooperative Group Study (NCGS), a collaborative surveillance study for assessing GH-treated children. MEASUREMENTS: BMI and BMI standard deviation score (BMI SDS) at baseline and during GH treatment were computed from height and weight data. RESULTS: BMI in TS patients increases with age as expected. However, BMI SDS increased starting at about age 9 y. A similar pattern of increase in BMI SDS was observed after each year of GH treatment for up to 4 y, but GH treatment did not change the magnitude of increase. BMI and BMI SDS curves before and during GH treatment were essentially superimposable. CONCLUSION: These findings suggest that mechanisms specific for TS are responsible for the age-related increase in BMI SDS. This increase was unaffected by GH treatment.

Combined use of growth hormone and gonadotropin-releasing hormone analogues: the national cooperative growth study experience.

Gonadotropin-releasing hormone ana-logues (GnRHa) are used to treat central precocious puberty. They also are used to delay puberty in short children with a prognosis for impaired adult height. In both cases, growth hormone (GH) treatment is sometimes added. To determine how North American pediatric endocrinologists are using the combination of GH and GnRHa, we searched the National Cooperative Growth Study (NCGS) database and identified 509 patients who were treated with both. Among them were 139 patients with a diagnosis of precocious puberty. Most of these (82%) also had GH deficiency (GHD). Of the 370 patients who did not have precocious puberty, 71% had GHD. There were 200 patients with precocious puberty who were treated with GH but not with GnRHa. The children who were given GH alone (77% of whom had GHD) were much younger than the children who were given both GH and GnRHa (5.7 +/- 2.9 years for those who were not treated with GnRHa vs 9.1 +/- 2.7 years for those who were). Data on both predicted adult height before GH treatment and near- adult height were available for 141 of the patients who were given both GH and GnRHa. There was a statistically significant increase in near-adult height over pre-GH predicted adult height in girls with precocious puberty (5.4 +/- 4.3 cm) and without precocious puberty (3.0 +/- 6.1 cm). There was no statistically significant gain in height for boys who did not have precocious puberty (1.3 +/- 6.8 cm). There were too few boys with precocious puberty (n = 7) to enable meaningful conclusions. In a multiple regression analysis of data on girls who did not have precocious puberty, duration of GH treatment was the most important variable predictive of height gain.gonadotropin-releasing hormone, growth hormone, precocious puberty, idiopathic growth hormone deficiency, organic growth deficiency, idiopathic short stature.

Growth hormone stimulation test results as predictors of recombinant human growth hormone treatment outcomes: preliminary analysis of the national cooperative growth study database.

Growth hormone (GH) stimulation tests are considered a prerequisite to clinical trials of recombinant human GH (rhGH) therapy, but the test results may not be predictive of the treatment outcomes with rhGH. We examined the GH stimulation test results as a predictor of the treatment outcome in a cohort of prepubertal subjects in the National Cooperative Growth Study. A standard is proposed in which a diagnosis of GH deficiency is considered appropriate when a patient has significant first-year catch-up growth and that a positive stimulation test result predicts this outcome. With this construct, a traditional interpretation of GH stimulation test results correctly identifies 64% of the rhGH treatment outcomes. The analysis shows an upper limit of diagnostic sensitivity of 82% and a lower limit of specificity of 25% in our study population. The results of our recent studies suggest that the sensitivity and specificity of the current GH stimulation tests are attributable in part to broad intersubject variation in GH clearance, rates of GH elimination, and GH volume of distribution. The combined studies suggest that the use of subject-specific pharmacokinetic parameters will improve the diagnostic interpretation of GH stimulation test results and improve rhGH treatment outcomes.growth hormone stimulation tests, recombinant human growth hormone, pharmacokinetic parameters, maximal stimulated growth hormone concentration.

Growth hormone isoforms in a girl with gigantism.

Several previous investigations have suggested that there may be different growth hormone isoforms in patients with acromegaly. We used three different site-specific monoclonal antibodies (MAbs) to investigate growth hormone (GH) isoforms in serum from an 8 year-old girl with a GH and prolactin secreting adenoma. The pattern of GH-immunoreactivity was dependent on the circumstances of collection. Serum obtained after oral glucose had very little cross reactivity with MAb 352 although concentrations of up to 15 micrograms/l were found with two other MAbs, 033 and 665. MAb 352 does not recognize the 20,000 dalton isoform of GH (20K) while both MAb 033 and 665 do. The same pattern of GH immunoreactivity (low MAb 352, equal and higher MAb 033 and 665) was seen in other baseline samples. In contrast, samples obtained after TRH/GnRH showed immunoreactivity patterns expected for a mixture of 22,000 dalton isoform of GH (22K) with only a small amount of 20K. GH samples obtained during sleep showed both patterns with episodic peaks with equal immunoreactivity superimposed on the basal pattern (decreased activity with MAb 352). Affinity chromatography of basal samples showed that a portion of the GH immunoreactivity was neither 22K nor 20K, although in stimulated samples, over 70% of GH was 22K or 20K GH. In conclusion, the nature of GH isoforms present in serum varies with GH concentration. These differences may contribute to the known difficulty in correlating disease activity and random GH measurements in patients with GH secreting adenomas.

The effect of growth hormone treatment on stature in Aarskog syndrome.

We describe 19 males with Aarskog syndrome who were treated with growth hormone (GH) and enrolled in the National Cooperative Growth Study (NCGS). There was a significant increase in both growth rate (3.9 +/- 1.9 cm/yr vs 8.9 +/- 1.7 cm/yr, p < 0.001) and height SD score (change in HtSDS = 1.0 +/- 0.8). The increase in HtSDS was dependent on treatment duration, frequency of injections, weight-for-height SDS, and HtSDS at enrollment. The results of our study suggest a positive effect of GH treatment on growth and adult height in Aarskog syndrome patients.

Weight relative to height before and during growth hormone therapy in prepubertal children.

We used the Genentech National Cooperative Growth Study database to examine differences in weight relative to height (weight for height standard deviation score or WTHTZ) in 3460 patients at enrollment and after one year of therapy with recombinant human growth hormone (rhGH), and in a subset of 450 patients treated for three years with rhGH. The major diagnostic categories were idiopathic growth hormone deficiency (IGHD), organic GH deficiency (OGHD), and idiopathic short stature (ISS). Children with IGHD and ISS were underweight for height at baseline but had a progressive increase in WTHTZ during three years of rhGH therapy. The same pattern applied to children with IGHD associated with septo-optic dysplasia and CNS trauma or infection. However, children with OGHD associated with craniopharyngiomas, other CNS tumors, leukemia, or CNS irradiation were overweight when starting rhGH and showed a decrease in WTHTZ during the first year of rhGH therapy. The increase in WTHTZ during rhGH treatment in children with ISS and OGHD suggests that the GH-induced increase in muscle mass exceeded loss of fat mass. Because children with neoplasm-related OGHD were overweight at baseline, the decline in WTHTZ during the first year of rhGH therapy suggests that loss of fat mass is the predominant effect in this subgroup.

Growth hormone treatment of girls with Turner syndrome: the National Cooperative Growth Study experience.

OBJECTIVE: To evaluate growth rate and adult height with recombinant growth hormone (GH) treatment in girls with Turner syndrome (TS) and predictors of their growth response. METHODS: Data on girls with TS who were treated with GH in the National Cooperative Growth Study (NCGS) were evaluated. As of January 1997, there were 2798 girls with TS in the NCGS database, 2652 of whom had not previously received GH. Follow-up data on growth were available for 2475 subjects, and data on adult height were available for 622. RESULTS: The average age of girls with TS at enrollment in the NCGS was 10.1 +/- 3.6 years. These patients had severely short stature compared with that of unaffected American girls (height, 118.5 +/- 16.5 cm; height standard deviation score [SDS], -3.1 +/- 0.9), but their heights were typical of those of American girls with TS (TS-specific height SDS, 0.01 +/- 0.9). Treatment with GH for an average duration of 3.2 +/- 2.0 years resulted in an increase in height SDS of 0.8 +/- 0.7 compared with unaffected girls and of 1.2 +/- 0.8 compared with TS standards. Growth rates increased from 4.0 +/- 2.3 cm/year before treatment to 7.5 +/- 2.0 cm/year after 1 year of treatment. Duration of treatment with GH was the strongest predictor of change in height SDS. After 6 to 7 years of treatment with GH, there was a cumulative change of 2.0 in mean height SDS. The 622 girls who reached adult height were older when they began taking GH. Their mean height gain over pre-GH projected height was 6.4 +/- 4.9 cm after 3.7 +/- 1.9 years of treatment. Their adult height was 148.3 +/- 5.6 cm. CONCLUSIONS: Although the response to treatment with GH varied, it was associated with highly significant gains in growth and adult height in girls with TS. Duration of treatment with GH was the most important variable predicting adult height.

Response to growth hormone in attention deficit hyperactivity disorder: effects of methylphenidate and pemoline therapy.

OBJECTIVE: To determine whether treatment of attention deficit hyperactivity disorder (ADHD) with methylphenidate hydrochloride or pemoline diminishes the response to growth hormone (GH) therapy in patients with idiopathic GH deficiency (IGHD) or idiopathic short stature (ISS). METHODS: The National Cooperative Growth Study database was used to identify patients between 3 and 20 years of age with IGHD or ISS and those within these groups who were treated with methylphenidate or pemoline for ADHD. Their growth in response to GH treatment (change in height standard deviation score [SDS]) was compared with that of patients with IGHD or ISS who were not treated for ADHD, by using a stepwise multiple regression analysis. RESULTS: In the IGHD cohort, there were 184 patients who were being treated for ADHD and 2313 who were not. In the ISS cohort there were 117 patients who were being treated for ADHD and 1283 who were not. There was a higher percentage of males being treated for ADHD in both cohorts. In the IGHD cohort, the change in height SDS was positively associated with the number of years of GH treatment, parents' heights, body mass index, and GH injection schedule, and was negatively associated with height SDS at the initiation of GH therapy, age, and maximum stimulated GH level. The use of methylphenidate or pemoline had a negative effect on the change in height SDS, but the magnitude of the effect was small. Similar effects were noted in the ISS cohort, but body mass index and the use of methylphenidate or pemoline had no effect on the change in height SDS. CONCLUSIONS: Concurrent ADHD therapy is associated with a slight decrease in the change in height SDS during GH treatment in patients with IGHD but not in those with ISS. Even in IGHD, the magnitude of the effect is small and should not deter the use of such concurrent therapy.

Adult height in children with growth hormone deficiency who are treated with biosynthetic growth hormone: the National Cooperative Growth Study experience.

OBJECTIVE: To determine whether the height gain during puberty in children with growth hormone deficiency (GHD) who are treated with biosynthetic growth hormone (GH) is similar to that in otherwise healthy children with delayed bone ages and whether the height standard deviation score (SDS), which began to increase before puberty, continues to increase during puberty. METHODS: The inclusion criteria included a diagnosis of idiopathic GHD, prepubertal on enrollment in the National Cooperative Growth Study, and spontaneous onset of puberty, as defined by Tanner stage 2 breast development in girls and a testicular volume of at least 3 mL in boys. Near-adult height was judged to have been attained in the subjects who had reached a chronologic age of at least 18 years (females) or 20 years (males) or had reached at least pubertal stage 4 and a chronologic age of at least 14 years (females) or 16 years (males). These subjects constituted group 1. Group 2 was a subgroup of these subjects who met a more stringent criterion for near-adult height; in addition to meeting the above criteria, they had to have attained a bone age of at least 14 years (females) or 16 years (males). RESULTS: Group 1 consisted of 480 males and 194 females. Group 2 consisted of 153 males and 105 females. In the subjects in group 1, the Tanner pubertal stage 2 was 14.1 +/- 1.5 years in males and 12.6 +/- 1.6 years in females; the bone age at this stage was 11. 9 +/- 1.5 years in males and 10.6 +/- 1.5 years in females; and the height SDS was -2.1 +/- 0.9 in males and -2.4 +/- 0.9 in females. The total height gained during puberty was 22.4 +/- 7.9 cm in males and 17.4 +/- 6.3 cm in females; the percentage of adult height gained during puberty was 13.3% +/- 4.6% in males and 11.3% +/- 4.0% in females; the near-adult height SDS was -1.3 +/- 1.0 in males and -1.6 +/- 0.9 in females; and the target adult height SDS was -0.4 +/- 0.8 in males and -0.5 +/- 0.7 in females. The growth characteristics in the subjects in group 2 were of similar magnitude. In both groups, there was a significant negative correlation between age at the onset of Tanner stage 2 and both the total height gained during puberty and the percentage of adult height gained. CONCLUSIONS: The growth characteristics of these subjects were similar to those reported in normal children and in previous reports of the pubertal growth in smaller populations of children with GHD. The height SDS increased in these subjects during puberty, but the target adult height SDS was not attained. This is a strong argument for early diagnosis and treatment in children with GHD to optimize prepubertal growth.

The role of serial sampling in the diagnosis of growth hormone deficiency.

We analyzed 12-hour serial sampling of growth hormone (GH) levels in two cohorts of short children: 96 children referred to a university endocrine clinic or studied on a research protocol and 825 children in the National Cooperative Growth Study of children treated with exogenous GH. The mean 12-hour GH levels correlated with growth velocity in 60 children with normal height and growth velocity in the university study, and this correlation was stronger in the boys. The testosterone levels also correlated with growth velocity and mean 12-hour GH levels in the boys. The mean 12-hour GH levels were lower in a group of 36 children with idiopathic short stature than in the control subjects, as were the peak GH levels within 1 hour after the onset of sleep and the insulin-like growth factor I levels. In the National Cooperative Growth Study cohort, pooled 12-hour GH levels were lower in the group with idiopathic GH deficiency (n = 300) than in the group with idiopathic short stature (n = 525), but the difference was not significant. The duration of GH treatment was the most significant predictor of change in the height SD score in both groups. Indices of spontaneous secretion of GH were not predictive of the response to GH treatment, nor were the results of provocative GH testing, the responses to GH treatment being similar in both groups over time. We conclude that the results of GH testing must be interpreted for each patient and that several testing modalities may be helpful in finding GH insufficiency that originates at various levels of the somatotropic axis.

Current dosing of growth hormone in children with growth hormone deficiency: how physiologic?

The current doses of recombinant growth hormone (rGH) are two to three times those used in the pituitary growth hormone era. These rGH doses (0.025 to 0.043 mg/kg/d) are similar to or moderately greater than the physiologic requirements. Growth velocity and height gains have been shown to be greater with 0.05 mg/kg/d of rGH than with 0.025 mg/kg/d. Larger doses of GH and early initiation of treatment result in greater heights at the onset of puberty and greater adult heights. Earlier onset of puberty and more rapid maturation, as indicated by bone age, were not observed in children who were given 0.18 to 0.3 mg/kg/wk of rGH. The frequency of adverse events is very low, but diligent surveillance of all children who are treated with rGH is essential.

Leukemia in children treated with growth hormone.

An association between treatment with growth hormone (GH) and the development of leukemia was described in 1988. This perceived association is best explained by the fact that there are more children with GH deficiency (GHD) with risk factors predisposing them to leukemia than in the general population. These factors include previous cancers and their treatment, as well as co-existing conditions such as Down, Bloom and Fanconi syndromes. Examination of large databases of GH-treated individuals shows that GH-treated patients without these risk factors do not have an increased incidence of leukemia.

A risk-benefit assessment of growth hormone use in children.

Growth hormone prepared by recombinant DNA technology (somatropin) has been commercially available for over 11 years. More than 38,000 children have been treated with different growth hormone products. While the best response to treatment occurs in children with severe growth hormone deficiency, therapy with growth hormone will increase the rate of statural growth in children with short stature of many different aetiologies. There are few studies of the effect of growth hormone treatment of final adult height, and the magnitude of this effect is harder to gauge, particularly in children with idiopathic short stature. Other benefits of growth hormone treatment in children include improvement in psychosocial functioning and physiological parameters, such as bone mineral density. Adverse effects associated with growth hormone treatment have been relatively uncommon. Most of the safety data on growth hormone have come from large postmarketing databases maintained by 2 pharmaceutical companies. The adverse event profile reported in children treated with growth hormone is different from that found in adults. Peripheral oedema and carpal tunnel syndrome, which are common in adults treated with growth hormone and frequently result in treatment discontinuation, are rare in children. Intracranial hypertension is rare, but can occur in children with growth hormone deficiency, Ullrich-Turner syndrome or renal insufficiency during the first 8 to 12 weeks after the start of growth hormone treatment; it has seldom been reported in adults with growth hormone deficiency. Children with growth hormone deficiency, Ullrich-Turner syndrome or renal insufficiency are prone to develop slipped capital femoral epiphyses both before and during growth hormone treatment. Therefore, limping and complaints of hip or knee pain should be carefully investigated.

Risk of leukemia in children treated with human growth hormone: review and reanalysis.

BACKGROUND: Data have suggested that any increased incidence of leukemia in growth-hormone (GH)-treated patients was limited to those with known risk factors for leukemia. However, previous studies may have overestimated the numbers of patient-years of risk by not excluding data from "positive-risk-factor" patients. This risk was reanalyzed by using data on children in the National Cooperative Growth Study (NCGS), with correction for this possible confounding factor. METHODS: The risk of leukemia in GH-treated patients without known risk factors was determined by using patient-years of GH therapy and patient-years since first exposure to GH therapy and the values obtained were compared with values from the Surveillance, Epidemiology, and End Results program of the National Cancer Institute. RESULTS: Three cases of leukemia in patients without known risk factors were found in the NCGS database; 3.42 cases would be expected in the 119,846 patient-years in the analysis using time since GH exposure. Two of these cases of leukemia occurred during GH therapy (67,773 patient-years); 2.13 cases would be expected. CONCLUSION: Excluding data on patients with known risk factors for leukemia provides a more accurate estimate of the risks in GH-treated patients. The incidence of leukemia in these patients is comparable to that in the general population of age-matched children.

National Cooperative Growth Study substudy VIII: a new look at the natural history of short stature.

National Cooperative Growth Study (NCGS) substudy VIII was designed to determine the characteristics of children who are referred to pediatric endocrinologists for evaluation of short stature but are not treated with growth hormone (GH). No specific course of treatment is required to enter the study. Data on the subjects' characteristics at enrollment, the diagnostic procedures used by the investigators, and the occurrences of various medical conditions and intercurrent illnesses will be collected prospectively and will be compared with the corresponding data on children in the NCGS who are treated with GH.

Growth hormone treatment in growth retarded children with end stage renal failure: effect on free/dissociable IGF-I levels.

Growth retardation in children with endstage renal disease (ESRD) is associated with normal to slightly low concentrations of insulin-like growth factor (IGF)-I and increased concentrations of IGF-binding proteins (IGFBPs) in serum. Consequently, IGF-I bioactivity is reduced in serum from uremic patients presumably due to a decrease in the concentration of free IGF-I. Improvement of linear growth with growth hormone (GH) treatment of uremic children is thought to be due to increased IGF-I/IGFBP ratio, thus resulting in increased free IGF-I levels during treatment. The purpose of the present study was to determine whether free/dissociable IGF-I levels are in fact low in uremic children and whether increased growth velocity during GH treatment is associated with an increase in the free IGF-I concentration. Serum total and free/dissociable IGF-I concentrations were measured in 5 children with ESRD before and during treatment with GH, and in control children matched for age, pubertal status, and body mass index. Height velocity increased from 3.7 +/- 1.0 cm/yr to 6.5 +/- 1.2 cm/yr with an increment in height SDS at the end of the first year of GH treatment. Free/dissociable IGF-I concentrations tended to be lower in uremic children compared to control children (3.0 +/- 0.3 vs 7.3 +/- 2.1 micrograms/l, respectively). During GH treatment, free/dissociable IGF-I levels increased significantly to 8.5 +/- 1.0 micrograms/l at 3 months and 6.9 +/- 1.4 micrograms/l at 6-24 months, p < 0.05 compared to pretreatment. Total IGF-I levels were 243 +/- 18 micrograms/l in children with ESRD before treatment and these values also increased during GH treatment (740 +/- 114 micrograms/l at 3 months and 442 +/- 44 micrograms/l at 6-24 months, p < 0.05, compared to pretreatment). Total IGF-I concentration in the control group was 439 +/- 114 micrograms/l. These results support the hypothesis that growth retardation in children with chronic renal failure is associated with a reduction in the concentration of free, biologically available IGF-I, and that increased growth velocity during GH treatment of these children is associated with restoration of free IGF-I concentrations.

Adult height in growth hormone (GH)-deficient children treated with biosynthetic GH. The Genentech Growth Study Group.

Near-adult height (AH) was determined in 121 children (72 males and 49 females) with GH deficiency (GHD) who were prepubertal when they began treatment with recombinant DNA-derived preparations of human GH. AH as a SD score was -0.7 +/- 1.2 (mean +/- SD), significantly greater than the pretreatment height SD score (-3.1 +/- 1.2), the predicted AH SD score (-2.2 +/- 1.2; Bayley-Pinneau method), and the height SD score at the start of puberty (-1.9 +/- 1.3). In contrast to studies of GH treatment outcome, which used pituitary-derived GH (pit-GH) in lower doses, we found that males did not have a higher AH SD score than females, spontaneous puberty did not diminish AH, and AH was significantly greater than that predicted at the start of GH treatment. In a multiple regression equation, the statistically significant variables (all P < 0.0001) related to AH (r2 = 0.70) were the following: duration of treatment with GH, sex (males were taller than females, as expected for the normal population), age (younger children had a greater AH) and height at the start of GH, and growth rate during first year of GH. For the AH SD score (r2 = 0.47), pretreatment predicted AH, duration of GH, and bone age delay were significant (P < 0.0002) explanatory variables. Bone age delay (chronological age-bone age) had a negative impact on the AH SD score. Target height, etiology of GHD, previous treatment with pituitary GH, and the presence or absence of spontaneous puberty did not significantly improve the prediction of AH. Early diagnosis of GHD and continuous treatment with larger doses of GH to near AH should improve the outcome in children with short stature due to GHD.