Plasma growth hormone response to synthetic GH-RH1-44 in 52 children and adults with growth hormone deficiency of various etiologies

52 patients (42 children and 10 adults) with growth hormone deficiency (GHD), grouped into four diagnostic categories, and 6 children with constitutional short stature who served as controls were tested for plasma GH response to synthetic GH-RH1-44 given in an intravenous bolus. The response was classified into three degrees according to the magnitude of the maximal rise: Good, greater than 9 ng/ml; Partial, 3.1-9.0 ng/ml; None, less than or equal to 3 ng/ml. Among the GHD patients the highest response was observed in patients with partial growth hormone deficiency (PGHD), and 60% of the children with isolated GH deficiency (IGHD) showed an increase in plasma GH levels. Nevertheless, the response of the GHD patients was lower than that in the control group. In the children and adolescents with PGHD and IGHD the response was not age related. Among those with multiple pituitary hormone deficiencies-idiopathic (MPHD-ID) there was no response in the adolescents although a hypothalamic disorder had been documented by other tests. Among those with MPHD-organic (MPHD-ORG) the GH-RH stimulated GH secretion in the patients with glioma, who had received only irradiation treatment, and in the youngest of the patients with craniopharyngioma. Of the 10 young adults tested none showed a good response. It is concluded that GH-RH is useful in differentiating between GH deficiency of hypothalamic origin and that of pituitary origin, and in selecting those patients who might benefit from long-term treatment with GH-RH in the future.     

Growth hormone response to growth hormone releasing hormone 1-40 in Turner's syndrome

The response of growth hormone (GH) to acute administration of GH-releasing hormone 1-40 (GHRH) was evaluated in 12 patients with Turner's syndrome and in 12 prepubertal or early pubertal girls. In 7 of 12 patients GHRH induced a definite increase (greater than 10 ng/ml) of plasma GH levels. In 5 patients there was a poor GH rise after GHRH administration (less than 10 ng/ml). Overall, the mean GH response of patients was significantly lower than that of normal girls. Five out of 7 patients with a 45 X,O karyotype had a reduced GH rise after GHRH, while all patients with non X,O karyotype (mosaicism and/or 46 X,iX) had a normal GH response to GHRH. Although the cause of short stature in patients with Turner's syndrome is most likely multifactorial, a reduced pituitary GH reserve, as documented by the reduced GH response to GHRH in some of our patients, may contribute to the growth impairment in this disorder.     

Evaluation of the growth-hormone-releasing hormone test in short normal and growth-hormone-deficient children

Growth-hormone-releasing hormone (GHRH) tests were performed once [GHRH(1-29)NH2, 1 microgram/kg] or on 2 consecutive days [GHRH(1-44)NH2, 1 and 2 microgram/kg administered in random order] in 27 children with idiopathic, isolated growth hormone (GH)-deficiency and in 49 short normal children, all clinically prepubertal. No differences in GH release were found between the tests performed on the 1st and 2nd day or according to GHRH dose or sex, both in GH-deficient and control children. 80% of GH-deficient and 87% of control children responded (GH peak greater than 10 ng/ml) to GHRH(1-29)NH2, and 65% of GH-deficient and all control children to GHRH(1-44)NH2. No differences in GH release were found between GH-deficient GHRH responders and control children. 17% of GH-deficient and 10% of control children responded only to one of the two tests performed on 2 consecutive days; the lack of responsiveness was unrelated to GHRH dose and sequence of GHRH administration (1st or 2nd day). The GHRH test does not seem to be a reproducible test for the evaluation of GH release, nor is it useful to differentiate GH-deficient GHRH responders from short normal children.     

Growth response of Egyptian children with idiopathic short stature during four years of growth hormone therapy

BACKGROUND:

Multiple factors affect the growth response to recombinant human growth hormone (rhGH) in children with idiopathic short stature (ISS).

AIM:

To evaluate the growth responses of children with ISS treated with rhGH, aiming to identify the predictors of growth response.

MATERIALS AND METHODS:

We studied 120 cases, 90 males (75%), with a mean age of 13.8±2.7 years and 30 females (25%), with a mean age of 12.3±2.5 years. All patients received rhGH with a standard dose of 20 IU/m²/week. The calculated dose per week was divided into six days and given subcutaneous at night.

RESULTS:

A significant positive trend was detected in the delta changes of all anthropometric data. For the first year, the growth response was positively correlated to CA and BA delay and negatively correlated to height, weight and IGF-1 SDSs. For the second year, the growth response was correlated positively to first year growth velocity, BA, triceps skin fold thickness SDS and deviation from target height, and negatively correlated to weight, IGFBP3 SDS and target height SDS. For the third year, the growth response was positively correlated to five variables namely target height, 2^nd year growth velocity, IGF-1 SDS, weight SDS and triceps skin fold thickness SDS. For the fourth year, growth response was positively correlated to 2^nd and 3^rd year growth velocity, BA, deviation from target height and weight/ height SDS.

CONCLUSION:

Our study showed multiplicity of predictors that is responsible for response in ISS children treated with rhGH, and BA was an important predictor.     

Effects of acute intravenous injection of two growth hormone-releasing hormones (GHRH 1-40 and 1-29) on serum growth hormone and other pituitary hormones in short children with pulsatile growth hormone secretion

We administered two different growth hormone-releasing hormones (GHRH) to 20 short, prepubertal children who had spontaneous secretion of growth hormone (GH), assessed from 24-hour GH secretion profiles (72 sampling periods of 20 min). We compared one i.v. injection of 1 microgram/kg of GHRH 1-40 with that of GHRH 1-29 regarding serum concentrations of GH, prolactin, luteinizing hormone, follicle-stimulating hormone and IGF-I. The children were allocated to two groups without statistical randomization. Both groups were given both peptides, with at least 1 week in between. The first group started with GHRH 1-40, the other with GHRH 1-29. The peptides both induced an increased serum concentration of GH of the same magnitude: mean maximal peak of 89 +/- 12 mU/l after GHRH 1-40 and 94 +/- 10 mU/l after GHRH 1-29 (n.s.). The mean difference in maximum serum GH concentration in each child after injection was 52 +/- 9 mU/l, range 1-153 mU/l. GHRH 1-29 also induced a short-term, small increase in the concentrations of prolactin (p less than 0.05), luteinizing hormone (p less than 0.01) and follicle-stimulating hormone (p less than 0.05). We conclude that the shorter sequence GHRH 1-29, when given in a dose of 1 microgram/kg, gives a rise in serum concentration of GH similar to that after the native form GHRH 1-40.     

Repetitive injections of growth hormone releasing hormone (GHRH1-44) to normal volunteers and patients with growth hormone deficiency

The present study was designed to answer the following three questions: Is there any difference between the growth hormone (GH) response to i.v. injections of GHRH 1-44 by a slowly injecting hormone pump or to a s. s. or rapid i. v. injection by syringe? Do nocturnal injections of GHRH 1-44 i. v. elicit different GH levels than during daytime? Can repetitive administration of GHRH 1-44 in patient with GH deficiency induce a physiological GH pattern and thereby normalize the condition resulting from a hypothalamic defect? A rapid i. v. bolus injection of 50 micrograms GHRH 1-44 by syringe with an injection time of one second elicited in the same subject at the same time of the day a twofold greater response than a slowly injecting (60 seconds) hormone pump. In six male adult volunteers each GHRH i. v. bolus was followed by a GH secretory pulse. The GH response at night (area under the curve and peak plasma GH levels) was significantly greater than at daytime (P less than 0.05) and greater than the GH pulses measured during a spontaneous nocturnal profile (P less than 0.05). Out of six GH deficient young adult patients who had been receiving extractive GH until two years prior to the study, three responded much like the controls, the other three patients-those who lacked any spontaneous nocturnal GH peaks-had markedly lower GH levels after GHRH (P less than 0.05). However, there was a clear-cut GH release after GHRH injection in each patient.(ABSTRACT TRUNCATED AT 250 WORDS)     

Factors influencing the growth hormone response to growth hormone-releasing hormone in children with idiopathic growth hormone deficiency

OBJECTIVE: To evaluate the factors influencing the growth hormone (GH) response to GH-releasing hormone (GHRH) test in idiopathic GH deficiency. METHODS: 28 patients aged 4.9 +/- 0.7 years with certain GH deficiency were given GHRH (2 microg/kg). RESULTS: The GH peak after GHRH was correlated negatively with age at evaluation (r = -0.37, p < 0.05) and body mass index (r = -0.44, p = 0.02), and positively with anterior pituitary height (r = 0.47, p = 0.02), GH peak after non-GHRH stimulation (r = 0.78, p < 0.0001) and spontaneous GH peak (r = 0.82, p = 0.007). It was lower in the patients aged >5 years than in the youngest (p = 0.04), but it was similar in the patients with and without features suggesting a hypothalamic origin. CONCLUSION: The GH response to GHRH test cannot be used to differentiate between hypothalamic and pituitary forms of idiopathic GH deficiency, probably because the GH response decreases after the first 5 years of life, whatever the origin of the deficiency.     

Comparison of growth hormone response to growth hormone-releasing factor 1-44 according to the combined study of sleep secretion with the responses to pharmacologic stimuli

The growth hormone (GH) response to GH-releasing factor (GRF) was studied in 54 severely growth-retarded patients (-2.1 to -6.5 SD) aged from 5 to 20 years (32 males and 22 females), among whom 34 were prepubertal and 20 at early pubertal stages. The patients were also submitted to a standard evaluation of their GH secretion, consisting of at least two classical pharmacologic stimulation (CPS) tests, such as ornithine, arginine and/or insulin, and one study of the GH sleep secretion (SS). The results of the standard evaluation allowed to distinguish 5 groups: (I) endocrinologically normal (n = 26); (II) completely GH deficient (n = 5); (III) partially GH deficient (n = 8); (IV) dissociated GH secretions with normal SS (n = 9), and (V) dissociated GH secretions with low SS (n = 6). The GH responses to GRF were correlated with both responses to CPS and SS. There was a large overlap of the individual responses to GRF between the 5 groups, but the mean responses in groups II, IV and V were significantly lower than in group I. Furthermore, the mean responses of groups IV and V were in the lower range of the normal. It is concluded that the GRF test may be useful to ascertain the diagnosis of functional or partial GH deficiency when the responses to CPS and SS are dissociated.     

Abnormalities of growth hormone release in response to human pancreatic growth hormone releasing factor (GRF (1-44) ) in acromegaly and hypopituitarism.

Human pancreatic growth hormone releasing factor (GRF (1-44)) is the parent molecule of several peptides recently extracted from pancreatic tumours associated with acromegaly. A study was conducted to examine its effects on the release of growth hormone in normal volunteers and in patients with hypopituitarism and acromegaly. GRF (1-44) dose dependently stimulated the release of growth hormone in normal people and produced no appreciable side effect. This response was grossly impaired in patients with hypopituitarism and, although similar to the growth hormone response to hypoglycaemia, was of quicker onset and a more sensitive test of residual growth hormone function. Patients with acromegaly appeared to fall into (a) those with a normal response to GRF, whose growth hormone suppressed significantly with oral glucose, and (b) those who had an exaggerated response to GRF (1-44), whose growth hormone had not suppressed previously after oral glucose. Present methods for testing growth hormone deficiency entail using the insulin stress test, which is time consuming, unpleasant, and sometimes dangerous. A single intravenous injection of GRF now offers the possibility of an easier, safer, and more reliable routine test for growth hormone deficiency. It has the further advantage of being free of side effects and readily performed in outpatients. Hence it seems likely to become the standard test and take the place of the insulin stress test.     

Short-term effect on growth of two doses of GRF 1-44 in children with growth hormone deficiency: comparison with growth induced by methionyl-GH administration

In a double-blind study 12 prepubertal children with idiopathic growth hormone (GH) deficiency were treated with growth hormone releasing factor (GRF) 1-44 in a dosage of 7.5 or 15 micrograms/kg body weight, administered once a day subcutaneously. With 7.5 micrograms/kg the average growth velocity increased from 2.5 to 4.6 cm/year, an insufficient response. With the higher dosage the average growth velocity increased from 2.7 to 7.0 cm/year, a similar increase as observed with GH therapy in subsequent periods. In 3 of the 6 children treated with the higher dose appropriate catch-up growth was observed. The growth response of the lower leg length was not always consistent with the statural growth response.     

Acute effects of clonidine and growth-hormone-releasing hormone on growth hormone secretion in patients with hyperthyroidism

Patients with hyperthyroidism have reduced growth hormone (GH) responses to pharmacological stimuli and reduced spontaneous nocturnal GH secretion. The stimulatory effect of clonidine on GH secretion has been suggested to depend on an enhancement of hypothalamic GH-releasing hormone (GHRH) release. The aim of our study was to evaluate the effects of clonidine and GHRH on GH secretion in patients with hyperthyroidism. Eight hyperthyroid females with recent diagnosis of Graves' disease (age range 20-55 years, body mass index range 19.2-26.2 kg/m2) and 6 healthy female volunteers (age range 22-35 years, body mass index range 19-25 kg/m2) underwent two experimental trials at no less than 7-day intervals: (a) an intravenous infusion of clonidine 150 micrograms in 10 ml of saline, or (b) a bolus intravenous injection of human GHRH (1-29)NH2, 100 micrograms in 1 ml of saline. Hyperthyroid patients showed blunted GH peaks after clonidine (7.1 +/- 1.7 micrograms/l) as compared to normal subjects receiving clonidine (28.5 +/- 4.9 micrograms/l, p less than 0.05). GH peaks after GHRH were also significantly lower in hyperthyroid subjects (8.0 +/- 1.7 micrograms/l) as compared to normal subjects receiving GHRH (27.5 +/- 4.4 micrograms/l, p less than 0.05). No significant differences in the GH values either after clonidine or GHRH were observed in the two groups of subjects examined. Our data demonstrate that the GH responses to clonidine as well as to GHRH in patients with hyperthyroidism are inhibited in a similar fashion with respect to normal subjects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Response to long-term growth hormone therapy in short children with reduced GH bioactivity

BACKGROUND/AIMS: The aim of the present study was to investigate whether short children with normal growth hormone (GH) immunoreactivity, but reduced bioactivity (bioinactive GH) could benefit from rhGH treatment as GH deficient (GHD) patients. Methods: We evaluated 12 pre-pubertal children (8 M, 4 F), with GH deficiency-like phenotype showing normal serum GH peak levels (>10 ng/ml), measured by immunofluorimetric assay (IFMA-GH), in contrast with a reduced GH bioactivity (bio-GH), evaluated using the Nb(2) cells. We also evaluated 15 age-matched GHD pre-pubertal children (11 M, 4 F) with serum GH peak <5 ng/ml. Both groups were treated with rhGH therapy at the dose of 0.23 mg/kg/week s.c. RESULTS: Serum bio-GH/IFMA-GH ratio at peak time for each patient during the provocative test was significantly lower in bioinactive GH than in GHD children (0.29 vs. 2.05, p = 0.00001). Recombinant human GH therapy induced a significant (p < 0.001) increase in growth rate in both groups during the first 2 years. In the third year of treatment, while growth rate in GHD children is maintained, in bioinactive GH patients it decreases remaining, however higher compared to the pre-treatment one. CONCLUSIONS: Short rhGH therapy given to selected bioinactive GH children improve growth rate and might result in greater final adult height.     

Growth hormone response to human pancreatic growth hormone releasing factor in cattle

The effects of a growth hormone releasing factor, human pancreatic growth hormone releasing factor-44 (hpGRF-44), on growth hormone (GH) secretion in calves, heifers and cows were studied. A single intravenous (iv) injection of 0.1, 0.25, 0.5 or 1.0 microgram of synthetic hpGRF-44 per kg of body weight (bw) in calves significantly elevated the circulating GH level within 2-5 min, while no increase in plasma GH was observed in saline injected control calves. The plasma GH level increased proportionally to the log dose of hpGRF-44, and reached a peak at 5-10 min (p less than 0.01). Subcutaneous injection of hpGRF-44 also elevated the plasma GH level, but the peak value at 15 min was 37% of that of iv injection (p less than 0.05). Intravenous injection of 0.25 microgram of hpGRF-44 per kg of bw to female calves, heifers, and cows significantly elevated mean the GH levels from 8.5, 2.3, and 1.6 ng/ml at 0 time to peak values of 97, 26, and 11.6 ng/ml, respectively (p less than 0.01). The plasma GH response and basal level in calves were significantly higher than those of heifers or cows (p less than 0.025). The plasma GH response to hpGRF-44 as well as the basal level decreased with advancing age. The plasma GH response to hpGRF-44 and basal GH in male calves were significantly greater than those in female calves (p less than 0.001). These results indicate that synthetic hpGRF-44 is a potent secretogogue for bovine GH, and suggest its usefulness in the assessment of GH secretion and reserve in cattle.     

Physiological growth hormone secretion in children with short stature and intra-uterine growth retardation

31 prepubertal children with short stature [mean height standard deviation score (SDS) -2.84] and low birth weight (mean -2.82 SDS) were studied. Mean age was 6.0 years and mean height velocity SDS was -0.76. Patients were classified as having either the clinical characteristics of Russell-Silver syndrome (RSS) (4 F, 13 M) or not (4 F, 10 M). All children had an overnight profile of spontaneous growth hormone (GH) secretion. 4 children achieved a maximum GH concentration of less than 20 mU/l. 9 children with RSS secreted only one large GH peak during the night. Most of the non-RSS group had normal GH pulse frequency but 3 boys had a fast-frequency pattern. Abnormal GH secretion may contribute towards growth failure in children with low birth weight/RSS.     

Peptide T bolus normalizes the growth hormone secretion pattern in two children with AIDS

In humans, HIV infection reduces growth hormone (GH) secretion contributing to AIDS wasting. In rats, the HIV envelope protein gp120 alone blocks GH secretion both in vitro and in vivo through GH-releasing hormone receptors. Peptide T, a modified octapeptide derived from gp120, normalizes GH secretion. We now report that an intravenous bolus of peptide T normalizes nocturnal GH secretion in two out of three children with AIDS. These results, coupled with the lack of toxicity of this experimental AIDS therapeutic, justify clinical trials for AIDS wasting and pediatric AIDS. A clinical and basic science update on peptide T appears in Current HIV Research.