Age related IGF-I changes and IGF-I generation in thalassemia major

We measured serum concentrations of insulin like growth factor-I (IGF-I) in 20 thalassemic males with short stature (height SDS <-2) and/or slow growth velocity (GV <-1 SD) throughout their childhood and adolescence, compared these data with normal reference data validated in our lab, and evaluated their growth hormone secretion in response to clonidine and glucagon stimulation. We also performed IGF-I generation test on 26 patients with beta thalassemia major (BTM) before and after blood transfusion to evaluate the effect of increased hemoglobin (Hb) on IGF-I and its response to GH. We obtained the following results. 1) No statistical difference in age, HSDS, target height SDS or bone age was observed between BTM patients with growth hormone deficiency (GHD) compared to those with normal GH secretion (GHS). 2) The age-related levels in serum total IGF-I in thalassemic males were significantly decreased from early childhood to 18 years of age compared to normal subjects. Thalassemic males with GHD did not show any significant peak of IGF-I levels until 18 years of age, whereas thalassemic males with normal GH response to provocation (GHS) achieved a significant peak level of IGF-I that was attenuated and late compared to normal males. The basal serum IGF-I concentrations at different ages did not differ between the GHD and GHS groups until the age of 12 years. After 12 years of age, IGF-I levels were significantly higher in thalassemic children with GHS. A significant increase in the circulating basal IGF-I concentrations from 53 +/-35 ug/l to 82.6 +/- 39 ug/L was achieved with increasing Hb concentration after blood transfusion. The serum total IGF-I levels increased significantly with the administration of human growth hormone (hGH) for 4 days, both before and after blood transfusion. The peak IGF-I response to GH injections did not differ before compared to after blood transfusion. The percent increment of IGF-I levels generated after GH injections was higher in thalassemic children with GHD as compared to those with GHS both before and after blood transfusion. In conclusion, our results showed that agerelated serum IGF-I concentrations were significantly lower in short thalassemic patients, with and without GHD, during childhood and adolescence, compared to normal standards. Correction of anemia significantly increased serum concentration of IGF-I but does not affect the increase of IGF-I in response to GH stimulation.     

The importance of growth hormone replacement therapy for bone mass in young adults with growth hormone deficiency

Growth hormone (GH) plays an important role in longitudinal bone growth in childhood, accrual of peak bone mass, and bone preservation in adults. GH deficiency (GHD) is associated with reduced bone turnover and decreased bone mineral density (BMD), especially in patients with childhood-onset GHD. GH replacement therapy stimulates bone remodeling and causes an initial decrease in BMD due to bone resorption and expansion of the remodeling space. This is followed by increased bone formation and a significant increase in BMD that continues with prolonged GH therapy. The effect appears to be dose-dependent. GH dose should be individualized based on factors such as age, oral estrogen therapy, and IGF-I levels. Young GH-deficient adults with low BMD measurements by dual-energy X-ray (DEXA) scan should be considered for GH replacement therapy to reduce future fracture risk.     

Growth and endocrine disorders secondary to cranial irradiation

External cranial radiation for the treatment of malignant diseases has become a frequent cause of growth hormone deficiency (GHD). The timing of occurrence and the frequency of GHD were related to the hypothalamic-pituitary radiation dose. Frequency varied from 50% in leukemia (2400 cGy) to 75% in face and neck tumors or medulloblastoma (2500-4500 cGy) and up to 100% in optic glioma (greater than 4500 cGy). The significantly more severe growth deficit in patients with GHD given higher radiation doses suggests different levels of residual GH secretion according to radiation dosage. The minimum harmful radiation dose is probably close to 1800-2000 cGy. Our data show that stimulation tests remain a useful means of defining GHD and predicting growth. A fair agreement between GH secretion and growth was found in most cases, regardless of the radiation dose. The only exception was a group of leukemic children (2400 cGy) who achieved normal prepubertal growth despite a low GH response. The 24-h spontaneous plasma GH profiles and IGF-I measurements may add information if growth is retarded despite a normal GH response. We showed that growth retardation occurring after some schedules of total body irradiation was not due to GH deficiency but rather to radiation-induced skeletal lesions. Early or true precocious puberty, generally associated with GHD, was another cause of height loss. As the role of GH deficiency in the final height reduction was demonstrated in all groups of patients after cranial radiation, we suggest that hGH therapy should be considered in any child with proven GH deficiency and significant growth retardation after such radiation.     

Reevaluation of growth hormone deficiency during and after growth hormone (GH) treatment: diagnostic value of GH tests and IGF-I and IGFBP-3 measurements

Retesting of patients with growth hormone (GH) deficiency (GHD), especially those with idiopathic GHD, has yielded normalization of the results in several studies. The aim of this study was to reevaluate patients diagnosed as GHD at completion or reconfirm the diagnosis before completion of GH treatment by retesting with provocative tests, and to evaluate the value of IGF-I and IGFBP-3 levels in the diagnosis of GHD. Fifty (33 M, 17 F) patients with GHD (peak GH level <0.46 pmol/l (10 ng/ml]) in two pharmacological tests were retested and IGF-I and IGFBP-3 levels measured. The age of the patients at retest was 15.2+/-5.0 yr. Thirteen of 50 patients (26%) normalized their GH secretion. According to the initial diagnosis, 69% of those with partial GHD (peak GH level 0.32-0.46 pmol/l [7-10 ng/ml]), 43% with isolated GHD, 33% idiopathic and 11% of those with complete GHD (peak GH level <0.32 pmol/l [7 ng/ml]) normalized their GH level at retesting. None of the patients with multiple hormone deficiency and none with small pituitary on MRI normalized GH levels at retest. The sensitivities of IGF-I and of IGFBP-3 were 70% and 67%, respectively, and the specificities were 100%, when peak GH cutoff is taken as 0.46 pmol/l (10 ng/ml) for the diagnosis of GHD. The sensitivities of IGF-I and IGFBP-3 increased to 76.5% and 73.5% when the cutoff level for GHD is taken as 0.32 pmol/l (7 ng/ml). Those patients who normalized their GH levels at retest showed a satisfactory height velocity when GH therapy was discontinued. In conclusion, reevaluation of GH status may also be undertaken while patients are still on treatment as well as at completion of treatment, especially in patients with idiopathic, partial and isolated GHD, by retesting and by IGF-I and IGFBP-3 measurements. Lowering the cutoff level of GH peak at pharmacological tests to 0.32 pmol/l (7 ng/ml) will lower the number of false positive results in the diagnosis of GHD.     

Insulin-like growth factor-I (IGF-I) and IGF-binding protein-3 (IGFBP-3) concentrations compared to stimulated growth hormone (GH) in the evaluation of children treated for malignancy

OBJECTIVE: The aim of this investigation was to evaluate the utility of IGF-I and IGFBP-3 determinations in screening for GH deficiency (GHD) in children previously submitted to treatment for childhood malignancy. PATIENTS AND METHODS: We compared the GH responses to two pharmacological tests (arginine and levo-dopa) with the IGF-I and IGFBP-3 levels in 48 patients (29 boys) who had undergone bone marrow transplantation (BMT) (36 patients) or treatment for a solid cranial tumor (12 patients). RESULTS: 22 patients (45.8%) showed GHD (i.e. GH peak < 8 ng/ml in both tests), and only three (13.6%) of the GHD patients had concomitant low IGF-I levels (i.e. -2 SD below the normal mean) and only one (4.5%) an abnormal IGFBP-3 value (i.e. -2 SD below the normal mean). Among the 26 children with normal GH secretion, 21 (80.8%) also showed normal IGF-I and IGFBP-3 levels, three (11.5%) had a concomitant low IGF-I value and two (7.7%) a concomitant low IGFBP-3 value. A significant correlation was found between GH secretion and age at diagnosis (r = 0.26, P < 0.05), and between IGF-I and IGFBP-3 (r = 0.52, P < 0.0001), but not between GH and IGF-I or IGFBP-3. Comparing the growth pattern of these patients from diagnosis to the first year after therapy or BMT, we found that while individual height changes did not correlate with the GH peak, a significant correlation was found between height SDS decrease and IGF-I (r = 0.31, P < 0.05) or IGFBP-3 SDS (r = 0.37, P < 0.01). CONCLUSION: Our results indicate that the cut-off of -2 SD for IGF-I and IGFBP-3 was insensitive in screening for GHD. A normal value did not exclude a subnormal GH response to provocative tests and therefore although IGF-I and IGFBP-3 levels may be indicators of the growth pattern, they cannot be used alone as a tool for identifying GHD children after treatment for childhood malignancy.     

Auxological, clinical and MRI findings in Taiwanese children with growth hormone deficiency

Growth hormone deficiency (GHD) may be classified into partial isolated GHD (partial IGHD), severe IGHD or multiple pituitary hormone deficiency (MPHD) by the severity of GHD or associated with deficiency of one or more other anterior pituitary hormones during provocative tests. Morphological alterations on magnetic resonance imaging (MRI) in patients with GHD include pituitary hypoplasia, absence or interruption of pituitary stalk, and absence or ectopic posterior lobe. This study investigated the auxological, clinical severity, and anatomical characteristics of the pituitary hypothalamic region by MRI and correlated their relationships. We evaluated these parameters in 45 Taiwanese children with GHD (31 males and 14 females), aged from 3.13 to 17.91 years (10.5+/-2.5), who were divided into diagnostic subgroups of partial IGHD (18 patients), severe IGHD (13 patients), and MPHD (14 patients). We found that BA-CA, peak GH, IGF-I, IGF-I SDS, and height SDS were significantly different among these three groups. The partial IGHD group had significantly higher IGF-I than the MPHD group. There was no significant difference in prematurity, cesarean delivery, birth order, neonatal jaundice, and target height among these three groups. On MRI, patients with MPHD had significantly smaller pituitary height (PHt) SDS (p = 0.0012) and higher frequency of pituitary hypoplasia, pituitary stalk interruption, and ectopic posterior lobe (p = 0.026, 0.008, 0.005, respectively) than the other two groups. Furthermore, PHt SDS was correlated not only with peak GH (r = 0.40, p = 0.0058), but also with basal IGF-I SDS (r = 0.49, p = 0.0007) and body height SDS (r = 0.44, p = 0.025). In conclusion, morphological alterations on MRI of the hypothalamic-pituitary area are correlated with the severity of hypopituitarism. Meticulous evaluation of auxological, clinical and MRI findings can help evaluation of the severity of hypopituitarism and facilitate appropriate treatment in children with GHD.     

GHRH and GH secretagogues: clinical perspectives and safety

The diagnosis and treatment of growth hormone deficiency (GHD), as well as the possibility of counteracting somatopause and age-related changes in body composition, structural functions, and metabolism, prompted interest in potential clinical uses of GH-releasing hormone (GHRH) and GH secretagogues (GHS). GHD often reflects hypothalamic GHRH deficiency and it has been clearly demonstrated that the age-related decline in the function of the GH/IGF-I axis reflects a reduction in hypothalamic function as evidenced by the preservation of the releasable pool of pituitary GH in aged subjects. The effectiveness of recombinant human GH (rhGH) is well established, but it is also recognized that GH replacement does not mimic physiological GH secretion which theoretically would be restored by GHRH and/or GHS. At present, it has been clearly demonstrated that GHRH and/or GHS represent reliable tools for the diagnosis of GHD. On the other hand, neither GHRH nor GHS has been shown to provide effective alternatives to rhGH for the treatment of GHD. Although GHRH and/or GHS represent the most logical approaches for the restoration of the GH/IGF-I axis to a youthful level of activity and for counteracting the somatopause, this hypothesis has never been proven definitively. Conceptually, GHRH replacement would be the most physiological approach and its safety is guaranteed, provided an appropriate dose is used, in order to avoid hyperactivity of the GH/IGF-I axis. However, a long-acting preparation is needed. On the other hand, GHS, e.g., ghrelin analogues, could be considered as a function of their selectivity of action. However, ghrelin has a wide spectrum of endocrine and non-endocrine actions at both central and peripheral levels. Thus, non-selective GHS, although available in orally active forms, could elicit unforeseen side effects. Previous studies with GHRH and/or GHS in aging patients provided encouraging results. However, it still remains to be definitively demonstrated that aged subjects would benefit from chronic treatment with these molecules.     

Usefulness of growth hormone (GH) stimulation tests and IGF-I concentration measurement in GH deficiency diagnosis

The diagnosis of growth hormone (GH) deficiency (GHD) is still problematic for the clinician. There is no gold standard for estimating GH secretion. The aim of this study was to compare the diagnostic usefulness of spontaneous GH secretion test, pharmacological tests with insulin, clonidine, L-dopa, and glucagon, and IGF-I measurement in GHD. We studied 180 prepubertal, short children. Predictive values were calculated for different GH cutoff levels for each diagnostic test. ROC curves were used to estimate the diagnostic usefulness of the tests. The results show that sleep is the strongest stimulatory agent for GH secretion. The estimation of GH secretion after onset of sleep can be used as a screening test in GHD diagnosis. The insulin test has the highest discrimination. A combination of insulin test with another provocative test allows high discrimination and accuracy for standard cut-off GH level. Measurement of IGF-I is characterized by low predictive values. IGF-I level below the mean according to age indicates high probability of GHD. Auxological parameters should be the most important factor in diagnosing GHD.     

Diagnosis of idiopathic growth hormone deficiency: contributions of data on the acid-labile subunit, insulin-like growth factor (IGF)-I and-II, and IGF binding protein-3

The diagnosis of non-organic growth hormone (GH) deficiency (GHD) remains difficult. OBJECTIVE: To evaluate the value of measuring plasma insulin-like growth factor (IGF)-I and -II, IGF binding protein-3 (IGFBP-3) and acid-labile subunit (ALS) as criteria for diagnosing GHD. PATIENTS: 120 prepubertal patients having at least one of the main auxological criteria defined by the GH Research Society for initiating GH exploration were classified as (1) certain GHD (n = 40), (2) transient GHD (n = 18), (3) idiopathic short stature (n = 27), or (4) extreme short stature (n = 35). RESULTS: All the patients with certain GHD had low (< or = -2 z-score) plasma concentrations of IGF-I and ALS, but only 35.1% had low IGF-II, and 48.6% had low IGFBP-3. All the patients but three (83.3%) with transient GHD had low IGF-I, but only 44.4% had low ALS, and only one had low IGF-II or IGFBP-3. The data for patients with idiopathic and extreme short stature and normal GH peak were similar to each other and to those for patients with transient GHD, except that IGF-I was less frequently low (49.2%, p <0.05). CONCLUSIONS: All the patients with certain GHD had both IGF-I and ALS z-scores < or = -2, unlike those with transient GHD, and idiopathic or extreme short stature. Almost all the patients with short stature and normal GH peak had normal serum IGF-II and IGFBP-3 concentrations.     

Confirming the diagnosis of growth hormone deficiency (GHD) and transitioning the care of patients with childhood-onset GHD

Growth hormone deficiency (GHD) diagnosed in childhood may persist into adult life. After attainment of final height, retesting of the patient's growth hormone-insulin-like growth factor (GH-IGF) axis using the adult GHD diagnostic criteria should be performed after an appropriate interval of 1-3 months off GH therapy. At the time of retesting, other pituitary hormones and serum IGF-I levels should also be measured. The opportunity should be taken to assess body composition, bone mineral density, and fasting lipid and insulin levels. Patients with severe, long-standing, multiple pituitary hormone deficiency, genetic defects, or severe organic GHD can be excluded from GH retesting. When the diagnosis of adult GHD is established, continuation of GH therapy can be recommended unless there is a known risk of diabetes mellitus or malignancy. The patient's transition to GH replacement in adulthood should be arranged as a close collaboration between the pediatric and adult endocrinologists, who should discuss the reinitiation of treatment with the patient.     

Administration of arginine plus growth hormone releasing hormone to evaluate growth hormone (GH) secretory status in children with GH deficiency

BACKGROUND: Diagnosis of growth hormone deficiency (GHD) in childhood is usually based on growth hormone (GH) response to at least two provocative stimuli. The aim of this study was to determine whether sequential administration of arginine (Arg) plus GH releasing hormone (GHRH) could be a useful tool in evaluating GHD in children. METHODS: Thirty patients with short stature (mean age 9.0 years) with decreased growth rate were tested for GHD with Arg and the insulin tolerance test (ITT). Patients with confirmed GHD (peak GH <8 ng/ml) were subsequently tested with Arg + GHRH. RESULTS: Maximum GH stimulation for Arg and ITT was 6.3 (1.0-7.8) and 6.7 (0.5-7.7) ng/ml, respectively. Peak GH for the Arg + GHRH test was 36.3 (4.3-84.5) ng/ml and significantly different from the other provocative tests. Peak GH values for the three tests were not significantly correlated between tests or with clinical parameters. There were no significant differences in Arg + GHRH results between children with or without abnormal hypothalamic-pituitary MRI scans. CONCLUSION: Arg + GHRH gave higher GH levels than insulin or Arg alone. Because of the different causes of childhood GHD (hypothalamic and/or pituitary dysfunction), the Arg + GHRH test is unsuitable .for evaluating GHD and deciding whether GH replacement therapy is indicated.     

Efficacy of insulin-like growth factor I levels in predicting the response to provocative growth hormone testing

Clinical testing of growth hormone (GH) sufficiency is a controversial area in endocrinology. Due to the episodic nature of endogenous GH secretion, diagnosis of GH deficiency has been defined as a failure to achieve normal GH levels in response to at least two stimuli. This testing is associated with significant patient morbidity and cost. We analyzed our experience over a 4-y period to determine whether clinical or biochemical variables could be used to predict the results of a specific GH testing procedure. Of 180 cases analyzed (67% male, mean age 8.89 +/- 4.39 y, range neonate-16 y), eight cases had incomplete GH testing results. Of the remaining 172, 19 were GH deficient (GH level less than 7 ng/mL). Younger age, higher body mass index and a greater degree of bone age delay were characteristic of the GH-deficient population; however, none of these variables alone was of diagnostic utility. Serum IGF-I level was below the normal range for 81% of the GH deficient and 47% of the GH-sufficient children; and was the only single variable that provided a reasonable between-group distinction. Discriminant analysis resulted in development of a new variable, based on IGF-I z scores, chronologic age, degree of bone age delay, and body mass index, which would have allowed exclusion of GH deficiency without provocative testing for 58% of the GH sufficient population, whereas permitting the diagnosis of GH deficiency for all GH-deficient subjects. Our data are dependent on the IGF-I assay method and the clinical definition for GH deficiency; therefore, the calculated predictive values are not applicable to all clinical populations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Growth hormone deficiency in a patient with lysinuric protein intolerance

Introduction Lysinuric protein intolerance (LPI; MIM 222700) is a rare, autosomal recessive metabolic disorder caused by mutations in the SLC7A7 gene, which encodes the light chain of the cationic amino acids (CAA) transporter y+. The clinical presentation of LPI includes gastrointestinal symptoms, failure to thrive, episodes of coma, hepatosplenomegaly and osteporosis. However, other findings have also been reported, and these suggest a multisystem involvement.Discussion We report a girl with confirmed LPI who presented with severe short stature that was unresponsive to adequate LPI treatment. The girl was found to have a classic growth hormone deficiency (GHD) and responded well to growth hormone (GH) replacement therapy.Conclusion While it is not known whether the mechanisms involved in the GHD of our patient are related to LPI, this case suggests that GH/IGF-I axis should be investigated in LPI children with persistent growth failure.     

Growth hormone deficiency and the transition from pediatric to adult care

ObjectiveTo discuss the approach to patients diagnosed with growth hormone deficiency (GHD) in childhood during the transition period from puberty to adulthood, focusing on the following: (1) physiology; (2) effects of recombinant human GH (rhGH) interruption/reinstitution after adult height achievement; (3) re-evaluation of somatrotropic axis; (4) management of rhGH reinstitution, when necessary.Source of dataNarrative review of the literature published at PubMed/MEDLINE until September 2020 including original and review articles, systematic reviews and meta-analyses.Synthesis of dataGrowth hormone is crucial for the attainment of normal growth and for adequate somatic development, which does not end concomitantly with linear growth. Retesting adolescents who already meet the criteria that predict adult GHD with high specificity is not necessary. Patients with isolated GHD have a high likelihood of normal response to GH testing after puberty. Adolescents with confirmed GHD upon retesting should restart rhGH replacement and be monitored according to IGF-I levels, clinical parameters, and complementary exams.ConclusionPatients with isolated idiopathic GHD in childhood are a special group who must be reevaluated for GHD as many of them have normal GH provocative tests upon retesting after puberty. Patients who confirm the persistence of GHD in the transition period should maintain rhGH replacement in order to reach an ideal peak bone mass, satisfactory body composition, lipid and glucose profiles, and quality of life.     

Somatostatin infusion withdrawal in the diagnosis of childhood growth hormone deficiency

OBJECTIVE: An evaluation of growth hormone (GH) testing for GH deficiency (GHD) in childhood is confounded by the lack of a world-wide consensus on the definition of GHD. Although a single GH test remains the most powerful biochemical tool in the evaluation of a child with growth failure, the test remains far from ideal. Withdrawal of somatostatin (SS) infusion is followed by a rebound rise of GH thought to be mediated by endogenous GH-releasing hormone (GHRH) function. This study was designed to compare the GH response to 90 min SS infusion in children with normal GH secretion versus children with GH deficiency. METHODS: Ten children with GHD and 10 healthy controls (NC) have been evaluated for GH response to somatostatin infusion withdrawal (SSIW) and compared with response of two provocative tests, glucagon plus propranolol test and L-Dopa test. All children received constant infusion of somatostatin for 90 min (3 microg/kg per h, Stilamin, Serono, Aubonne, Switzerland). In order to determine GH, blood samples were obtained 90 min before the SS infusion and 0, 15, 30, 45, 60, 75, and 90 min after the cessation of infusion. RESULTS: Growth hormone peak levels with SSIW were significantly lower in GH deficient children than in healthy children (2.5 +/- 1.2 ng/dL, vs 21.9 +/- 5.3 ng/dL, respectively, P < 0.01). No adverse effects were observed during or after somatostatin infusion. CONCLUSION: In the present study, SSIW elicited a significant GH rise in healthy children but not in children with GH deficiency. Although further controlled studies using more data are necessary to expand these findings, the results suggested that children with GH deficiency can be reliably discriminated from healthy children by SSIW.     

Evaluation of insulin-like growth factor (IGF)-I and IGF binding protein-3 generation test in short stature

BACKGROUND: Differentiation between growth hormone deficiency (GHD) and idiopathic short stature (ISS) based on GH tests and basal IGF-I and IGFBP-3 levels may be difficult. The aim of this study was to evaluate the role of pharmacological GH tests, IGF-I and IGFBP-3 generation test and height velocity off-treatment in the evaluation of GHD and ISS. METHODS: Thirty-three (17 M, 16 F) prepubertal short (height SDS < -2) children were divided into two groups: Group 1 (n = 19) with peak GH level <10 tg/l (GHD) and Group 2 (n = 14) GH > or =10 microg/l in two sex steroid primed pharmacological GH tests. Having excluded other diagnoses, Group 2 was regarded as having ISS. The generation test was performed concomitantly (0.1 IU/kg GH s.c. for 4 days) with IGF-I and IGFBP-3 measured on the 4th day in both groups. The patients were followed for a year for height velocity (HV). RESULTS: Group 1 and 2 had comparable height SDS (-2.3 +/- 0.4 and -2.3 +/- 0.3) at comparable ages (7.8 +/- 2.8 and 7.0 +/- 2.7 yr). Although the deltaIGF-I response was low (<2.0 nmol/l 115 ng/ ml]) in seven (37%) children in the GHD group, all GHD patients with low height velocity had adequate (> or =14 nmol/I [400 ng/ml]) deltaIGFBP-3 response. deltaIGFBP-3 in the generation test showed a negative correlation with HV (p = 0.021, r = -0.570) and also with basal IGFBP-3 (p <0.001, r = -0.743) in the GHD group. In the ISS group, deltaIGF-I and deltaIGFBP-3 responses were low in 31% and 7%, respectively, and the correlation between basal IGF-I, IGFBP-3 and HV and between delta values in the generation test were significantly positive, pointing to a difference in the growth response of these children. CONCLUSION: In the GHD group, based on pharmacological tests, an adequate deltaIGFBP-3 response in the generation test predicts poor height velocity at follow up and thus strengthens the diagnosis of true GHD.     

The catecholamine response to hypoglycemia in children with isolated growth hormone deficiency syndromes and multiple pituitary hormone defects

We examined the catecholamine response to insulin-induced hypoglycemia in 46 short children evaluated for growth hormone (GH) deficiency by both pharmacologic stimulation and integrated concentration of GH. Twelve patients had quantitatively normal GH secretion by both pharmacologic stimulation and integrated concentration of GH (GHNORM). Twenty-two patients had normal GH to pharmacologic stimulation but subnormal integrated concentration of GH (GHND). Twelve patients had GH deficiency by both tests (GHD): six had isolated GH deficiency (GHD type 1) and six had multiple hormone deficiencies (GHD type 2). There was no significant difference between the peak epinephrine, norepinephrine, and cortisol responses of GH-NORM, GHND, and GHD type 1 patients. The mean peak epinephrine response of GHD type 2 patients was significantly lower (564 +/- 561 pg/ml, p less than 0.03) compared to the other patient groups. There was no significant difference between the peak norepinephrine levels between GHD type 2 patients and the remaining groups. There was no correlation between decrease in blood glucose and either increase in growth hormone, catecholamine, or cortisol concentrations. There was a significant correlation between log peak epinephrine and peak cortisol response (r = 0.53, p less than 0.0002) of the 46 subjects. Neither the basal nor stimulated catecholamine levels correlated with the integrated concentration of cortisol. We conclude that isolated GH deficiency is not associated with impairment of the catecholamine response to hypoglycemia; impairment of the epinephrine response to hypoglycemia is only associated with multiple pituitary hormone deficiencies; in children, the degree of glucose lowering is not correlated with the magnitude of peak GH, catecholamine, or cortisol responses.     

Children with craniopharyngioma. Early growth failure and rapid postoperative weight gain

Pre- and postoperative growth was analyzed in 22 children with craniopharyngioma. In 19 children a growth failure preceded the diagnosis by a mean of 4 years. Six children were obese preoperatively. During the first 3 postoperative months relative weight increased greater than 10% in 14/21 children (there was one surgical death). One year after surgery 13/21 were obese. Neither the size of the tumor nor the mode of surgery was decisive in the development of the obesity. Serum insulin and insulin-like growth factor I (IGF-I) were assessed in four children with growth hormone deficiency (GHD) who, after surgery for craniopharyngioma, were growing normally without GH substitution. One of them was normal in weight and had normal insulin and IGF-I levels; the others were obese and had supranormal insulin and subnormal IGF-I levels. One of the four and two other children with unsubstituted GHD reached final height SDS -0.8, -2.0 and -2.4. One child with normal postoperative GH response reached final height SDS -0.7. Final height SDS greater than or equal to -2.5 was gained with GH substitution by 6/11 children. It was greater than 2.0 SD below the height SDS expected from the heights of the parents in 7/11. An adequate monitoring of children's growth would lead to earlier diagnosis and probably better outcome.     

Effects of recombinant human insulin-like growth factor I administration in adults with growth hormone deficiency

Recombinant human insulin-like growth factor I (IGF-I), 40 μg/kg/body weight, was administered subcutaneously at 08.00 hours to six adult patients with growth hormone deficiency (GHD). The mean maximal IGF-I concentrations were found 2–6 hours after injection. Concentrations then gradually declined, though mean values were still above basal 24 hours after the injection. Only one patient maintained IGF-I levels above the lower normal range throughout 24 hours. There was a significant decrease in mean IGF-II concentrations when measured 4 and 24 hours after injection of IGF-I. The diurnal variations of insulin and IGF binding protein-1 were preserved. There were no side-effects, and blood glucose remained normal. These results show that in patients with low IGF-I levels resulting from GHD, it is necessary to administer IGF-I at intervals of less than 24 hours to obtain IGF-I levels that are within the normal range.