UMLS:C0011860 - FACTA Search

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Query: UMLS:C0011860 (type 2 diabetes)
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Several studies report increased growth hormone (GH) responses to provocative stimuli in patients with diabetic retinopathy. We studied GH responses to 1 microgram/kg body wt human pancreatic GH-releasing hormone 1-44 (hpGHRH 1-44) in 33 patients with type I diabetes mellitus, 31 patients with type II diabetes mellitus, and 2 control groups (N = 11 and 8). Based on the results of fundoscopy and fluorescein angiography, the diabetic patients were subdivided into patients without diabetic retinopathy, patients with nonproliferative diabetic retinopathy, and patients with proliferative diabetic retinopathy. Growth hormone responses to hpGHRH 1-44 in diabetic patients with proliferative or nonproliferative retinopathy or without retinopathy were not significantly different regardless of the type of diabetes. Remarkably, GH responses to hpGHRH 1-44 in type I diabetic patients without retinopathy were significantly higher than the matched controls. Our data suggest that diabetic retinopathy in type I and in type II diabetes is not associated with increased GH responsiveness to hpGHRH 1-44, whereas in type I diabetes mellitus without diabetic retinopathy, a GH hyperresponsiveness to hpGHRH seems to occur.
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PMID:No evidence for increased growth hormone responses to growth hormone-releasing hormone in patients with diabetic retinopathy. 310 Mar 67

Growth hormone levels following an intravenous bolus injection of 1 micrograms/kg body weight growth hormone releasing hormone were measured in 21 non-obese and 26 obese patients with Type 2 (non-insulin-dependent) diabetes mellitus and in 13 control subjects. Growth hormone responses in non-obese Type 2 diabetic patients were not statistically different from control subjects. However, obese Type 2 diabetic patients had significantly decreased growth hormone responses to growth hormone releasing hormone when compared with non-obese Type 2 diabetic patients (p less than 0.02). In 9 Type 2 diabetic patients growth hormone releasing hormone tests were performed both during hyperglycaemia and after metabolic improvement by insulin treatment. Growth hormone responses before and after insulin treatment were not statistically different. Our data demonstrate that growth hormone responses to growth hormone releasing hormone in non-obese Type 2 diabetic patients do not differ significantly from control subjects; obesity blunts growth hormone responses to growth hormone releasing hormone in Type 2 diabetes mellitus; and growth hormone responses following growth hormone releasing hormone administration in Type 2 diabetes mellitus are not influenced by the state of metabolic control.
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PMID:Effect of growth hormone releasing hormone on growth hormone secretion in type 2 (non-insulin-dependent) diabetes mellitus. 310 23

Growth hormone (hGH) reserve following arginine administration and the paradoxical hGH response to thyrotropin-releasing hormone (TRH) were studied in 30 diabetics without evidence of vascular complications. The diabetics were divided into 4 groups according to the type of their disease and to the metabolic condition within the IDDM group (insulin-dependent: IDDM, in acceptable response and in poor metabolic control; non-insulin-dependent: NIDDM, and juvenile diabetics not requiring insulin at least for two years after diagnosing their disease: NIDDY). The results were compared with controls of identical age and normal weight. A paradoxical hGH response to TRH stimulation was found only in IDDM patients in poor metabolic control. In this group the hGH reserve revealed by arginine was significantly larger than in the others. It was shown that the induced hGH release was independent of the sex distribution of the groups and of the basal hGH values. Magnitude of the hGH reserve and appearance of the paradoxical hGH response were not necessarily correlated but the substantial reserve was frequently associated with a paradoxical response. It can be assumed that the unfavorable metabolic condition is of decisive importance in giving rise to these anomalies. Our observations seem to confirm the need for good metabolic control if the pathological hGH secretion in diabetics is to be prevented.
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PMID:Arginine induced growth hormone (hGH) response and paradoxical hGH secretion stimulated by TRH in diabetes mellitus. 311 18

Growth hormone (GH) response was studied in 8 insulin-dependent and 7 non-insulin-dependent diabetics after stimulation with L-Dopa (500 mg orally) and TRH (0.2 mg iv.). L-Dopa induced a clear GH response in insulin-dependent diabetes (IDDM) and in the control group while in non-insulin-dependent diabetes (NIDDM) peak GH levels were lower (P less than 0.05) and 4 of 7 subjects failed to respond to L-Dopa stimulation. TRH had no effect on GH levels in NIDDM and in the controls. Insulin-dependent diabetics responded to TRH stimulation and GH levels at 20 and 30 min were significantly higher as compared with NIDDM and the control group. The degree of hyperglycemia seemed not to influence GH response. The highest GH levels were noted in two patients with proliferative retinopathy. It is suggested that TRH-induced GH release may be a characteristic feature in some patients with IDDM.
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PMID:TRH-induced growth hormone release in insulin-dependent diabetes mellitus. 644 6

Growth hormone secretion is blunted in obesity. Recent studies have shown that the sub-group of obesity with preponderance of accumulation of fat in visceral depots is associated with endocrine abnormalities. We therefore measured IGF-I concentrations in serum in 27 men who also underwent computerized tomography measurements of regional and total body fat mass. Furthermore, euglycemic-hyperinsulinemic glucose clamps were used to determine insulin resistance, and established 'risk factors' for cardiovascular disease and non-insulin dependent diabetes mellitus were measured, i.e. blood pressure, plasma lipids, and blood glucose, as well as sex steroid hormones. Visceral fat mass systolic blood pressure and triglycerides were higher (P < 0.05) in the group with low (87 +/- 4 micrograms/l) IGF-I values, compared to those with high (126 +/- 6 micrograms/l) IGF-I values, divided after the median value. IGF-I was negatively correlated with visceral fat mass (r = 0.40), independently of subcutaneous and total fat mass. As described before visceral fat mass was directly associated to a majority of the measured 'risk factors', as well as indirectly to testosterone and sex hormone binding globulin (SHBG) concentrations. The latter were also strongly related statistically to the 'risk factors'. IGF-I concentrations showed, however, weaker correlations with the metabolic factors, blood pressure or sex steroid hormones. Multivariate analyses revealed that the correlations of visceral fat with the risk factors were not influenced by IGF-I, while testosterone or SHBG totally abolished these associations. The results indicate that low serum IGF-I concentrations, suggesting deficient growth hormone secretion, are associated with visceral but not with subcutaneous or total fat masses.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Low concentrations of insulin-like growth factor-I in abdominal obesity. 838 69

Physiologic systems have substantial reserves in younger individuals. The process of aging and intercurrent pathologic processes gradually eliminate these reserves. Changes in endocrine systems, including menopause in women, androgen deficiency in men, loss of skeletal mass, decrease in growth hormone serum concentrations, and increased incidence of type 2 diabetes are all more common or certain in older individuals. This review summarizes the progression of each of these processes with age, the potential outcomes of the untreated process, and the treatment outcomes for these age-related losses. Maintenance of a premenopausal lipid profile presumably protects against cardiovascular events. Maintenance of skeletal mass reduces fracture risk and risk for loss of mobility and independence. Testosterone replacement in hypogonadal older men improves strength and presumably function and independence. Growth hormone therapy is reported to have similar effects. Improvement of long-term outcomes in older type 2 diabetics, however, is more difficult to demonstrate.
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PMID:The endocrinology of aging. 1043 Aug 20

Growth hormone (GH) treatment has been used in children with intrauterine growth retardation (IUGR) to promote growth with success in several short- and long-term clinical trials. Intermittent GH therapy has also been advocated in children with IUGR. This study was designed to evaluate the growth of children with IUGR after discontinuation of a two-year trial of GH treatment. Sixteen children (12 F, 4 M) who had received GH (Genotropin) at age 5.3 (1.3) years at a dose of 0.2 IU/kg/day for 2 years (Group 1) and 10 (6 F, 4 M) controls of age 4.3 (1.7) years without treatment (Group 2) were followed after completion of the trial over a median period of 4 years. Height SDS of the GH-treated group showed an increase from -3.0 (0.5) to -1.9 (0.7) (p <0.001) over 2 years of therapy. Off therapy, height SDS decreased to -3.5 (0.5) at a mean age of 11.2 (1.6) years. The difference between the initial and recent height SDS in this group was significantly different (p = 0.02). Height SDS of the control group, -2.7 (1.4) initially, did not change over the two-year observation period. At follow-up, seven control children received GH in a similar fashion for one year. In spite of an insignificant increase in height SDS on one year of GH, it decreased to -2.9 (1.6) at age 11.0 (2.1) years at the latest visit. There was no significant difference between the recent heights of the two groups at final examination. One girl in Group 1 developed acanthosis nigricans and type 2 diabetes mellitus at age 13.3 years, after the follow-up period. A second patient developed osteosarcoma in the left tibia at age 9.9 years, for which she received chemotherapy and surgery. In conclusion, height SDS showed a significant increase on GH therapy for 2 years in children with IUGR; however, it decelerated after discontinuation of therapy. At the final visit, GH therapy did not seem to have had any effect on height prognosis. This finding shows that GH should be given continuously to improve final height in children with IUGR.
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PMID:Follow-up height after discontinuation of growth hormone treatment in children with intrauterine growth retardation. 1209 89

During the year 2000, several original studies were published regarding the metabolic effects of growth hormone therapy in pediatric patients. Pharmacologic doses of growth hormone were rarely associated with abnormalities in glucose tolerance in children with intrauterine growth retardation and Turner syndrome; however, serum insulin levels were elevated. A report from the Pharmacia International Growth Study database suggested a possible increase in type 2 diabetes in growth hormone-treated patients, indicating the need for continued surveillance for this condition. Growth hormone therapy increased markers of bone turnover and bone mineral density in children with chronic renal failure and Prader-Willi syndrome. In Prader-Willi syndrome, 2 years of growth hormone therapy also induced a sustained decrease in body fat, improvement in strength and physical skills, and increased lean body mass. Serum leptin, a reflection of body fat, declined with growth hormone therapy in a dose-dependent manner in intrauterine growth retardation children; the magnitude of the decline correlated with linear growth response. Skin is a target organ for growth hormone in children; growth hormone increased dermal thickness and reduced skin stiffness in growth hormone-deficient children. Reassuring data were published regarding the risk of tumor recurrence and mortality in children with brain tumors treated with growth hormone. Growth hormone administered to short children prior to kidney transplantation did not have adverse effects on subsequent graft survival or number of rejection episodes.
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PMID:Metabolic effects of growth hormone in the child and adolescent. 1213 Sep 8

Exenatide [AC002993, AC2993A, AC 2993, LY2148568, exendin 4], a glucagon-like peptide-1 (GLP-1) agonist, is a synthetic exendin 4 compound under development with Amylin Pharmaceuticals for the treatment of type 2 diabetes. Both exendin 4 and its analogue, exendin 3, are 39-amino acid peptides isolated from Heloderma horridum lizard venom that have different amino acids at positions 2 and 3, respectively. Exendins are able to stimulate insulin secretion in response to rising blood glucose levels, and modulate gastric emptying to slow the entry of ingested sugars into the bloodstream. Amylin Pharmaceuticals acquired exclusive patent rights for the two exendin compounds (exendin 3 and exendin 4) from the originator, Dr John Eng (Bronx, NY, US). On 20 September 2002, Amylin and Eli Lilly signed a collaborative agreement for the development and commercialisation of exenatide for type 2 diabetes. Under the terms of the agreement, Eli Lilly has paid Amylin a licensing fee of 80 million US dollars and bought Amylin's stock worth 30 million US dollars at 18.69 US dollars a share. After the initial payment, Eli Lilly will pay Amylin up to 85 US dollars million upon reaching certain milestones and also make an additional payment of up to 130 million US dollars upon global commercialisation of exenatide. Both companies will share the US development and commercialisation costs, while Eli Lilly will pick up up to 80% of development costs and all commercialisation costs outside the US. Amylin and Eli Lilly will equally share profit from sales in the US, while Eli Lilly will get 80% of the profit outside the US and Amylin will get the rest. This agreement has also enabled Amylin to train its sales force to co-promote Lilly's human growth hormone Humatrope. Alkermes will receive research and development funding and milestone payments, and also a combination of royalty payments and manufacturing fees based on product sales. Alkermes undertakes the responsibility for the development of several initial formulations of the long-acting drug and manufacturing of the final product, while Amylin will be responsible for clinical trials, regulatory filings and worldwide marketing. The goal of the exenatide LAR programme is to develop a once-a-month injectable formulation of exenatide. In November 2003, Amylin announced positive results from the second of three pivotal, phase III studies that evaluated the effects of exenatide in combination with sulfonylureas in 377 randomised patients with type 2 diabetes. The design of the study was similar to that from the first study. The final third phase III study of exenatide was completed in November 2003. This study investigated the effects of exenatide in combination with metformin and sulfonylureas. Amylin and Eli Lilly announced that all of the pivotal phase III trials met the primary glucose control endpoint as measured by glycosylated haemoglobin. An NDA submission for exenatide is projected for mid-2004. A phase II, dose-ascending study in patients with type 2 diabetes was initiated in June 2002. This multicentre (US), double-blind, placebo-controlled study evaluated the safety, tolerability and the pharmacokinetic profile of exenatide LAR in up to 100 patients with type 2 diabetes. A phase I study of exenatide LAR began in Europe in March 2001 and was completed in Q3 2001. A long-acting, sustained-release formulation of exenatide lowered both pre- and post-meal glucose concentration during a 24h period in patients with type 2 diabetes. In November 2002, analysts at Prudential Financial estimated that exenatide, pending approval, has the potential to reach sales of 477 million US dollars in 2006.
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PMID:Exenatide: AC 2993, AC002993, AC2993A, exendin 4, LY2148568. 1472 90

Several studies have demonstrated an association between low birth weight and impaired insulin sensitivity or even type 2 diabetes mellitus (DM2) in later life. Growth hormone (GH) is known to increase fasting and postprandial insulin levels. For that reason concern has been expressed regarding possible detrimental effects of GH therapy in children born SGA. In a Dutch trial the possible side effects of GH therapy on carbohydrate metabolism were assessed in short children born SGA after 6 years and at 6 months after discontinuation of GH therapy. This study included 79 prepubertal short children born SGA, participating in a multicenter double-blind, randomized, dose-response GH trial. Inclusion criteria were: 1) birth length SDS below -1.88, 2) age 3-11 years in boys and 3-9 years in girls, 3) height SDS < -1.88, 4) no spontaneous catch-up growth, and 5) an uncomplicated neonatal period. Mean (SD) value for age was 7.3 (2.1) years, birth length SDS -3.6, height SDS -3.0 (0.7) and BMI SDS -1.2 (1.3). All children were randomly assigned to either group A (n = 41) using 1 mg GH/m2/day or group B (n = 38) using 2 mg/m2/ d/ay (approximately 0.1 or 0.2 IU/kg/d, respectively). Standard oral glucose tolerance tests (OGTTs) were performed before and during 6 years of GH therapy and 6 months after discontinuation of GH therapy. Before GH therapy 8% of the children had impaired glucose tolerance (IGT) according to criteria of the WHO. After 6 years of GH therapy, IGT was found in 4% and after stopping GH in 10%. Mean fasting glucose increased significantly with 0.5 mMol/l after 1 year of GH therapy, without a further increase thereafter. GH therapy induced considerably higher fasting and glucose-stimulated insulin levels. None of the observed changes were different between the GH dosage groups. Children who remained prepubertal had similar glucose and insulin levels compared to children who entered puberty. HbA1c levels were always in the normal range and none of the children developed diabetes mellitus. After discontinuation of GH therapy the mean serum glucose levels remained normal and the mean serum insulin levels decreased significantly, to normal age reference values. Before the start of GH the mean systolic blood pressure was significantly higher compared to age-matched peers, whereas during GH therapy a significant decline in mean systolic blood pressure occurred, which remained similar after discontinuation of GH treatment. In conclusion, continuous, long-term GH therapy in short children born SGA has no adverse effects on glucose levels, even with GH dosages up to 2 mg/m2/day. However, as has been reported in other patient groups, GH induced higher fasting and glucose-stimulated insulin levels, indicating insulin resistance. After discontinuation of GH, serum insulin levels declined to normal age-matched reference levels. Since impaired insulin sensitivity and DM2 have been demonstrated in relatively young patients born SGA, long-term follow-up of children born SGA is advised, also after discontinuation of GH therapy.
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PMID:Small for gestational age (SGA): endocrine and metabolic consequences and effects of growth hormone treatment. 1513 8

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