UMLS:C0011854 - FACTA Search

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Query: UMLS:C0011854 (type 1 diabetes)
20,749 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A major problem in replacing insulin in type I diabetes mellitus is that currently no depot preparation exists that is capable of mimicking the background insulin secretion of the healthy pancreas. Because all of the currently available intermediate- or long-acting insulin preparations have a peaked-action profile, excess insulin action at midnight and insulin waning at dawn occur whenever such an insulin preparation is given at supper time. If the target fasting plasma glucose is the ambitious near-normoglycemia of intensive insulin therapy, intermediate-acting insulin at suppertime easily results in hypoglycemia in the early evening hours and hyperglycemia in the fasting state. The problems of overnight glycemia in type I diabetes are further complicated by the dawn phenomenon and the Somogyi phenomenon. The dawn phenomenon is the combination of an initial decrease in insulin requirements between approximately 2400 and approximately 0300, followed by an increase in the insulin needs between approximately 0500 and approximately 0800. The dawn phenomenon is the result of changes in hepatic (and extrahepatic) insulin sensitivity, which are best attributed to nocturnal growth hormone secretion. The dawn phenomenon is a day-to-day reproducible event that occurs in nearly all diabetic patients. Its contribution to fasting hyperglycemia correlates with diabetes duration (inversely) and the HbA1c percentage (directly). Overall, it is estimated that the specific contribution of the dawn phenomenon to fasting hyperglycemia is approximately 2 mM (approximately 35 mg/dl), but it may be much greater because of the warning of the depot-insulin preparation injected the previous evening. The Somogyi phenomenon, strictly speaking, refers to fasting hyperglycemia that occurs after inducement of nocturnal hypoglycemia by regular insulin. Because the present therapeutic regimens of NPH/Lente insulin given at suppertime cause overnight hyperinsulinemia, excessive fasting hyperglycemia rarely follows nocturnal hypoglycemia, except when excessive glucose is ingested to correct hypoglycemia. However, nocturnal hypoglycemia may easily deteriorate glycemic control later in the day, because it induces prolonged posthypoglycemic insulin resistance, which results in postbreakfast and late-morning hyperglycemia. With nocturnal insulin therapy, it is important to consider the problems of insulin pharmacokinetics, the dawn phenomenon, and the Somogyi phenomenon to prevent both nocturnal hypoglycemia and excessive fasting hyperglycemia.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Nocturnal blood glucose control in type I diabetes mellitus. 829 80

We evaluated the effect of physiologic hyperinsulinemia (plasma insulin 329 +/- 62 vs 687 +/- 62 pmol/L) on counterregulatory hormone responses in 8 IDDM subjects studied during a 2-hour hypoglycemic clamp study with an equivalent degree of hypoglycemia (plasma glucose 3.1 +/- 0.1 and 3.0 +/- 0.1 mmol/L, respectively). Plasma epinephrine levels were increased by 71% during the last 60 minutes of hypoglycemia in the high insulin study (840 +/- 180 vs 1440 +/- 310 pmol/L, respectively p = 0.006). In addition, plasma cortisol and norepinephrine were also increased in the high insulin study (by 19% and 24% respectively, p < 0.01, for both). Plasma growth hormone and glucagon concentrations were not altered by high dose insulin infusion. In spite of increased epinephrine secretion, the glucose infusion rate required to maintain glucose was 2-fold greater in the high insulin study, and there was greater suppression of lipolysis in that group. We conclude that hyperinsulinemia may enhance counterregulatory hormone secretion in IDDM.
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PMID:Physiologic hyperinsulinemia enhances counterregulatory hormone responses to hypoglycemia in IDDM. 849 33

To characterize its insulin-antagonistic effect, growth hormone (GH) was infused at variable rates (24, 12 or 6 mU kg-1 min-1) for 1 h in 7 IDDM patients. Saline infusion was used as control (C) and all patients participated in all studies. The effect of insulin was measured with the euglycaemic clamp technique for 6 h combined with d-(3-3H)-glucose to evaluate glucose turnover. The insulin levels during the clamps were similar in all studies (23 +/- 3 mU l-1). The infusions produced peak GH levels of (24 rate = 24) 157 +/- 11, (12 rate = 12) 76 +/- 7, and (6 rate = 6) 45 +/- 8 mU l-1 (mean +/- SEM). The insulin-antagonistic effect of GH on glucose uptake was seen after 2 h and was at a maximum 4 to 5 h after the start of the GH infusion (difference in glucose infusion rate between C and 24 was 1.7 +/- 0.4 mg kg-1 min-1, p < 0.01). The resistance was due to a less pronounced effect of insulin to both inhibit rate of appearance and to stimulate rate of disappearance. Infusion of GH at 12 mU kg-1 min-1 induced a less pronounced insulin resistance both with regards to maximal effect (glucose infusion rate C - GH 1.4 +/- 0.5 mg kg-1 min-1, p < 0.05) and duration (3 h). At 6 mU kg-1 min-1, a clear GH-induced insulin-antagonistic effect was only seen during the third hour of the clamp (glucose infusion rate C-GH 1.3 +/- 0.5 mg kg-1 min-1, p < 0.05). GH infusion impaired the effect of insulin to lower both the levels of free fatty acids (NEFA) and glycerol between 2 and 5 h after the start of the infusion (NEFA, C:110 +/- 29, 24:303 +/- 95, p < 0.05: glycerol, C:32 +/- 4, 24:50 +/- 7 mumol l-1, p < 0.05). The present study therefore demonstrates that the insulin-antagonistic effect of GH in IDDM is related to the plasma levels both with regard to duration and response. The results also indicate that GH impairs the effect of insulin on lipolysis in IDDM after physiological peaks.
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PMID:Characterization of the insulin-antagonistic effect of growth hormone in insulin-dependent diabetes mellitus. 858 32

The aims of the present study were to compare nocturnal growth hormone (GH) secretion, insulin requirements and insulin sensitivity on two occasions in six adolescent girls with type 1 diabetes when the GH secretion was reduced one night by an oral dose of 100 mg of pirenzepine at bedtime. The mean nocturnal intravenous insulin infusion required to maintain a normal constant blood glucose concentration between 24:00 and 07:00 was 53% higher during the night on placebo (p = 0.0212). During the night on pirenzepine, the serum GH area under the curve (AUC) was reduced in all patients to a mean concentration which was 50.1% (15-78%) of that during the night without pirenzepine (p = 0.0036). The nocturnal urinary GH excretion was also reduced in all of the investigated patients (p = 0.0229). Insulin sensitivity in the morning, measured by the euglycaemic hyperinsulinaemic glucose clamp, increased significantly from 115 +/- 51 mg m-2 min-1 after the night on placebo to 205 +/- 67 mg m-2 min-1 after the night on pirenzepine (p = 0.0161). No side-effects were observed during the pirenzepine night. Negative correlations were found between the nocturnal serum GH AUC and the insulin-stimulated glucose metabolism (r = -0.65, p = 0.0241) and between the nocturnal urinary GH excretion and the insulin-stimulated glucose metabolism (r = -0.77, p = 0.0054). In conclusion, the present study shows a relation between GH secretion and insulin resistance in adolescent girls with type 1 diabetes. The administration of pirenzepine acutely reduces GH secretion and improves insulin sensitivity.
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PMID:Reduced growth hormone secretion improves insulin sensitivity in adolescent girls with type 1 diabetes. 883 76

Some insulin-dependent diabetic (IDDM) patients develop severe forms of retinopathy. Putative risk factors such as hypertension, poor metabolic control, nephropathy and growth hormone levels do not fully explain the progress of retinopathy in these patients. It has been discussed whether there is a genetic marker, since some diabetic patients without any known predisposing risk factors develop severe retinopathy and others do not. In the present study, HLA-DR and DQ were compared in two patient groups with IDDM. One group consisted of patients with early-onset diabetes, with severe non-proliferative or proliferative retinopathy; the other group had no or only mild signs of retinopathy. High resolution HLA typing was carried out by polymerase chain reaction (PCR) and hybridization with allele specific probes. Alleles on the DR3-DQ2 haplotype, DRB1*0301, DQA1*0501 and DQB1*0201, were more frequent in patients with severe retinopathy. A difference was seen when combining certain alleles in the genotypes of DQA1*03/0501 (p > 0.05) and DQB1*0201/0302 (p < 0.01). The findings of the present study suggest that DQB1*0201/0302 is the strongest genetic marker for severe retinopathy and DRB1*0301/0401 only has a secondary influence when combined with this genotype. It seems as if IDDM patients who are positive for the genotype DR3-DQ2/DR4-DQ8 (DRB1*0301-DQA1*0501-DQB1*0201/DRB1*0401 -DQA1*03-DQB1*0302) are at greater risk of developing severe retinopathy.
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PMID:HLA-DQB1*0201/0302 is associated with severe retinopathy in patients with IDDM. 893 97

Insulin-dependent (type I) diabetic patients are known to have an exaggerated growth hormone (GH) response to GH-releasing hormone (GHRH), which is hypothesized to be due to a decrease in somatostatin tone. The aim of the study was to ascertain the influence of the presence and activity of the autoimmune process involving a key enzyme (glutamic acid decarboxylase [GAD]) in the synthetic pathway of a neurotransmitter regulating somatostatin secretion, ie, gamma-aminobutyric acid (GABA), on the GH response to GHRH alone or combined with an acetylcholinesterase inhibitor, pyridostigmine (PD), in patients with type I diabetes mellitus. Twenty non-obese type I diabetic patients and 17 normal subjects underwent an intravenous (IV) injection of 100 micrograms GHRH(1-29)NH2. Twelve of 20 diabetic subjects and all of the control subjects also underwent a second experimental procedure, administration of 120 mg oral PD 60 minutes before IV injection of 100 micrograms GHRH. Diabetic subjects with serum GAD antibody (GADA) levels more than 3 U (n = 10) showed significantly higher serum GH levels after GHRH injection as compared both with diabetic patients with GADA less than 3 U (n = 10) and with normal controls, whether expressed as absolute or peak values. GH peaks after GHRH were significantly (rs = .46, P < .05) correlated with the level of GADA in the whole population of type I diabetic subjects studied. PD significantly enhanced the GH response to GHRH, in terms of both absolute and peak values, in patients without GADA (n = 6) and in normal subjects. On the contrary, PD failed to enhance the GH response to GHRH in diabetic patients with GADA (n = 6). Our findings suggest that autoimmunity may play a key role in determining the exaggerated GH response to GHRH in type I diabetes mellitus. The mechanism underlying this effect is hypothesized to be the production of antibodies to GAD, a key enzyme in the synthesis of GABA, and in turn a reduced GABAergic stimulatory tone on somatostatin production at the hypothalamic level.
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PMID:Glutamate decarboxylase autoimmunity and growth hormone secretion in type I diabetes mellitus. 910 40

Proximal tubular dysfunction may be implicated in the pathogenesis of diabetic nephropathy. An investigation of proximal tubular function was carried out by assessing proximal tubular sodium-reabsorption and low molecular weight protein excretion in a group of patients with type 1 diabetes mellitus. Normoalbuminuric [group A, n = 6, albumin excretion rate (AER) mean (range) 4 (0-10) micrograms/min], and microalbuminuric [group B, n = 6, AER 88 (35-198) micrograms/min] patients with type 1 diabetes were compared with matched controls. Simultaneous lithium and growth hormone (GH) clearance and urinary beta 2-microglobulin excretion were assessed. Fasting plasma glucose at the start of the study was [median (range)] 13 (10.2-15.1), 9.3 (5.9-15) and 4.1 (4.0-5.0) mmol/l in groups A, B and controls, respectively, with a mean coefficient of variation during the study of 3.9% (group A) and 5.2% (group B). There was no significant difference in plasma glucose levels between patients in groups A and B. Urinary GH excretion was raised in the patients with microalbuminuria (group B; P < 0.05), although there was no difference in serum GH clearance rate between the patient groups and controls. Urinary GH correlated with B 2-microglobulin in the diabetic subjects (r = 0.665, P < 0.05) and with the degree of microalbuminuria in group B patients (r = 1, P < 0.01). Urinary GH was also greater than 10 microU, the median value observed in the controls, in 5 of 6 (83%) patients in group A. Glomerular filtration rate (GFR) and effective renal plasma flow (ERPF) measured by constant infusion of 51Cr-ethylene diamine tetra-acetic acid (EDTA) and I125-para-amino hippuric acid (PAH), respectively, showed relative hyperfiltration in the normoalbumiruric group compared with controls (P < 0.05) and group B (P < 0.05). Absolute proximal reabsorption of sodium and of water (APRNa and APRH2O) was significantly higher in group A patients (P < 0.05). Although GFR was significantly higher in group A patients, no differences were found in fractional proximal reabsorption of sodium and water (FPRNa+H2O) or end proximal delivery between the patient groups and controls. Therefore, the measurement of protein reabsorptive capacity provides a more sensitive marker of renal tubular impairment in type 1 diabetes than sodium/fluid reabsorptive capacity. In patients with microalbuminuria, both glomerular and tubular damage may coexist. Our results stress the usefulness of markers of renal tubular function in monitoring the course of diabetic nephropathy. This study also shows that assessment of GH clearance has promise as a marker of renal tubular protein reabsorptive capacity.
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PMID:Proximal tubular reabsorption of growth hormone and sodium/fluid in normo- and microalbuminuric insulin-dependent diabetes mellitus. 913 54

Hypoglycemia elicits a characteristic sequence of responses in healthy humans. These responses (and their arterialized venous glycemic thresholds) include: 1) Decreased insulin secretion (approximately 4.5 mmol/L). 2) Increased glucose counterregulatory hormone (glucagon, epinephrine, growth hormone and cortisol) secretion (approximately 3.6-3.8 mmol/L). 3) Symptoms of hypoglycemia (approximately 3.0 mmol/L). 4) Cognitive dysfunction (approximately 2.6 mmol/L). Thus, insulin secretion decreases as plasma glucose levels fall within the physiological range, and counterregulatory hormone secretion increases as plasma glucose levels fall just below the physiological range at substantially higher glucose levels than those required to produce symptoms and impair cognitive function. These data are entirely consistent with the body of evidence that insulin, glucagon and epinephrine stand high in the hierarchy of redundant glucoregulatory factors that prevent, as well as correct, hypoglycemia. When the same methods are used, these thresholds are remarkably reproducible from laboratory to laboratory. Nonetheless, the glycemic thresholds are dynamic rather than static. They vary in relation to recent antecedent glycemia. For example, lower plasma glucose concentrations are required to elicit autonomic, including epinephrine, and symptomatic responses in patients with well controlled IDDM, a phenomenon best attributed to recent antecedent iatrogenic hypoglycemia. This is the basis of the clinical syndrome of hypoglycemia unawareness, which is now known to be reversible with scrupulous avoidance of iatrogenic hypoglycemia. The latter also at least partially reverses reduced epinephrine responses to hypoglycemia, a key component (in the setting of absent glucagon responses) of the syndrome of defective glucose counterregulation. While perhaps seemingly adaptive, these threshold shifts appear to be maladaptive since both defective glucose counterregulation and hypoglycemia unawareness are associated with substantially increased rates of severe iatrogenic hypoglycemia in people with IDDM.
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PMID:Hierarchy of physiological responses to hypoglycemia: relevance to clinical hypoglycemia in type I (insulin dependent) diabetes mellitus. 913 76

In insulin dependent diabetes mellitus (IDDM) either elevated growth hormone (GH) levels or abnormal responses to specific as well as unspecific stimuli have been reported. As hyperglycemia is known to blunt GH response to various stimuli, a normal GH response to GHRH in presence of hyperglycemia should also be considered inappropriate. To investigate the mechanism underlying this inappropriate GH response, in 9 patients with IDDM, selected for normal GH response to GHRH, we studied the GH response to two consecutive GHRH boluses (1 microgram/kg), the second of which preceded 30 min before by pyridostigmine (120 mg p.o.). Seven age matched normal volunteers were evaluated as control group. Basal plasma glucose and serum GH levels were significantly higher in patients with IDDM than in normal subjects (184.4 +/- 9.6 vs 86.2 +/- 4.4 mg/dl, p < 0.01 and 2.4 +/- 1.0 vs 1.0 +/- 0.4 microgram/l, p < 0.01 respectively). Both in normal subjects and in patients with IDDM the GH response to the second consecutive GHRH administration was lower than that of the first GHRH bolus (delta AUC: 82.5 +/- 28.3 vs 401.1 +/- 131.2 micrograms/l/h, p < 0.05 and 77.2 +/- 30.4 vs 336.8 +/- 60.0 p < 0.02, respectively). Pyridostigmine was able to restore the blunted GH responsiveness to the second GHRH administration in both groups, but this response was found higher in normal than in diabetic subjects (delta AUC: 1250.8 +/- 136.2 vs 527.5 +/- 147.6, p < 0.01). Since the GH-releasing effect of PD is likely to be mediated by the inhibition of hypothalamic somatostatin release, our results suggest that there is also an impaired somatostatin tone in hyperglycemic type 1 diabetic patients with normal GH response to GHRH.
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PMID:Repeated administration of growth hormone-releasing hormone with or without previous administration of pyridostigmine in insulin-dependent diabetes mellitus. 917 28

IDDM is associated with elevated circulating levels of growth hormone (GH) and reduced insulin-like growth factor I (IGF-I). GH antagonizes the action of insulin-increasing insulin requirements in IDDM. The effects of subcutaneously administered rhIGF-I on glycemic control, insulin requirements, and GH secretion were studied in eight adults with IDDM. Patients received either placebo or rhIGF-I (50 microg/kg b.i.d.) for 19 days in a randomized, double-blind, parallel-design, placebo-controlled trial. Overnight GH, plasma glucose, free insulin, IGF-I, fructosamine, and lipid profiles were assessed during this period. rhIGF-I therapy increased IGF-I concentration from 117.1 +/- 14.2 (mean +/- SE) ng/ml (baseline) to 310.5 +/- 40.6 and 257.1 +/- 41.2 ng/ml on day 5 (P < 0.01 vs. baseline) and day 20 (P < 0.01 vs. baseline), respectively. After 19 days of rhIGF-I treatment, fructosamine concentrations were unchanged compared with baseline (439 +/- 32 vs. 429 +/- 35 micromol/l, day -1 vs. day 20, respectively), yet insulin requirements were decreased by approximately 45% (0.67 +/- 0.08 vs. 0.36 +/- 0.07 U x kg(-1) x day(-1), day -1 vs. day 19, respectively, P < 0.005). After 4 days of rhIGF-I therapy, there was a decrease in free insulin levels (8.38 +/- 1.47 vs. 4.98 +/- 0.84 mU/l, P < 0.05), mean overnight GH concentration (12.6 +/- 3.3 vs. 3.8 +/- 2.1 mU/l, P = 0.05), and total cholesterol and triglycerides (4.68 +/- 0.31 vs. 4.25 +/- 0.35 mmol/l, P < 0.05, 1.27 +/- 0.19 vs. 0.95 +/- 0.21 mmol/l, P < 0.001, respectively). There was no change in any variable in the placebo-treated patients. This study demonstrates that subcutaneous administration of rhIGF-I decreases insulin requirements and improves the plasma lipid profile while maintaining glycemic control in adults with IDDM. The excess nocturnal release of GH, characteristic of IDDM, is also decreased by rhIGF-I therapy.
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PMID:rhIGF-I administration reduces insulin requirements, decreases growth hormone secretion, and improves the lipid profile in adults with IDDM. 928 46

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