Alcohol and glucose counterregulation during acute insulin-induced hypoglycemia in type 2 diabetic subjects

To investigate the influence of alcohol on glucose counterregulation and recovery during acute insulin-induced hypoglycemia in type 2 diabetic subjects, 8 diet-treated type 2 diabetic subjects were examined twice after an overnight fast. A graded hyperinsulinemic (1 mU/kg/min, 60 to 195 minutes) euglycemic/hypoglycemic clamp was performed with concomitant infusion of 3-(3)H-glucose to assess glucose turnover. After a euglycemic baseline period (150 to 180 minutes), 200 mL of water was taken either alone or with alcohol (0.4 g/kg body weight). Hypoglycemia (plasma glucose nadir, 2.8 mmol/L) was subsequently induced, and the recovery period followed after discontinuation of insulin and the variable glucose infusion. On both study days, circulating concentrations of insulin and glucose were comparable. Alcohol intake markedly increased plasma lactate (area under the curve [AUC], recovery period) (244 +/- 30 v 12 +/- 4 mmol/L x 240 minutes; P = .00009) and suppressed plasma nonesterified fatty acids (NEFA) (AUC, recovery period) (95 +/- 13 v 161 +/- 18 mmol/L x 240 minutes; P = .0008). No differences were found in the counterregulatory response of catecholamines, cortisol, and growth hormone (GH). However, alcohol intake decreased peak glucagon significantly (155 +/- 12 v 200 +/- 17 pg/mL; P = .038). In diet-treated, mild type 2 diabetic subjects, alcohol does not modify recovery from insulin-induced hypoglycemia.     

Effects of glimepiride on insulin and glucagon release from isolated rat pancreas at different glucose concentrations

The effects of glimepiride, the newest sulphonylureic compound, on pancreatic insulin and glucagon secretion were studied using the classical, isolated, perfused rat pancreas model. The influence of four different environmental glucose conditions (during a glycaemic stimulus with glucose increasing from 5 to 8.33 mM and at stable 0, 5 and 2.22 mM glucose levels) on the effects of glimepiride was also assessed. At a pharmacological concentration glimepiride strongly stimulated beta-cell activity, producing a characteristic biphasic insulin release with a sharp first-phase secretory peak, followed by a prolonged and sustained second phase. Environmental glucose concentrations markedly influenced the extent, but not the pattern of glimepiride-induced insulin secretion, as hormone release dropped significantly when the glucose level was reduced. Glimepiride failed to influence alpha-cell activity at any of the environmental glycaemic levels.     

Effects of insulin treatment without and with recurrent hypoglycemia on hypoglycemic counterregulation and adrenal catecholamine-synthesizing enzymes in diabetic rats

Untreated diabetic rats show impaired counterregulation against hypoglycemia. The blunted epinephrine responses are associated with reduced adrenomedullary tyrosine hydroxylase (TH) mRNA levels. Recurrent hypoglycemia further impairs epinephrine counterregulation and is also associated with reduced phenylethanolamine N-methyltransferase mRNA. This study investigated the adaptations underlying impaired counterregulation in insulin-treated diabetic rats, a more clinically relevant model. We studied the effects of insulin treatment on counterregulatory hormones and adrenal catecholamine-synthesizing enzymes and adaptations after recurrent hypoglycemia. Groups included: normal; diabetic, insulin-treated for 3 wk (DI); and insulin-treated diabetic exposed to seven episodes (over 4 d) of hyperinsulinemic-hypoglycemia (DI-hypo) or hyperinsulinemic-hyperglycemia (DI-hyper). DI-hyper rats differentiated the effects of hyperinsulinemia from those of hypoglycemia. On d 5, rats from all groups were assessed for adrenal catecholamine-synthesizing enzyme levels or underwent hypoglycemic clamps to examine counterregulatory responses. Despite insulin treatment, fasting corticosterone levels remained increased, and corticosterone responses to hypoglycemia were impaired in DI rats. However, glucagon, epinephrine, norepinephrine, and ACTH counterregulatory defects were prevented. Recurrent hypoglycemia in DI-hypo rats blunted corticosterone but, surprisingly, not epinephrine responses. Norepinephrine and ACTH responses also were not impaired, whereas glucagon counterregulation was reduced due to repeated hyperinsulinemia. Insulin treatment prevented decreases in basal TH protein and increased PNMT and dopamine beta-hydroxylase protein. DI-hypo rats showed increases in TH, PNMT, and dopamine beta-hydroxylase. We conclude that insulin treatment of diabetic rats protects against most counterregulatory defects but not elevated fasting corticosterone and decreased corticosterone counterregulation. Protection against epinephrine defects, both without and with antecedent hypoglycemia, is associated with enhancement of adrenal catecholamine-synthesizing enzyme levels.     

Differences between nighttime and daytime hypoglycemia counterregulation in healthy humans

Disturbances in hormonal counterregulation may be the main reason why many type 1 diabetic patients are asymptomatic during nighttime hypoglycemia. While it is known that sleep attenuates counterregulatory responses to hypoglycemia, the influence of the time of day on hormonal counterregulation regulation remains obscure. We induced hypoglycemia at 2 different time intervals, ie, in the morning and in the early night, in healthy subjects staying awake throughout the experiments. As compared with the morning hypoglycemia, epinephrine response during early nighttime hypoglycemia was markedly enhanced (P < .001). Baseline corticotropin (ACTH) and cortisol levels were higher in the morning than during nighttime (P < .001 for both). However, the increase of both hormones was stronger at nighttime (P = .045 and P < .001, respectively), so that at the end of the hypoglycemic clamp, levels at nighttime were comparable to morning levels. In the morning, the increase in glucagon levels was more pronounced than during nighttime (P = .019), but given that baseline glucagon levels were distinctly higher at nighttime than in the morning (P = .003), at the end of the clamps, levels of this hormone remained still higher at nighttime than in the morning (P = .017). The increase in growth hormone during hypoglycemia did not differ between morning and nighttime (P = .728). Data shows that several components of hormonal counterregulation against hypoglycemia are influenced by the time of day. Especially, the markedly enhanced epinephrine response to early nighttime hypoglycemia could be clinically important, because this neuroendocrine response is known to play a crucial role in mediating the awareness of and metabolic defensive mechanism against hypoglycemia.     

Effects of oral glucose on systemic glucose metabolism during hyperinsulinemic hypoglycemia in normal man

The widespread use of oral glucose in the treatment of hypoglycemia is mainly empirically based, and little is known about the time lag and subsequent magnitude of effects following its administration. To define the systemic impact and time course of effects following oral glucose during hypoglycemia, we investigated 7 healthy young men twice. On both occasions, a 6-hour hyperinsulinemic (1.5 mU/kg/min)-hypoglycemic clamp was performed to ensure similar plasma glucose profiles during a stepwise decrease toward a nadir less than 50 mg/100 mL after 3 hours. On the first occasion, subjects ingested 40 g glucose and 4 g 3-ortho-methylglucose ([3-OMG] to trace glucose absorption) dissolved in 400 mL tap water after 3.5 hours. The second examination was identical except for the omission of 40 g oral glucose, and glucose levels were clamped at hypoglycemic concentrations similar to those recorded on the first examination. Plasma glucose curves were superimposable, and all participants reached a nadir less than 50 mg/100 mL. Similar increases in growth hormone (GH) and glucagon were observed in both situations. The glucose infusion rates (GIRs) were lower after oral glucose, with the difference starting after 5 to 10 minutes, being statistically significant after 20 minutes, and reaching a maximum of 8.5 +/- 1.6 mg/kg/min after 40 minutes. Circulating 3-OMG increased after 20 minutes. In both situations, infusion of insulin resulted in insulin levels of approximately 150 microU/mL and a suppression of C-peptide levels from 2.0 to 1.1 nmol/L (P < .01). After glucose ingestion, both serum C-peptide and glucagon-like peptide-1 (GLP-1) increased (C-peptide from 1.1 +/- 0.05 to 1.4 +/- 0.05 nmol/L and GLP-1 from 3.2 +/- 0.8 to 18.1 +/- 3.3 pmol/L), in contrast to the situation without oral glucose (P < .05). Isotopically determined glucose turnover was similar. In conclusion, our data suggest that oral glucose affects systemic glucose metabolism rapidly after 5 to 10 minutes. Quantitatively, the immediate impact is relatively small, with the gross impact observed after approximately 40 minutes. Future studies aiming to identify therapeutic oral agents with prompt effect seem warranted.     

A potential important role of skeletal muscle in human counterregulation of hypoglycemia

CONTEXT: During hypoglycemia, systemic glucose uptake (SGU) decreases and endogenous glucose release (EGR) increases. Skeletal muscle appears to be primarily responsible for the reduced SGU and may be important for the increased EGR by providing lactate for gluconeogenesis (GN). OBJECTIVE: The objective of the study was to test the hypothesis that reduced muscle glucose uptake and increased muscle lactate release both make major contributions to glucose counterregulation using systemic isotopic techniques in combination with forearm net balance measurements. SETTING: The study was conducted at the University of Giessen Clinical Research Center. PARTICIPANTS: Nine healthy volunteers participated in the study. Intervention: A 2-h hyperinsulinemic euglycemic clamp (blood glucose approximately 4.4 mm) was followed by a 90-min hypoglycemic clamp (blood glucose approximately 2.6 mm). RESULTS: Compared with the euglycemic clamp, SGU decreased (21.0 +/- 2.0 vs. 29.6 +/- 1.8 micromol.kg body weight(-1).min(-1); P < 0.001), whereas EGR (11.2 +/- 1.7 vs. 4.9 +/- 1.3 micromol.kg body weight(-1) .min(-1); P < 0.003), arterial lactate concentrations (1051 +/- 162 vs. 907 +/- 115 microm; P < 0.02), systemic lactate release (23.5 +/- 0.9 vs. 17.1 +/- 0.9 micromol.kg body weight(-1).min(-1); P < 0.001), and lactate GN (4.50 +/- 0.60 vs. 2.74 +/- 0.30 micromol.kg body weight(-1).min(-1); P < 0.02) increased during hypoglycemia; the proportion of lactate used for GN remained unchanged (38 +/- 4 vs. 32 +/- 3%; P = 0.27). Whole-body muscle glucose uptake decreased approximately 50% during hypoglycemia (6.4 +/- 1.9 vs. 13.6 +/- 2.9 micromol.kg body weight(-1).min(-1); P < 0.001), which accounted for approximately 85% of the reduction of SGU. Whole-body muscle lactate release increased 6.6 +/- 1.6 micromol.kg body weight(-1). min(-1) (P < 0.01), which could have accounted for all the increase in systemic lactate release and, considering the proportion of lactate used for GN, contributed 1.4 +/- 0.4 micromol.kg body weight(-1).min(-1) (approximately 25%) to the increase in EGR. CONCLUSIONS: Reduced muscle glucose uptake and increased muscle lactate release both make major contributions to glucose counterregulation in humans.     

Multiple defects in counterregulation of hypoglycemia in modestly advanced type 2 diabetes mellitus

In type 2 diabetes mellitus (T2DM), little is known about hormonal responses to hypoglycemia. In particular, beta-cell responses to hypoglycemia have not been carefully investigated and potentially because of confounding factors or insufficient power, conflicting data have been obtained regarding growth hormone responses. We therefore compared hormonal responses including rates of insulin secretion during a 2-hour hyperinsulinemic hypoglycemic clamp in a relatively large number of nondiabetic (n=21) and moderately insulin-deficient subjects with T2DM (homeostasis model assessment of beta-cell function [HOMA-%B], 751+/-160 vs 1144+/-83 [pmol/L]/[mmol/L], P<.04) (n=14) matched for age, sex, and body mass index. Subjects with T2DM were excluded for antecedent hypoglycemia, and baseline glycemia was controlled by a variable infusion of insulin overnight. Although both groups of subjects had indistinguishable plasma glucose levels at baseline and virtually identical levels of plasma insulin and glucose throughout the hypoglycemic clamp, insulin secretion decreased more slowly in the subjects with T2DM. The time required for insulin secretion to decline to half its baseline level was markedly increased (38.9+/-4.9 vs 22.3+/-1.3 minutes [SD], P<.01), and insulin secretion decreased to a lesser extent (-0.79+/-0.17 vs -1.51+/-0.09 [pmol/L]/kg per minute, P<.002). Moreover, responses of glucagon (28.3+/-7.3 vs 52.8+/-7.0 ng/L, P<.05) and growth hormone (2.9+/-0.8 vs 6.3+/-0.9 ng/mL, P<.04) were reduced in the subjects with T2DM, whereas responses of epinephrine, norepinephrine, and cortisol were similar to those in nondiabetic subjects (all P>0.6). We conclude that multiple defects exist in hormonal responses to hypoglycemia in T2DM with moderate beta-cell failure. These include delayed and reduced decreases in insulin secretion, and impaired increases of plasma glucagon and growth hormone.     

Glucose counterregulation during recovery from neuroglucopenia: Which mechanism is important?

Neuroglucopenia (NGP), which is a serious potential hazard for all insulin-treated diabetics, stimulates many neural and hormonal responses including increased glucagon secretion and activation of beta-adrenergic receptors of the autonomic nervous system. To determine which of these responses is important in recovery from NGP, we induced NGP in baboons by the intravenous (IV) injection of 2-deoxy-D-glucose with and without beta-adrenergic blockade (propranolol) and somatostatin. Thirty minutes after the induction of NGP the animals recovered, and the mean (+/- SEM) rise in arterial plasma glucose was 6.6 +/- 0.9 mmol/L, in glycerol 0.106 +/- 0.22 mmol/L, and in beta-hydroxybutyrate 0.091 +/- 0.22 mmol/L. Animal recovery and glucose rise were uninfluenced by the infusion of propranolol (mean 30 minute plasma glucose rise of 6.2 +/- 0.8 mmol/L) and somatostatin (6.8 +/- 0.8 mmol/L). However, the combined infusion of somatostatin and propranolol prevented animal recovery and glucose rise (1.0 +/- 0.1 mmol/L). The glycerol and beta-hydroxybutyrate rises were blocked by the propranolol infusion alone. Thus, recovery from NGP and the associated rise in plasma glucose, glycerol, and beta-hydroxybutyrate are prevented by the combination of the suppression of the glucagon and beta-adrenergic response to NGP. Furthermore, if the results of our study are extrapolated to insulin-dependent diabetic patients, most of whom have an impaired glucagon response to insulin-induced hypoglycemia/neuroglucopenia, they would be critically dependent on beta-adrenergic mechanisms for recovery from NGP.     

The role of endocrine counterregulation for estimating insulin sensitivity from intravenous glucose tolerance tests

CONTEXT: During insulin-modified frequently sampled iv glucose tolerance tests (IM-FSIGT), which allow assessment of insulin action, plasma glucose can markedly decrease. OBJECTIVE: This study aimed to assess the counterregulatory impact of the insulin-induced fall of glucose on minimal model-derived indices of insulin sensitivity (S(I)) and glucose effectiveness. PARTICIPANTS: Thirteen nondiabetic volunteers (seven males, six females, aged 26 +/- 1 yr, body mass index 22.1 +/- 0.7 kg/m(2)) were studied. DESIGN: All participants were studied in random order during IM-FSIGT (0.3 g/kg glucose; 0.03 U/kg insulin at 20 min) and during identical conditions but with a variable glucose infusion preventing a decrease of plasma glucose concentration below euglycemia (IM-FSIGT-CLAMP). Five participants additionally underwent euglycemic-hyperinsulinemic (1 mU.kg(-1).min(-1)) clamp tests. RESULTS: Plasma glucose declined during IM-FSIGT to its nadir of 50 +/- 3 mg/dl at 60 min in parallel to a rise (P < 0.05 vs. basal) of plasma glucagon, cortisol, epinephrine, and GH. Glucose infusion rates of 4.6 +/- 0.5 mg.kg(-1).min(-1) between 30 and 180 min during IM-FSIGT-CLAMP prevented the decline of plasma glucose and the hypoglycemia counterregulatory hormone response. S(I) was approximately 68% lower during IM-FSIGT (3.40 +/- 0.36 vs. IM-FSIGT-CLAMP: 10.71 +/- 1.06 10(-4).min(-1) per microU/ml, P < 0.0001), whereas glucose effectiveness did not differ between both protocols (0.024 +/- 0.002 vs. 0.021 +/- 0.003 min(-1), P = NS). Compared with the euglycemic hyperinsulinemic clamp test, S(I) expressed in identical units from IM-FSIGT was approximately 66% (P < 0.001) lower but did not differ between the euglycemic hyperinsulinemic clamp test and the IM-FSIGT-CLAMP (P = NS). CONCLUSIONS: The transient fall of plasma glucose during IM-FSIGT results in lower estimates of S(I), which can be explained by hormonal response to hypoglycemia.     

Plasma glucagon and glucose recovery after hypoglycemia: the effect of total autonomic blockade.

The role of the autonomic nervous system in the glucagon response to hypoglycemia has not been fully clarified. We have studied the effect of total pharmacological blockade of the autonomic nervous system (concomitant alpha- and beta-adrenergic blockade with simultaneous atropine injection) and of isolated alpha-adrenergic blockade on hormonal responses to hypoglycemia and on blood glucose recovery after hypoglycemia in healthy subjects. Neither of the pharmacological blockades had any significant effects on plasma glucagon responses to hypoglycemia nor had they any effect on the rate of blood glucose recovery after hypoglycemia. We conclude that the autonomic nervous system has no major influence on the glucagon response to hypoglycemia in healthy man. Changes in autonomic nervous activity are not essential for blood glucose recovery after hypoglycemia in healthy man.     

Naloxone attenuates recovery from insulin-induced hypoglycemia in normal man

The effect of the opioid antagonist, naloxone, on recovery of serum glucose concentrations from insulin-induced (0.1 U/kg) hypoglycemia was determined in five normal adult men. Each subject was studied on 2 separate days, at least 2 weeks apart, during an infusion of either normal saline (6.5 ml/h) or naloxone (0.8 mg/h). The order of the infusions was randomized and double blinded. Although glucose recovery was complete by 120 min after insulin administration during each study, the fractional rate of glucose recovery as determined by analysis of covariance was significantly slower during the naloxone infusions (P = 0.008). Plasma glucagon, serum cortisol, and serum GH concentrations were not different during glucose recovery on either study day. These studies suggest that endogenous opioids contribute to glucose recovery from insulin-induced hypoglycemia and therefore may be important to glucose homeostasis in normal man.     

烟酰胺单核苷酸对低血糖后葡萄糖再灌注大鼠学习记忆的影响

目的 探讨研究烟酰胺单核苷酸对低血糖后葡萄糖再灌注大鼠学习记忆能力的影响及其保护作用机制.方法 将30只SPF级雄性SD大鼠随机分为假手术组(Sham组,10只)、低血糖后葡萄糖再灌注组(GR组,10只)及低血糖后葡萄糖再灌注并给予烟酰胺单核苷酸治疗组(GR+NMN组,10只).采用Morris水迷宫实验检测各组大鼠学...     

Prediction of recovery time from hypoglycemia in patients with insulin overdose

Insulin overdose results in prolonged hypoglycemia. We hypothesized that if a huge amount of insulin is subcutaneously injected, the duration of hypoglycemia depends on the dose of insulin rather than the type of insulin. We conducted a literature review of insulin overdose and 33 cases were included in this study. We assessed the correlation between recovery time from hypoglycemia and insulin dose. As a result, there was a significant correlation between recovery time from hypoglycemia and insulin dose (r=0.88, p<0.0001) and this correlation was expressed as y=0.045x; where y is time (h) and x is insulin dose (U), corresponding to that if 1000 U insulin is injected, hypoglycemia will persist for ~45 h. This equation may be useful to predict the duration of glucose supplementation for treatment of insulin overdose.     

Effects of insulin-induced acute hypoglycemia and normoglycemic hyperinsulinemia on the retinal uptake and ocular metabolism of glucose in rabbits

Glucose is the principal metabolic substrate for the retina in mammals, being essential for maintaining the functional activity of the retina; it can be supplied to the tissue by both vitreous humor and blood. Yet, the impact of hypoglycemia on retinal glucose metabolism has been poorly investigated. We have therefore studied the effects of acute insulin-induced hypoglycemia on the glucose uptake and metabolism in the retina, by analyzing the hypoglycemia-induced changes in the ocular distribution and metabolic fate of [3H]-2-deoxy-D-glucose (2-DG) and [14C]-D-glucose, both injected in the vitreous body. Rabbits were rendered hypoglycemic by subcutaneous injection of insulin (0.8 and 1.2 IU/kg). Insulin-induced hypoglycemia increased both retinal [3H]-radioactivity levels and retina to vitreous humor ratio of [3H]-radioactivity levels ([3H]-[R/VH]). Radio-chromatography showed that hypoglycemia did not induce any change in the retinal conversion of 2-DG to 2-DG-6-phosphate, but increased the conversion of [14C]-D-glucose to [14C]-lactate. Normoglycemic hyperinsulinemia caused no change in either retinal [3H]-radioactivity levels or [3H]-[R/VH] while decreasing retinal [14C]-radioactivity levels and retina to vitreous ratios of 14C-radioactivity levels. These results indicate that acute hypoglycemia increases the uptake rate of glucose by the retina and suggest that normoglycemic hyperinsulinemia may decrease retinal lactate, possibly stimulating its removal from the retina.     

Regional cerebral blood flow in normal man during insulin-induced hypoglycemia and in the recovery period following glucose infusion.

The effect of moderate hypoglycemia (p-glucose, 2.0 +/- 0.3 mmol/L; mean +/- SD) on regional cerebral blood flow (rCBF) was studied in a group of 10 healthy, right-handed men (aged 23 to 28 years) using an intravenous xenon 133 single photon emission computed tomography technique (SPECT). After 10 minutes of hypoglycemia, global CBF had increased to 46.3 +/- 9.6 mL/100 g/min compared with the initial normoglycemic flow of 38.6 +/- 6.8 mL/100 g/min (P less than .01). The relative distribution of the rCBF changed significantly (P less than .05, ANOVA) from before to during hypoglycemia. Of the 10 regions analyzed, the highest increments in rCBF during hypoglycemia were found in the frontal (21.5% +/- 15.2%) and parietal (20.6% +/- 14.2%) lobes, and the lowest (10.7% +/- 9.4%) were found in the pons/brainstem regions. The increase in rCBF persisted for 15 minutes after normalization of blood glucose. The persisting high flow after hypoglycemia affected all regions, but a further 10.1% +/- 7.2% increase was observed in the pons/brainstem area (P less than .05). The CBF was significantly higher in the right compared with the left hemisphere (2.8%, 1.2%, and 3.9%, respectively; P less than .05) in all measurements. A decrease in brain volume was found at the final examination, compared with the hypoglycemic state (2.6%; P less than .05). It is concluded that moderate hypoglycemia leads to a marked increase in CBF and in the relative distribution of rCBF, which persists in the immediate period after normalization of the blood glucose level.     

Effect of pancreas transplantation on glucose counterregulation in insulin-dependent diabetic patients prone to severe hypoglycaemia.

Pancreatic transplantation was performed in three patients with insulin-dependent diabetes mellitus in whom recurrent and severe episodes of hypoglycaemia had been found to be due to defective glucose counterregulation. Thus in these patients the spontaneous blood glucose recovery after insulin-induced hypoglycaemia (0.1 U kg-1 h-1 i.v. insulin until blood glucose levels fell below 2.8 mmol l-1) was delayed, and the responses of glucagon, epinephrine and growth hormone (GH) were absent or diminished. After pancreas transplantation the patients exhibited essentially normal blood glucose control. When the insulin infusion test was repeated 3 months after the transplantation, the blood glucose level recovered rapidly after insulin withdrawal. The glucagon response was restored, and the responses of epinephrine and GH were improved. Plasma C-peptide was suppressed by approximately 50%, which is less than is observed in normal subjects. It is concluded that glucose counterregulation improves after pancreas transplantation. This appears to be mainly due to an improvement in the hypoglycaemia-induced glucagon response, but an amelioration of sympatho-adrenal and hypothalamic-pituitary regulatory mechanisms may also be involved. The apparent failure to suppress completely the insulin release from the denervated pancreas transplant indicates that inhibition of beta-cell secretion during insulin-induced hypoglycaemia may be partly under neural control.