Glucose counterregulation and waning of insulin in the Somogyi phenomenon (posthypoglycemic hyperglycemia)

Metabolomics and biochemical insights on the regulation of aging-related diabetes by a low-molecular-weight polysaccharide from green microalga Chlorella pyrenoidosa

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C. pyrenoidosa polysaccharide (CPP) have hypoglycemic activity and oxidation resistance.

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CPP prevents oxidative stress and stimulates insulin via affecting phenylpyruvic acid.

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CPP can regulate the GLP-1R/IL-6R and ZO-1/MMP-2 pathways.

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CPP activated BCL-6 to promote cell survival in brain.

Globally, aging and diabetes are considered prevalent threats to human health. Chlorella pyrenoidosa polysaccharide (CPP) is a natural active ingredient with multiple health benefits including antioxidant and hypolipidemic activities. In this study, the aging-related diabetic (AD) mice model was established to investigate the underlying hypoglycemic and antioxidant mechanisms of CPP. It improved superoxide dismutase, catalase (CAT), glutathione peroxidase (GSH-px), and malondialdehyde activities in liver and insulin secretion. CAT and GSH-px activity in the brain increased after CPP administration. In addition, through histopathological examinations, it was evident that injuries in the liver, brain, jejunum, and pancreas were restored by CPP. This restoration was likely mediated via the activation of glucagon-like peptide-1 receptor/FOXO-1 (forkhead box O1) pathway concurrent with the inhibition of interleukin-6 receptor/FOXO-1 pathway. Furthermore, metabolomics and correlation analysis revealed that CPP possibly relived AD through changes in insulin levels and declined oxidative stress as regulated by phenylpyruvic acid. These findings suggested that CPP exerted antioxidant and hypoglycemic roles in an AD mice model, thereby providing a sound scientific foundation for further development and utilization of CPP.

Confirmation of the Absence of Somogyi Effect in Patients with Type 2 Diabetes by Retrospective Continuous Glucose Monitoring Systems

BACKGROUND

The Somogyi effect is defined as fasting hyperglycemia secondary to nocturnal hypoglycemia. In past decades, this effect proved to be rare or absent. However, many endocrinologists still believe in this phenomenon in clinical practice. Does the Somogyi effect truly exist? We aimed to answer this question with a study based on a larger sample size.

METHODS

We collected retrospective CGMs data from 2,600 patients with type 2 diabetes with stable treatment of insulin. Nocturnal hypoglycemia was defined as a CGMs sensor glucose of less than 3.9 mmol/L for at least 15 min between 24:00 and 06:00. Morning fasting glucose was compared between people with nocturnal hypoglycemia and without nocturnal hypoglycemia.

RESULTS

Valid CGMs data were obtained on 4,705 of 5,200 nights. Morning fasting glucose was observed lower after nights with nocturnal hypoglycemia compared with nights without hypoglycemia (P < 0.001). 84 cases presented fasting glucose of more than 7 mmol/L after nocturnal glucose of less than 3.9 mmol/L. Only 27 cases presented fasting glucose of more than 7 mmol/L after nocturnal glucose of less than 3.0 mmol/L. Fasting glucose values below 3.9 mmol/l in the morning were associated with a 100% risk of nocturnal hypoglycemia, while fasting glucose values over 9.6 mmol/l in the morning were associated with no risk of nocturnal hypoglycemia. Correlation analysis showed that the nocturnal glucose nadir was significantly correlated with fasting glucose levels (r = 0.613, P < 0.001).

CONCLUSIONS

Our data provided no support for the existence of the Somogyi effect. If fasting glucose exceeds 9.6 mmol/L, we do not have to worry about asymptomatic nocturnal hypoglycemia in patients with type 2 diabetes.

The dawn phenomenon in type 2 diabetes: its association with glucose excursions and changes after oral glucose-lowering drugs

Background:

We investigated the association between glucose excursions and the dawn phenomenon, and the effects of oral-glucose lowering drugs on the dawn phenomenon in patients with type 2 diabetes (T2D).

Methods:

We conducted a post hoc analysis using data from a previous randomized trial. Patients with T2D on metformin monotherapy were randomized to receive add-on acarbose or glibenclamide for 16 weeks. Ambulatory continuous glucose monitoring (CGM) was conducted before randomization and at the end of the study. Using the CGM data, we assessed glucose excursions as indicated by mean amplitude of glycemic excursions (MAGE). The magnitude of the dawn phenomenon was calculated as the difference between the nocturnal nadir (0:00 to 6:00 a.m.) and prebreakfast glucose level.

Results:

A total of 50 patients with T2D [mean age 53.5 ± 8.2 years, mean glycated hemoglobin (HbA1c) 8.4 ± 1.2%] were analyzed. There was an independent association between MAGE and the dawn phenomenon [β coefficient 0.199, 95% confidence interval (CI) 0.074–0.325, p = 0.003]. HbA1c improved significantly after treatment with acarbose or glibenclamide. However, only treatment with acarbose significantly improved glucose excursions. The dawn phenomenon decreased significantly only in patients treated with acarbose (from 35.9 ± 15.7–28.3 ± 16.5 mg/dl, p = 0.037), but not in those treated with glibenclamide (from 35.9 ± 20.6–34.6 ± 17.0 mg/dl, p = 0.776).

Conclusion:

Glucose excursions were independently associated with the dawn phenomenon in patients with T2D on metformin monotherapy. Both glucose excursions and the dawn phenomenon improved after treatment with acarbose, but not after treatment with glibenclamide.

The physiological basis of insulin therapy in people with diabetes mellitus

Insulin therapy has been in use now for 100 years, but only recently insulin replacement has been based on physiology. The pancreas secretes insulin at continuously variable rates, finely regulated by sensitive arterial glucose sensing. Pancreatic insulin is delivered directlyin the portal blood to insulinize preferentially the liver. In the fasting state, insulin is secreted at a low rate to modulate hepatic glucose output. After liver extraction (50%), insulin concentrations in peripheral plasma are 2.4-4 times lower than in portal, but still efficacious to restrain lipolysis. In the prandial condition, insulin is secreted rapidly in large amounts to increase portal and peripheral concentrations to peaks 10-20 times greater vs the values of fasting within 30-40 min from meal ingestion. The prandial portal hyperinsulinemia fully suppresses hepatic glucose production while peripheral hyperinsulinemia increases glucose utilization, thus limitating the post-prandial plasma glucose elevation. Physiology of insulin indicates that insulin should be replaced in people with diabetes mimicking the pancreas, i.e. in a basal-bolus mode, for fasting and prandial state, respectively. Despite the presently ongoing limitations (subcutaneous and peripheral rather than portal and intravenous insulin delivery), basal-bolus insulin allows people with diabetes to achieve A1c in the range with minimal risk of hypoglycaemia, to prevent vascular complications and to ensure good quality of life.

Differential Effect of Hypoalbuminemia on Hypoglycemia on Type 2 Diabetes Patients Treated with Insulin Glargine 300 U/ml and Insulin Degludec

INTRODUCTION

Hypoglycemia resulting from insulin therapy for treatment of diabetes increases the risk of adverse cardiovascular events. Determining biomarkers that provide accurate estimation of hypoglycemia risk may allow for more accurate patient management and care. The purpose of this study was to determine the cutoff value of serum albumin (s-alb) that increases the risk of hypoglycemia in patients treated with insulin degludec.

METHODS

This study used a crossover design and randomized 30 patients admitted for glycemic control to compare differences between insulin glargine 300 U/ml (Gla300) and degludec treatments.

RESULTS

The cutoff value of s-alb associated with 24-h hypoglycemia and nocturnal hypoglycemia in patients treated with degludec was 3.8 g/dl. In patients with s-alb levels < 3.8 g/dl, mean percentages of time with hypoglycemia, clinically important hypoglycemia, and nocturnal hypoglycemia were significantly lower in those treated with Gla300 compared with patients treated with degludec.

CONCLUSION

This study identified a cutoff value for s-alb levels that indicates risk of hypoglycemia in patients treated with degludec. Monitoring s-alb levels in patients treated with degludec will help to mitigate the risk of hypoglycemia.

TRIAL REGISTRATION

University Hospital Medical Information Network (UMIN 000031044).

An Adaptive Nonlinear Basal-Bolus Calculator for Patients With Type 1 Diabetes

BACKGROUND

Bolus calculators help patients with type 1 diabetes to mitigate the effect of meals on their blood glucose by administering a large amount of insulin at mealtime. Intraindividual changes in patients physiology and nonlinearity in insulin-glucose dynamics pose a challenge to the accuracy of such calculators.

METHOD

We propose a method based on a continuous-discrete unscented Kalman filter to continuously track the postprandial glucose dynamics and the insulin sensitivity. We augment the Medtronic Virtual Patient (MVP) model to simulate noise-corrupted data from a continuous glucose monitor (CGM). The basal rate is determined by calculating the steady state of the model and is adjusted once a day before breakfast. The bolus size is determined by optimizing the postprandial glucose values based on an estimate of the insulin sensitivity and states, as well as the announced meal size. Following meal announcements, the meal compartment and the meal time constant are estimated, otherwise insulin sensitivity is estimated.

RESULTS

We compare the performance of a conventional linear bolus calculator with the proposed bolus calculator. The proposed basal-bolus calculator significantly improves the time spent in glucose target ( P < .01) compared to the conventional bolus calculator.

CONCLUSION

An adaptive nonlinear basal-bolus calculator can efficiently compensate for physiological changes. Further clinical studies will be needed to validate the results.

Hypoglycemia impairs quality of blood glucose simulation in a clinical decision support system

BACKGROUND

Clinical decision support systems allow for decisions based on blood glucose simulations. The DiasNet simulation tool is based on accepted principles of physiology and simulates blood glucose concentrations accurately in type 1 diabetes mellitus (T1DM) patients during periods without hypoglycemia, but deviations appear after hypoglycemia, possibly because of the long-term glucose counter-regulation to hypoglycemia. The purpose of this study was to evaluate the impact of hypoglycemia on blood glucose simulations.

METHOD

Continuous glucose monitoring (CGM) data and diary data (meals, insulin, self-monitored blood glucose) were collected for 2 to 5 days from 17 T1DM patients with poor glycemic control. Hypoglycemic episodes [CGM glucose <63 mg/dl (3.5 mmol/liter) for ≥20 min] were identified in valid (well-calibrated) CGM data. For 24 hours after each hypoglycemic episode, a simulated (DiasNet) glucose profile was compared to the CGM glucose.

RESULTS

A total of 52 episodes of hypoglycemia were identified in valid data. All subjects had at least one hypoglycemic episode. Ten episodes of hypoglycemia from nine subjects were eligible for analysis. The CGM glucose was significantly (p < .05) higher than simulated blood glucose for a period of 13 h, beginning 8 h after hypoglycemia onset.

CONCLUSIONS

The present data show that hypoglycemia introduces substantial and systematic simulation errors for up to 24 h after hypoglycemia. This underlines the need for further evaluation of mechanisms behind this putative long-term glucose counter-regulation to hypoglycemia. When using blood glucose simulations in decision support systems, the results indicate that simulations for several hours following a hypoglycemic event may underestimate glucose levels by 100 mg/dl (5.6 mmol/liter) or more.

Mechanisms of insulin resistance after insulin-induced hypoglycemia in humans: the role of lipolysis

OBJECTIVE

Changes in glucose metabolism occurring during counterregulation are, in part, mediated by increased plasma free fatty acids (FFAs), as a result of hypoglycemia-activated lipolysis. However, it is not known whether FFA plays a role in the development of posthypoglycemic insulin resistance as well.

RESEARCH DESIGN AND METHODS

We conducted a series of studies in eight healthy volunteers using acipimox, an inhibitor of lipolysis. Insulin action was measured during a 2-h hyperinsulinemic-euglycemic clamp (plasma glucose [PG] 5.1 mmo/l) from 5:00 p.m. to 7:00 p.m. or after a 3-h morning hyperinsulinemic-glucose clamp (from 10 a.m. to 1:00 p.m.), either euglycemic (study 1) or hypoglycemic (PG 3.2 mmol/l, studies 2-4), during which FFA levels were allowed to increase (study 2), were suppressed by acipimox (study 3), or were replaced by infusing lipids (study 4). [6,6-(2)H(2)]-Glucose was infused to measure glucose fluxes.

RESULTS

Plasma adrenaline, norepinephrine, growth hormone, and cortisol levels were unchanged (P > 0.2). Glucose infusion rates (GIRs) during the euglycemic clamp were reduced by morning hypoglycemia in study 2 versus study 1 (16.8 +/- 2.3 vs. 34.1 +/- 2.2 micromol/kg/min, respectively, P < 0.001). The effect was largely removed by blockade of lipolysis during hypoglycemia in study 3 (28.9 +/- 2.6 micromol/kg/min, P > 0.2 vs. study 1) and largely reproduced by replacement of FFA in study 4 (22.3 +/- 2.8 micromol/kg/min, P < 0.03 vs. study 1). Compared with study 2, blockade of lipolysis in study 3 decreased endogenous glucose production (2 +/- 0.3 vs. 0.85 +/- 0.1 micromol/kg/min, P < 0.05) and increased glucose utilization (16.9 +/- 1.85 vs. 28.5 +/- 2.7 micromol/kg/min, P < 0.05). In study 4, GIR fell by approximately 23% (22.3 +/- 2.8 micromol/kg/min, vs. study 3, P = 0.058), indicating a role of acipimox per se on insulin action.

CONCLUSION

Lipolysis induced by hypoglycemia counterregulation largely mediates posthypoglycemic insulin resistance in healthy subjects, with an estimated overall contribution of approximately 39%.

PXR and CAR in energy metabolism

The nuclear receptors pregnane X receptor (PXR, or NR1I2) and constitutive androstane receptor (CAR, or NR1I3) were originally identified as xenosensors that regulate the expression of Phase I and Phase II drug-metabolizing enzymes and transporters. Recent results suggest that PXR and CAR also have important endobiotic roles in energy metabolism by affecting the metabolism of fatty acids, lipids and glucose. PXR and CAR exert their effects on energy metabolism through direct gene regulation or through crosstalk with other transcriptional regulators. This review focuses on the roles of CAR and PXR in energy metabolism and offers a perspective on whether PXR and CAR represent novel therapeutic targets for the management of metabolic syndrome.

Detection of nocturnal hypoglycemia in insulin-treated diabetics by a skin temperature--skin conductance meter

The efficacy and credibility of a skin temperature--skin conductance meter (Teledyne Sleep Sentry) for detecting hypoglycemia was studied during night-time in 22 adult insulin-treated diabetics. Capillary blood glucose concentration was measured 99 times (when the alarm sounded, in case of hypoglycemic symptoms, and at 3 a.m.). Hypoglycemia was defined as a capillary blood glucose concentration of less than or equal to 3 mmol/l. Blood glucose was measured 61 times in connection with sounding of the alarm and 38 times without the alarm sounding. At 3 a.m. the Sleep Sentry sounded the alarm 22 times, of which hypoglycemia was present 6 times giving a diagnostical specificity or diagnostical true positive rate of 0.27 (95% confidence limits 0.11-0.50). In 35 of 38 cases of no alarm the blood glucose was greater than 3 mmol/l, giving a diagnostical sensitivity of 0.92 (95% confidence limits 0.79-0.98). The Sleep Sentry sounded the alarm in 6 of 9 cases of hypoglycemia, giving a nosological sensitivity of 0.67 (95% confidence limits 0.30-0.93). The Sleep Sentry did not sound the alarm in 35 of 51 cases of non-hypoglycemia, giving a nosological specificity of 0.69 (95% confidence limits 0.54-0.81). In other words, the Sleep Sentry detects about 2/3 of blood glucose values less than or equal to 3 mmol/l, but in addition it sounds a false alarm in 2/3 of the cases.

Importance of growth hormone for blood glucose regulation following insulin-induced nocturnal hypoglycemia in insulin-dependent diabetes mellitus

The effect of growth hormone (GH) on the glucose homeostasis following nocturnal hypoglycemia was studied between 4 a.m. and noon in eight male patients with insulin-dependent diabetes mellitus (IDDM) by a somatostatin (250 micrograms/h)-insulin (0.4 mU/kg/min)-glucose (6 mg/kg/min)-infusion test (SIGIT). The patients participated in two experiments in which hypoglycemia at 4 a.m. was induced by i.v. insulin (1.5 mU/kg/min). In both experiments the endogenous secretion of GH was suppressed by somatostatin (250 micrograms/h) and glucagon (0.5 ng/kg/min) was given as substitute for the somatostatin-induced suppression of endogenous glucagon secretion. GH (20 mU/kg/h) or saline was given for 60 min from nadir blood glucose in random order. Mean nadir glucose values were the same in both studies (1.7 +/- 0.2 vs. 1.7 +/- 0.1 mmol/l) and no differences were registered in plasma-free insulin, glucagon and the responses of adrenaline and cortisol to hypoglycemia. The infusion of GH resulted in plasma GH levels of about 50 micrograms/l at the end of the infusion, thereafter decreasing to low or immeasurable levels within 2 hours. Infusion of GH evoked a marked hyperglycemia within 4 hours. It is concluded that when hypoglycemia is accompanied by a transient increase in plasma GH, insulin resistance occurs after a lag period of approximately 4 hours and that this effect persists for at least another 4 hours.

Studies of insulin resistance following hypoglycemia in insulin-dependent diabetes mellitus

Insulin resistance was assessed after a hypoglycemia induced by insulin (1.5 mU X kg-1 X min-1) between 7 and 8 a.m. in 10 well-insulinized patients with insulin-dependent diabetes mellitus (IDDM). Blood glucose levels during a somatostatin (100 micrograms X h-1)-insulin (0.4 mU X kg-1 X min-1)-glucose (4.5 mg X kg-1)-infusion test (SIGIT) performed between 11 a.m. and 3 p.m. served as an indicator of total body insulin resistance. Plasma epinephrine, growth hormone, and cortisol increased in response to hypoglycemia, while blunted responses of glucagon were simultaneously registered. At the start of the subsequent SIGIT, blood glucose and plasma-free insulin concentrations were similar to those obtained in the control study without preceding hypoglycemia, and at this point all counter-regulatory hormones had returned to basal. During the SIGIT close to identical levels of plasma-free insulin and counter-regulatory hormones were registered, despite which a significant hyperglycemia was seen 2 hours after the start of the SIGIT when preceded by hypoglycemia. In a separate study, the SIGIT was shown to have a good reproducibility in IDDM patients. We conclude that hypoglycemia evokes a state of insulin resistance for several hours, as demonstrated by elevated blood glucose levels during a somatostatin-insulin-glucose-infusion test.

Hypoglycaemia in Elderly Patients with Diabetes Mellitus

Achieving target glycaemic goals while avoiding hypoglycaemia is a major challenge in the management of elderly patients with diabetes mellitus. Repeated episodes of hypoglycaemia may cause extreme emotional distress in such patients, even when the episodes are relatively mild. Moreover, evidence is mounting that hypoglycaemia among elderly patients is a very real and costly health concern. The strongest predictors of severe hypoglycaemia in the elderly are advanced age, recent hospitalisation and polypharmacy. Education is the key to preventing recurrent or severe hypoglycaemia. As such, there should be close coordination of care between the patient, physician and all other healthcare providers in identifying the cause of hypoglycaemia in elderly patients, and appropriate steps should be taken to prevent further episodes. Prevention of hypoglycaemia has the potential to improve psychosocial aspects of elderly health, including enhanced quality of life, boosted confidence, improved compliance with antidiabetic regimens and avoidance of long-term complications. Since the elderly population represents a unique group, it is imperative to focus on the aetiologies that are exclusive to this group. Advanced age itself is a risk factor for hypoglycaemia, and elderly patients with comorbidities are at increased risk when they are hospitalised. Elderly patients with diabetes often have compromised renal function, which intereferes with drug elimination and thus predisposes them to prolonged life-threatening hypoglycaemia. In addition, patients on five or more prescription medications are prone to drug-associated hypoglycaemia. Although sulfonylurea-associated hypoglycaemia is common, drugs such as ACE inhibitors and nonselective beta-adrenoceptor antagonists can also predispose patients to hypoglycaemia. Greater attention should be paid to the avoidance of hypgolycaemia in nursing home residents. Recurrent hypoglycaemia in elderly patients is not only detrimental to achieving good glycaemic control, it is also a substantial economic burden. Once the causes of hypoglycaemia have been identified, it is crucial to formulate and institute a prevention plan. Firstly, global evaluation of the patient should be carried out to identify possible predisposing risk factors. Secondly, target glycaemic goals should be tailored to each patient. Thirdly, selection of antidiabetic agents should be judicious, then patients and family should be educated to recognise and treat hypoglycaemia. Finally, coordinated care should be provided to identify, treat and prevent hypoglycaemia.

Insulin glargine: long-acting basal insulin analog for improved metabolic control

The primary aim of insulin therapy is to replace endogenous insulin secretion in patients with type 1 or type 2 diabetes in a physiologically sound manner, mimicking normal secretion patterns to adequately regulate glucose metabolism. The currently available human insulins for basal therapy--neutral protamine Hagedorn (NPH), Lente and Ultralente--and analogs such as insulin glargine, differ in pharmacokinetic properties. Clinical trial data indicate that insulin glargine may satisfy basal insulin requirements, with an improved safety profile relative to other available insulins used for basal supplementation. This review describes the unique pharmacokinetic properties and clinical efficacy of insulin glargine.

Integrating model-based decision support in a multi-modal reasoning system for managing type 1 diabetic patients

We present a multi-modal reasoning (MMR) methodology that integrates case-based reasoning (CBR), rule-based reasoning (RBR) and model-based reasoning (MBR), meant to provide physicians with a reliable decision support tool in the context of type 1 diabetes mellitus management. In particular, we have implemented a decision support system that is able to jointly exploit a probabilistic model of the glucose-insulin system at the steady state, a RBR system for suggestion generation and a CBR system for patient's profiling. The integration of the CBR, RBR and MBR paradigms allows for an optimized exploitation of all the available information, and for the definition of a therapy properly tailored to the patient's needs, overcoming the single approaches limitations. The system has been tested both on simulated and on real patients' data.

Controlled multicenter study on the effect of computer assistance in intensive insulin therapy of type 1 diabetics

This paper describes the results of a controlled multicenter study on the effect of the computer assistance in the intensive insulin therapy. The patient collective consisted of 50 diabetics, randomly divided in two groups with 25 patients per group. The Multiple Subcutaneous Injection (MSI) group was treated with the usually intensive regimen. The treatment in the Computer Assisted Meal Related Insulin Therapy (CAMIT) group was performed with the aid of a specialized pocket computer. Only in the CAMIT group during the study we observed a significant decrease: in the mean blood glucose (BG) with 1.6+/-0.4 mmol/l (P<0.05), in the BG amplitudes by 1.0+/-0.3 mmol/l (P<0.05), and in the hypoglycemia frequency-from 2.0+/-0.4 to 1.2+/-0.3 (P<0.01) hypoglycemic episodes weekly. The HbA(1) values fell in the MSI group by 3.7+/-3.7% and in the CAMIT group significantly by 15.6+/-2.2% (P<0.05). Consequently, the computer-assisted intensive insulin therapy resulted in an improved metabolic control.

Bedtime uncooked cornstarch supplement prevents nocturnal hypoglycaemia in intensively treated type 1 diabetes subjects

OBJECTIVES

The present study tests two interrelated hypotheses: (1) that bedtime ingestion of uncooked cornstarch exerts a lower and delayed nocturnal blood glucose peak compared with a conventional snack; (2) that bedtime carbohydrate supplement, administered as uncooked cornstarch, prevents nocturnal hypoglycaemia without altering metabolic control in intensively treated type 1 diabetes (IDDM) patients.

DESIGN AND SUBJECTS

The above hypotheses were tested separately (1) by pooling and analysing data from two overnight studies of comparable groups of patients with non-insulin dependent diabetes mellitus (NIDDM) (14 and 10 patients, respectively), and (2) by a double-blind, randomized 4-week cross-over study in 12 intensively treated IDDM patients.

SETTING

Sahlgrenska University Hospital, Göteborg. Sweden.

INTERVENTIONS

(1) Ingestion of uncooked cornstarch and wholemeal bread (0.6 g of carbohydrates kg-1 body weight) and carbohydrate-free placebo at 22.00 h. (2) Intake of uncooked cornstarch (0.3 g kg-1 body weight) and carbohydrate-free placebo at 23.00 h.

MAIN OUTCOME MEASURES

(1) Nocturnal glucose and insulin levels; (2) frequency of self-estimated hypoglycaemia (blood glucose [BG] levels < 3.0 mmol L-1) at 03.00 h, HbA1c and fasting lipids.

RESULTS

Bedtime uncooked cornstarch ingestion led to a lower (2.9 +/- 0.5 vs. 5.2 +/- 0.6 mM, P = 0.01) and delayed (4.3 +/- 0.6 vs. 2.0 +/- 0.0 h, P < 0.01) BG peak, compared with a conventional snack, in NIDDM patients. Four weeks of bedtime uncooked cornstarch supplement, as compared with placebo, led to a 70% reduction in the frequency of self-estimated hypoglycaemia at 03.00 h (P < 0.05), without affecting HbA1c or fasting lipids in IDDM patients.

CONCLUSIONS

Uncooked cornstarch, ingested at bedtime, mimicked the nocturnal glucose utilization profile following insulin replacement, with a peak in blood glucose after 4 h. In IDDM patients, bedtime uncooked cornstarch supplement diminished the number of self-estimated hypoglycaemic episodes, without adversely affecting HbA1c and lipid levels. Hence, bedtime uncooked cornstarch ingestion may be feasible to prevent a mid-nocturnal glycaemic decline following insulin replacement in IDDM and, based on the nocturnal blood glucose profile, may also be preferable compared with conventional snacks.

Determination of Insulin Requirements: Excessive Insulin Dosages Common in Type 1 Diabetes Mellitus

OBJECTIVE

To report our experience of determining insulin requirements for initiating continuous subcutaneous insulin infusion (CSII) pump therapy, using an algorithm for intravenous administration of insulin, in patients with poorly controlled diabetes.

METHODS

We describe assessment of insulin requirements and analyze data from 27 consecutive admissions. All patients had type 1 diabetes mellitus and were being converted to CSII pump therapy. Twenty-four-hour intravenous insulin requirements were used to initiate CSII pump therapy, and further dose adjustments were undertaken, to optimize glycemic control. Basal, bolus, and total daily insulin requirements were calculated before, during, and 3 months after conversion to CSII therapy.

RESULTS

At entry, the mean glycohemoglobin was 11.2% (normal, 5.0 to 8.0%), and the mean daily insulin dose were 45.8 U (0.59 U/kg). Calculated daily insulin requirements using an algorithm for intravenously administered insulin were 37.3 U (0.50 U/kg). At 3 months, mean daily insulin requirements had increased to 39.2 U (0.52 U/kg), and glycohemoglobin improved to 9.4%. Most patients (78%) remained on insulin doses within 10% of the calculated requirements. All patients who were receiving more than 0.6 U/kg daily before assessment required a reduction in insulin dosage to improve glycemic control.

CONCLUSION

Many patients with type 1 diabetes are receiving excessive insulin doses. An algorithm for intravenous administration of insulin may be useful for determining requirements and appropriate insulin doses for CSII pump therapy, especially in patients with poor glycemic control.

Pharmacokinetics, pharmacodynamics and glucose counterregulation following subcutaneous injection of the monomeric insulin analogue [Lys(B28),Pro(B29)] in IDDM

The aim of these studies was to compare the pharmacokinetics, pharmacodynamics, counterregulatory hormone and symptom responses, as well as cognitive function during hypoglycaemia induced by s.c. injection of 0.15 IU/kg of regular human insulin (HI) and the monomeric insulin analogue [Lys(B28),Pro (B29)] (MI) in insulin-dependent-diabetic (IDDM) subjects. In these studies glucose was infused whenever needed to prevent decreases in plasma glucose below 3 mmol/l. After MI, plasma insulin increased earlier to a peak (60 vs 90 min) which was greater than after HI (294 +/- 24 vs 255 +/- 24 pmol/l), and plasma glucose decreased earlier to a 3 mmol/l plateau (60 vs 120 min) (p < 0.05). The amount of glucose infused to prevent plasma glucose falling below 3 mmol/l was approximately three times greater after MI than HI (293 +/- 26 vs 90 +/- 25 mumol.kg-1 x 60-375 min-1, p < 0.05). After MI, hepatic glucose production was more suppressed (0.7 +/- 1 vs 5.9 +/- 0.54 mumol.kg-1.min-1) and glucose utilization was less suppressed than after HI (11.6 +/- 0.65 vs 9.1 +/- 0.11 mumol.kg-1.min-1) (p < 0.05). Similarly, plasma NEFA, glycerol, and beta-OH-butyrate were more suppressed after MI than HI (p < 0.05), whereas plasma lactate increased only after MI, but not after HI. Responses of counterregulatory hormones, symptoms and deterioration in cognitive function during plasma glucose plateau of 3 mmol/l were superimposable after MI and HI (p = NS).(ABSTRACT TRUNCATED AT 250 WORDS)

Post-hypoglycaemic hyperketonaemia does not contribute to brain metabolism during insulin-induced hypoglycaemia in humans

It is controversial as to whether ketone bodies are utilized by the human brain as a fuel alternative to glucose during hypoglycaemia. To clarify the issue, we studied 10 normal volunteers during an experimental hypoglycaemia closely mimicking the clinical hypoglycaemia of patients with Type 1 (insulin-dependent) diabetes mellitus or insulinoma. Hypoglycaemia was induced by a continuous infusion of insulin (0.40 mU.kg-1.min-1 for 8 h, plasma insulin approximately 180 pmol/l) which decreased the plasma glucose concentration to approximately 3.1 mmol/l during the last 3 h of the studies. Subjects were studied on two occasions, i.e. spontaneous, counterregulatory-induced post-hypoglycaemic increase in 3-beta-hydroxybutyrate (from approximately 0.2 to approximately 1.1 mmol/l at 8 h), or prevention of post-hypoglycaemic hyperketonaemia (plasma beta-hydroxybutyrate approximately 0.1 mmol/l throughout the study) after administration of acipimox, a potent inhibitor of lipolysis. In the latter study, glucose was infused to match the hypoglycaemia observed in the former study. The glycaemic thresholds and overall responses of counterregulatory hormones, symptoms (both autonomic and neuroglycopenic), and deterioration of cognitive function (psychomotor tests) were superimposable in the control study in which ketones increased spontaneously after onset of hypoglycaemic counterregulation, as compared to the study in which ketones were suppressed (p = NS). The fact that responses of counterregulatory hormones, symptoms and deterioration in cognitive function were not exaggerated when posthypoglycaemic hyperketonaemia was prevented, indicate that during hypoglycaemia, the counterregulatory-induced endogenous hyperketonaemia does not provide the human brain with an alternative substrate to glucose. Thus, it is concluded that during hypoglycaemia, endogenous hyperketonaemia does not contribute to brain metabolism and function.

Control of glycaemia

Maintenance of plasma glucose concentrations within a narrow range despite wide fluctuations in the demand (e.g. vigorous exercise) and supply (e.g. large carbohydrate meals) of glucose results from coordination of factors that regulate glucose release into and removal from the circulation. On a moment-to-moment basis these processes are controlled mainly by insulin and glucagon, whose secretion is reciprocally influenced by the plasma glucose concentration. In the resting postabsorptive state, release of glucose from the liver (equally via glycogenolysis and gluconeogenesis) is the key regulated process. Glycogenolysis depends on the relative activities of glycogen synthase and phosphorylase, the latter being the more important. The activities of fructose-1,6-diphosphatase, phosphoenolpyruvate carboxylkinase and pyruvate dehydrogenase regulate gluconeogenesis, whose main precursors are lactate, glutamine and alanine. In the postprandial state, suppression of liver glucose output and stimulation of skeletal muscle glucose uptake are the most important factors. Glucose disposal by insulin-sensitive tissues is regulated initially at the transport step and the mainly by glycogen synthase, phosphofructokinase and pyruvate dehydrogenase. Hormonally induced changes in intracellular fructose 2,6-bisphosphate concentrations play a key role in muscle glycolytic flux and both glycolytic and gluconeogenic flux in the liver. Under stressful conditions (e.g. hypoglycaemia, trauma, vigorous exercise), increased secretion of other hormones such as adrenaline, cortisol and growth hormone, and increased activity of the sympathetic nervous system, come into play; their actions to increase hepatic glucose output and to suppress tissue glucose uptake are partly mediated by increases in tissue fatty acid oxidation. In diabetes, the most common disorder of glucose homeostasis, fasting hyperglycaemia, results primarily from excessive release of glucose by the liver due to increased gluconeogenesis; postprandial hyperglycaemia results from both impaired suppression of hepatic glucose release and impaired skeletal muscle glucose uptake. These abnormalities are usually due to the combination of impaired insulin secretion and tissue resistance to insulin, the causes of which remain to be determined.

Adjusting insulins

The teaching of effective insulin adjustment is a formal process that benefits from being carried out in a standardized way. The unique methods outlined in this report have been taught to people with diabetes for over 8 years. Iterative in nature, the methods are safe and work to achieve specified blood glucose or HbA1c targets. They are designed to accommodate each individual's habits, recognizing that acceptance depends on adapting the medication to the life-style rather than vice versa. New technology was used to mediate insulin adjustments at home. Insulin adjustment of itself, however, is but one of five interdependent factors involved in successful self-management. These include (1) choosing sites of insulin injection; (2) choosing species of origin of insulins to be used; (3) reviewing life-style habits, including diet and exercise; (4) implementing dosage titration; and (5) follow-up. Lack of formalized insulin adjustment methods may be a major reason why many diabetes control programs fail to demonstrate significantly better metabolic control in their patients.

Impaired glucose disposal following mild hypoglycemia in nondiabetic and type I diabetic humans

Insulin-mediated glucose disposal was studied immediately prior to and following moderate hypoglycemia in nondiabetic subjects and subjects with insulin-dependent (type I) diabetes mellitus (IDDM), the latter having varying epinephrine secretory capacities. Plasma insulin concentration was fixed throughout the study at approximately 300 to 400 pmol/L to avoid effects of waning insulin action and plasma glucose was clamped at either 5 mmol/L (euglycemic control) or at 3.1 mmol/L (hypoglycemic) periods of 120 minutes. Baseline (clamp 1) and postexperiment (clamp 2) periods were assessed for net glucose disposal (as a function of the exogenous glucose infusion rate) and glucose kinetics using 3H-glucose. In normal subjects, glucose disposal increased progressively by 132% during control studies but only by 57% with intervening hypoglycemia (P less than .005). Similarly, 33% during hypoglycemia, P less than .025). These changes were mediated by reduction of whole-body glucose uptake (rate of glucose disappearance [Rd], [3H]-3-glucose) and metabolic clearance rates with comparable suppression of hepatic glucose production in both groups. The increase in plasma free-fatty acids (FFA) following hypoglycemia was modest but greater in subjects with IDDM (P less than .01), whereas IDDM had reduced concentrations of epinephrine (P less than .01) and glucagon (P less than .005) during hypoglycemia. In subjects with IDDM but not in normal subjects, the change in posthypoglycemia glucose disposal was inversely correlated with the increase in plasma norepinephrine (R2 = .54, P less than .004) and epinephrine (R2 = .32, P less than .04). Glucose disposal did not correlate with other counterregulatory hormones, plasma FFA, or antecedent glycemic control.(ABSTRACT TRUNCATED AT 250 WORDS)

Lack of beta 2-adrenoceptor induced long-acting effect on glucose tolerance in type 2 diabetic patients

The long-acting effect of a 10-min pulse infusion of the beta 2-adrenergic agonist fenoterol on oral glucose tolerance tests in controls and in normotensive patients with type 2 diabetes mellitus on diet was compared. During an oral glucose load starting 2 h after fenoterol control persons showed hyperglycemia (area: 25,950 +/- 467 vs. 22,650 +/- 410, P less than 0.01), hyperinsulinemia (area: 13,980 +/- 1050 vs. 8160 +/- 405, P less than 0.02) and a pronounced fall of serum potassium (area: 775 +/- 26 vs. 748 +/- 25, P less than 0.02). The patient group showed no late response to fenoterol: plasma glucose (area: 51,000 +/- 382 vs. 51,300 +/- 413, n.s.), serum insulin (area: 7215 +/- 233 vs. 8280 +/- 410, n.s.), serum potassium (area: 748 +/- 26 vs. 750 +/- 24, n.s.). The data show that there is a defect of the beta 2-adrenergic long-acting effect on glucose metabolism and on insulin release in type 2 diabetes mellitus.

The effect of asymptomatic nocturnal hypoglycemia on glycemic control in diabetes mellitus

To assess the effect of asymptomatic nocturnal hypoglycemia on glycemic control in insulin-dependent diabetes mellitus, we studied, on three nights, 10 patients receiving their usual regimens of continuous subcutaneous insulin infusion. During a control night, the patients' mean (+/- SE) plasma glucose level reached a nadir of 4.5 +/- 0.2 mmol per liter at 3 a.m.; the fasting glucose level was 5.9 +/- 0.3 mmol per liter at 7:30 a.m., and a peak glucose level of 8.6 +/- 0.3 mmol per liter was reached at 10 a.m., after breakfast. During nights two and three, supplemental insulin was infused intravenously from 10 p.m. to 2 a.m. to simulate a clinical overdose of insulin. On these nights, either hypoglycemia (2.4 +/- 0.2 mmol per liter) was permitted to occur or a nearly normal glucose level (5.5 mmol per liter) was maintained by infusion of glucose. The subjects were asymptomatic on all three nights. Despite comparable plasma free insulin levels from 4 to 11 a.m., both fasting (7.3 +/- 0.2 mmol per liter) and postbreakfast (12.5 +/- 0.4 mmol per liter) plasma glucose levels were significantly higher after hypoglycemia than when hypoglycemia was prevented (6.2 +/- 0.2 mmol per liter and 8.7 +/- 0.4 mmol per liter, respectively; P less than 0.001 in both cases). Fasting levels of plasma glucose correlated directly with overnight plasma levels of epinephrine (r = 0.78, P less than 0.001), growth hormone (r = 0.57, P less than 0.009), and cortisol (r = 0.52, P less than 0.02) but correlated inversely with the overnight nadir of plasma glucose (r = -0.62, P less than 0.005). We conclude that asymptomatic nocturnal hypoglycemia can cause clinically important deterioration in glycemic control (the Somogyi phenomenon) in patients receiving intensive insulin therapy, and should therefore be considered in the differential diagnosis of unexplained morning hyperglycemia.

Transient insulin resistance following infusion of adrenaline in type 1 (insulin-dependent) diabetes mellitus

Insulin resistance was assessed after an intravenous infusion of adrenaline (50 ng.kg-1.min-1) or saline (control study) given between 08.00 and 08.30 hours in nine patients with Type 1 (insulin-dependent) diabetes mellitus. The blood glucose level during a somatostatin (100 micrograms/h)-insulin (0.4 mU.kg-1.min-1)-glucose (4.5 mg.kg-1.min-1)-infusion-test performed between 10.30 and 14.30 hours served as an indicator of the total body insulin resistance. Blood glucose was maintained around 7 mmol/l between 08.00 and 10.30 hours by a constant infusion of regular insulin (0.57 mU.kg-1.min-1) and a variable infusion of a 20% glucose solution. The infusion of adrenaline raised plasma adrenaline to 2.7 +/- 0.3 nmol/l (mean +/- SEM) at the end of the infusion; thereafter it returned to its basal level within 30 min. The plasma levels of free insulin, glucagon, cortisol and growth hormone were similar in the adrenaline and the control studies from 08.00 to 14.30 hours. In comparison with the control study the infusion of adrenaline decreased the need for intravenous glucose significantly over the initial 2 h. Furthermore, during the somatostatin-insulin-glucose infusion test the blood glucose rose significantly (p less than 0.05) over the initial 2 h; thereafter no significant differences between the two studies were seen. It is concluded that a short term infusion of adrenaline, resembling the adrenergic hormone response to hypoglycaemia, induces a diabetogenic effect which subsides within 6 h after omission of the adrenaline infusion.

Non-insulin-dependent diabetic patients (NIDDMs) do not demonstrate the dawn phenomenon at presentation

A dawn rise of plasma glucose (PG) and/or insulin, the 'dawn phenomenon', has been commonly reported in treated diabetic patients and normal subjects. To evaluate the effect of treatment on this phenomenon in non-insulin-dependent diabetics (NIDDMs), PG, C peptide, immunoreactive insulin (IRI), growth hormone (GH), cortisol, epinephrine, and norepinephrine were measured hourly between 24.00 and 09.00 h in 17 newly diagnosed untreated NIDDMs (group 1). The study was repeated in 11 patients after a year of treatment (group 2). The PG levels did not change significantly at any time from 03.00 to 08.00 h in group 1 but increased continuously from 6.7 +/- 0.5 mmol/l at 04.00 h to 7.8 +/- 0.5 mmol/l at 08.00 h (P less than 0.01) in group 2. IRI and C peptide decreased significantly after 07.00 h in both groups. GH and catecholamine changes were similar in group 1 and group 2. Cortisol levels showed a nadir at 02.00 h and a peak after 07.00 h in both groups. Our results demonstrate no dawn rise of mean PG, IRI and C peptide in newly diagnosed untreated NIDDMs but a significant rise of PG in the early morning period in NIDDMs after a year of treatment with diet alone and diet plus sulphonylureas. Therefore other factors such as treatment and/or duration of the diabetes may play an important role in the pathogenesis of the dawn phenomenon.

Failure of nocturnal hypoglycemia to cause fasting hyperglycemia in patients with insulin-dependent diabetes mellitus

To test the hypothesis that nocturnal hypoglycemia causes fasting hyperglycemia (the Somogyi phenomenon) in patients with insulin-dependent diabetes mellitus, we studied 10 patients, who were on their usual therapeutic regimens, from 10 p.m. through 8 a.m. on three nights. On the first night, only a control procedure was performed (blood sampling only); on the second night, hypoglycemia was prevented (by intravenous glucose infusion, if necessary, to keep plasma glucose levels above 100 mg per deciliter [5.6 mmol per liter]); and on the third night, hypoglycemia was induced (by stepped intravenous insulin infusions between midnight and 4 a.m. to keep plasma glucose levels below 50 mg per deciliter [2.8 mmol per liter]). After nocturnal hypoglycemia was induced (36 +/- 2 mg per deciliter [2.0 +/- 0.1 mmol per liter] [mean +/- SE] from 2 to 4:30 a.m.), 8 a.m. plasma glucose concentrations (113 +/- 18 mg per deciliter [6.3 +/- 1.0 mmol per liter]) were not higher than values obtained after hypoglycemia was prevented (182 +/- 14 mg per deciliter [10.1 +/- 0.8 mmol per liter]) or those obtained after blood sampling only (149 +/- 20 mg per deciliter [8.3 +/- 1.1 mmol per liter]). Indeed, regression analysis of data obtained on the control night indicated that the 8 a.m. plasma glucose concentration was directly related to the nocturnal glucose nadir (r = 0.761, P = 0.011). None of the patients was awakened by hypoglycemia. Scores for symptoms of hypoglycemia, which were determined at 8 a.m., did not differ significantly among the three studies. We conclude that asymptomatic nocturnal hypoglycemia does not appear to cause clinically important fasting hyperglycemia in patients with insulin-dependent diabetes mellitus on their usual therapeutic regimens.

Prolonged insulin resistance following insulin-induced hypoglycaemia

Nineteen normal male volunteers underwent a 10-h glucose clamp study to examine the duration and mechanism of insulin resistance after hypoglycaemia. Dextrose delivery by the Biostator to maintain the target blood glucose level fell below baseline 2 h after induction of hypoglycaemia and remained suppressed for at least 7 h after insulin hypoglycaemia. Insulin secretion as manifested by C-peptide levels remained suppressed for 3-4 h after insulin hypoglycaemia despite return of blood glucose to baseline by 90 min. Glucose kinetic data (3-3H-glucose) performed in six of the subjects indicated that the prolonged insulin resistance was due to significantly increased hepatic glucose production and to suppressed glucose utilisation, persisting for at least 4 h after counterregulatory hormone levels had returned to normal. Post-hypoglycaemic insulin resistance as determined by dextrose delivery was markedly attenuated and the rise in hepatic glucose output totally eliminated in five hypopituitary subjects without growth hormone or cortisol responses to hypoglycaemia. We conclude that post-hypoglycaemic insulin resistance occurs in non-diabetic subjects and persists for at least 7 h following hypoglycaemia. This prolonged insulin resistance is largely related to release of growth hormone and cortisol.

Insulin resistance in type 1 (insulin-dependent) diabetes following hypoglycaemia--evidence for the importance of beta-adrenergic stimulation

The insulin effect, evaluated with the euglycaemic clamp technique, was studied before and after hypoglycaemia in 7 patients with Type 1 (insulin-dependent) diabetes. Following an initial 2 h clamp (clamp I) hypoglycaemia was induced and 2 h later a second clamp (clamp II), identical to the former, was performed. Each subject was studied twice; during infusion with saline (placebo) or propranolol. Glucose production and disposal were studied with the 3(3H)glucose technique. During placebo infusion, hypoglycaemia elicited an insulin resistance leading to approx. 50% reduction in the steady state glucose infusion rate during clamp II as compared to clamp I (clamp I 2.58 +/- 0.32, clamp II 1.26 +/- 0.08 mg . kg-1 . min-1, p less than 0.02). The insulin resistance was prevented by infusing propranolol (clamp I 2.29 +/- 0.29, clamp II 2.85 +/- 0.56 mg . kg-1 . min-1). The posthypoglycaemic insulin resistance was due to a less pronounced insulin effect on both glucose production (clamp I 0.29 +/- 0.21, clamp II 0.86 +/- 0.19 mg . kg-1 . min-1, p less than 0.05) and glucose utilisation (clamp I 2.84 +/- 0.26, clamp II 2.13 +/- 0.23 mg . kg-1 . min-1, p less than 0.05). The insulin resistance on both glucose production and utilisation was prevented by propranolol. Thus, the present study demonstrates that hypoglycaemia elicits a prolonged insulin resistance which is due to a less pronounced effect of insulin to both inhibit splanchnic glucose production and to stimulate peripheral glucose utilisation. The insulin resistance is due to beta-adrenergic stimulation and can be prevented by propranolol.

Outpatient management of diabetes mellitus

Outpatient encounters form the mainstay of managing type I diabetes mellitus in children and adolescents. Management philosophy rests on the premise that normal physical and emotional growth is attainable and long-term complications minimized by maintenance of metabolic (glycemic) control. Management principles involve a coordinated team approach of physician, nurse-educator, and dietitian interacting with the family unit to educate them in the appropriate use and adjustment of insulin regimens, to recognize and treat the Somogyi and dawn phenomena, adjustment of nutritional needs, short- and long-term monitoring via home blood glucose and glycosylated hemoglobin measurements, and clues from the history and physical examination that permit anticipatory or reactive steps to achieve the treatment goals.

Early posthypoglycemic insulin resistance in man is mainly an effect of beta-adrenergic stimulation

The insulin effect following hypoglycemia was studied with the euglycemic clamp technique in seven healthy subjects. Following an initial euglycemic clamp hypoglycemia was induced and after glucose recovery a second clamp was performed. Glucose production (Ra) and utilization (Rd) were studied with [3-3H]glucose. Each subject was studied four times; during infusion of placebo, propranolol, somatostatin, and a control study where hypoglycemia was prevented. Hypoglycemia induced an insulin resistance with a lower steady state glucose infusion rate following the hypoglycemia during placebo as compared to the control study (2.5 +/- 0.5 and 4.8 +/- 1.0 mg/kg min, respectively, P less than 0.05). The insulin resistance was due to an attenuated insulin effect on both inhibition of Ra (impaired by 37%) and stimulation of Rd (impaired by 61%). The insulin-antagonistic effect was completely prevented by propranolol but only partly by somatostatin. Thus, early posthypoglycemic insulin resistance (2.5-3.5 h after hypoglycemia) is a sustained effect mainly due to beta-adrenergic stimulation.

Complications of insulin-dependent diabetes mellitus: management of insulin reactions and acute illness

Occasional mild hypoglycemia is an unavoidable and usually acceptable side effect of intensive insulin therapy. Patients with insulin-dependent diabetes mellitus may have impaired glucose counterregulation, which may increase the risk of hypoglycemia and justify less ambitious glycemic goals. A conservative but flexible approach to the treatment of insulin reactions is appropriate in order to avoid hyperglycemia. Insulin requirements are often increased during acute illness, and frequent self-monitoring of blood glucose concentrations is necessary to determine the need for supplementation with regular insulin. Frequent supplementation, together with modification of diet and maintenance of fluid intake, should not only minimize the need for hospitalization but also prevent severe deterioration in glycemic control.

Cognitive function during hypoglycaemia in type I diabetes mellitus

Neuropsychological testing was carried out in 16 insulin dependent (type I) diabetic men during four periods when mean blood glucose concentrations were (A) 6.3 (SEM 0.13) mmol/l (113.5 (SEM 2.3) mg/100 ml), (B) 2.9 (0.05) mmol/l (52.3 (0.9) mg/100 ml), and (C) 1.8 (0.03) mmol/l (32.4 (0.05) mg/100 ml), all measured during intravenous insulin infusion, and (D) 6.1 (0.13) mmol/l (109.9 (2.3) mg/100 ml), measured after intravenous glucose. The total neuropsychological test score decreased between periods A and B, A and C, and B and C, whereas improvement occurred between periods C and D (all p less than 0.02). These results were not due to changes in individual subjects alone but were consistent for the whole group. During hypoglycaemia there were changes in the patients' estimates of elapsed time, which were underestimated at period C as compared with the estimates at periods A, B, and D (all p less than 0.05). None of the 16 patients noticed symptoms of hypoglycaemia at period A or B, 12 reported symptoms at C, and one at D. Patients with type I diabetes may show a deterioration in neuropsychological skills during periods of asymptomatic subnormal or hypoglycaemic blood glucose concentrations.

Frequency of daytime biochemical hypoglycaemia in insulin-treated diabetic patients: relation to daily median blood glucose concentrations

The frequency and distribution of daytime biochemical hypoglycaemia (capillary blood glucose concentration below 3 mmol/l) was assessed in type 1 diabetic patients on conventional twice daily insulin therapy (n = 79) and on continuous subcutaneous insulin infusion (n = 20). Patients collected and mailed to the hospital blood for seven-point blood glucose profiles. For both treatment regimens the frequency of biochemical hypoglycaemia on individual days was inversely related to the median blood glucose concentration in a curvilinear manner (p less than 0.001). Hypoglycaemia was more frequent pre-prandially than post-prandially (p less than 0.01), and was evenly distributed during the day in patients on continuous subcutaneous insulin infusion. In patients on conventional therapy, however, pre-lunch hypoglycaemia was four times more frequent than pre-breakfast or pre-dinner hypoglycaemia (p less than 0.0001).

Strict nocturnal diabetic control diminishes subsequent glycemic escape during acute insulin withdrawal

Five Type 1 (insulin dependent) diabetic patients with no endogenous insulin secretion and very low antiinsulin antibody levels (IBC less than 4%) were studied twice. Nocturnal plasma glucose was maintained by intravenous insulin just beyond each extreme of the normal range, either "hypoglycemic," at 2.71 +/- 0.03 mmol/L, or "hyperglycemic," 8.59 +/- 0.13 mmol/L. Glucose turnover measurements were performed before and after insulin was discontinued the following morning. The steady state plasma glucose concentration achieved during subsequent glycemic escape was significantly lower following nocturnal hypoglycemia, (16.1 +/- 0.3 v 20.2 +/- 0.03 mmol/L; P less than 0.01). The initial rate of rise of plasma glucose was identical in both groups. Free insulin levels, although significantly higher in the hypoglycemic study, before withdrawal, 24.3 +/- 6.0 v 13.3 +/- 0.8 mU/L, (P less than 0.01), fell to similarly low levels 1 hour after insulin withdrawal. Free fatty acid and total ketone concentrations were normalized during hypoglycemia, but remained elevated in the hyperglycemic group. Lactate concentrations were not different in the two studies. During glycemic escape glucose appearance rate (Ra) rose faster following hypoglycemia, but similar final rates were achieved in each group. When related to plasma glucose concentration glucose uptake (Rd) was normal following hypoglycemia and remained persistently greater than the hyperglycemic group throughout the 5 hours following insulin withdrawal. Plasma cortisol, pancreatic glucagon, and growth hormone levels were not significantly different in the two groups following withdrawal. It is suggested that the persistent normal glucose uptake, following glycemic control that has been sufficient to normalize plasma metabolites, will limit glycemic excursions caused by acute reductions in plasma-free insulin concentration.(ABSTRACT TRUNCATED AT 250 WORDS)

Rationale for inhibition of growth hormone secretion in the management of the diabetic patient

Patients with diabetes mellitus, especially the insulin-dependent variety, have increased circulating levels of growth hormone. On the basis of currently available information, the potential advantages of inhibition of growth hormone secretion as an adjunct in the treatment of diabetes mellitus include improved metabolic control (less hyperglycaemia, greater stability), resulting from diminution of the insulin-antagonistic actions of this hormone, and reduced micro- and possibly macro-angiopathy, resulting not only from improved metabolic control but also from decreased direct effects of growth hormone on blood vessels.