Jan Östman

Differences at the Receptor and Postreceptor Levels Between Human Omental and Subcutaneous Adipose Tissue in the Action of Insulin on Lipolysis

The possible existence of regional differences in the antilipolytic action of insulin in human adipose tissue was investigated in vitro. Insulin-induced inhibition of glycerol release and insulin binding, measured in terms of receptor number, receptor affinity, and dissociation rates, were determined in omental and subcutaneous adipose tissue segments and isolated fat cells of 16 nonobese subjects who were undergoing elective abdominal surgery but were otherwise healthy. The sensitivity of the antilipolytic effect of insulin was higher in subcutaneous than in omental adipose tissue; the half-maximal effect was obtained with 1 and 3 μU/ml of insulin, respectively (P < 0.01). Responsiveness of the antilipolytic effect of insulin was threefold higher in the subcutaneous than in the omental region (P < 0.005). Insulin receptor affinity was significantly higher in subcutaneous than in omental fat cells, but there was no difference in receptor number (about 300,000 sites/cell). 125I-insulin dissociated more rapidly from omental than from subcutaneous adipocytes in both the absence and the presence of excess native insulin. The data suggest that significant regional differences exist in the antilipolytic action of insulin in man; omental fat being less responsive than subcutaneous fat. The difference involves the insulin receptor affinity, which is caused at least partly by variations in the insulin dissociation rate but is also due to differences in insulin action at the postreceptor level.

Regional differences in the control of lipolysis in human adipose tissue

Omental fat cells were 30% smaller than those in subcutaneous regions. In omental fat cells with a mean diameter of 95 mu, the basal cAMP concentration was 50% lower, but the basal rate of glycerol release was three times as rapid as in subcutaneous (epigastric) fat cells of identical size. Added at maximal effective concentration, noradrenaline increased the level of cAMP and the rate of glycerol release more markedly in the omental than in the subcutaneous adipocytes, whereas the response to isopropyl noradrenaline was similar. Before starvation the lipolytic effects of noradrenaline and isopropyl noradrenaline, respectively, were identical in the two regions of subcutaneous adipose tissue investigated (femoral and hypogastric). The findings were well related to the tissue levels of cAMP induced by the two agents. During starvation noradrenaline and isopropyl noradrenaline increased the cAMP level and the rate of lipolysis in fat cells obtained from the hypogastric region, whereas noradrenaline decreased these parameters in femoral adipocytes. Starvation was associated with a more prominent inhibitory effect of phenylephrine on basal and isopropyl-noradrenaline-induced lipolysis in femoral than in hypogastric adipose tissue. In conclusion, differences exist between different regions of adipose tissue in their lipolytic responsiveness to noradrenaline, which seems related to the balance between alpha- and beta-adrenergic receptor response.

Prevention of Kidney Graft Diabetic Nephropathy by Pancreas Transplantation in Man

Kidney graft biopsies were performed 2–3 yr after transplantation in eight type I (insulin-dependent) diabetic patients who had previously been subjected to kidney transplantation (six patients) or combined kidney and segmental pancreas transplantation (two patients). In five of the six patients that had undergone only kidney transplantation, light microscopic examination of the graft biopsy revealed changes compatible with diabetic nephropathy, and electron microscopic morphometry showed a thickening of the glomerular basement membrane (GBM). In the two patients who had been subjected to combined pancreas and kidney transplantation, the kidney graft biopsy showed no light microscopic changes suggestive of diabetic nephropathy, and electron microscopy showed no thickening of the GBM. Thus, it appears to be possible to prevent the recurrence of diabetic nephropathy in human kidney allografts by simultaneous pancreas transplantation.

Turnover and splanchnic metabolism of free fatty acids and ketones in insulin-dependent diabetics at rest and in response to exercise.

Nine insulin-dependent diabetics and six healthy controls were studied at rest, during, and after 60 min of bicycle exercise at a work load corresponding to 45% of their maximal oxygen intake. The catheter technique was employed to determine splanchnic and leg exchange of metabolites. FFA turnover and regional exchange was evaluated using [14C]oleate infusion. Basal glucose (13.8 +/- 1.1 mmol/l), ketone body (1.12 +/- 0.12 mmol/l), and FFA (967 +/- 110 mumol/l) concentrations were elevated in the diabetics in comparison with controls. In the resting state, splanchnic ketone acid production in the diabetics was 6-10-fold greater than in controls. Uptake of oleic acid by the splanchnic bed was increased 2-3-fold, and the proportion of splanchnic FFA uptake converted to ketones (61%) was threefold greater than in controls. In contrast, splanchnic fractional extraction of oleic acid was identical in diabetics and controls. A direct relationship was observed between splanchnic uptake and splanchnic inflow (plasma concentration X hepatic plasma flow) of oleic acid that could be described by the same regression line in the diabetic and control groups. During exercise, splanchnic ketone production rose in both groups. In the control group the increase in ketogenesis was associated with a rise in splanchnic inflow and in uptake of oleic acid, a rise in splanchnic fractional extraction of oleate, and an increase in the proportion of splanchnic FFA uptake converted to ketone acids from 20-40%. In the diabetic group, the increase in ketogenesis occurred in the absence of a rise in splanchnic inflow or uptake of oleic acid, but was associated with an increase in splanchnic fractional extraction of oleic acid and a marked increase in hepatic conversion of FFA to ketones, so that the entire uptake of FFA was accountable as ketone acid output. Splanchnic uptake of oleic acid correlated directly with splanchnic oleic acid inflow in both groups, but the slope of the regression line was steeper than in the resting state. Plasma glucagon levels were higher in the diabetic group at rest and during exercise, while plasma norepinephrine showed a twofold greater increment in response to exercise in the diabetic group (to 1,400-1,500 pg/ml). A net uptake of ketone acids by the leg was observed during exercise but could account for less than 5% of leg oxidative metabolism in the diabetics and less than 1% in controls. Despite the increase in ketogenesis during exercise, a rise in arterial ketone acid levels was not observed in the diabetics until postexercise recovery, during which sustained increments to values of 1.8-1.9 mmol/l and sustained increases in splanchnic ketone production were observed at 30-60 min. The largest increment in blood ketone acids and in splanchnic ketone production above values observed in controls thus occurred in the diabetics after 60 min of recovery from exercise. We concluded that: (a) In the resting state, increased ketogenesis in the diabetic is a consequence of augmented splanchnic inflow of FFA and increased intrahepatic conversion of FFA to ketones, but does not depend on augmented fractional extraction of circulating FFA by the splanchnic bed. (b) Exercise-induced increases in ketogenesis in normal subjects are due to augmented splanchnic inflow and fractional extraction of FFA as well as increased intrahepatic conversion of FFA to ketones. (c) When exercise and diabetes are combined, ketogenesis increases further despite the absence of a rise in splanchnic inflow of FFA. An increase in splanchnic fractional extraction of FFA and a marked increase intrahepatic conversion of FFA to ketones accounts for the exaggerated ketogenic response to exercise in the diabetic. (d) Elevated levels of plasma glucagon and/or norepinephrine may account for the increased hepatic ketogenic response to exercise in the diabetic. (e) Ketone utilization by muscle increases during exercise but constitutes a quantitatively minor oxidative fuel for muscle even in the diabetic. (f) The accelerated ketogenesis during exercise in the diabetic continues unabated during the recovery period, resulting in an exaggerated postexercise ketosis.

The antilipolytic effect of insulin in human adipose tissue in obesity, diabetes mellitus, hyperinsulinemia, and starvation

The antilipolytic effect of insulin in vitro was investigated in conditions known to be associated with resistance to the effect of insulin on glucose metabolism. Human subcutaneous adipose tissue was obtained from 14 obese subjects before and during starvation for 7 days, 12 untreated non-insulin dependent diabetics (NIDDM), 6 untreated insulin dependent diabetics (IDDM), and 10 nonobese control subjects. The tissue was incubated with and without insulin in concentration ranging from 1-10,000 microunits/ml. Responsiveness (maximum effect) and sensitivity to insulin were determined under basal induction conditions, since insulin had a bimodal effect on noradrenaline stimulated lipolysis. Under normal conditions both insulin sensitivity and insulin responsiveness were positively correlated with the basal rate of lipolysis. In obesity, IDDM and NIDDM there were no change in insulin sensitivity or in insulin responsiveness. When the obese subjects were divided into one hyperinsulinemic group (6 individuals) and one group with normal fasting serum insulin levels (7 individuals) a similar antilipolytic effect of insulin was observed in the two groups. During starvation there was a 20-fold increase in insulin sensitivity (p less than 0.01) but no change in insulin responsiveness in femoral fat and only a decrease in responsiveness (p less than 0.01) in abdominal fat. The present data supports the view that antilipolysis in human fat cells is not involved in the insulin resistance seen in obesity, starvation, diabetes and hyperinsulinemia.

Residual insulin production, glycaemic control and prevalence of microvascular lesions and polyneuropathy in long-term Type 1 (insulin-dependent) diabetes mellitus

SummaryThe aim of the present study was to evaluate the role of residual insulin production in long-term Type 1 (insulin-dependent) diabetes mellitus. Ninety-seven patients with a disease duration of 9–16 years and onset before the age of 30 years were studied. C-peptide excretion in 24-h urine samples was measured as an indicator of residual insulin production. Thirty-five patients (36%) excreted C-peptide (>-0.2 nmol); as many as possible of them were carefully matched with a non-excretor patient with regard to age at onset of diabetes and disease duration. Twenty-nine pairs were obtained, and 22 of them agreed to participate in further investigations of glycaemic control and microangiopathic lesions. The patients who excreted C-peptide had significantly lower HbA1c than the non-excretor group, 6.9±0.3% vs 7.9±0.3%, (p<0.025). Moderate-to-advanced background retinopathy was found in 2 patients in the excretor group and in 7 patients in the nonexcretor group. Microalbuminuria [ratio of albumin: creatinine (mg/l:mmol/l) >-5] was found in 1 and in 5 patients, respectively, while proteinuria [ratio of protein: creatinine (mg/l: mmol/l× 10) >-136] was found in 0 and in 4 patients, respectively. Microalbuminuria and/or proteinuria was found in 7 of the non-excretor group as compared to 1 in the excretor group (p=0.046). When all the variables were taken into account, microalbuminuria and/or proteinuria and/or moderate-to-advanced background retinopathy was found in 3 of the excretor group compared to 11 of the non-excretor group (p=0.022). Reduced sensory and motor nerve conduction velocities were common findings and occurred with the same frequency in the two groups. The data suggest that residual insulin production in long-term Type 1 diabetes is associated with a more satisfactory glycaemic control and a lower prevalence of early microangiopathic eye and kidney lesions.

Hypoglycemia Risk During Exercise After Intramuscular Injection of Insulin in Thigh in IDDM

The influence of bicycle exercise (60% of W170 [working capacity at a pulse rate of 170 beats/min]; 40 min) on the absorption of 125I-labeled fast-acting insulin (10 U; Actrapid human insulin) after intramuscular compared with subcutaneous injection in the thigh was studied on 2 consecutive days in 10 insulin-dependent diabetes mellitus (IDDM) patients. Insulin absorption was measured as disappearance of radioactivity (1st-order elimination rate constants) by continuous external monitoring and as appearance of plasma free immunoreactive insulin (IRI). Subcutaneous adipose tissue blood flow (ATBF) and skeletal muscle blood flow (MF) were measured concomitantly in the contralateral thigh with the raXe wash-out technique. Plasma glucose was determined intermittently. The rate constant for 125l-insulin increased during exercise from 0.46 ± 0.08 to 1.17 ± 0.14%/min after intramuscular injection (P < 0.001) and from 0.31 ± 0.05 to 0.45 ± 0.09%/min (NS) after subcutaneous injection. The rate constant of 125I-insulin from muscle remained elevated during the 80-min recovery period. The peak plasma free-IRI value was 39 mU/L higher, the area under the IRI curve was ∼80% greater, and the decrease in plasma glucose was ∼2 mM greater after intramuscular injection. Whereas MF increased fivefold, ATBF did not rise significantly during exercise. The results demonstrate that intramuscular compared with subcutaneous thigh injection of insulin followed by bicycle exercise induces a marked increase in insulin absorption and a substantial fall in plasma glucose. Because accidental intramuscular injection of insulin may occur frequently, these findings highlight a previously unobserved risk for an unexpected decrease in plasma glucose levels in connection with leg exercise in IDDM patients. This risk could be minimized by injection into a skin fold or by use of shorter needles for thigh injection.

Male predominance of type 1 (insulin-dependent) diabetes mellitus in young adults : results from a 5-year prospective nationwide study of the 15-34 year age group in Sweden

SummaryThe incidence of diabetes mellitus in Sweden in the 15–34 year age group was prospectively studied on a nationwide basis, beginning 1 January 1983. A total of 1,214 male and 720 female cases of newly-diagnosed (excluding gestational) diabetes were reported over a 5-year period. This corresponds to an incidence of 20.5 per 100,000/year in male subjects and 12.7 per 100,000/year in female subjects. Most cases were classified as Type 1 (insulin-dependent) diabetes, with an incidence of 15.9 in males and 8.6 in females. The incidence of Type 1 diabetes decreased gradually with age, while the incidence of Type 2 (non-insulin-dependent) diabetes increased. A male predominance was found in all age groups, with a male-to-female ratio of 1.8∶1 for Type 1 diabetes and 1.3∶1 for Type 2 diabetes. Maximum blood glucose concentration at diagnosis was significantly higher in males than in females in both Type 1 and Type 2 diabetic subjects. In contrast, the percent desirable weight was significantly higher in females, both in Type 1 and Type 2 diabetic subjects. The difference in diabetes incidence therefore cannot be attributed to any methodological error. The present finding of a marked male predominance after puberty in Type 1 diabetes in an ethnically quite homogeneous population supports the hypothesis that environmental risk factors and life-style are important for the development of the disease.

SUCCESSFUL OUTCOME OF SEGMENTAL HUMAN PANCREATIC TRANSPLANTATION WITH ENTERIC EXOCRINE DIVERSION AFTER MODIFICATIONS IN TECHNIQUE

Segmental pancreatic transplantation is now the most widely favoured form of pancreatic transplantation, but the major difficulty with this procedure is the handling of the exocrine secretion. The use of a pancreaticoenteric anastomosis for exocrine diversion has been re-evaluated and several ancillary measures to reduce the risk of fistula and bacterial contamination have been applied. In three consecutive patients there have been no complications related to the exocrine pancreas. The pancreatic and renal grafts of these patients are functioning well 7, 3, and 2 months, respectively, after transplantation.

Negative association between type 1 diabetes and HLA DQB1*0602-DQA1*0102 is attenuated with age at onset

HLA-associated relative risks of type 1 (insulin-dependent) diabetes mellitus were analysed in population-based Swedish patients and controls aged 0-34 years. The age dependence of HLA-associated relative risks was assessed by likelihood ratio tests of regression parameters in separate logistic regression models for each HLA category. The analyses demonstrated an attenuation with increasing age at onset in the relative risk for the positively associated DQB1*0201-A1*0502/B1*0302-A1*0301 (DQ2/8) genotype (P = 0.02) and the negatively associated DQB1*0602-A1*0102 (DQ6.2) haplotype (P = 0.004). At birth, DQ6.2-positive individuals had an estimated relative risk of 0.03, but this increased to 1.1 at age 35 years. Relative risks for individuals with DQ genotype 8/8 or 8/X or DQ genotype 2/2 or 2/X, where X is any DQ haplotype other than 2, 8 or 6.2, were not significantly age-dependent. An exploratory analysis of DQ haplotypes other than 2, 8 and 6.2 suggested that the risk of type 1 diabetes increases with age for DQB1*0604-A1*0102 (DQ6.4) and that the peak risk for the negatively associated DQB1*0301-A1*0501 haplotype is at age 18 years. There was also weak evidence that the risk for DQB1*0303-A1*0301 (DQ9), which has a positive association in the Japanese population, may decrease with age. We speculate that HLA-DQ alleles have a significant effect on the rate of beta cell destruction, which is accelerated in DQ2/8-positive individuals and inhibited, but not completely blocked, in DQ6.2-positive individuals.