Lori J. Smith scite author profile

To assess the roles of decrements in insulin and increments in glucagon in the prevention of hypoglycemia during moderate exercise (approximately 60% peak O2 consumption for 60 min), normal young men were studied during somatostatin infusions with insulin and glucagon infused to 1) hold insulin and glucagon levels constant, 2) decrease insulin, 3) increase glucagon, and 4) decrease insulin and increase glucagon during exercise. In contrast to a comparison study (saline infusion), when insulin and glucagon were held constant, glucose production did not increase and plasma glucose decreased from 5.5 +/- 0.2 to 3.4 +/- 0.2 mmol/l (P less than 0.001) initially during exercise. Notably, plasma glucose then plateaued and was 3.3 +/- 0.2 mmol/l at the end of exercise. This decrease was at most only delayed when either insulin was decreased or glucagon was increased independently. However, when insulin was decreased and glucagon was increased simultaneously, there was an initial increase in glucose production, and the glucose level was 4.5 +/- 0.2 mmol/l at 60 min, a value not different from that in the comparison study. Thus we conclude that both decrements in insulin and increments in glucagon play important roles in the prevention of hypoglycemia during exercise and do so by signaling increments in glucose production. However, since hypoglycemia did not develop during exercise when changes in insulin and glucagon were prevented, an additional counterregulatory factor, such as epinephrine, must be involved in the prevention of hypoglycemia during exercise, at least when the primary factors, insulin and glucagon, are inoperative.

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Catecholamines in prevention of hypoglycemia during exercise in humans

Marker

Hirsch

Smith

et al. 1991

American Journal of Physiology-Endocrinology and Metabolism

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To assess the role of catecholamines in the prevention of hypoglycemia during moderate exercise (approximately 60% peak O2 consumption for 60 min), normal humans were studied with combined alpha- and beta-adrenergic blockade and with adrenergic blockade while changes in insulin and glucagon were prevented with the islet clamp technique (somatostatin infusion with insulin and glucagon infused at fixed rates). The results were compared with those from an islet clamp alone study. In contrast to a comparison study (saline infusion), adrenergic blockade resulted in a small initial decrease in plasma glucose during exercise, from 5.0 +/- 0.2 to 4.4 +/- 0.2 mmol/l (P less than 0.01), but the level then plateaued. There was a substantial exercise-associated decrement in plasma glucose when insulin and glucagon were held constant, i.e., from 5.5 +/- 0.2 to 3.4 +/- 0.2 mmol/l (P less than 0.0001), but the level again plateaued. However, when insulin and glucagon were held constant and catecholamine actions were blocked simultaneously, progressive hypoglycemia, to 2.6 +/- 0.6 mmol/l (P less than 0.001), developed during exercise. Hypoglycemia was the result of an absent increase in glucose production and an exaggerated initial increase in glucose utilization. Thus we conclude that sympathochromaffin activation plays a minor role when insulin and glucagon are operative, but a catecholamine, probably epinephrine, becomes critical to the prevention of hypoglycemia during exercise when changes in insulin and glucagon do not occur.

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Role of GH in regulating nocturnal rates of lipolysis and plasma mevalonate levels in normal and diabetic humans

Boyle

Avogaro

Smith

et al. 1992

American Journal of Physiology-Endocrinology and Metabolism

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To define the role that nocturnal increments in growth hormone (GH) play in maintaining lipolysis, glycerol turnover was measured in six patients with GH deficiency and six normal subjects during sleep. Glycerol production initially decreased in both groups but then increased to 1.44 +/- 0.20 mumol.kg-1.min-1 by 0800 h in normal subjects, whereas GH deficiency was associated with a continuous fall to 0.77 +/- 0.10 mumol.kg-1.min-1, P less than 0.02. Nonesterified fatty acid levels paralleled these changes. Six GH-deficient patients received basal GH replacement including a pulse during sleep, which resulted in normal fasting fatty acid levels (P less than 0.05, replaced vs. chronic deficiency). To assess a possible link between the normal nocturnal increase in plasma mevalonate (the product of the rate-limiting step in cholesterol synthesis) and sleep-associated GH release, 11 GH-deficient patients and 11 normal subjects were studied. Peak nocturnal and fasting mevalonate concentrations were not correlated with GH level. We conclude that nocturnal growth hormone secretion is essential for maintaining lipolysis but that it is not related to normal increments in mevalonate and, by inference, to cholesterol synthesis during sleep.

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Failure of Nocturnal Hypoglycemia to Cause Daytime Hyperglycemia in Patients With IDDM

Hirsch

Smith

Havlin

et al. 1990

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To test the hypothesis that nocturnal hypoglycemia causes postprandial hyperglycemia the next day (the Somogyi phenomenon) in patients with insulin-dependent diabetes mellitus (IDDM), we studied 10 moderately well controlled patients, who were on their usual therapeutic regimens, from 2000 to 2000 on three occasions. On a control day, samples were obtained without intervention. On another day, nocturnal hypoglycemia was prevented (by intravenous infusion of glucose, if necessary, from 2200 to 0400 to keep plasma glucose levels at greater than 5.6 mM). On another day, nocturnal hypoglycemia was induced (by stepped intravenous insulin infusions between 2200 and 0200 to reduce plasma glucose levels to less than 2.8 mM). After nocturnal hypoglycemia (1.9 +/- 0.2 mM), fasting (0800), morning (0800-1100), afternoon (1200-1500), evening (1600-2000), and entire-day (0800-2000) plasma glucose concentrations were no higher than those after prevention of nocturnal hypoglycemia or sampling only. On the control day, fasting and daytime plasma glucose levels were directly related to the preceding 2200 (r = 0.723, P less than 0.02, and r = 0.762, P = 0.01, respectively) and nocturnal nadir (r = 0.714, P less than 0.02, and r = 0.728, P less than 0.02) plasma glucose concentrations. Daytime plasma glucose levels were unrelated to peak nocturnal plasma glucagon, epinephrine, norepinephrine, growth hormone, or cortisol concentrations. We conclude that nocturnal hypoglycemia does not appear to cause clinically important daytime hyperglycemia in patients representative of most patients with IDDM.

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Absence of the dawn phenomenon and abnormal lipolysis in Type 1 (insulin-dependent) diabetic patients with chronic growth hormone deficiency

et al. 1992

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Summary.To determine the role of growth hormone in overnight insulin requirements and lipolysis, five patients with chronic growth hormone deficiency and Type 1 (insulindependent) diabetes mellitus and six control patients with diabetes were each studied on two separate nights. Insulin was infused at a variable rate throughout one night to maintain euglycaemia and fixed at 04.00 hours on another. During the variable infusion, euglycaemia was maintained in control patients by a 36% increase in insulin infusion rate between 03.00 and 08.00 hours while a 46% decrease in the rate was required in growth hormone deficient patients (p < 0.02). Despite this difference, mean free insulin values were equivalent. This finding is suggestive of increased insulin clearance in growth hormone sufficient patients. Glucose levels rose in control and fell in growth hormone deficient patients when insulin infusion rates were fixed at 04.00 hours. Glycerol production and non-esterified fatty acid concentrations were significantly lower in the growth hormone deficient diabetic patients, p < 0.001, and when normalized with a heparin infusion, had no effect on insulin requirements. We conclude that: (1) growth hormone contributes to the development of the "dawn phenomenon," possibly by increasing insulin clearance (2) growth hormone helps sustain nocturnal lipolysis in Type i diabetes and (3) non-esterified fatty acids are not involved in the dawn phenomenon.

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Lori J. Smith

Insulin and glucagon in prevention of hypoglycemia during exercise in humans

Catecholamines in prevention of hypoglycemia during exercise in humans

Role of GH in regulating nocturnal rates of lipolysis and plasma mevalonate levels in normal and diabetic humans

Failure of Nocturnal Hypoglycemia to Cause Daytime Hyperglycemia in Patients With IDDM

Absence of the dawn phenomenon and abnormal lipolysis in Type 1 (insulin-dependent) diabetic patients with chronic growth hormone deficiency

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