Glucoregulation during exercise: hypoglycemia is prevented by redundant glucoregulatory systems, sympathochromaffin activation, and changes in islet hormone secretion

Hypoglycemia in the Critically Ill Patient

Hypoglycemia is diagnosed convincingly when typical symptoms are associated with a low plasma glucose concentration and are relieved by glucose administration. It requires urgent treatment (usually with intravenous glucose in the hospital setting), diagnostic explanation, and long-term prevention. The latter is based upon an understanding of the pathogenesis of hypoglycemia in the affected patient. Postabsorptive (fasting) hypoglycemia is often caused by drugs (especially insulin, a sulfonylurea, or alcohol); it can also result from endogenous hyperinsulinism (insulinoma, autoimmune hypoglycemia), a non-β-cell tumor, hormonal deficiencies, or a variety of clinical syndromes including sepsis, cardiac, renal, and hepatic failure, and even inanition per se. Hypoglycemia is a treatable cause of acute morbidity. It is sometimes a cause of chronic morbidity and even mortality that could have been prevented.

Pancreatic β-cell identity, glucose sensing and the control of insulin secretion

Insulin release from pancreatic β-cells is required to maintain normal glucose homoeostasis in man and many other animals. Defective insulin secretion underlies all forms of diabetes mellitus, a disease currently reaching epidemic proportions worldwide. Although the destruction of β-cells is responsible for Type 1 diabetes (T1D), both lowered β-cell mass and loss of secretory function are implicated in Type 2 diabetes (T2D). Emerging results suggest that a functional deficiency, involving de-differentiation of the mature β-cell towards a more progenitor-like state, may be an important driver for impaired secretion in T2D. Conversely, at least in rodents, reprogramming of islet non-β to β-cells appears to occur spontaneously in models of T1D, and may occur in man. In the present paper, we summarize the biochemical properties which define the 'identity' of the mature β-cell as a glucose sensor par excellence. In particular, we discuss the importance of suppressing a group of 11 'disallowed' housekeeping genes, including Ldha and the monocarboxylate transporter Mct1 (Slc16a1), for normal nutrient sensing. We then survey the changes in the expression and/or activity of β-cell-enriched transcription factors, including FOXO1, PDX1, NKX6.1, MAFA and RFX6, as well as non-coding RNAs, which may contribute to β-cell de-differentiation and functional impairment in T2D. The relevance of these observations for the development of new approaches to treat T1D and T2D is considered.

Exercise and type 1 diabetes (T1DM)

Physical exercise is firmly incorporated in the management of type 1 diabetes (T1DM), due to multiple recognized beneficial health effects (cardiovascular disease prevention being preeminent). When glycemic values are not excessively low or high at the time of exercise, few absolute contraindications exist; practical guidelines regarding amount, type, and duration of age-appropriate exercise are regularly updated by entities such as the American Diabetes Association and the International Society for Pediatric and Adolescent Diabetes. Practical implementation of exercise regimens, however, may at times be problematic. In the poorly controlled patient, specific structural changes may occur within skeletal muscle fiber, which is considered by some to be a disease-specific myopathy. Further, even in well-controlled patients, several homeostatic mechanisms regulating carbohydrate metabolism often become impaired, causing hypo- or hyperglycemia during and/or after exercise. Some altered responses may be related to inappropriate exogenous insulin administration, but are often also partly caused by the "metabolic memory" of prior glycemic events. In this context, prior hyperglycemia correlates with increased inflammatory and oxidative stress responses, possibly modulating key exercise-associated cardio-protective pathways. Similarly, prior hypoglycemia correlates with impaired glucose counterregulation, resulting in greater likelihood of further hypoglycemia to develop. Additional exercise responses that may be altered in T1DM include growth factor release, which may be especially important in children and adolescents. These multiple alterations in the exercise response should not discourage physical activity in patients with T1DM, but rather should stimulate the quest for the identification of the exercise formats that maximize beneficial health effects.

Blood glucose regulation during prolonged, submaximal, continuous exercise: a guide for clinicians

Management of many chronic diseases now includes regular exercise as part of a viable treatment plan. Exercise in the form of prolonged, submaximal, continuous exercise (SUBEX; i.e., approximately 30 min to 1 h, approximately 40-70% of maximal oxygen uptake) is often prescribed due to its relatively low risk, the willingness of patients to undertake, its efficacy, its affordability, and its ease of prescription. Specifically, patients who are insulin resistant or that have type 2 diabetes mellitus may benefit from regular exercise of this type. During this type of exercise, muscles dramatically increase glucose uptake as the liver increases both glycogenolysis and gluco-neogenesis. While a redundancy of mechanisms is at work to maintain blood glucose concentration ([glucose]) during this type of exercise, the major regulator of blood glucose is the insulin/glucagon response. At exercise onset, blood [glucose] transiently rises before beginning to decline after approximately 30 min, causing a subsequent decline in blood [insulin] and rise in blood glucagon. This leads to many downstream effects, including an increase in glucose output from the liver to maintain adequate glucose in the blood to fuel both the muscles and the brain. Finally, when analyzing blood [glucose], consideration should be given to nutritional status (postabsorptive versus postprandial) as well as both what the analyzer measures and the type of sample used (plasma versus whole blood). In view of both prescribing exercise to patients as well as designing studies that perturb glucose homeostasis, it is imperative that clinicians and researchers alike understand the controls of blood glucose homeostasis during SUBEX.

Hyperinsulinaemia during exercise does not suppress hepatic glycogen concentrations in patients with type 1 diabetes: a magnetic resonance spectroscopy study

AIMS/HYPOTHESIS

We compared in vivo changes in liver glycogen concentration during exercise between patients with type 1 diabetes and healthy volunteers.

METHODS

We studied seven men with type 1 diabetes (mean +/- SEM diabetes duration 10 +/- 2 years, age 33 +/- 3 years, BMI 24 +/- 1 kg/m(2), HbA(1c) 8.1 +/- 0.2% and VO(2) peak 43 +/- 2 ml [kg lean body mass](-1) min(-1)) and five non-diabetic controls (mean +/- SEM age 30 +/- 3 years, BMI 22 +/- 1 kg/m(2), HbA(1c) 5.4 +/- 0.1% and VO(2) peak 52 +/- 4 ml [kg lean body mass](-1) min(-1), before and after a standardised breakfast and after three bouts (EX1, EX2, EX3) of 40 min of cycling at 60% VO(2) peak. (13)C Magnetic resonance spectroscopy of liver glycogen was acquired in a 3.0 T magnet using a surface coil. Whole-body substrate oxidation was determined using indirect calorimetry.

RESULTS

Blood glucose and serum insulin concentrations were significantly higher (p < 0.05) in the fasting state, during the postprandial period and during EX1 and EX2 in subjects with type 1 diabetes compared with controls. Serum insulin concentration was still different between groups during EX3 (p < 0.05), but blood glucose concentration was similar. There was no difference between groups in liver glycogen concentration before or after the three bouts of exercise, despite the relative hyperinsulinaemia in type 1 diabetes. There were also no differences in substrate oxidation rates between groups.

CONCLUSIONS/INTERPRETATION

In patients with type 1 diabetes, hyperinsulinaemic and hyperglycaemic conditions during moderate exercise did not suppress hepatic glycogen concentrations. These findings do not support the hypothesis that exercise-induced hypoglycaemia in patients with type 1 diabetes is due to suppression of hepatic glycogen mobilisation.

Effect of an acute beta-adrenergic blockade on the blood glucose response during lactate minimum test

The aim of this study was to determine the relationship between blood lactate and glucose during an incremental test after exercise induced lactic acidosis, under normal and acute beta-adrenergic blockade. Eight fit males (cyclists or triathletes) performed a protocol to determine the intensity corresponding to the individual equilibrium point between lactate entry and removal from the blood (incremental test after exercise induced lactic acidosis), determined from the blood lactate (Lacmin) and glucose (Glucmin) response. This protocol was performed twice in a double-blind randomized order by ingesting either propranolol (80 mg) or a placebo (dextrose), 120 min prior to the test. The blood lactate and glucose concentration obtained 7 minutes after anaerobic exercise (Wingate test) was significantly lower (p < 0.01) with the acute beta-adrenergic blockade (9.1 +/- 1.5 mM; 3.9 +/- 0.1 mM), respectively than in the placebo condition (12.4 +/- 1.8 mM; 5.0 +/- 0.1 mM). There was no difference (p > 0.05) between the exercise intensity determined by Lacmin (212.1 +/- 17.4 W) and Glucmin (218.2 +/- 22.1 W) during exercise performed without acute beta-adrenergic blockade. The exercise intensity at Lacmin was lowered (p < 0.05) from 212.1 +/- 17.4 to 181.0 +/- 15.6 W and heart rate at Lacmin was reduced (p < 0 .01) from 161.2 +/- 8.4 to 129.3 +/- 6.2 beats min(-1) as a result of the blockade. It was not possible to determine the exercise intensity corresponding to Glucmin with beta-adrenergic blockade, since the blood glucose concentration presented a continuous decrease during the incremental test. We concluded that the similar pattern response of blood lactate and glucose during an incremental test after exercise induced lactic acidosis, is not present during beta-adrenergic blockade suggesting that, at least in part, this behavior depends upon adrenergic stimulation.

Metabolic and hormonal responses to exercise in children and adolescents

Ethical and methodological factors limit the availability of data on metabolic and hormonal responses to exercise in children and adolescents. Despite this, it has been reported that young individuals show age-dependent responses to short and long term exercise when compared with adults. Adenosine triphosphate (ATP) and phosphocreatine stores are not age-dependent in children and adolescents. However, phosphorus-31 nuclear magnetic resonance spectroscopy (31PNMR) studies showed smaller reductions in intramuscular pH in children and adolescents during high intensity exercise than adults. Muscle glycogen levels at rest are less important in children, but during adolescence these reach levels observed in adults. Immaturity of anaerobic metabolism in children is a major consideration, and there are several possible reasons for this reduced glycolytic activity. There appear to be higher proportions of slow twitch (type I) fibres in the vastus lateralis part of the quadriceps in children than in untrained adults, and anaerobic glycolytic ATP rephosphorylation may be reduced in young individuals during high intensity exercise. Reduced activity of phosphofructokinase-1 and lactate dehydrogenase enzymes in prepubertal children could also explain the lower glycolytic capacity and the limited production of muscle lactate relative to adults. These observations may be related to reduced sympathetic responses to exhaustive resistance exercise in young people. In contrast, children and adolescents are well adapted to prolonged exercise of moderate intensity. Growth and maturation induce increases in muscle mass, with proliferation of mitochondria and contractile proteins. However, substrate utilisation during exercise differs between children and adults, with metabolic and hormonal adaptations being suggested. Lower respiratory exchange ratio values are often observed in young individuals during prolonged moderate exercise. Data indicate that children rely more on fat oxidation than do adults, and increased free fatty acid mobilisation. glycerol release and growth hormone increases in preadolescent children support this hypothesis. Plasma glucose responses during prolonged exercise are generally comparable in children and adults. When glucose is ingested at the beginning of moderate exercise, plasma glucose levels are higher in children than in adults, but this may be caused by decreased insulin sensitivity during the peripubertal period (as shown by glucose: insulin ratios).

CONCLUSIONS

Children are better adapted to aerobic exercise because their energy expenditure appears to rely more on oxidative metabolism than is the case in adults. Glycolytic activity is age-dependent, and the relative proportion of fat utilisation during prolonged exercise appears higher in children than in adults.

Effect of adrenaline on glucose kinetics during exercise in adrenalectomised humans

1. The role of adrenaline in regulating hepatic glucose production and muscle glucose uptake during exercise was examined in six adrenaline-deficient, bilaterally adrenalectomised humans. Six sex- and age-matched healthy individuals served as controls (CON). 2. Adrenalectomised subjects cycled for 45 min at 68 +/- 1 % maximum pulmonary O2 uptake (VO2,max), followed by 15 min at 84 +/- 2 % VO2, max without (-ADR) or with (+ADR) adrenaline infusion, which elevated plasma adrenaline levels (45 min, 4.49 +/- 0.69 nmol l-1; 60 min, 12.41 +/- 1.80 nmol l-1; means +/- s.e.m.). Glucose kinetics were measured using [3-3H]glucose. 3. Euglycaemia was maintained during exercise in CON and -ADR, whilst in +ADR plasma glucose was elevated. The exercise-induced increase in hepatic glucose production was similar in +ADR and -ADR; however, adrenaline infusion augmented the rise in hepatic glucose production early in exercise. Glucose uptake increased during exercise in +ADR and -ADR, but was lower and metabolic clearance rate was reduced in +ADR. 4. During exercise noradrenaline and glucagon concentrations increased, and insulin and cortisol concentrations decreased, but plasma levels were similar between trials. Adrenaline infusion suppressed growth hormone and elevated plasma free fatty acids, glycerol and lactate. Alanine and beta-hydroxybutyrate levels were similar between trials. 5. The results demonstrate that glucose homeostasis was maintained during exercise in adrenalectomised subjects. Adrenaline does not appear to play a major role in matching hepatic glucose production to the increase in glucose clearance. In contrast, adrenaline infusion results in a mismatch by simultaneously enhancing hepatic glucose production and inhibiting glucose clearance.

Glucose administration before exercise modulates catecholaminergic responses in glycogen-depleted subjects

In glycogen-depleted subjects (GD) a nonlinear increase in epinephrine (Epi) and norepinephrine (NE) parallels blood lactate (La) during graded exercise. The effect of glucose (Glc) supplementation and route of administration on these relationships was studied in 26 GD athletes who were randomly assigned to receive 1.3 g/kg Glc by slow intravenous infusion (IV; n = 9), oral administration (PO; n = 9), or artificially sweetened placebo in 1 liter of water (Asp; n = 8) in the 2 h preceding a graded maximal exercise. Performance and La were similar among the three groups in normal glycogen (NG) or GD conditions. However, slightly improved performances were observed in GD compared with NG and were associated with a shift to the right in La curves. Blood Glc concentrations were higher in IV and PO before exercise, but they rapidly decreased to lowest levels in IV, gradually decreased over time in PO, and remained stable in Asp or NG. Insulin concentrations were highest in IV and lowest in Asp and NG at onset of exercise, rapidly decreasing in IV and PO although remaining at higher levels than in Asp or NG. In contrast, higher serum levels of free fatty acids were measured during exercise in Asp with no significant differences in glucagon or glycerol among the three groups. Free and sulfated NE increases were smaller in IV than in PO and Asp on exhaustion. In contrast, free and conjugated Epi were most increased in IV, with smallest increases in Asp. Dopamine levels were most increased in IV at exhaustion. We conclude that the changes of Epi and NE concentrations, associated with the activation of glucoregulatory mechanisms, including hyperinsulinemia, display different magnitude and time courses during exercise in GD subjects who receive oral vs. intravenous load of Glc before exercise. We speculate that the magnitude of insulin surge after acutely increased Glc before exercise in GD subjects may exert dissociative effects on adrenal-dependent glycogenolysis and on sympathetic responses.

Neurohumoral, peptidergic and biochemical responses to supine exercise in two groups with primary autonomic failure: Shy-Drager syndrome/multiple system atrophy and pure autonomic failure

The neurohumoral, peptidergic and biochemical responses to supine leg exercise were studied in two groups with primary autonomic failure: Shy-Drager syndrome (SDS, n = 15) and pure autonomic failure (PAF, n = 15), to determine if these accounted for exercise-induced hypotension and the greater blood pressure (BP) fall in PAF. Responses were compared to normal subjects (controls, n = 15), in whom BP rose with exercise. Resting plasma noradrenaline (NA) was higher in controls than SDS, and was lowest in PAF. With exercise, NA increased in controls, with a small rise in SDS, but no change in PAF. Resting plasma adrenaline (A) was higher in controls and SDS than PAF, with no change during exercise. Plasma dopamine was unrecordable at all stages in all groups. Resting plasma renin activity (PRA) was higher in controls than SDS and PAF, and was unchanged with exercise in all groups. Plasma insulin, C-peptide and serum growth hormone (GH) were similar at rest and with exercise in the three groups. Plasma glucose was higher at rest in SDS and PAF, and increased with exercise in all three groups. In conclusion, neither exercise-induced hypotension, nor the differences between SDS and PAF could be related to abnormalities in the release of A, PRA, insulin, glucose or GH. The abnormal NA response to exercise was consistent with the BP fall being due to inadequate compensatory sympathetic activity. In SDS, the small NA increase, in the presence of supersensitivity, may have reduced their BP fall as compared to PAF. These results suggest that impaired sympathetic neural activity is a key factor in exercise-induced hypotension.

Coupling of external to cellular respiration during exercise: the wisdom of the body revisited

The changes in cellular respiration needed to increase energy output during exercise are intimately and predictably linked to external respiration through the circulation. This review addresses the mechanisms by which lactate accumulation might influence O2 uptake (VO2) and CO2 output (VCO2) kinetics. Respiratory homeostasis (a steady state with respect to VO2 and VCO2) is achieved by 3-4 min for work rates not associated with an increase in arterial lactate. When blood lactate increases significantly above rest for constant work rate exercise, VO2 characteristically increases past 3 min (slow component) at a rate proportional to the lactate concentration increase. The development of a similar slow component in VCO2 is not evident. The divergence of VCO2 from VO2 increase can be accounted for by extra CO2 release from the cell as HCO3- buffers lactic acid. Thus the slow component of aerobic CO2 production (parallel to VO2) is masked by the increase in buffer VCO2. This CO2, and the consumption of extracellular HCO3- by the lactate-producing cells, shifts the oxyhemoglobin dissociation curve rightward (Bohr effect). The exercise lactic acidosis has been observed to occur after the minimal capillary PO2 is reached. Thus the lactic acidosis serves to facilitate oxyhemoglobin dissociation and O2 transport to the muscle cells without a further decrease in end-capillary PO2. From these observations, it is hypothesized that simultaneously measured dynamic changes in VO2 and VCO2 might be useful to infer the aerobic and anaerobic contributions to exercise bioenergetics for a specific work task.

Glucose and free fatty acid utilization during prolonged exercise in prepubertal boys in relation to catecholamine responses

Ten prepubertal boys performed 60-min cycle exercise at about 60% of their maximal oxygen uptake as previously measured. To measure packed cell volume, plasma glucose, free fatty acids (FFA), glycerol and catecholamines, blood samples were drawn at rest using a heparinized catheter and at the 15th, 30th and 60th min of the exercise and after 30 min of recovery. At rest, the blood glucose concentrations were at the lowest values for normal. Exercise induced a small decrease of blood glucose which was combined with an abrupt increase of the noradrenaline concentration during the first 15 min. The FFA and glycerol concentrations increased throughout the exercise linearly with that of adrenaline. Compared to adults, the FFA uptake expressed per minute and per litre of oxygen uptake was greater in children. These results suggested that it is difficult for children to maintain a constant blood glucose concentration and that prolonged exercise provided a real stimulus to hypoglycaemia. An immediate and large increase in noradrenaline concentration during exercise and a greater utilization of FFA was probably used by children to prevent hypoglycaemia.

Impaired adrenergic response to prolonged exercise in type I diabetes

Patients with type I diabetes mellitus commonly experience hypoglycemia related to physical activity. We investigated the metabolic and hormonal response to exercise in type I diabetics, normal controls, and controls exercising under hypoglycemic conditions. All subjects exercise for 60 minutes at 60% to 65% of their VO2max while insulin concentrations were clamped at basal or hyperinsulinemic levels. With low-dose insulin infusion, despite similar free insulin levels, diabetics had a greater decrease in plasma glucose concentrations during exercise than controls. Nevertheless, the increments of epinephrine (E) and norepinephrine (NE) during exercise tended to be less in the diabetic subjects. Circulating levels of free fatty acids (FFA) were lower in diabetics, especially during early recovery from exercise. To better compare responses, a group of normal controls exercised during an infusion of insulin, which resulted in a similar decrease in plasma glucose to that of exercising diabetics. While exercising during a similar degree of hypoglycemia, diabetics had a significantly smaller increment of E and NE compared with controls. Increments of glucagon (GL) and growth hormone (GH) were not different. These studies suggest that there is a subnormal catecholamine response to exercise under hypoglycemic conditions in some patients with type I diabetes. The hypoglycemia during and after exercise in these individuals is probably the result of multiple factors, including relative hyperinsulinemia, decreased increment in catecholamines, and decreased availability of FFA.

Exercise induced hormonal and metabolic changes in Thoroughbred horses: effects of conditioning and acepromazine

Nine Thoroughbred horses were assessed to determine the normal response of insulin, glucose, cortisol, plasma potassium (K) and erythrocyte K through conditioning and to exercise over 400 and 1,000 m. In addition, adrenaline, noradrenaline, cortisol, plasma K, erythrocyte K and L-lactate concentrations were evaluated in response to maximal exercise with and without the administration of acepromazine. Conditioning caused no obvious trends in plasma K, erythrocyte K, insulin or glucose concentration. Serum cortisol increased (P less than 0.05) from the initial sample at Week 1 to Weeks 4 and 5 (attributed to a response to training), and then decreased. During conditioning, three horses had low erythrocyte K concentrations (less than 89.3 mmol/litre). Further work is needed to define the significance of low erythrocyte K concentrations in the performance horse. In all tests maximal exercise increased plasma K, glucose and cortisol concentrations, whereas insulin and erythrocyte K concentrations decreased. Thirty minutes following exercise, plasma K and erythrocyte K concentrations returned to resting values; whereas glucose and cortisol concentrations continued to increase and the insulin concentration also was increased. The magnitude of the changes varied for pre-conditioned vs post-conditioned exercise tests and the duration of exercise. The administration of acepromazine prior to exercise over 1,000 m failed to alter the circulating noradrenaline and adrenaline concentrations in anticipation of exercise or 2 mins following exercise. Acepromazine administration, however, did cause lower L-lactate concentration 2 mins (P less than 0.03) and 30 mins (P less than or equal to 0.005) following exercise. Also, erythrocyte K showed a delayed return to baseline levels at 30 mins post exercise. Further evaluation of these trends may help explain the beneficial role acepromazine plays in limiting signs of exertional rhabdomyolysis when administered prior to exercise.

Insulin and glucagon secretion in swimming mice: effects of adrenalectomy and chemical sympathectomy

Swimming-stress is known to inhibit glucose-stimulated insulin secretion and stimulate glucagon secretion. In the present study, in mice, we investigated the relative contribution of sympathetic nerves and the adrenals to these effects. Mice were pretreated either with adrenalectomy or chemical sympathectomy induced by i.v. injection of 6-hydroxydopamine (6-OHDA), which destroys sympathetic nerve terminals. Two days later, the mice were injected i.v. with either glucose (5.6 mmol/kg) or saline, immediately before being subjected to 2 min swimming-stress or 2 min resting. Directly thereafter, blood was sampled. In normal controls, swimming inhibited glucose-stimulated insulin secretion and elevated plasma glucagon levels (P less than 0.01). Both these responses were absent both in adrenalectomized and in chemically sympathectomized mice. We also found that in resting animals, adrenalectomy reduced plasma levels of glucagon (P less than 0.05) and glucose (P less than 0.01), and that in adrenalectomized mice, swimming lowered basal plasma insulin levels (P less than 0.05). Furthermore, 6-OHDA-treatment elevated basal plasma glucagon levels (P less than 0.01). Thus, we show that, in the mouse, the inhibition of glucose-stimulated insulin secretion and the stimulation of glucagon secretion that occur during swimming-stress are both dependent on mechanisms requiring both the adrenals and intact sympathetic nerve terminals.

Plasma glucose metabolism during exercise in humans

Plasma glucose is an important energy source in exercising humans, supplying between 20 and 50% of the total oxidative energy production and between 25 and 100% of the total carbohydrate oxidised during submaximal exercise. Plasma glucose utilisation increases with the intensity of exercise, due to an increase in glucose utilisation by each active muscle fibre, an increase in the number of active muscle fibres, or both. Plasma glucose utilisation also increases with the duration of exercise, thereby partially compensating for the progressive decrease in muscle glycogen concentration. When compared at the same absolute exercise intensity (i.e. the same VO2), reliance on plasma glucose is also greater during exercise performed with a small muscle mass, i.e. with the arms or just 1 leg. This may be due to differences in the relative exercise intensity (i.e. the %VO2peak), or due to differences between the arms and legs in their fitness for aerobic activity. The rate of plasma glucose utilisation is decreased when plasma free fatty acid or muscle glycogen concentrations are very high, effects which are probably mediated by increases in muscle glucose-6-phosphate concentration. However, glucose utilisation is also reduced during exercise following a low carbohydrate diet, despite the fact that muscle glycogen is also often lower. When exercise is performed at the same absolute intensity before and after endurance training, plasma glucose utilisation is lower in the trained state. During exercise performed at the same relative intensity, however, glucose utilisation may be lower, the same, or actually higher in trained than in untrained subjects, because of the greater absolute VO2 and demand for substrate in trained subjects during exercise at a given relative exercise intensity. Although both hyperglycaemia and hypoglycaemia may occur during exercise, plasma glucose concentration usually remains relatively constant. Factors which increase or decrease the reliance of peripheral tissues on plasma glucose during exercise are therefore generally accompanied by quantitatively similar increases or decreases in glucose production. These changes in total glucose production are mediated by changes in both hepatic glycogenolysis and hepatic gluconeogenesis. Glycogenolysis dominates under most conditions, and is greatest early in exercise, during high intensity exercise, or when dietary carbohydrate intake is high. The rate of gluconeogenesis is increased when exercise is prolonged, preceded by a restricted carbohydrate intake, or performed with the arms. Both glycogenolysis and gluconeogenesis appear to be decreased by endurance exercise training. These effects are due to changes in both the hormonal milieu and in the availability of hepatic glycogen and gluconeogenic precursors.(ABSTRACT TRUNCATED AT 400 WORDS)

Insulin and glucagon secretion in swimming mice: effects of autonomic receptor antagonism

To study the regulation of islet hormone secretion in exercise-stress, we developed a swimming mouse model. Mice swam for 2, 6, or 10 minutes whereafter blood was sampled for analysis of plasma levels of insulin, glucagon, and glucose. Plasma insulin levels, which were not different from resting controls after 2 or 6 minutes of swimming, were slightly lower after 10 minutes of swimming (P less than .05). Plasma glucagon levels were increased after 2, 6, and 10 minutes of swimming (P less than .001), and plasma glucose levels were lower after 6 and 10 minutes of swimming (P less than .05). Glucose (5.6 mmol/kg)-stimulated insulin secretion was inhibited by 52% +/- 9% by the swimming (P less than .001). The mechanisms behind this inhibition of glucose-stimulated insulin secretion and the increase in basal plasma glucagon levels induced during 2 minutes of swimming were investigated by the use of autonomic receptor antagonists, administered intraperitoneally 20 minutes before the swimming period. The ganglionic antagonist hexamethonium (56 mumols/kg) prevented the swimming-induced inhibition of glucose-stimulated insulin secretion, indicating involvement of nerves in the inhibition. Also the nonselective alpha-adrenoceptor antagonist phentolamine (6.0 mumols/kg) and the alpha 2-adrenoceptor antagonist yohimbine (3.6 mumols/kg) prevented the inhibition of glucose-stimulated insulin secretion induced by swimming, whereas the beta-adrenoceptor antagonist L-propranolol (9.6 mumols/kg) had no effect. The swimming-induced increase in plasma glucagon levels was partially inhibited by hexamethonium by (58% +/- 24%, P less than .05). Phentolamine and yohimbine totally prevented the increase in plasma glucagon levels, whereas L-propranolol had no effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Physiological bases for the treatment of the physically active individual with diabetes

Substrate utilisation and glucose homoeostasis during exercise is controlled by the effects of precise changes in insulin, glucagon and the catecholamines. The important role these hormones play is clearly seen in people with diabetes, as the normal endocrine response is often lost. In individuals with insulin-dependent diabetes (IDDM), there can be an increased risk of hypoglycaemia during or after exercise or, conversely, there can be a worsening of the diabetic state if insulin deficiency is present. In contrast, it appears that people with non-insulin-dependent diabetes (NIDDM) can generally exercise without fear of a deleterious metabolic response. The exercise response both in healthy subjects and in those with diabetes is dependent on many factors such as age, nutritional status and the duration and intensity of exercise. Since there are so many variables which govern individual response to exercise, an exact exercise prescription for all people with diabetes cannot be made. There are many adjustments to the therapeutic regimen which an individual with IDDM can make in order to avoid hypoglycaemia during or after exercise. In general, a reduction in insulin dosage and the added ingestion and continual availability of carbohydrates are wise precautions. On the other hand, exercise should be postponed if blood glucose is greater than 2500 mg/L and ketones are present in the urine. As more is understood about the regulation of substrate metabolism during exercise, more refined therapeutic strategies can be defined. An understanding of the metabolic response to exercise is critical for generating an effective and safe training programme for all diabetic individuals who wish to be physically active.

Regulation of hepatic glucose output during moderate exercise in non-insulin-dependent diabetes

In normal subjects during moderate exercise there is a strong negative correlation between plasma glucose and hepatic glucose output (HGO) suggesting a negative feedback regulation of HGO by plasma glucose. Little information is available about HGO responses to exercise in non-insulin-dependent diabetes mellitus (NIDDM). To determine whether the same feedback relationship is operative, we have compared the glucose turnover responses to moderate exercise (50% Vo2max for 60 minutes) of nonobese non-insulin-dependent diabetic subjects (NIDDM, n = 7) with a group of age-matched controls (n = 5). Glucose turnover responses to exercise in NIDDM were heterogeneous. Plasma glucose showed sustained falls, no change, or sustained rises in different individuals. Similarly, HGO responses ranged from undetectable to responses comparable to those of normal subjects. The mean integrated HGO response in NIDDM was significantly reduced compared with controls (11 +/- 6 [SEM] v 33 +/- 7 mmol/h/70 kg, P less than .05); mean glucose utilization response was also reduced but not significantly different from controls (NIDDM 18 +/- 5 v control 35 +/- 6). In NIDDM there was no significant feedback-control relationship between plasma glucose and HGO (r = -0.20, P = NS) in contrast to controls (r = -0.87, P less than .01). We conclude that feedback control of HGO by plasma glucose during moderate exercise is impaired in NIDDM. This impairment may be due to defective nonpancreatic glucoregulatory mechanisms.

Direct muscarinic cholinergic inhibition of hepatic glucose production in humans

To explore the potential role of the parasympathetic nervous system in human glucoregulatory physiology, responses to the muscarinic cholinergic agonist bethanechol (5.0 mg s.c.) and antagonist atropine (1.0 mg i.v.) were measured in normal humans. There were no changes in the plasma glucose concentration or rates of glucose production or utilization following atropine administration. After bethanechol administration there were no changes in the plasma glucose concentration or fluxes despite increments in plasma glucagon (75 +/- 7 to 103 +/- 10 pg/ml, P less than 0.02). There were no changes in insulin or C-peptide levels. To test the hypothesis that direct muscarinic inhibition of glucose production was offset by an indirect action of the agonist, specifically increased glucagon secretion with consequent stimulation of glucose production, bethanechol was administered while glucagon levels were held constant with the islet clamp technique (somatostatin infusion with insulin, glucagon and growth hormone replacement at fixed rates). Under that condition the muscarinic agonist induced a 25% decrement in the plasma glucose concentration (101 +/- 8 to 75 +/- 8 mg/dl, P less than 0.05). When compared with separate clamp control studies (with placebo rather than bethanechol injection) both the rate of glucose production and the glucose concentration were reduced (P less than 0.05) following bethanechol injection; the rate of glucose utilization was unaltered. Thus, we conclude: Withdrawal of parasympathetic tone does not appear to be an important glucoregulatory process in humans. Direct muscarinic cholinergic inhibition of hepatic glucose production occurs in humans but during generalized muscarinic activation this is offset by an indirect muscarinic action, increased glucagon secretion with consequent stimulation of glucose production. Thus, particularly if regional neuronal firing occurs, the parasympathetic nervous system may play an important role in human glucoregulatory physiology.

Regulation of glucose turnover during exercise in pancreatectomized, totally insulin-deficient dogs. Effects of beta-adrenergic blockade

To examine whether glucose metabolic clearance increases and whether catecholamines influence glucose turnover during exercise in total insulin deficiency, 24-h fasted and insulin-deprived pancreatectomized dogs were studied before and during exercise (60 min; 100 m/min; 10% slope) with (n = 8) and without (n = 8) propranolol infusion (PI, 5 micrograms/kg-min). Exercise with or without PI was accompanied by four and fivefold increments in norepinephrine and epinephrine respectively, while glucagon (extrapancreatic) fell slightly. Basal plasma glucose and FFA concentrations and rates of tracer-determined (3[3H]glucose) hepatic glucose production (Ra) and total glucose clearance (including urinary glucose loss) were 459 +/- 24 mg/dl, 1.7 +/- 0.5 mmol/liter, 7.8 +/- 0.9 mg/kg-min and 1.6 +/- 0.1 ml/kg-min, respectively. When corrected for urinary glucose excretion, basal glucose metabolic clearance rate (MCR) was 0.7 +/- 0.1 mg/kg-min and rose twofold (P less than 0.0001) during exercise. Despite lower lactate (3.3 +/- 0.6 vs. 6.6 +/- 1.3 mmol/liter; P less than 0.005) and FFA levels (1.1 +/- 0.2 vs. 2.2 +/- 0.2 mmol/liter; P less than 0.0001) with PI, PI failed to influence MCR during exercise. Ra rose by 3.7 +/- 1.7 mg/kg-min during exercise (P less than 0.02) while with PI the increase was only 1.9 +/- 0.7 mg/kg-min (P less than 0.002). Glucose levels remained unchanged during exercise alone but fell slightly with PI (P less than 0.0001). Therefore, in total insulin deficiency, MCR increases marginally with exercise (13% of normal); the beta adrenergic effects of catecholamines that stimulate both FFA mobilization and muscle glycogenolysis do not regulate muscle glucose uptake. The exercise-induced rise in hepatic glucose production does not require an increase in glucagon levels, but is mediated partially by catecholamines. Present and previous data in normal and alloxan-diabetic dogs, suggest that (a) in total insulin deficiency, control of hepatic glucose production during exercise is shifted from glucagon to catecholamines and that this may involve catecholamine-induced mobilization of peripheral substrates for gluconeogenesis and/or hepatic insensitivity to glucagon, and (b) insulin is not essential for a small exercise-induced increase in muscle glucose uptake, but normal insulin levels are required for the full response. Furthermore, the catecholamines appear to regulate muscle glucose uptake during exercise only when sufficient insulin is available to prevent markedly elevated FFA levels. We speculate that the main role of insulin is not to regulate glucose uptake by the contracting muscle directly, but to restrain lipolysis and thereby also FFA oxidation in the muscle.

Somatostatin infusion enhances hepatic glucose production during hyperglucagonemia

Somatostatin (SRIH) is widely employed in metabolic studies to permit quantitation of glucose production and disposal rates while the endocrine pancreas is suppressed and the hormonal milieu is under the investigator's control. In these studies it is assumed that if peripheral levels of insulin and glucagon are the same during SRIH infusion as during control studies, the effects of these hormones on glucose metabolism are equivalent. If the effect of glucagon is influenced by SRIH infusion, then these techniques may be unsuitable for the study of the regulation of hepatic glucose output. To assess the influence of SRIH on glucagon-stimulated hepatic glucose production (Ra), we determined Ra during paired studies in ten healthy (five younger and five older) subjects. In each study an insulin infusion designed to yield physiologic systemic insulin levels of 20 to 30 microU/mL was given from 0 to 210 minutes. In addition, from 60 to 210 minutes either glucagon alone (3.5 ng/kg/min) (I + IRG) or glucagon (3.5 ng/kg/min) and SRIH (250 micrograms/h) (I + IRG + SRIH) was infused. Since results for plasma levels of insulin, C-peptide, glucagon, and Ra were similar in young and old subjects, the two age groups were combined for analysis. Basal plasma insulin, glucagon, C-peptide, glucose, and Ra were similar in each arm of the study. Insulin values were nearly identical from 60 to 210 minutes (I + IRG, 23.8 +/- 1.1; I + IRG + SRIH, 24.0 +/- 1.0 microU/mL).(ABSTRACT TRUNCATED AT 250 WORDS)

Abnormal glucoregulation during exercise in type II (non-insulin-dependent) diabetes

We studied the effects of exercise on the levels of plasma glucose and glucoregulatory hormones before and after 6 weeks of thrice-weekly physical training in 20 sedentary type II (non-insulin-dependent) diabetic patients and 11 control subjects matched for previous physical activity. Parameters were measured at rest, after 30 minutes of bicycle exercise at 70% to 75% of maximal oxygen uptake, and after 30 minutes of recovery. In the untrained state exercise resulted in a decrease in plasma glucose levels in diabetics but not in controls (-12 +/- 5 v + 4 +/- 2 mg/dL, P less than .01) and the expected drop in plasma insulin level was absent in diabetics. These differences in glucose and insulin response persisted after physical training. There was a tendency for patients with diabetes to have a smaller R-R interval variation during deep breathing, an abnormal resting heart rate response to physical training, and a lesser increment in plasma epinephrine levels following exercise, findings consistent with autonomic dysfunction. Physical training resulted in a blunting of the exercise-induced increment of plasma epinephrine, growth hormone, and lactate levels in control subjects, but not in diabetics. Our data demonstrate a hypoglycemic effect of exercise in mildly hyperglycemic nonobese type II diabetics. Possible causative factors include: hyperglycemia per se, a lack of physiologic suppression of plasma insulin, and abnormalities of autonomic or hypothalamic regulatory function.

Physical stress and catecholamine release

In both health and disease, noradrenaline and adrenaline concentrations in plasma increase with intensity and duration of exercise (Figure 1). These changes are only to a minor extent due to decreased catecholamine clearance (Figure 2). The increase in sympathoadrenal activity during exercise is primarily elicited by feed-forward stimulation from motor centres in the brain (Figure 3, Table 1), and by afferent impulses from working muscles (Figure 4). During continued exercise, changes in internal milieu may enhance the catecholamine response. Of particular interest from a metabolic point of view is the fact that during exercise a decrease in plasma glucose causes a relatively large increase in plasma adrenaline (Figure 5). Sympathoadrenal activity is of major importance for exercise capacity. By depressing insulin secretion, as well as by direct effects on target tissues, sympathoadrenal activity enhances mobilization of glycogen as well as triglyceride from both extra- and intramuscular depots. After training, noradrenaline responses to given absolute work loads are reduced, while responses to given relative loads, i.e. work load in percent of individual work capacity, VO2/VO2max%, are unchanged. Prolonged endurance training may increase the size and secretory capacity of the adrenal medulla (Figure 7, Table 2), an adaptation which may improve exercise capacity. Differences in catecholamine levels cannot explain the fact that physically-active individuals have a lower cardiac mortality than inactive ones.