Acute sub-diaphragmatic anterior vagus nerve stimulation increases peripheral glucose uptake in anaesthetized rats.

The sub-diaphragmatic vagus innervates various organs involved in the control of glucose homeostasis including the liver, pancreas and the intestines. In the current study, we investigated the effect of acute electrical stimulation of the anterior trunk of the sub-diaphragmatic vagus on glucose fluxes in anaesthetized adult male rats. After overnight fast, rats underwent either vagus nerve stimulation (VNS+, n = 11; rectangular pulses at 5 Hz, 1.5 mA, 1 msec pulse width) or sham stimulation (VNS-; n = 11) for 120 min under isoflurane anesthesia. Before stimulation, the rats received an i.v. bolus of 1 mL/kg of a sterilized aqueous solution containing 125 mg/mL of D-[6,6-2H2] glucose. Endogenous glucose production (EGP) and glucose clearance rate (GCR) were calculated by kinetic analysis from the wash-out of injected D-[6,6-2H2]glucose from the circulation. VNS+ resulted in lower glucose levels compared to the VNS- group (p < 0.05), with similar insulin levels. EGP was similar in both groups, but the GCR was higher in the VNS+ group compared to the VNS- group (p < 0.001). Circulating levels of the sympathetic transmitter norepinephrine were reduced by VNS+ relative to VNS- treatment (p < 0.01). It is concluded that acute anterior sub-diaphragmatic VNS causes stimulation of peripheral glucose uptake, while plasma insulin levels remained similar, and this is associated with lower activity of the sympathetic nervous system.

Ileal transposition: A non-restrictive bariatric surgical procedure that reduces body fat and increases ingestion-related energy expenditure.

BACKGROUND: Ileal Transposition (IT) was developed as a model to study body weight reduction without the restrictive or malabsorptive aspects of other bariatric surgeries, but the exact mechanisms of the alterations in body weight after IT are not completely understood. OBJECTIVE: To provide a detailed description of the surgical procedure of IT, and describe its effect on energy balance parameters. METHODS: Adult male Lewis rats underwent either IT (IT+) or sham (IT-) surgery. Following surgery body weight and energy intake were monitored. After attaining weight stability (> 30 days), energy expenditure and its components were assessed using indirect calorimetry at a day of fasting, limited intake, and ad libitum intake. At the end of the study body composition analysis was performed. RESULTS: IT+ resulted in transiently reduced energy intake, increased ingestion-related energy expenditure (IEE) and decreased body and adipose tissue weight when compared to IT-. At weight stability, neither energy budget (i.e., energy intake - energy expenditure), nor energy efficiency was different in IT+ rats compared to IT-. CONCLUSION: Our data show that the primary cause of weight reduction following IT+ is a transient reduction in energy intake. If the increased IEE is related to a higher level of satiety, compensatory feeding to bridge body weight difference between IT+ and IT- rats is less likely to occur.

Running wheel access fails to resolve impaired sustainable health in mice feeding a high fat sucrose diet.

Diet and physical activity are thought to affect sustainable metabolic health and survival. To improve understanding, we studied survival of mice feeding a low-fat (LF) or high-saturated fat/high sugar (HFS) diet, each with or without free running wheel (RW) access. Additionally several endocrine and metabolic health indices were assessed at 6, 12, 18 and 24 months of age. As expected, HFS feeding left-shifted survival curve of mice compared to LF feeding, and this was associated with increased energy intake and increased (visceral/total) adiposity, liver triglycerides, and increased plasma cholesterol, corticosterone, HOMA-IR, and lowered adiponectin levels. Several of these health parameters improved (transiently) by RW access in HFS and LF fed mice (i.e., HOMA-IR, plasma corticosterone), others however deteriorated (transiently) by RW access only in HFS-fed mice (i.e., body adiposity, plasma resistin, and free cholesterol levels). Apart from these multiple and sometimes diverging health effects of RW access, RW access did not affect survival curves. Important to note, voluntary RW activity declined with age, but this effect was most pronounced in the HFS fed mice. These results thus challenge the hypothesis that voluntary wheel running can counteract HFS-induced deterioration of survival and metabolic health.

Individual behavioral characteristics of wild-type rats predict susceptibility to experimental autoimmune encephalomyelitis.

Neuroendocrine-immune interactions are thought to be important in determining susceptibility to autoimmune disease. Animal studies have revealed that differences in susceptibility to experimental autoimmune encephalomyelitis (EAE) are related to reactivity in the hypothalamo-pituitary-adrenal axis. It is known that there is a close relation between neuroendocrine parameters and behavioral characteristics, suggesting that behavior and disease susceptibility may be associated. In the present study we investigated whether behavioral characteristics of wild-type rats are related to susceptibility to disease. We show here that the latency of the animal to attack an intruder correlates significantly with the EAE disease score: animals that do not attack the intruder during the test period are more resistant to the disease than animals with short attack latency times. These data, obtained in an unselected strain of wild-type rats, demonstrate that behavioral response patterns of individual animals can in part predict susceptibility to autoimmune disease.

Hepatic portal vein cannulation for infusion and blood sampling in freely moving rats.

Chronic portal vein cannulation in the rat is an important technique to study secretory rates of hormones from the endocrine pancreas. Moreover, it can be used for studying the effects of enteric hormones and pharmaca on behavioral and physiological processes. This article contains an extensive description of a cannulation technique of the portal vein that has many advantages over those reported so far in the literature, and that was very successful in several behavioral and physiological studies during the last decade.

Insulin levels after portal and systemic insulin infusion differ in a dose-dependent fashion.

The role of the liver in the regulation of systemic insulin levels is not well understood. The reported extraction rates vary between 0 to 85%, and extraction of a constant fraction of 50% of the portally delivered insulin is generally assumed. In the present study, we have investigated the role of the liver in the regulation of systemic insulin levels in the normal rat. Insulin was infused into the portal vein of conscious and freely moving rats in doses of 20, 40, 80 pmol/min during 15 min to mimic the gradual release of insulin by the native endocrine rat pancreas. The profiles of plasma insulin and glucose levels in the systemic circulation were compared to those obtained after direct infusion into the systemic circulation. The effect of intraportal and direct systemic infusion on plasma insulin and blood glucose levels were virtually similar where 20 pmol/min was applied. But, these effects were different if the dose was 40 pmol/min, and this difference increased when the dose was increased to 80 pmol/min, since hypoglycemia was less severe and normoglycemia was restored more rapidly with portal than with systemic infusion. Thus, our results show that the fraction of intraportally infused insulin reaching the systemic circulation decreases with higher doses of insulin. This suggests that the liver contains adaptable mechanisms to reduce the systemic insulin levels.

Control of insulin secretion and glucose homeostasis in exercising diabetic rats with intrasplenic or kidney subcapsular islet grafts.

This study was designed 1) to investigate mechanisms of insulin secretion during exercise after transplantation of islets in the spleen and under the kidney capsule, and 2) to compare these organs as transplantation site regarding an adequate portal or systemic delivery of insulin and glucose homeostasis during exercise. Diabetic rats were provided with 5 microL isogenic islet tissue in the spleen or under the kidney capsule, which results in normoglycemia, and were submitted to a swimming test. Portal plasma insulin levels were higher than simultaneously sampled systemic insulin levels in the control and in the intrasplenic islet grafted group, but not in the kidney subcapsular islet-grafted group. Plasma portal and systemic insulin levels decreased, and glucose levels increased during exercise in all groups. The exercise-induced increase in levels of catecholamines was larger in systemic than in portal plasma, suggesting catecholamine extraction by the lungs or intestines. The experiments were repeated after removing of adrenal medulla, resulting in nondetectable or very low plasma adrenaline levels. Despite these low adrenaline levels, insulin levels decreased during exercise. The results indicate that 1) the exercise-induced reduction of insulin secretion is not mediated by circulating adrenaline, but is probably under control of the sympathetic nervous system, which could be the result of reinnervation of the transplanted islets. 2) Although a portal-systemic insulin gradient was absent in rats with kidney subcapsular islet grafts, the absence of a difference in glucose homeostasis during exercise between the sites revealed that all investigated sites are preferential to transplant islets.

Sympathoadrenal activity during exercise in partial diabetic and diabetic rats.

Insulin-dependent diabetes mellitus is associated with altered fat and carbohydrate metabolism and disturbed sympathoadrenal functioning. The aim of this study was to investigate whether the short-term diabetic state alters the activity of the sympathoadrenal system and of the adrenal cortex during exercise. In addition, the possible reciprocal effects of a deviating sympathoadrenal functioning and an altered non-esterified fatty acid (NEFA) and glucose metabolism were investigated. Therefore, control rats, diabetic rats, and partial diabetic rats were submitted to swimming (15 minutes). Permanent heart catheters allowed frequent blood sampling without disturbing the animals. Blood glucose and plasma NEFA levels increased during exercise. partial diabetic animals showed similar effects as controls. In contrast, the glucose and NEFA increments were significantly higher in diabetic rats than in control and partial diabetic rats. During exercise, the very low insulin levels were unaltered in diabetic rats, whereas they decreased in the other groups. Exercise-induced elevations of plasma epinephrine and norepinephrine were similar in all groups, but were lower for corticosterone in the diabetic animals. Therefore, these results provide evidence that the exaggerated NEFA mobilization in diabetic rats is only the result of reduced inhibition of lipolysis by the relative lack of insulin. It is concluded that the short-term diabetic state does not alter the activity of the sympathetic nervous system during exercise, but lowers the activity of the adrenal cortex.

Kinetics of intraperitoneally infused insulin in rats. Functional implications for the bioartificial pancreas.

Intraperitoneal transplantation of encapsulated islets can restore normoglycemia in diabetic recipients but not normal glucose tolerance nor normal insulin responses to a physiological stimulus. This study investigates whether the intraperitoneal implantation site as such contributes to the interference with optimal transport kinetics between the islets and the bloodstream. Insulin was infused into the peritoneal cavity of conscious and freely moving rats in doses of 20, 40, and 80 pmol.l-1.min-1 during 15 min, to mimic the gradual release of insulin from an encapsulated, i.e., a nonvascularized, islet graft. With 20 pmol.l-1.min-1, we observed virtually no rise of insulin levels, and it took 30 min until glucose levels had dropped significantly. With 40 and 80 pmol.l-1.min-1 insulin infusions, there was a dose-dependent rise of insulin and decrease of glucose levels. When compared with intraportal infusions with the same insulin dosages, however, they were strongly delayed and reduced as well as prolonged. Similar results were obtained when inulin instead of insulin was intraperitoneally infused, with indicates that the transport of insulin from the peritoneal cavity to the bloodstream is mainly by passive diffusion. With a view on the clinical efficacy of the bioartificial pancreas, our findings indicate that we should focus on finding or creating a transplantation site that, more than the unmodified peritoneal cavity, permits close contact between the bloodstream and the encapsulated islet tissue.

Overfeeding-induced obesity in rats: insulin sensitivity and autonomic regulation of metabolism.

The metabolic consequences of the development of obesity and the underlying mechanisms were investigated. For this purpose, male rats were overfed for 5 weeks through long-term gastric catheters. Permanent cardiac cannulas implanted before the overfeeding period allowed frequent blood sampling and infusions without disturbing the rats. Hyperalimented rats became grossly obese, displayed elevated basal plasma norepinephrine (NE) concentrations, and developed hyperinsulinemia and insulin insensitivity, but remained normoglycemic and preserved normal intravenous (IV) glucose tolerance. During physical exercise (ie, 15 minutes of swimming), obese rats displayed exaggerated increases in blood glucose concentrations, whereas plasma free fatty acid (FFA) responses were blunted. These alterations were probably due to decreased NE release by the sympathetic nervous system during exercise and to altered tissue responsivity to adrenergic stimulation. The latter was demonstrated by infusions of catecholamines in the resting state. Responses to mild stress were increased in obese animals, as indicated by increased responses of plasma epinephrine (E) and corticosterone during handling and first contact with water. The results of the present study indicate that overfeeding induces changes in the sympathetic control of metabolism and insulin secretion. Whereas elevated NE levels in the basal state probably reflect increased energy expenditure, the pattern of nutrient mobilization during exercise is directed toward sparing of fats.

Exercise-induced sympathetic FFA mobilization in VMH-lesioned rats is normalized by fasting.

This study investigates whether reduced sympathetic responses during physical exercise in ventromedial hypothalamus (VMH)-lesioned obese rats are the direct result of damage to hypothalamic circuits or a secondary effect of the altered metabolism in obesity. Obese, VMH-lesioned rats and lean controls were deprived of food for 48 h and submitted to 15 min of swimming. Food-deprived lean and obese rats displayed increased free fatty acid mobilization and utilization, whereas blood glucose concentrations were decreased. Basal plasma insulin levels were reduced by fasting in both groups, when compared with the ad libitum situation, but remained higher in the obese animals. Fasting augmented the norepinephrine response of the obese rats, resulting in equal profiles in lean and obese animals. These results indicate that VMH-lesioned animals are able to increase the sympathetic activation of adipose tissue during exercise to overcome an energy deficiency. Therefore, the function of the VMH in the regulation of the sympathetic nervous system controlling metabolism can be taken over by redundant mechanisms. The reduced sympathetic activity in ad libitum fed VMH-lesioned animals is therefore likely to be the result of the altered metabolism.

Hyperinsulinemia and glucose tolerance in obese rats with lesions of the ventromedial hypothalamus: dependence on food intake and route of administration.

This study was performed to investigate the consequences of developing obesity on glucose homeostasis in animals showing hyperphagia plus vagal hyperinsulinemia and rats that were normophagic and hyperinsulinemic. Male rats were lesioned in the ventromedial hypothalamus (VMH) and kept either under ad libitum or absolute (oral or intragastrical) pair-feeding conditions for 4 weeks. Hyperphagic rats, as well as normophagic VMH rats, became obese, but only ad lib-fed obese rats displayed glucose intolerance to intravenous (IV) glucose infusions. Orally pair-fed VMH rats also showed normal oral and intragastric glucose tolerance, but in intragastrically fed VMH animals and controls, oral and intragastric glucose tolerance was decreased. These results indicate that (1) obesity as a consequence of VMH lesions is not dependent on hyperphagia, confirming earlier reports, and also independent of the ingestion of bulk meals. (2) beta-cell release of insulin to IV glucose infusion is not sufficient when hyperphagia and vagally mediated hyperinsulinemia coincide, and is therefore dependent on several factors; and (3) oral glucose intolerance develops when preabsorptive reflexes are blunted, irrespective of whether the animals were hyperinsulinemic or not.

Altered sympathetic control of nutrient mobilization during physical exercise after lesions in the VMH.

To study the impact of obesity on sympathetic nervous regulation of nutrient mobilization, obese rats and lean controls were subjected to physical exercise. Male Wistar rats, rendered obese by bilateral electrolytic lesions of the ventromedial hypothalamus (VMH) were subjected to 15 min swimming. Permanent cardiac catheters allowed frequent blood sampling. At rest, glucose, free fatty acids (FFA), and insulin concentrations were elevated in the obese animals, whereas catecholamine levels were similar in both groups. During exercise, glucose concentrations reached higher values in the lesioned rats, whereas these animals did not display the normal FFA increment. Plasma insulin concentrations were suppressed in both groups, and the rate of suppression was very similar when expressed as percentage change from resting levels. There was no difference in plasma epinephrine responses during swimming, but the increase in norepinephrine was diminished in the obese animals. The results suggest that obesity after VMH lesion leads to reduced stimulation of lipolysis by norepinephrine and a predominant mobilization of glucose during exercise, both favoring glucose utilization and the accumulation of fat.

Biphasic insulin secretion after intravenous but not after intraportal CCK-8 infusion in rats.

The effects of physiological doses of sulfated cholecystokinin-8 (CCK-8) on insulin secretion were investigated in unrestrained unanesthetized rats. The routes of administration were intravenous or intraportal infusion. Intravenous infusion (0.33-5.0 micrograms CCK-8.kg-1.20 min-1) resulted in a biphasic response pattern consisting of a fast 1st-min rise in plasma insulin concentration and a slower second phase that lasted throughout the infusion. The first phase showed the same amplitude with all amounts of CCK-8 administered in this study, whereas the second phase exhibited dose dependency. Blood glucose levels were lowered during all infusions of CCK-8, although the second phase of insulin release was absent with the lowest dose. These results suggest a strong stimulatory effect of CCK-8 on the pancreatic beta-cells, probably by changing the set point for glucose. The described effects of intravenous administration of CCK-8 cannot be produced when the infusion is given into the portal vein. Only very high concentrations of CCK-8 (15 micrograms.kg-1.20 min-1) produced a small increase in plasma insulin levels, indicating a strong CCK-8-eliminating mechanism in the liver. These results indicate that 1) CCK-8 evokes biphasic insulin release and a concomitant drop in glucose levels, and 2) CCK-8 acting on the beta-cell in vivo is not of intestinal origin but is probably released by the pancreatic vagal branch.

Inhibition of glutathione efflux in the recirculating rat liver perfusion by cysteine but not by oxothiazolidine carboxylate, an intracellular cysteine precursor.

In the recirculating rat liver perfusion a continuous release of glutathione into the perfusion medium is observed. Addition of L-cysteine to the perfusion medium immediately arrested this glutathione efflux. The cysteine precursor oxothiazolidine carboxylate did not block the glutathione efflux in spite of the fact that it generated more L-cysteine inside the liver cells than L-cysteine itself; L-cysteine is rapidly oxidized to cystine, that is no longer taken up by the liver. The results suggest that the inhibition of glutathione efflux results from the presence of cystine in the perfusion medium.