Maria Montserrat Diaz Pedrosa Furlan

Morphoquantitative effects of acute diabetes on the myenteric neurons of the proximal colon of adult rats

The effects of acute diabetes on the density and size of the myenteric neurons of the proximal colon of adult rats were investigated. The injection of streptozotocin was followed by a period of observation of seven days, during which the diabetic animals showed weight loss, excessive food and water intake, large urinary debt and hyperglicemia. The whole-mounts from the proximal colon were stained with the techniques of Giemsa and of the NADH-diaphorase, and the employment of these techniques made it possible to verify a decrease on the neuronal density and on the cell body size of the myenteric neurons in the colon of the diabetic rats. These observations were discussed in terms of the pathophysiology of the diabetes and the experimental protocol.

Number and size of myenteric neurons of the duodenum of adult rats with acute diabetes

This study had as its purpose to assess the effects of acute diabetes induced by streptozotocin (35 mg/kg body weight) on the number and size of the myenteric neurons of the duodenum of adult rats considering equally the antimesenteric and intermediate regions of the intestinal circumference. Experimental period extended for a week. Neuronal counts were carried out on the same number of fields of both regions of the duodenal circumference and measurements of neuronal and nuclear areas on equal numbers of cells. Number and size of the myenteric neurons stained with Giemsa were not significantly different between groups. On the other hand, the proportion of NADH-positive neurons increased from 18.54% on the controls to 39.33% on the diabetics. The authors discuss that this increased reactivity probably results from a greater NADH/NAD+ ratio, described in many tissues of diabetic animals, which has consequences on the modulation of the enzymes that use these cofactors and whose activity is detected by the NADH-diaphorase technique.

Effects of Insulin Treatment on HuC/HuD, NADH Diaphorase, and nNOS-Positive Myoenteric Neurons of the Duodenum of Adult Rats with Acute Diabetes

We carried out this investigation with the purpose of verifying whether insulin treatment prevents changes in the density of myoenteric neurons of the duodenum of Wistar rats with streptozotocin short-term diabetes. The animals from the diabetic group (D) lost more weight than the controls (group C), while the insulin treatment (group T) prevented weight loss in three animals and increased visceral fat in all of the animals of this group. Insulin treatment did not prevent the early loss of HuC/HuD myoenteric neurons. The density of nNOS-positive neurons did not change significantly in groups D and T. The density of NADHd-positive neurons in these groups was greater than in group C, indicating that short-term diabetes increases the activity of respiratory chain enzymes.

Ketogenesis evaluation in perfused liver of diabetic rats submitted to short-term insulin-induced hypoglycemia

Ketogenesis, inferred by the production of acetoacetate plus ß‐hydroxybutyrate, in isolated perfused livers from 24‐h fasted diabetic rats submitted to short‐term insulin‐induced hypoglycemia (IIH) was investigated. For this purpose, alloxan‐diabetic rats that received intraperitoneal regular insulin (IIH group) or saline (COG group) injection were compared. An additional group of diabetic rats which received oral glucose (gavage) (100 mg kg−1) 15 min after insulin administration (IIH + glucose group) was included. The studies were performed 30 min after insulin (1.0 U kg−1) or saline injection. The ketogenesis before octanoate infusion was diminished (p < 0.05) in livers from rats which received insulin (COG vs. IIH group) or insulin plus glucose (COG vs. IIH + glucose group). However, the liver ketogenic capacity during the infusion of octanoate (0.3 mM) was maintained (COG vs. IIH group and COG vs. IIH + glucose group). In addition, the blood concentration of ketone bodies was not influenced by the administration of insulin or insulin plus glucose. Taken together, the results showed that inspite the fact that insulin and glucose inhibits ketogenesis, livers from diabetic rats submitted to short‐term IIH which received insulin or insulin plus glucose showed maintained capacity to produce acetoacetate and ß‐hydroxybutyrate from octanoate. Copyright

Paradoxical increase in liver ketogenesis during long-term insulin-induced hypoglycemia in diabetic rats.

It is well established that insulin inhibits liver ketogenesis. However, during insulin-induced hypoglycemia (IIH) the release of counterregulatory hormones could overcome the insulin effect on ketogenesis. To clarify this question the ketogenic activity in livers from alloxan-diabetic rats submitted to long-term IIH was investigated. Moreover, liver glycogenolysis, gluconeogensis, ureagenesis and the production of l-lactate were measured, and its correlation with blood levels of ketone bodies (KB), l-lactate, glucose, urea and ammonia was investigated. For this purpose, overnight fasted alloxan-diabetic rats (DBT group) were compared with control non-diabetic rats (NDBT group). Long-term IIH was obtained with an intraperitoneal injection of Detemir insulin (1 U/kg), and KB, glucose, l-lactate, ammonia and urea were evaluated at 0, 2, 4, 6, 8 or 10 h after insulin injection. Because IIH was well established two hours after insulin injection this time was used for liver perfusion experiments. The administration of Detemir insulin decreased (P < 0.05) blood KB and glucose levels, but there was an increase in the blood l-lactate levels and a rebound increase in blood KB during the glucose recovery phase of IIH. In agreement with these results, the capacity to produce KB from octanoate was increased in the livers of DBT rats. Moreover, the elevated blood l-lactate levels in DBT rats could be attributed to the higher (P < 0.05) glycogenolysis when part of glucose from glycogenolysis enters glycolysis, producing l-lactate. In contrast, except glycerol, gluconeogenesis was negligible in the livers of DBT rats. Therefore, during long-term IIH the higher liver ketogenic capacity of DBT rats increased the risk of hyperketonemia. In addition, in spite of the fact that the insulin injection decreased blood KB, there was a risk of worsening lactic acidosis.

Blood glucose regulation during fasting in rats under food restriction since birth

The effect of severe food restriction since birth o n regulation of fasting glycemia in male Wistar rat s was investigated. The control group (CG) had free suppl y of chow, while the restriction group (RG) receive d 50% of the amount ingested by the CG. The experiments were don e in adult (60 days) overnight fasted rats in which glycemia, liver free glucose levels and hepatic glycogen conc entration were measured. In part of the experiments in situ liver perfusion was done. The results showed that livers from the RG had higher glycogenolysis rates but low er gluconeogenesis rates from L-alanine (10 mM). Since RG showed maintained glycemia during fasting, it c ould be concluded that livers from RG produced glucose pref erentially from glycogenolysis in detriment of gluc oneogenesis. These findings demonstrated that in spite of severe caloric restriction, the metabolic adaptations of the liver did exist to assure the maintenance of blood glucose fo r brain supply during fasting.

Evaluation of the areas of neuronal cell bodies and nuclei in the myenteric plexus of the duodenum of adult rats

This study compared the areas of cell body and nucleus profiles of the myenteric neurons in the antimesenteric and intermediate regions of the duodenum of adult rats. Five male rats were used. The duodenum was removed and dissected to whole-mount preparations, which were stained by the Giemsa technique. The areas of cell body and nucleus profiles of 100 neurons, 50 from each region, of each animal, were assessed with image analyser. Based on the global mean+/-SD of the areas of cell body profiles, neurons were labelled as small, medium or large. It was observed that the neurons did not differ significantly in size or incidence between the antimesenteric and intermediate regions. However, the nuclei of the small and medium neurons were significantly smaller in the latter region. It is discussed that the smaller nuclear size could be related to the cell bodies being slightly smaller on this region and to a possible smaller biosynthetic activity which would influence nuclear size.