Reversibility of hyperglycaemia and islet abnormalities in the high fat-fed female ZDF rat model of type 2 diabetes.

INTRODUCTION: We characterised the development of Type 2 diabetes and associated changes in islet appearance in female ZDF rats and explored its suitability for studies with novel therapeutic agents. METHODS: Female ZDF rats were either chow or high fat (60%) fed for up to 36 days and blood glucose and plasma insulin concentration measured. Additionally, we restored two groups of rats back to chow diet after ten and nineteen days of high fat feeding to determine the reversibility. Finally, two other groups of high fat-fed animals were dosed either orally with drug vehicle or had a minipump implanted subcutaneously to determine the effect of dosing method upon the progression of this disease model. The beta cell mass and morphology were assessed by immunohistochemistry for insulin. RESULTS: High fat feeding elevated blood glucose compared to chow-fed controls which peaked by 15 days, and maintained throughout the study. Plasma insulin reached a maximum after 8 days, but declined over the remaining 4 weeks. Assessment of islets revealed marked disruption, dispersion and weaker insulin staining. The area and percentage ß-cells were higher in high fat-fed animals. High fat diet treatment reversal when animals were moderately hyperglycaemic, when plasma insulin was still elevated, reversed the hyperglycaemia and maintained islet morphology similar to that of chow-fed animals. In contrast, dietary reversal when plasma insulin was declining, did not prevent continual decline in plasma insulin, ß-cell mass or islet disruption. Oral dosing tended to increase blood glucose and decrease plasma insulin whereas administration by minipump lowered blood glucose. DISCUSSION: The obese female ZDF rat offers the opportunity for preclinical evaluation of novel therapies directed towards improving pancreatic function, provided treatment is initiated prior to the precipitous decline in insulin production. Caution should be exercised in comparison of compounds administered by different dosing routes however.

The intravenous glucose tolerance test in cannulated Wistar rats: a robust method for the in vivo assessment of glucose-stimulated insulin secretion.

INTRODUCTION: Glucose-stimulated insulin secretion (GSIS) is critical in mammalian fuel homeostasis and is diminished early in the evolution of beta-cell dysfunction, ultimately contributing to the development of Type 2 diabetes. We sought to standardise and validate the intravenous glucose tolerance test (IVGTT), a commonly used technique to assess GSIS, in anaesthetised and conscious cannulated male Han Wistar rats. METHODS: Male Han Wistar rats were cannulated via the right jugular vein and left carotid artery. Anaesthetised and chronically cannulated conscious models underwent IVGTT using increasing doses of glucose (0.2, 0.5 and 1.0 g glucose/kg LBM) or following pre-treatment with Exendin-4 (EX-4) before receiving a 0.5 g glucose/kg LBM bolus dose. Blood glucose, plasma insulin and plasma C-peptide were measured at time-points throughout the experiments. RESULTS: Dose-dependent increases in blood glucose, insulin and C-peptide (where measured) were observed following administration of increasing doses of an intravenous glucose bolus in both the anaesthetised and conscious cannulated rats. The 0.5 g glucose/kg LBM bolus resulted in an intermediate response and was used in the second part of the study. EX-4 pre-treatment in combination with glucose resulted in GSIS potentiation, as assessed by plasma insulin measurement alone (anaesthetised model) or insulin and C-peptide measurements (conscious model). DISCUSSION: The IVGTT was standardised in anaesthetised and conscious cannulated male Han Wistar rats by performing a glucose dose response study and validated by examining GSIS potentiation using EX-4. Based on these results, the 0.5 g glucose/kg LBM bolus dose is recommended as the dose to use to assess GSIS in any standardised screening phase of new compounds with the potential to enhance glucose-sensitive pancreatic function. The experimental conditions described in these studies could be transferred to disease models for more detailed assessment of novel compound efficacy.