Antidiabetic and Antioxidant Impacts of Desert Date ( Balanites aegyptiaca) and Parsley ( Petroselinum sativum) Aqueous Extracts: Lessons from Experimental Rats

Physicochemical and sensory characteristics of melon milk samples prepared from toasted, autoclaved, boiled and germinated melon seeds were determined. The germinated melon milk (GMM) had higher protein and ash contents but lower pH and viscosity than the other treated milk samples. Toasting the melon seeds improved the ash, protein, total solids and soluble solids of melon milk more than the boiling and autoclaving processes. The mean sensory scores showed that the GMM was rated lower than the other types of processed milk samples for all the sensory attributes evaluated. The toasted melon milk (TMM) had higher sensory ratings for color, mouthfeel and flavor and was generally preferred to the other treated melon milk samples.

The objective of this study is to induce experimental diabetes mellitus by Streptozotocin in normal adult Wistar rats via comparison of changes in body weight, consumption of food and water, volume of urine and levels of glucose, insulin and C-peptide in serum, between normal and diabetic rats. Intra-venous injection of 60mg/kg dose of Streptozotocin in adult wistar rats, makes pancreas swell and at last causes degeneration in Langerhans islet beta cells and induces experimental diabetes mellitus in the 2-4 days. Induction of experimental diabetes mellitus is indeed the first step in the plan of purification of pancreatic Langerhans islet cells of normal rats for transplanting under the testis subcutaneous of experimentally induced diabetic rats. Streptozotocin induces one type of diabetes which is similar to diabetes mellitus with non-ketosis hyperglycemia in some animal species. For induction of experimental diabetes in male adult rats weighted 250-300 grams (75-90 days), 60mg/kg of Streptozotocin was injected intravenously. Three days after degeneration of beta cells, diabetes was induced in all animals. The diabetic and normal animals were kept in the metabolic cages separately and their body weight, consumption of food and water, urine volume, the levels of serum glucose, insulin and C-peptide quantities in all animals were measured and then these quantities were compared. For a microscopic study of degeneration of Langerhans islet beta cells of diabetic rats, sampling from pancreas tissue of diabetic and normal rats, staining and comparison between them, were done. Induction of diabetes with Streptozotocin decreases Nicotinamide-adenine dinucleotide (NAD) in pancreas islet beta cells and causes histopathological effects in beta cells which probably intermediates induction of diabetes. In this study, we used Streptozotocin for our experiments in induction of experimental diabetes mellitus. After Induction of diabetes, consumption of food and water, volume of urine and glucose increased in the diabetic animals in comparison with normal animals, but the weight of body and the volume of insulin and C-peptide decreased in the diabetic animals. Sampling and staining of pancreas tissue of diabetic and normal rats showed that the Langerhans islet beta cells of diabetic rats have been clearly degenerated. In three days, Streptozotocin makes pancreas swell and at last causes degeneration in Langerhans islet beta cells and induces experimental diabetes. It also changes normal metabolism in diabetic rats in comparison with normal rats. Consumption of water and food, volume of urine, serum glucose increases in diabetic animals in comparison with normal rats but the levels of serum insulin, C-peptide and body weight decreases.

Insulin-stimulated glucose uptake in adipose tissue and striated muscle is critical for reducing post-prandial blood glucose concentrations and the dysregulation of this process is one hallmark of Type II (non-insulin-dependent) diabetes mellitus. It has been well established that the insulin-stimulated redistribution of the insulin responsive glucose transporter, GLUT-4, from intracellular storage sites to the plasma membrane depends on the production of phosphoinositide 3,4,5 trisphosphate by the Class IA Phosphatidylinositol 3' kinase. Recent discoveries however, have shown the presence of a second insulin signalling pathway leading to GLUT-4 translocation, a pathway dependent on insulin receptor signalling emanating from caveolae or lipid rafts at the plasma membrane. This pathway begins with the phosphorylation of the adaptor protein Cbl by the insulin receptor, and results in the activation of a small GTP binding protein, TC10, a member of the Rho family. TC10 is able to modulate actin structure in 3T3L1 adipocytes, and its overexpression inhibits insulin-stimulated GLUT-4 translocation, an inhibition completely dependent on localization of TC10 to the caveolae or lipid rafts. The spatial compartmentalization of insulin signalling from caveolae or lipid rafts provides a novel signalling pathway that functions in concert with general signalling mechanisms in the control of actin dynamics regulating insulin-dependent GLUT-4 translocation.