insulin-glargine and Disease-Models--Animal

Insulin treatment was confirmed to reduce insulin resistance, but the underlying mechanism remains unknown. Caveolin-1 (Cav-1) is a functional protein of the membrane lipid rafts, known as caveolae, and is widely expressed in mammalian adipose tissue. There is increasing evidence that show the involvement of Cav-1 in the AKT activation, which is responsible for insulin sensitivity. Our aim was to investigate the effect of Cav-1 depletion on insulin sensitivity and AKT activation in glargine-treated type 2 diabetic mice. Mice were exposed to a high-fat diet and subject to intraperitoneal injection of streptozotocin to induce diabetes. Next, glargine was administered to treat T2DM mice for 3 weeks (insulin group). The expression of Cav-1 was then silenced by injecting lentiviral-vectored short hairpin RNA (shRNA) through the tail vein of glargine-treated T2DM mice (CAV1-shRNA group), while scramble virus injection was used as a negative control (Ctrl-shRNA group). The results showed that glargine was able to upregulate the expression of PI3K and activate serine phosphorylation of AKT through the upregulation of Cav-1 expression in paraepididymal adipose tissue of the insulin group. However, glargine treatment could not activate AKT pathway in Cav-1 silenced diabetic mice. These results suggest that Cav-1 is essential for the activation of AKT and improving insulin sensitivity in type 2 diabetic mice during glargine treatment.

Topics: Animals; Caveolin 1; Disease Models, Animal; Insulin Glargine; Insulin Resistance; Mice; Mice, Inbred NOD

The main objective of this experimental study was to evaluate the feasibility of diabetes induction by total pancreatectomy and pancreatic allotransplant after diabetes induction by total pancreatectomy. The secondary objective was to evaluate metabolic (C-peptide, glycemia) and inflammatory (lactate and platelet levels) parameters after diabetes induction by total pancreatectomy and pancreatic allotransplant after total pancreatectomy.. The study protocol was approved by the French Minister of Research (APAFiS no.18169). Insulin-dependent diabetes was induced by total pancreatectomy in one male Sus scrofa pig, and pancreatic allotransplant was performed, after total pancreatectomy, in 3 male Sus scrofa pigs. Total pancreatectomy was performed under general anesthesia,with meticulous dissection of the portal vein and the splenic vein to preserve the spleen. Concerning pancreas procurement, extensive pancreas preparation occurred during thewarm phase,before coldperfusion. Pancreatic allotransplant was performed using donor aorta (with superior mesenteric artery and celiac trunk).. Diabetes induction was successful, with negative C-peptide values at 3 hours after total pancreatectomy. Glycemic control without hypoglycemic events was obtained with the use of long-acting insulin administered once per day. No rapid-acting insulin was used. In animals that received pancreatic allotransplant, after enteral feeding was started, glycemic control without hypoglycemic events and without insulin was obtained in 2 animals.. In an experimental porcine model, diabetes induction by total pancreatectomy and pancreatic allotransplant after total pancreatectomy are feasible and effective. The development of these models offers the potential for new investigations into ischemia-reperfusion injuries, improvement of pancreas procurement methods, and preservation techniques.

Topics: Animals; Biomarkers; Blood Glucose; Blood Platelets; C-Peptide; Diabetes Mellitus, Type 1; Disease Models, Animal; Feasibility Studies; Hypoglycemic Agents; Insulin Glargine; Lactic Acid; Male; Pancreas Transplantation; Pancreatectomy; Sus scrofa; Time Factors; Transplantation, Homologous

Recombinant insulin Lisargine is a new type of insulin. In this study, we aimed to compare its pharmacodynamic (PD) and pharmacokinetic (PK) with Lantus.. The PD test was performed by exploring the effect of single administration on blood glucose of normal rats and STZ-induced diabetic rats, and the effect of multiple administrations on blood glucose of STZ-induced diabetic rats. Further PD tests include receptor affinity test, receptor autophosphorylation test and adipocyte glucose uptake test. Four IU and 8 IU per dog Lisargine was used for PK test, insulin was measured and area under curve (AUC) was calculated.. With single injection, Lisargine 1.5 IU/kg had significant hypoglycemic effects at 1 and 2 h, similar to that of Lantus. Lisargine 5 IU/kg and 10 IU/kg lowered the blood glucose of STZ-induced diabetic rats at 1, 2, 4 & 6 h significantly. With multiple injections, Lantus lowered blood glucose at 2, 4 & 6 h, Lisargine 2.5 IU/kg, 5 IU/kg, and 10 IU/kg lowered blood glucose at 2 & 4 h significantly, compared with vehicle. There was no difference for receptor affinity test, receptor autophosphorylation test and adipocyte glucose uptake test between Lisargine and Lantus. The PK of Lisargine and Lantus of healthy Beagle dogs was very similar.. This animal study demonstrated that PK and PD of Lisargine and Lantus were similar, suggesting the bioequivalence of these products.

Topics: Animals; Diabetes Mellitus, Experimental; Disease Models, Animal; Dogs; Hypoglycemic Agents; Injections; Insulin; Insulin Glargine; Lysine; Male; Rats; Rats, Sprague-Dawley; Streptozocin

Metabolic disorders, such as PCOS (polycystic ovarian syndrome) and T2DM (type 2 diabetes mellitus), are associated with menstrual dysfunction, anovulation, infertility, and early pregnancy loss. Ovarian dysfunction is not only related to low pregnancy rates but also to the increased risk of miscarriage. Women with PCOS or T2DM, characterized by hyperinsulinemia, commonly experience ovarian dysfunction. In this study, we first explored whether high insulin levels directly affected ovarian functioning during embryo implantation. Mice in the insulin-treated group were given a subcutaneous injection of human recombinant insulin. After insulin treatment, serum levels of E2 (estrogen), PROG (progesterone), LH (luteinizing hormone), and FSH (follicle-stimulating hormone) were obviously lower, and there was a significant decrement of ovarian GDF9 (growth differentiation factor 9) mRNA. H&E (hematoxylin and eosin) staining showed a greater number of immature follicles and less luteinization in the insulin group. Further autophagy was studied in this process. A significant increase of P62 (SQSTM1/Sequestosome1) and a decrease of Cathepsin B, BECN1 (Beclin 1), and ULK1 (Unc-51-like kinase 1) mRNA in ovary was found in the insulin group. Western blot analysis showed that the expressions of LC3 (microtubule-associated protein 1 light chain 3), BECN1, and Cathepsin B proteins in ovaries from insulin group were obviously reduced, while P62 proteins were significantly increased. All these results illustrated that insulin could directly impair ovarian function during embryo implantation and the imbalance of ovarian autophagy due to insulin. Autophagy could enhance the impaired ovarian function results from insulin.

Topics: Animals; Animals, Outbred Strains; Anovulation; Autophagy; Autophagy-Related Protein-1 Homolog; Beclin-1; Cathepsin B; Disease Models, Animal; Embryo Implantation; Embryo Loss; Female; Gene Expression Regulation, Developmental; Growth Differentiation Factor 9; Hyperinsulinism; Insulin Glargine; Mice; Ovary; Pregnancy; Random Allocation; Sequestosome-1 Protein

Previous epidemiological studies have reported a potential link between insulin analogues and breast cancer; however, a prospective randomised controlled trial showed neutral effects of insulin glargine on cancer risk. Insulin glargine is metabolised in vivo to an M1 metabolite. A question remains whether a subset of individuals with slower rates of glargine metabolism or who are on high doses could, theoretically, have an increased risk of cancer progression if a tumour is already present. In this study, we aimed to determine whether a non-metabolisable form of insulin glargine induced murine breast cancer growth.. A mouse model of type 2 diabetes (MKR) was used for these studies. MKR mice were injected with two murine mammary cancer cell lines: Mvt-1 cells (derived from MMTV-c-Myc/Vegf tumours) and Met1 cells (derived from MMTV-polyoma virus middle T antigen tumours). Mice were treated with 25 U/kg per day of the long-acting insulin analogues, insulin glargine, insulin detemir, insulin degludec or non-metabolisable glargine, or vehicle.. No difference in tumour growth was seen in terms of tumour size after insulin glargine, detemir, degludec or vehicle injections. Non-metabolisable glargine did not increase tumour growth compared with insulin glargine or vehicle. Insulin glargine and non-metabolisable glargine led to insulin receptor phosphorylation in vivo rather than IGF-1 receptor phosphorylation.. These results demonstrate that in a mouse model of type 2 diabetes, at high concentrations, basal insulin analogues and a non-metabolisable glargine analogue do not promote the progression of breast tumours.

Topics: Animals; Cell Line, Tumor; Diabetes Mellitus, Type 2; Disease Models, Animal; Female; Humans; Hypoglycemic Agents; Insulin; Insulin Glargine; Mammary Neoplasms, Animal; Mice; Phosphorylation; Receptor, Insulin; Receptors, Somatomedin

Adult pig islet isolation has greatly improved in the past few years. Islet grafts may now be tested in large animals. Continuous Glucose Monitoring System (CGMS) was applied to diabetic Goettingen Minipigs (GMP) to improve the management of hyperglycemia and hypoglycemia and their welfare before transplantation.. GMP (25-35 kg) received a minipig diet once daily. Diabetes was induced by streptozotocin (STZ; 150 mg/kg intravenous [IV]; n = 5) or by surgical pancreatectomy (PGMP; n = 3). Interstitial glucose concentration (IGC) was monitored continuously with an implanted sensor; CGMS was calibrated using conventional blood glucose tests 3-4 times per day; CGMS data were fed into the monitor memory and analyzed using CGMS software.. Glucose sensors were handled accurately. Diabetes occurred 2-3 days after STZ or immediately after pancreatectomy with basal C-peptide secretion of <0.4 ng/mL (measured using intravenous glucose tolerance test) and prompt loss of body weight. Insulin substitution was necessary to keep the GMP in good condition for up to 5-6 months, with stable body weight and normal behavior. Some GMP became hypoglycemic, which was only documented by CGMS, but not by conventional glucose assays. Tight glucose control and substitution of exocrine enzymes (Creon 25,000 E/d) reduced morbidity of the PGMP, which was then comparable with that of STZ-GMP.. The CGMS, developed for humans, is equally suitable for the 2 GMP diabetes models. Close-meshed glucose monitoring and insulin treatment improved the general condition of the diabetic GMP, ie, the islet graft recipients, and will thus greatly add to posttransplantation success.

Topics: Animals; Biosensing Techniques; Blood Glucose; Diabetes Mellitus, Experimental; Diabetes Mellitus, Type 1; Disease Models, Animal; Hypoglycemic Agents; Insulin; Insulin Glargine; Insulin Secretion; Insulin, Long-Acting; Monitoring, Physiologic; Pancreatectomy; Swine; Swine, Miniature

(Prepro)insulin is considered a central antigenic determinant in diabetic autoimmunity. Insulin has been used to modify diabetes development in NOD mice and prediabetic individuals. We have recently shown that (prepro)insulin can adversely promote diabetes development in murine type 1 diabetes. Based on these findings we have developed experimental autoimmune diabetes (EAD), a new mouse model characterized by (1) CD4(+)/CD8(+) insulitis, induced by (2) (prepro)insulin DNA vaccination, leading to (3) beta cell damage and insulin deficiency in (4) RIP-B7.1 transgenic mice (H-2(b)). EAD develops rapidly in 60-95% of mice after intramuscular, but not intradermal ("gene gun"), vaccination; and DNA plasmids expressing insulin or the insulin analogues glargine, aspart, and lispro are equally potent to induce EAD. Similar to NOD mice, diabetes is adoptively transferred into syngeneic recipients by spleen cell transplantation in a dose-dependent fashion. We have devised a two-stage concept of EAD in which T cell activation and expansion is driven by in vivo autoantigen expression, followed by islet damage that requires beta cell expression of costimulatory B7.1 for disease manifestation. Taken together, EAD is a novel, genetically defined animal model of type 1 diabetes suitable to analyze mechanisms and consequences of insulin-specific T cell autoimmunity.

Topics: Adoptive Transfer; Animals; Autoimmunity; Diabetes Mellitus, Experimental; Diabetes Mellitus, Type 1; Disease Models, Animal; Hyperglycemia; Injections, Intramuscular; Insulin; Insulin Glargine; Insulin Lispro; Insulin, Long-Acting; Islets of Langerhans; Lymphocyte Subsets; Mice; Mice, Transgenic; Spleen; T-Lymphocytes; Time Factors; Transplantation, Isogeneic; Vaccination; Vaccines, DNA