Active clinical trials for "Diabetes Mellitus, Type 1"

The purpose of this study is to evaluate an overnight system that will turn off the insulin pump automatically if the system predicts that a low blood sugar is likely. The study system includes a combination continuous glucose monitor (CGM)/ insulin pump made by Medtronic MiniMed, Inc and a regular laptop computer that runs a computer program that predicts low blood sugar. It works by (1) measuring the glucose levels under the skin with a continuous glucose monitor, (2) using a computer program on a laptop to predict what will happen to the glucose level over the next 35-55 minutes, and (3) turning off the insulin pump when the computer program predicts that low blood sugar will occur. We have tested this system overnight in the hospital and are ready to test the system in the home environment to learn more about how well it will work and to make sure that the blood sugar does not go too high when the pump shuts off. This study has several phases and will take about a month or a little more for a patient to complete. Patients will use the study system for about 5 days at home to show that the patient is able to use it correctly. After that, the patient will be asked to use the study system each night for an additional 3-4 weeks. During this time, the system will be active for two-thirds of the nights and not active for one-third of the nights. When the system is active and predicts that your blood sugar will become low, the insulin pump will shut off for up to 2 hours. The study will include 2 clinical centers in the United States.

The proposed mechanistic formula feeding study sets out to identify the mechanism(s) by which an extensively hydrolyzed casein formula is able to protect children at risk for type 1 diabetes (T1D) from beta-cell autoimmunity.

The purpose of this study is to determine if oral Cyclosporine A and oral Lansoprazole are effective in rendering patients with existing type 1 diabetes, insulin independent. This two-arm study was designed to evaluate the safety and efficacy for insulin independence by utilizing the FDA-approved oral immune tolerance agent, Cyclosporine A, and the FDA-approved proton-pump inhibitor, Lansoprazole. Lansoprazole and other proton-pump inhibitors increase gastrin levels. Gastrin was initially shown to have the potential to increase new beta cell formation in 1955 (Zollinger RM and Ellison EH. Ann Surg. 1955;142(4):709-23). Studies with the immune tolerance agent, Cyclosporine A, previously demonstrated that among recently diagnosed type 1 diabetes patients, insulin independence was achieved in as many as 67.5% of patients within 7 weeks of therapy (Bougneres PF et al. N Engl J Med. 1988:17;318(11):663-70). Cyclosporine A protected the remaining beta cells from further autoimmune attack, but over time, there was limited beta cell regeneration, and insulin was ultimately required by all patients. Therefore, this study proposes the usage of Cyclosporine A with a beta regeneration agent. Follow-up studies for up to 13 years among 285 type 1 patients utilizing Cyclosporine A for 20 months, did not demonstrate renal or other side effects (Assan R. et al. Diabetes Metab Res Rev. 2002;18(6):464-72). Human clinical trials with gastrin and epidermal growth factor demonstrated reductions in daily insulin requirements by much as 75% within 3 months following four weeks of therapy among existing type 1 diabetes patients (Transition Therapeutics, March 5, 2007 http://www.transitiontherapeutics.com/media/archive.php Accessed January 1, 2013). Lack of the ability to sustain these results was likely due to the ongoing autoimmune attack on the new beta cells generated by therapy. Gastrin alone has been shown to induce beta cell neogenesis from human pancreatic ductal tissue without epidermal growth factor in in vitro studies (Suarez-Pinzon WL et al. JCEM. 2005;90(6):3401-3409). Type 1 diabetes is an autoimmune disease. Despite evidence that many different immune tolerance agents have successfully reversed diabetes in rodent type 1 models, none have been successful in sustaining insulin independence in man (Ablamunits V et al. Ann NY Acad Sci. 2007;1103:19-32). The distinctions and complexities of islets in man are far different than that of rodents (Levetan CS and Pierce SM. Endocr Pract. 2012 Nov 27:1-36 Epub ahead of print). We hypothesize that in man, both an immune tolerance agent and a beta regeneration agent are required to sustain insulin independence. Based upon proton-pump inhibitors having been shown to increase plasma gastrin levels up to 10-fold, this clinical trial utilizes the oral proton-pump inhibitor, Lansoprazole. This study will determine the safety and efficacy of Cyclosporine A used with and without Lansoprazole to determine the impact on insulin independence among patients with existing type 1 diabetes. Cyclosporine A is utilized to protect the new beta cells formed by Lansoprazole. The combination of the two therapies may render reductions in insulin requirements and have a greater impact on sustained insulin independence than previously reported with Cyclosporine A or gastrin alone among type 1 patients.A This 52-week study consists of two treatment arms designed to assess the safety and efficacy of achieving insulin independence using: Oral Lansoprazole/Oral Cyclosporine A Oral Placebo/Oral Placebo It is hypothesized that the combination of oral Cyclosporine A and oral Lansoprazole will safely render significantly more patients with existing type 1 diabetes, insulin independent and may serve as a novel and innovative treatment approach for patients with type 1 diabetes utilizing two FDA-approved therapies.

The study is a two centre, open-label, uncontrolled single group phase 1A study of C19-A3 GNP peptide (10 μg peptide equivalent content) administered via Nanopass microneedles every 28 days for 8 weeks (3 doses), with follow-up for 6 weeks (14 weeks in total from first dose). Treatment will be given into the arm at a volume of 50ul. No blinding or randomisation will be performed. In keeping with standard phase 1 study designs, no placebo or control group is included as the primary aim is to establish whether there are any major unexpected safety issues in the use of this IMP for the first time in man. 8 subjects will be recruited at 2 centres: Cardiff, UK and Linköping, Sweden.

The objective is to determine if lowering serum uric acid by means of allopurinol in the course of kidney disease may be effective in preventing or improving albuminuria and renal function in Type 1 Diabetic patients. The study is a double blinded, randomised, placebo-controlled cross-over clinical trial.

The investigators are conducting a prospective cross-over study to evaluate the effects of vitamin D supplementation on diabetes control and the pro-inflammatory markers involved in microvascular complications in adolescents with Type 1 Diabetes. The investigators expect to see a significant improvement in glycemic control and a reduction of serum pro-inflammatory markers in adolescents with Type 1 Diabetes and vitamin D deficiency or insufficiency, who are treated with vitamin D.

A small, pilot, randomised, cross over trial that investigates the potential for DPPIVi therapy to reduce insulin requirements in type 1 diabetes was studied. We investigated whether this drug reduces daily insulin doses, leads to weight reduction, reduces blood glucose fluctuation and improves glucose control. Through reduction of blood glucose variability, we want investigated, whether it has the capability of improving the magnitude of epinephrine responses at 2.5mmol/L by performing a hyperinsulinaemic, hypoglycaemia clamp study after each arm. A successful outcome would then lead to an application for funds for a larger, multicentre intervention study. The benefits of this therapeutic advance are clear and this has the potential to make a dramatic improvement to the lives of people with type 1 diabetes in our community.

This is a single center, double blind randomized cross over design trial that will compare the impact of N-acetyl cysteine (200 mg) vs. saline infusion during experimental hypoglycemia on day one on the responses to experimental hypoglycemia on day two. 18 participants will be studied twice, 8 weeks apart. On each occasion they will undergo a 2 hour hypoglycemic clamp (target 50 mg/dl) in the morning and in the afternoon on day one and then again on the morning of day 2 and day 3. During the morning clamps, samples will be collected for later measurement of serum epinephrine levels, plasma and red blood cell NAC, cysteine, and glutathione concentrations and GSH/GSSG ratios (redox status), and participants will be asked to complete a hypoglycemia symptom questionnaire

Type 1 diabetes mellitus (T1D) results from immune-mediated destruction of insulin-producing islet cells. The loss of islet cells is traditionally treated with insulin therapy and in some cases pancreas or islet cell transplantation. Another approach would be to preserve islet cell mass before it is irreversibly lost. Previous trials using immune suppression within 6 weeks of T1D onset have demonstrated diminished exogenous insulin requirements compared to untreated controls. In our prior phase I non-randomized study, by extending immune suppression to the point of immune ablation / immune reset with autologous HSC support, several patients with new onset T1D have maintained an insulin-free, drug free remissions for more than 4 years. Although these results appear highly promising, it may be argued that our results are mitigated by the documented honeymoon effect following T1D, that is by a normal transient insulin free interval occurring after disease onset in some patients. The goal of this trial is to extend this phase I study of new onset T1D to clarify whether our post transplant insulin free interval is due to treatment intervention (transplant) or a result of a normally occurring "insulin free honeymoon period". Both groups will receive identical change of life style (i.e. diet, exercise) education.

Type 1 diabetes mellitus (T1D) is an autoimmune disease in which the insulin-producing pancreatic beta cells are destroyed, resulting in poor blood sugar control. The purpose of this study is to assess the safety and effectiveness of low molecular weight sulfated dextran (LMW-SD) on post-transplant islet function in people with T1D who have responded to intensive insulin therapy and have received kidney transplants. This study is taking place in Uppsala and Stockholm, Sweden, and Oslo, Norway.