View clinical trials related to Type 2 Diabetes.
Filter by:Treatment of diabetes mellitus type II with basal insulin, for patients treated in Clalit outpatient clinics that are not adequately controlled with current treatment.
Brief summary: Aspirin (ASA) has been shown to provide marked benefits in primary and secondary prevention of cardiovascular events. Substantial evidence suggests that low-dose ASA therapy should also be used as a primary prevention strategy in men and women with diabetes who are at high cardiovascular risk. On the other hand, there is current evidence on the potential benefits of low-dose ASA therapy in subjects with impaired fasting glucose, including those with metabolic syndrome. Most important, previous laboratory animal and clinical trial research convincingly demonstrates administration time-dependent (with reference to circadian rhythms) effects of ASA. Thus, the effects of ASA upon lipoperoxides, b-adrenergic receptors, and blood pressure (BP) in clinically healthy subjects depend on the circadian timing of ASA administration. The administration-time-dependent influence of ASA on BP was previously demonstrated in a randomized trial on healthy women and other independent double-blind, randomized, placebo-controlled clinical trials conducted, first, on clinically healthy subjects, a second one on normotensive and hypertensive subjects, a third one on pregnant women at high risk for preeclampsia and a fourth one in previously untreated patients with mild hypertension. The findings of these BP studies are consistent; BP-lowering effect of low-dose ASA is achieved when administered at bedtime but not upon awakening. In keeping with the chronopharmacological effects of ASA and the previous findings suggesting that ASA at low dose may exert a potential beneficial effect on BP, endothelium function and cardiovascular function, this prospective, randomized, parallel-arm study will investigate the potential influence of ASA on the primary prevention of cardiovascular, cerebrovascular and renal events in subjects with either impaired fasting glucose (≥ 100 mg/dl) or previous diagnosis of type 2 diabetes mellitus, who will receive low-dose ASA (100 mg/day) at different circadian times (upon awakening or at bedtime) in relation to their rest-activity cycle.
The use of energy from food changes when people sleep. However, it is still not known if differences in the amount of nighttime sleep have an effect on the amount of energy that people who have a relative with type 2 diabetes (parent, sibling, or grandparent) use to perform their daily activities. This study is being done to test the hypothesis that the daily use of energy in people who have a history of type 2 diabetes in their family will be different after they have slept short hours for 16 days in comparison to when they have slept longer hours for 16 days.
The purpose of this research study is to evaluate two nutrition and exercise programs in children ages 9-12 who are at risk for developing type 2 diabetes. This study also includes the involvement of parents or guardians who are willing to participate in these programs with the child.
The TODAY study group has prepared a protocol with the primary objective of collecting blood and phenotypic information to be used to explore relationships between candidate genes and type 2 diabetes (T2D), as well as obesity, insulin resistance, and cardiovascular complications of insulin resistance. Participation in the genetics study includes a blood draw for analysis of diabetes type and DNA extraction, as well as collection of basic family and medical history. Appropriate informed consent and assent are obtained from all participants to extract DNA and send blood, genetic material, and medical history to the Central Repository of the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) of the National Institutes of Health (NIH). The data are kept indefinitely by the Central Repository. The NIDDK will issue requests for proposals (RFP) throughout the scientific community for research that may help in the development of new diagnostic tests, new treatments, and new ways to prevent diabetes and other related comorbidities.
Currently, it is not known if the amount of nighttime sleep has any effect on the overall physical fitness, and on how much energy do people who have a relative with type 2 diabetes (parent, sibling, or grandparent) use to perform activities of daily living. This study will test the hypothesis that individual differences in nighttime sleep duration are related to differences in the amount of energy used to perform activities of daily living and the overall level of physical fitness of the individual.
The use of sugar and starch-like foods for energy (carbohydrate metabolism) changes when people sleep. However, it is still not known if differences in the amount of nighttime sleep have an effect on the carbohydrate metabolism of people who have a relative with type 2 diabetes (parent, sibling, or grandparent). This study is being done to test the hypothesis that the carbohydrate metabolism of people who have a history of type 2 diabetes in their family will be different after they have slept short hours for 10 days in comparison to when they have slept longer hours for 10 days.
The use of sugar and starch-like foods for energy (carbohydrate metabolism) changes when people sleep. However, it is still not known if differences in the amount of nighttime sleep have an effect on the carbohydrate metabolism of people who have a relative with type 2 diabetes (parent, sibling, or grandparent). This study is being done to test the hypothesis that individual differences in habitual sleep duration may be related to differences in the carbohydrate metabolism of people who have a history of type 2 diabetes in their family.
A diet (42% carbohydrate) specialized to the unique metabolic characteristics of peripubertal African AMerican girls (hyperinsulinemic, low insulin sensitive) will be more effective in maintaining glucose and insulin homeostasis compared to a standard diet (55% carbohydrate)
The purpose of the study is to investigate the weight-sparing effect of detemir and assess glycemic control and treatment satisfaction when switching from NPH to detemir, to improve metabolic control.