Active clinical trials for "Diabetic Neuropathies"

This is a Platform Protocol to perform Phase II clinical trials in The Early Phase Pain Investigation Clinical Network (EPPIC-Net), under The Helping to End Addiction Long-termSM Initiative, or NIH HEAL InitiativeSM, related to the treatment of Painful Diabetic Peripheral Neuropathy (PDPN) in a platform setting to test multiple assets under a single protocol.

The purpose of this post-market study is to evaluate the real-world experience of Nevro's Spinal Cord Stimulation (SCS) therapy in patients with chronic, intractable leg pain due to painful diabetic neuropathy (PDN). This is a multicenter, prospective, observational global study, that will partner diabetes management teams with pain physicians to provide an interdisciplinary treatment regimen for PDN patients. Outcomes will be assessed via standardized assessments.

Part Ⅰ:Infrared thermograms of four parts of the soles of the feet, dorsum of the feet, palms of the hands, and dorsum of the hands of healthy volunteers, diabetic patients, and patients with diabetic peripheral neuropathy were collected by using infrared thermography, and the patterns of change in the average temperatures of the parts of the participants in the three groups were analysed and compared by using the accompanying software. Part Ⅱ: Diabetic Peripheral Neuropathy (DPN) mainly presents with symmetrical pain,numbness, and ankylosing sensation, but reversal after diagnosis is particularly difficult. Electroacupuncture can significantly improve the function of peripheral nerves, regulate local blood flow, and reduce the inflammatory response to promote nerve regeneration, but no study has shown that electroacupuncture can effectively prevent the occurrence of DPN. Therefore, it is of great research significance to determine whether electroacupuncture has the possibility in preventing the occurrence of DPN.

The present study aims to evaluate the efficacy and safety of the use of customized silicone digital orthoses for six months in the distribution of plantar pressure, in the reduction of pre-ulcerative lesions and plantar ulcers in the forefoot, foot deformities, quality of life and foot health and functionality in people with diabetes and neuropathy with risk category 2 and 3 for ulcers, according to the International Working Group on Diabetic Foot.

Tis study aims to assess whether multiple sessions of sham-controlled HF-rTMS applied to the motor cortex significantly reduces treatment-resistant neuropathic pain in diabetic patients. This study will also investigate the effect of those rTMS sessions on functional connectivity of the M1 with brain areas involved in pain processing, underlying brain metabolism and brain plasticity using rs-fMRI, MRS and Paired-pulse stimulation respectively in those patients. Subjects will be randomized into two groups to receive real or sham rTMS protocol. A washout period of at least 8 weeks will be respected between protocols to minimize carry-over effects. Sham stimulation will be delivered using a sham coil, providing the same auditory and sensory stimuli. One daily rTMS session for 5 days of HF-rTMS, will be delivered through an H-coil applied to the primary motor area of the leg. Each session will last 20 minutes during which 30 consecutive trains of 50 stimuli will be delivered at 20 Hz at 100% of resting motor threshold (RMT), with an intertrain interval of 30s

The purpose of this study is to evaluate the effectiveness of providing sensation of the missing limb to individuals with above and below the knee limb loss. The investigators will implanted stimulating electrodes to send small electrical currents to the remaining nerves. These small electrical currents cause the nerves to generate signals that are then transferred to your brain similar to how the information about your foot and lower limb used to be transferred to the brain prior to your limb loss. Additionally, there is the option to have muscle recording electrodes implanted within the muscles of the lower limb with the goal to develop a motor controller that would allow the user to have intuitive control of a robotic prosthetic leg.

Diabetic peripheral neuropathy (DPN) is the most common chronic complication of diabetes, affecting about 50% of patients with diabetes and leading to severe morbidity, poor quality of life, high mortality, and high health care costs. Due to the complex structure and anatomy of the peripheral nervous system, DPN presents with a very broad spectrum of clinical symptoms and deficits, including severe pain, sensory deficits, foot ulcers and amputations. Presently there is no treatment for DPN and even with good blood glucose control DPN develops especially in patients with type 2 diabetes. There is a need to identify effective interventions for DPN. Preclinical studies have provided evidence that the combination of fish oil and salsalate is an effective treatment of DPN. The human subject study to be performed will examine the effect of fish oil with and without salsalate on the blood lipid profile and circulating metabolites of omega-3 polyunsaturated fatty acids (PUFA). Fish oil is an excellent source for the nutrition dependent omega-3 PUFA, primarily eicosapentaenoic acid (EPA; 20:5) and docosahexaenoic acid (DHA; 22:6). These fatty acids are the source of anti-inflammatory metabolites known as resolvin, neuroprotectin and maresin. Preclinical studies have also demonstrated that the metabolites of EPA and DHA are neuroprotective. Furthermore, when fish oil is combined with salsalate the production of these metabolites is increased in vivo. Thus, the investigators hypothesize that fish oil and salsalate will be an effective therapy of DPN. However, prior to doing a formal study of the effect of fish oil + salsalate on DPN there is a need to learn more about what concentration combination will provide the most efficacious effect on the omega-3 index (defined as the sum of EPA and DHA, as a percentage of total fatty acids in red blood cells) and that will safely increase the production of the anti-inflammatory metabolites. These studies will be performed at two sites the University of Iowa (Dr. Yorek) and University of Michigan (Dr. Pop-Busui) by treating human subjects with type 2 diabetes and DPN with either 2g or 4g of fish oil per day (capsules) for 4 months and then adding salsalate 1.5 g or 3g per day (tablets) to the fish oil treatments for an additional 2 months. At baseline and after treatment with fish oil alone and after treatment with the combination of fish oil and salsalate the omega-3 index and levels of circulating omega-3 PUFA metabolites will be determined as primary endpoints. Secondary endpoints will include determination of circulatory inflammatory markers and non-invasive measurements for DPN. The risks to subjects are minimal and are very reasonable in relation to the importance of the knowledge to be gained.

The objective of the proposed work is to develop non-pharmacological interventions for diabetic peripheral neuropathy (DPN), to improve quality of life of individuals with diabetes, and reduce the prevalence of opiate prescription, sensation loss, falls, and deaths caused by DPN. To this end, the proposed study will investigate and determine the feasibility of the non-pharmacological intervention device. The feasibility study involves 16 participants, split evenly between pre-neuropathic diabetic and neuropathic diabetic participants. During the study, each group will receive the same 45-minute intervention on 10 days spread over no more than 14 days total. Feasibility will be determined by change in pain assessed before and after intervention.

Inadequate rehabilitation training after amputation can result in poor patient outcomes, injuries, and wasted healthcare resources. This is a serious public health problem due to an aging population and rising prevalence of diabetes (main cause of amputation in the U.S.). In this study, the investigators will examine the effects of external vs. internal attentional focus instruction on learning of a balance task in individuals with existing amputation and those at risk of amputation (older adults with diabetes). With the proposed research, the investigators aim to expand the understanding of motor learning in individuals with and at risk of lower limb loss to provide knowledge that will lead to more effective and efficient rehabilitation.

Fatigue in diabetic neuropathy compromises patients' physical activity and poses questions on how to plan correct rehabilitation training. Conclusive interpretation of muscular mechanisms of fatigue in diabetic neuropathy has not yet been achieved. Among the various instrumental evaluations for fatigue, multichannel surface electromyography (sEMG) is a recognized tool that permits the study of myoelectric manifestations of fatigue. Aim of the study is to assess if differences in myoelectric manifestations of fatigue between patients affected by diabetic neuropathy exist after an aerobic or endurance training.