Active clinical trials for "Diabetic Nephropathies"

Asia is in the midst of an epidemic of diabetes. Epidemiological figures suggest that there are more than 110 million people affected by diabetes in China, with a significant proportion of young adults already affected. With increasingly young age of onset, the financial implications due to productivity loss and health care expenditures are colossal. As a result, prevention of diabetes and diabetic complications has been identified as a top healthcare priority in China. In Chinese, diabetic kidney disease with albuminuria, which reflects widespread vascular damage, is a major predictor for end-stage renal failure, cardiovascular complications and death, and a major contributor to the increased healthcare burden associated with diabetes. There is an immense demand for effective tools which can accurately predict diabetes and diabetic complications. Only few genetic factors have been consistently shown to be associated with diabetic kidney disease or other diabetic complications. Identification of genetic factors or other biomarkers predicting these complications can facilitate early identification of high risk subjects for treatment, as well as provide novel targets for drug treatment. To address this, the investigators plan to utilize both hypothesis-generating whole-genome approach as well as candidate gene-based studies to identify novel genetic, epigenetic factors as well as other biomarkers associated with the development of diabetic cardiovascular and renal complications, as well as other diabetes-related outcomes. The Hong Kong Diabetes Biobank (HKDB) is being established in order to serve as a territory-wide diabetes register and biobank for epidemiological analyses, as well as large-scale discovery and replication of genetic and epigenetic markers, and other biomarkers relating to diabetes, diabetes complications or related outcomes. Subjects will be recruited from diabetes centres across Hong Kong, and will have detailed clinical information collected at the time of written consent and blood taking. Subjects will have detailed assessment of baseline diabetes complications through a structured clinical assessment, and will be prospectively followed up for development of different diabetes-related endpoints, as well as collection of clinical information and causes of hospitalization, along with information on medications and prescription records. This multi-centre cohort and biobank aims to improve our understanding of the epidemiology of diabetes and diabetes complications and related outcomes, as well as provide a unique resource for large-scale biomarker research to advance diabetes care and precision medicine in diabetes.

Despite decades of research, the pathogenesis of human diabetic kidney disease remains largely unclear. Our goal is to use archived human kidney biopsy tissue from patients with and with diabetic nephropathy to identify new molecules that drive and/or protect against disease progression. We will use RNA sequencing to identify transcriptomic changes that associate with histologic and functional outcomes.

Diabetic kidney disease (DKD) is a common complication of diabetes, and is now the most common form of chronic kidney disease. DKD is the leading cause of kidney disease requiring dialysis or kidney transplantation, and its global incidence and prevalence have reached epidemic levels. While the risk of developing DKD can be ameliorated by tight blood glucose and blood pressure control, it is not fully preventable and once established DKD cannot be cured. Therefore many patients are left with poor and worsening health and with increased mortality risk. Developing new ways to treat DKD requires healthcare professionals to be able to identify those patients most in need of treatment. One promising approach for identifying patients that are at risk is the use of imaging measurements (called "biomarkers") derived from Magnetic Resonance Imaging (MRI) and Ultrasound (US) of the kidneys. Evidence from early studies shows that such imaging biomarkers can identify underlying problems in DKD such as blood supply, oxygen supply, kidney scarring and kidney function, in ways that are better than those currently available. The investigators think that imaging biomarkers will improve the identification of patients who are likely to decline from DKD in the short term. The changes found by imaging may even happen before effects on the blood and urine. The investigators plan to test this hypothesis by performing a study observing 500 patients with early stage DKD, recruited in 5 sites across Europe. All patients will have detailed assessment at the start of their involvement, including clinical assessment, blood and urine samples, and MRI and US scans. The investigators will look at whether imaging biomarkers are associated with other measures that predict progression in DKD, and follow patients every year for 3 years (4 years total study participation) to see if the imaging biomarkers predict worsening DKD.

The primary objective of this study is to determine the effects of semaglutide on kidney oxygenation and function in type 1 diabetes. The secondary objective is to determine the glycemic effects and safety of semaglutide in type 1 diabetes.

With the improvement of people's living standard, the prevalence of Diabetes is increasing year by year. In present, 350 million people worldwide are suffering from diabetes, and by 2035, there will be as high as 600 million. Diabetes causes a variety of complications, including diabetic nephropathy, which is one of the most common complications of Diabetes. Diabetic nephropathy is a microvascular complication of diabetes. Microalbuminuria and glomerular filtration rate decrease are the main manifestation. Even more, it can progress to end-stage renal changes. Data showed that diabetic nephropathy accounts for about 40% of patients with end-stage renal disease receiving renal replacement therapy. However, the treatment of diabetic nephropathy is still lacking. In the past 40 years, few drugs have been proven to ameliorate the progression of diabetic nephropathy. Even though, the renal function of a large number of diabetic nephropathy patients is gradually deteriorating. Therefore, it is urgent to find a therapeutic drug that acts on different targets. Trimetazidine is a piperazine derivative. It is mainly used in the treatment of stable angina pectoris. Its safety has been well verified. In recent years, the role of trimetazidine in acute renal damage has been widely reported. A large number of studies have shown that trimetazidine can reduce the effect of contrast agent on renal function and reduce the incidence of contrast nephropathy. There fore, Trimetazidine is a promising drug for delaying the progression of diabetic nephropathy.

This is a prospective, observational, cohort study of patients with a clinical diagnosis of diabetes who are undergoing clinically indicated kidney biopsy. The intent is to collect, process, and study kidney tissue and to harvest blood, urine and genetic materials to elucidate molecular pathways and link them to biomarkers that characterize those patients have a rapid decline in kidney function (> 5 mL/min/1.73m2/year) from those with lesser degrees of kidney function change over the period of observation. High through-put genomic analysis associated with genetic and biomarker testing will serve to identify key potential therapeutic targets for DKD by comparing patients with rapid and slow progression patterns. Each participating clinical site will search for, consent, harvest the biopsy sample, and enroll the participants as required for the TRIDENT protocol.

The study will investigate, primarily, the safety, feasibility and tolerability and, secondarily, the preliminary efficacy of an allogeneic bone marrow-derived Mesenchymal Stromal Cell (MSC) therapy (ORBCEL-M) in study subjects with type 2 diabetes (T2D) and progressive diabetic kidney disease (DKD).

The current protocol plans to enroll participants with youth-onset Type 2 Diabetes (T2D) as well as obese and lean controls from the Renal-HEIR - Renal Hemodynamics, Energetics and Insulin Resistance in Youth Onset Type 2 Diabetes Study (n=100) [COMIRB #16-1752] in a prospective investigation that seeks to 1) define the changes in kidney function by gold standard techniques and energetics by functional Magnetic Resonance Imaging (MRI) in adolescents with and without T2D as they transition to young adulthood; 2) quantify kidney oxidative metabolism by 11C-acetate Positron Emission Tomography (PET) in a subset of participants who are ≥18 years of age with youth-onset T2D and/or obesity; 3) determine peripheral arterial stiffness by SphygmoCor. Mechanistic insight will be provided by transcriptomic analyses of repeat biopsies 3-years after their initial biopsy for eligible participants with youth-onset T2D, as well as molecular analysis of tissue obtained from J-wire endovascular biopsies. This study will also leverage this well-characterized cohort of youths to define youth-onset T2D-related changes in brain morphology and function by structural MRI and resting-state functional MRI and through the assessment of cognitive function (fluid and crystallized intelligence) using the NIH Toolbox Cognitive Battery (NIHTB-CB), as an exploratory objective. All enrollees in Renal-HEIR have consented to be contacted for future research opportunities.

The overall objective of the proposed randomized trial is to test whether implementation of intensively integrated care of microvascular risk factors (glycated hemoglobin [HbA1C], urinary albumin-to-creatinine ratio [ACR], blood pressure [BP], estimated glomerular filtration rate [eGFR], uric acid [UA] and low-density lipoprotein cholesterol [LDL]) will improve and reduce diabetic kidney disease events (DKD morbidity and mortality) among patients with diabetes and additional microvascular risk factors compared to usual care in public primary care setting (community health service center) in Xiamen, China.

Diabetes is the leading cause of chronic kidney disease (CKD) and end-stage kidney disease worldwide. Diabetic kidney disease (DKD) is a clinical diagnosis based upon the presence of reduced glomerular filtration rate (GFR) and/or increased urinary albumin excretion (UACR) in diabetes. The inhibition of the renin-angiotensin system (RAS) has been identified as the cornerstone in the management of DKD for decades. Recently, more evidence supports the use of Sodium-glucose cotransporter 2 inhibitors (SGLT2i) in the treatment of DKD. They were associated with slower progression of renal disease and lower rates of clinically relevant kidney events. Those studies confirmed the SGLT2i efficacy in kidney protection and showed that their addition to angiotensin-converting enzyme inhibitors (ACEi) or angiotensin receptor blockers (ARBS) will be more effective than using ACEi or ARBS alone. It is unclear whether SGLT2i is used as a first-line instead of ACEi or ARB, and to what extent it will be effective in managing DKD compared to the proven effect of ACEi/ARBs alone. This study provides a unique opportunity to address this gap in the literature. The aim of this study is to compare, head to head, the renal performance of ACEi (standard of care) versus SGLT2 in diabetic patients who have evidence of deteriorating renal function evidenced by either the reduction of e GFR or increased UACR. Scientific hypotheses: Null hypothesis: after one year, the mean change of the e GFR in the enalapril group - Mean change of the e GFR in the empagliflozin group > or = 5 ml/min/1.73m2 Alternative hypothesis: after one year, the mean change of the e GFR in the enalapril group - Mean change of the e GFR in the empagliflozin group < 5 ml/min/1.73m2