Active clinical trials for "Polycystic Kidney Diseases"

Gut microbes can influence numerous aspects of human biology. Alterations in the function and composition of gut microbial flora (gut microbiota ) have been linked to inflammatory bowel disease, chronic inflammation, dyslipidemia, diabetes mellitus, atopic disorders, cardiovascular disease, neoplasms, and obesity. However, little is known whether renal failure alters the composition of gut microbiota and whether an alteration in the gut microbiota of patients with renal failure impacts on the development of co-morbid conditions such as accelerated atherosclerosis, abnormal bone mineral metabolism, and chronic inflammation that are associated with renal failure. Nonetheless, several lines of evidence suggest that renal failure alters the chemical environment of the intestinal lumen, which could impose a selective pressure on the growth of certain gut microbes. The investigators hypothesize that the gut microbiota of patients with renal failure is different from those without renal failure. To test this hypothesis the investigators are conducting a cross-sectional study of gut microbiota in patients with different degrees of renal failure due to polycystic kidney disease (PKD).

The purpose of this study is to establish normal Magnetic Resonance quantitative values (tissues stiffness, Apparent Diffusion Coefficient values and Blood Oxygen Level Determination values for both renal cortex and medullary tissues and total renal blood flow) for young Autosomal Dominant Polycystic Kidney Disease patients with normal renal function, and normal young adult controls without Autosomal Dominant Polycystic Kidney Disease and normal renal function. Hypothesis: Newer Magnetic Resonance quantitative imaging parameters (tissue stiffness, Apparent Diffusion Coefficient, Blood Oxygen Level Determination levels, Magnetization Transfer and renal blood flow) will have different values in young adult ADPKD patients as compared to normal volunteers.

Chronic Kidney Disease (CKD) is associated with bone changes and very high fracture rates. A component of bone is marrow. Bone marrow fat is increased in patients with CKD compared to those in the normal population of the same age. It is not clear if there will be changes in the marrow fact content in those with CKD on Pioglitazone. In people with normal kidney function, thiazolidinedione group of drugs have had variable effects on bone marrow fat content, as measured by MRS. This is important as changes in marrow fat are likely related to changes in the bone in patients with chronic kidney disease.

Polycystic kidney disease (PKD) is a genetic disease that occurs in 1 in 500 individuals and leads to kidney failure in half of all affected. Currently, no treatments exist for PKD. PKD-affected kidney cells divide and multiply inappropriately, and form fluid-filled sacs called cysts. Kidney cysts continue to grow throughout life, destroying normal kidney tissue, leading to kidney failure. Based on evidence from basic science research it is believed that drinking high amounts of water can slow the abnormal cysts growth. This study aims to look at changes in urine composition with high water intake in PKD-affected persons compared to healthy individuals.

This is a single center, comparative cohort study to investigate alterations in hepatic transporter function in subjects with autosomal dominant polycystic kidney disease (ADPKD) compared to healthy subjects and subjects with non-ADPKD renal disease. Eligible subjects will be 18-65 years of age and of any race/ethnicity and gender.

Autosomal dominant polycystic kidney disease (ADPKD) is an inherited disease. We plan DNA analysis using the next generation sequencer (NGS) and examine the relationship between mutational types and clinical phenotypes. The accuracy of DNA analysis with NGS is tested by Sanger's method. The kidney and life survival curves will be compared between PKD1, PKD2 and non-ADPKD family members.

To collect characteristics of patients with ADPKD across a broad population, over time to better understand disease progression (signs, symptoms and outcomes). Association with total kidney volume changes and other measures of disease progression will be determined in order to identify a population at increased risk for disease progression. The economic and quality life impact of ADPKD will be assessed. Subjects who terminated participation early from clinical trials with tolvaptan may also be followed.

The number of people with kidney disease is constantly rising and renal failure represents one of the major health care burdens globally. An accurate measurement of kidney function is urgently needed to better understand and treat loss of renal function. Kidneys have an intrinsic reserve capacity to respond to a higher work load by increasing filtration in their nephrons. The number of nephrons and their reserve capacity define how well kidneys can adapt to an increased demand and disease. The degree of renal reserve capacity becomes particularly important when the number of functioning nephrons is significantly reduced either due to surgical removal of one kidney as in living kidney donation or in tumor nephrectomy or due to progressive injury as in autosomal dominant polycystic kidney disease (ADPKD). A reduced functional reserve likely reflects an impaired adaptive capacity and increased risk of accelerated loss of function in the remaining single kidney or in kidneys exposed to a disease. Despite the importance of accurately measuring baseline and reserve capacity renal function, due to the time- and laborintensive procedure, in clinical routine this testing is rarely done. Investigators aim to measure renal functional reserve (RFR) and loss of function in patients undergoing nephrectomy (living kidney donors and renal tumor patients) as well as in patients with ADPKD. The results should provide evidence whether renal functional reserve indeed predicts adaptive capacity and functional loss after removal of a healthy kidney (living donors), of a tumor kidney (cancer patients) or in progressive kidney disorders (ADPKD patients). Investigators are confident that the proposed project will enhance the understanding of progressive kidney disease and with this improve donor safety, planning of tumor nephrectomy, and prediction of renal functional loss as well as provide a strong argument that dynamic renal function testing, i.e. accurate measurement of baseline and reserve capacity, is necessary in certain disease entities.

This pilot study will compare endothelial function in patients with ADPKD with matched healthy volunteers and normotensive chronic kidney disease stage 1 & 2 patients. Patients will undergo a single assessment of endothelial function and measurement of plasma and urine levels of biomarkers of endothelial function.

Autosomal dominant polycystic kidney disease (ADPKD) is the most common monogenic cause of end-stage kidney disease (ESKD). The disorder is characterized by development and continued growth of multiple cysts requiring renal replacement therapy in 50% of patients by age 60 years. However, ADPKD is also a complex metabolic disorder defined by insulin resistance (IR) and mitochondrial dysfunction which may be causally related to cyst expansion, kidney function decline and contribute to reduced life expectancy. Renal hypoxia, stemming from a potential metabolic mismatch between increased renal energy expenditure and impaired substrate utilization, is proposed as a novel unifying early pathway in the development and expansion of renal cysts in ADPKD. By examining the interplay between renal O2 consumption and energy utilization in young adults with and without ADPKD, the investigators hope to identify novel therapeutic targets to impede development of cyst expansion in future trials. The investigators propose to address the specific aims in a cross-sectional study with 20 adults with ADPKD (50% female, ages 18-40 years). Comparative data will be provided from healthy adults from an ongoing study with similar study design and methods (CROCODILE Study: Control of Renal Oxygen Consumption, Mitochondrial Dysfunction, and Insulin Resistance). For this protocol, participants will complete a one day study visit at Children's Hospital Colorado. Patients will undergo a dual energy x-ray absorptiometry (DXA) to assess body composition, and a 11C-acetate positron emission tomography (PET/CT) scan to quantify renal O2 consumption. After the PET/CT, participants will undergo a hyperinsulinemic-euglycemic clamp while fasting to quantify insulin sensitivity. Glomerular Filtration Rate (GFR) and Effective Renal Plasma Flow (ERPF) will be measured by iohexol and PAH clearances during the hyperinsulinemic-euglycemic clamp.