47 Clinical Trials for Various Conditions
The goal of this double-blind, placebo-controlled randomized clinical trial is to test the effect of 12 weeks of orally administered MitoQ (mitoquinol mesylate) supplementation on cognition in 50 people with early phase schizophrenia-spectrum disorders (E-SSD) who have mitochondrial dysfunction (called high risk, or HR). Cognitive impairments in SSD can cause significant disability. Yet, there are no effective treatments for cognitive impairments in SSD. It has been shown that alterations in a certain type of brain cell (parvalbumin interneurons, or PVI) underlie cognitive deficits in SSD. These PVI, which fire at a fast rate, utilize high amounts of energy from the mitochondria and are highly vulnerable to oxidative stress. MitoQ is an antioxidant. Research has shown that, in mice, MitoQ can reduce oxidative stress in the mitochondria. The main question that this clinical trial aims to answer is: • Does MitoQ supplementation, compared to placebo, improve cognition in HR patients? Secondary questions that this clinical trial aims to answer are the following: Does MitoQ supplementation, compared to placebo: * Improve positive and negative symptoms of SSD in HR patients? * Improve functioning in HR patients? * Improve/normalize blood markers of mitochondrial dysfunction in HR patients? The investigators will enroll 100 individuals with E-SSD. These enrolled participants will participate in an initial screening visit to determine if they qualify for the actual clinical trial. At the screening visit, the investigators will ask about psychiatric history to determine diagnosis; ask about medical history; do a physical exam; collect blood and urine samples; do a pregnancy test; and ask participants to bring in their current medications in their original packaging so it is known what they are taking. After the screening visit, the investigators will invite 50 HR patients (identified with a blood test) to continue with the clinical trial. Participants who qualify for the clinical trial will be asked to: * Take a supplement (MitoQ or placebo) once per day for 12 weeks in addition to their usual medications. * Come in for a study visit every 4 weeks over the 16-week study period. At these study visits, the investigators will do a physical exam; ask about symptoms and side effects; take blood and urine samples; and ask questions about general health and well-being, quality of life, mental health, emotional health, and mood. At visits 1 (baseline) and 4 (12 weeks), participants will also take a cognitive assessment.
Neurofibromatosis type 1 is a common genetic disease with a broad spectrum of clinical manifestations in multiple organs of the body. This project will study the (dys)function of mitochondria in patients with neurofibromatosis through multiple collections of blood samples from patients and people not afflicted by neurofibromatosis (control group). This study will evaluate how the function of mitochondria changes with time and if medications and supplements can influence the function of the mitochondria. Patients will also answer questions regarding symptoms like fatigue and pain.
Frailty and sarcopenia are modifiable risk factors for morbidity and mortality in patients with ESRD. Exercise is the recommended intervention to prevent frailty and sarcopenia, however, many clinical trials have shown limited clinical improvement in muscle mass and physical function. We propose that mitochondrial dysfunction is one of the deterrents to the effectiveness of the exercise. We plan to evaluate the additive effect of HIIT and CoQ10, a mitochondrial-targeted therapy, on mitochondrial function and physical performance. Understanding the interplay among CoQ10, exercise, and mitochondrial function will identify novel mechanisms to improve the efficiency of exercise. This will also serve to prevent frailty, sarcopenia, and muscle dysfunction in patients with ESRD.
This proposal hypothesizes that mitochondrial bioenergetics in the patient will correspond to mtDNA DAMPs levels and markers of inflammation. We predict these will serve as a prognostic indicator of Sepsis induced cardiac dysfunction (SICD) outcomes. Successful completion of these studies will provide a clearer understanding of the etiology of SICD development and therefore will have a high impact on biomedical research by identifying a new mechanism for understanding sepsis induced organ failure. Importantly, they will also provide a means for more directed and focused therapies, based upon individual bioenergetic/mitochondrial-mediated inflammation profiles. The combined, complementary expertise of the Mentor/co-primary investigators (Drs. Mathru and Ballinger) provide an excellent combination in both basic and translational research. They also have experience conducting studies and publications that will strengthen this research project. Importantly, the methods for characterizing mitochondrial bioenergetics from platelets were developed here at UAB, and methods for quantitative assessment of mtDNA DAMPs have been recently developed.
The proposed study is designed to test the hypothesis that treatment of resveratrol for 12 weeks will improve both endothelin-B receptor (aim 1) and skeletal muscle mitochondrial function (aim 2) in people with type 1 diabetes.
This study evaluates metabolic and functional parameters in the skeletal muscle of Parkinson's disease patients for comparison to a set of healthy age-matched controls.
Type 1 diabetes (T1D) is a complex metabolic disorder with many pathophysiological disturbances including insulin resistance (IR) and mitochondrial dysfunction which are causally related to the development of diabetic kidney disease (DKD) and which contribute to reduced life expectancy. Renal hypoxia, stemming from a potential metabolic mismatch between increased renal energy expenditure and impaired substrate utilization, is increasingly proposed as a unifying early pathway in the development of DKD. By examining the interplay between factors responsible for increased renal adenosine triphosphate (ATP) consumption and decreased ATP generation in young adults with and without T1D, this study hopes to identify novel therapeutic targets to impede the development of DKD in future trials. The investigators propose to address the specific aims in a cross-sectional study with 30 adults with T1D and 20 controls without a diagnosis of diabetes. 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) scan to assess body composition, renal Magnetic Resonance Imaging (MRI) to quantify renal oxygenation and perfusion, and a Positron Emission Tomography/Computed Tomography (PET/CT) scan to quantify renal O2 consumption. After the PET and MRI, participants will undergo a hyperinsulinemic-euglycemic clamp 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. To further investigate the mechanisms of renal damage in T1D, two optional procedures are included in the study: 1) kidney biopsy procedure and 2) induction of induced pluripotent stem cells (iPSCs) to assess morphometrics and genetic expression of renal tissue.
The purpose of this study is to investigate the role of mitochondrial derived oxidative stress on exercise capacity and arterial hemodynamics in HFpEF patients with and without chronic kidney disease.
We are trying to understand how insulin (a type of hormone in the body that regulates how the body regulates how one metabolizes protein and carbohydrates) and exercise alter proteins involved in energy production and metabolism in skeletal muscle.
The aim of this study is to evaluate the safety and tolerability of triheptanoin in participants with Rett syndrome using laboratory values, electrocardiogram, rate of adverse events (AE), and physical exam.This study also seeks to evaluate the efficacy of UX007 (triheptanoin) in improving overall seizure frequency and dystonia.
This study consists of three separate appointments including a clinical assessment (interview and questionnaires), a blood draw, a social stress test, and a brain MRI.
While the last several years have seen great strides in the treatment of relapsing forms of MS, progressive MS, responsible for the majority of MS-related disability, lags far behind. Despite much research, the lack of understanding related to what causes patients' relentless decline in function results in an inability to develop targeted treatment strategies suitable for clinical trials. This grant has two main goals. The first goal is to extend the investigators preliminary study on rat neurons treated with the CSF of MS patients to a larger number of Progressive patients in order to validate the initial findings and extend the study to include analysis of human neurons. The initiating PI (Dr. Casaccia) and the Partnering PI and Clinical Neurologist (Dr. Katz Sand) have recently identified components that are present in the CSF of progressive patients that impair the ability of rat neurons to produce energy. The partnering PI, Dr. Quinzii (Columbia University) together with collaborator Dr. Fossati (NY Stem Cells Foundation), have characterized human neurons generated from stem cells derived from skin biopsies of progressive patients and detected the presence of energetic deficits. The experimental plan will build on these results and test hypotheses of disease progression. The overall goal is to improve understanding on how to stop neurons from degenerating and stop clinical progression. The second goal is to ask whether it is possible to define a progressive disease course on the basis of combined biochemical, functional and imaging measurements. The initiating PI will be responsible for the biochemical assessment of CSF and serum samples and, together with partnering PI Quinzii, will also provide functional bioassays measurements of mitochondrial bioenergetics impairment in patients. These data will be combined with clinical assessment and MRI evaluations conducted by the partnering PI Katz Sand and collaborator Inglese. A two year clinical and imaging follow up from the initial recruitment will allow to define whether the combined measurements can be used by clinical neurologists to define the disease course and better identify therapeutic options for patients. The expectation is that the completion of the stated aims of research will allow an advancement of the current knowledge of the progressive form of MS and lead to potential new therapeutic targets.
The purpose of this study is to gain insight into the side-effects of statin consumption, and assess the ability of epicatechin (a compound in dark chocolate) to counteract or reverse these changes. The investigators' prior research has shown that epicatechin can improve skeletal muscle structure and mitochondrial (which gives us energy) structure.
In this study, 50 children between 3 and 12 years old with formally diagnosed autistic spectrum disorders (ASD) and also having significant mitochondrial dysfunction will be treated for a 3 month period with the Mitochondrial Cocktail, a combination of specific nutritional supplements and metabolite intermediates (including anti-oxidants) and bio-energy substrates. A series of neurological and psychological evaluations will be conducted by trained evaluators/clinicians to evaluate both the severity and the clinical presentation of the ASD/mitochondrial dysfunction with each subject at baseline prior to treatment, after the 3 month treatment and again at 6 months, after another 3 month non-treatment period. In addition, laboratory investigations will be conducted at the same time-points to assess the mitochondrial dysfunction and cellular biomarkers thought to be associated with autistic and mitochondrial disorders. These investigations will include the analysis of samples of blood and cheek/buccal swabs collected from each child to assess select biochemical markers of ASD. The Mitochondrial Cocktail treatment will be administered at home once a day continuously for a total of 3 months. All the children in the study will be treated with the same Mitochondrial Cocktail (an open label study).
The goal of this study is to understand how and why insulin resistant individuals respond differently to exercise as compared with insulin sensitive individuals at the skeletal muscle and gene expression level.
Researchers at Arkansas Children's Hospital Research Institute are conducting a study about mitochondrial function in children. The study involves up to 5 visits to Arkansas Children's Hospital with fasting blood draws, behavioral assessments, and/or questionnaires. This study is not currently recruiting, but continues to follow those who were enrolled. There is no cost for visits or study-related exams. For further information, please contact the program manager, Leanna Delhey, at ldelhey@uams.edu or 501-364-4519
The purpose of this study is to determine whether a relationship exists between gene deletion(s) specific to the mitochondrial electron transport chain and presentation of clinical characteristics in patients with Phelan-McDermid Syndrome (PMS).
The purpose of this project is to evaluate the level of mitochondrial dysfunction several patient populations: Burn, trauma, and control group of healthy volunteers. Study hypothesis: Increased plasma concentrations of a newly discovered inflammatory mediated, called mtDNA DAMPS associated with the occurrence of multi-organ dysfunction syndrome in severly injured patients. As the severity of a burn injury or trauma injury increase, so will systemic mitochondrial dysfunction.
The purpose of this study is determine if you have too much fat in your body that it will decrease the conversion of food energy into energy that your body can use.
The purpose of this study is to determine whether insulin resistance is accompanied by "exercise resistance". Investigators will use mass spectrometry and proteomics analysis to test the hypothesis is that a bout of exercise that increases mitochondrial protein abundance in lean, healthy individuals is less effective in insulin resistant patients.
The purpose of this study is to examine the effect of the chronic treatment of type 2 diabetes (T2DM) with dapagliflozin on: (1) mitochondrial gene function/expression and insulin signaling/action and (2) oral glucose tolerance and beta cell function. Dapagliflozin is a potent, highly specific inhibitor of renal glucose transport \[SGLT2\].
Background: - Fatigue is a very common early and late side effect of cancer treatment, including radiation therapy. The cause of fatigue is poorly understood, making it hard to diagnose and treat. More research is necessary to understand why patients receiving cancer treatment experience fatigue. Changes in mitochondria, parts of body cells that help provide energy to the cell, may contribute to fatigue. Researchers are interested in looking at blood chemicals and mitochondrial genes of cancer patients to study those associated with fatigue. Objectives: - To study the relationship between fatigue and the effects of cancer treatment. Eligibility: * Men at least 18 years of age who have been diagnosed with localized prostate cancer and are scheduled to receive external beam radiation therapy. * Participants on study 09-NR-0088, Molecular-Genetic Correlates of Fatigue in Cancer Patients Receiving External Beam Radiation Therapy, are also eligible. Design: * This study requires three outpatient visits to the NIH Clinical Center. * Participants will be seen before they start radiation treatment, at the middle of treatment, and at the end of treatment. Each visit will take less than 30 minutes to complete. * Participants will complete questionnaires that ask about fatigue and depression. * Participants will provide blood samples for research testing and potential HIV testing. * No treatment will be provided as part of this protocol.
Obesity and type 2 diabetes are occurring at epidemic rates in the United States and worldwide. The global burden of diabetes is estimated to double over the next 25 years. Obese children are at risk for the development of insulin resistance, relative insulin deficiency and type 2 diabetes mellitus (DM). The prevention of type 2 DM is hindered by the lack of a non-invasive predictive test, knowledge as to individual risk and effective preventative measures. There is increasing evidence that alterations in mitochondria contribute to the development of diabetes in humans. Therefore, it is important to explore mitochondrial dysfunction as a potential predictor of diabetes in children and a potential target for prevention. The aims of the proposed protocol are to determine whether an intensive exercise intervention can improve mitochondrial function in children identified as having mitochondrial dysfunction and insulin resistance. The use of a non-invasive imaging technique will allow for a functional in vivo assessment of mitochondrial activity. The investigators propose the investigation of an intensive exercise protocol designed to improve mitochondrial function in children who are insulin resistant and have documented mitochondrial dysfunction by magnetic resonance spectroscopy. The study is designed to investigate the plasticity of abnormal mitochondrial function in high risk children. In summary, the proposed projects will investigate mitochondrial function as a non-invasive predictive marker for the development of insulin resistance and type 2 diabetes mellitus in children and attempt to modify mitochondrial function with an intensive exercise intervention. The study of mitochondrial dysfunction in children may both identify those at risk for disease and provide a molecular therapeutic target for prevention and treatment. The investigators hypothesize that children with insulin resistance and mitochondrial dysfunction who are randomized to intensive exercise versus standard lifestyle advice will show improvement in mitochondrial function and insulin sensitivity.
The purpose of this study is to compare the effects of an 8-week aerobic training program upon fat oxidation in vivo and markers of skeletal muscle mitochondrial content and oxidative capacity in sedentary obese subjects with and without type 2 diabetes. We will also investigate if mitochondrial content in muscle predicts success of weight loss. The specific aims are: * To compare systemic fat oxidation rates; * To measure mitochondrial content in muscle before and after aerobic training; * To determine if decreased mitochondrial content is also associated with decreased mitochondrial oxidative capacity; * To measure non-plasma fatty acid oxidation in vivo during submaximal exercise conditions both prior and after aerobic training; * To determine whether increases in fat oxidation due to physical activity predict weight loss success when a reduced calorie diet is added to a physical activity program.
This study will examine whether mitochondrial function is impaired in patients with bipolar disorder. Mitrochondria are small organelles inside the cell that are responsible for energy production. Recent studies in animals and humans suggest that abnormalities of mitrochondria may be involved in bipolar depression. The study will also examine whether the food supplement Coenzyme Q10 (CoQ10) improves mitochondrial function and symptoms such as depressed mood, low energy, anxiety or slowness in thinking and movements in bipolar patients. CoQ10 has been used to increase cell energy production and as an antioxidant. It has had some benefit in patients with Parkinson's disease and migraine and in prolonging survival in patients with cancer and heart failure. Patients 18-65 years of age with bipolar disorder who are currently in a depressive episode of at least 4 weeks duration may be eligible for this study. The study has four phases, as follows: Phase I: Medication Withdrawal Patients taper off all psychotropic medications, usually over 1 to 2 weeks. Phase II: Baseline Evaluation After being off all medication for about 2 weeks, patients undergo the following procedures: * Magnetic resonance imaging (MRI) and magnetic resonance spectroscopy (MRS). The two procedures are performed in an MRI scanner. Both tests use a strong magnetic field and radio waves to obtain images that provide information on brain anatomy and chemistry. * Blood tests to assess mitochondrial function isolated from blood cells. * Skin biopsy for tests of mitochondria. A small sample of skin tissue 5 x 5 millimeters is surgically removed. Phase III: Administration of CoQ10 or Placebo Participants are randomly assigned to take either CoQ10 or placebo (an inactive look-alike substance) twice a day by mouth. While taking the study medication, patients have the following procedures periodically: * Rating scales for anxiety and depression and adverse events. * Check of vital signs. * Blood and urine sample collections. Phase IV: Study Completion At the end of the 8 weeks of treatment, patients have a physical examination and electrocardiogram, and the procedures in phase II are repeated. Participants may then receive short-term treatment (up to 12 weeks) with medications for bipolar depression, followed by referred to a community physician for long-term treatment. ...
The purpose of this study is to see if magnetic resonance spectroscopy (MRS) can be used to detect damage to the mitochondria in HIV-infected patients taking nucleoside reverse transcriptase inhibitor (NRTI) drugs. HIV-infected patients taking NRTI drugs may have an increase in a chemical in their blood called lactate. High lactate levels may damage the energy source of the cell (mitochondria). Damage to mitochondria may cause lactic acidosis, liver failure, and other problems. It is important to find effective ways to see if the mitochondria of HIV-infected patients have been damaged. This study will see if MRS can be used to determine mitochondrial damage.
This was a Phase 2, randomized, double-blind, placebo-controlled study, enrolling 41 elderly subjects with previous evidence of mitochondrial dysfunction to evaluate whether the administration of MTP-131 (elamipretide) will change either hand skeletal muscle energetics or muscle performance in age-related skeletal muscle mitochondrial dysfunction.
The purposes of this study are to evaluate if switching an antiretroviral medication from efavirenz (EFV) to atazanavir/ ritonavir (ARV/r) will, in a 96-week period, change: 1. the amount of fat in HIV patients with lipoatrophy, 2. metabolic lab values such as your lipid (fat) profile, glucose (blood sugar), and insulin (a hormone that regulates glucose) in HIV patients with lipoatrophy.
In the absence of treatment, severe mitral valve regurgitation (MR) results in left atrium (LA) dilatation and hypertrophy, followed ultimately by left ventricular dysfunction and heart failure. One promising intervention for the prevention of the deleterious effects of pressure overload-induced cardiac hypertrophy and heart failure is dietary supplementation with n-3 polyunsaturated fatty acids (PUFAs). However, the molecular targets and mechanisms by which n-3 PUFAs exert their effects are not completely defined. A possible target of n-3 PUFAs is the mitochondrial membrane which has broad implications given that mitochondrial dysfunction and altered metabolism have been associated with cardiac hypertrophy and heart failure. The investigators have recently identified significant mitochondrial dysfunction in the LA of patients with severe MR, as compared to their non-hypertrophied right atrium (RA). However, the investigators have not addressed the possibility that intervention with purified n-3 PUFAs (Lovaza) could improve mitochondrial function. From a mechanistic perspective, the investigators have observed in vitro that n-3 PUFAs accumulate predominately into the mitochondrial membrane of cardiomyocytes where the investigators believe they exert their effects on the biophysical organization of the membrane. Therefore, the CENTRAL HYPOTHESIS is that administering Lovaza to patients with severe MR will reduce apoptosis and improve mitochondrial function in LA (Aim 1). This change in mitochondrial function will be driven by significant biochemical and biophysical remodeling of the mitochondrial membrane (Aim 2).
SPIMD-301 is a 48-week, randomized, double-blind, parallel-group, placebo-controlled trial to assess efficacy and safety of single daily subcutaneous (SC) administration of elamipretide as a treatment for subjects with primary mitochondrial myopathy associated with nuclear DNA mutations (nPMD).