9 Clinical Trials for Various Conditions
This clinical study will utilize a new cell therapy approach (Human embryonic stem cells derived cardiomyocytes or hESC-CMs) to improve survival and cardiac function in patients with chronic left ventricular dysfunction secondary to MI (Myocardial Infarction).
Before initiating the full randomized study, a Pilot Safety Phase will be performed. In this phase the composition of cells administered via the Biosense Webster MyoStar NOGA Injection Catheter System will be tested. The randomized portion of the study will be conducted after a full review of the safety data from the pilot Phase by the Data safety monitoring board. Following the Pilot Phase of five (5) Fifty (50) patients scheduled to undergo cardiac catheterization and meeting all inclusion/exclusion criteria will be evaluated at baseline. Patients will be randomized in a 2:2:1 ratio to one of three Treatment Strategies.
Thirty (30) patients with chronic ischemic left ventricular dysfunction secondary to MI scheduled to undergo cardiac catheterization will be enrolled in the study. This is a phase II study intended to gain additional safety and efficacy assessments among two dose levels previously studied in a phase I setting.
The technique of transplanting progenitor cells into a region of damaged myocardium, termed cellular cardiomyoplasty, is a potentially new therapeutic modality designed to replace or repair necrotic, scarred, or dysfunctional myocardium. Ideally, graft cells should be readily available, easy to culture to ensure adequate quantities for transplantation, and able to survive in host myocardium; often a hostile environment of limited blood supply and immunorejection. Whether effective cellular regenerative strategies require that administered cells differentiate into adult cardiomyocytes and couple electromechanically with the surrounding myocardium is increasingly controversial, and recent evidence suggests that this may not be required for effective cardiac repair. Most importantly, transplantation of graft cells should improve cardiac function and prevent adverse ventricular remodeling. To date, a number of candidate cells have been transplanted in experimental models, including fetal and neonatal cardiomyocytes, embryonic stem cell-derived myocytes, tissue engineered contractile grafts, skeletal myoblasts, several cell types derived from adult bone marrow, and cardiac precursors residing within the heart itself. There has been substantial clinical development in the use of whole bone marrow and skeletal myoblast preparations in studies enrolling both post-infarction patients, and patients with chronic ischemic left ventricular dysfunction and heart failure. The effects of bone-marrow derived mesenchymal stem cells (MSCs) have also been studies clinically. Currently, bone marrow or bone marrow-derived cells represent highly promising modality for cardiac repair. The totality of evidence from trials investigating autologous whole bone marrow infusions into patients following myocardial infarction supports the safety of this approach. In terms of efficacy, increases in ejection fraction are reported in the majority of the trials. Chronic ischemic left ventricular dysfunction resulting from heart disease is a common and problematic condition; definitive therapy in the form of heart transplantation is available to only a tiny minority of eligible patients. Cellular cardiomyoplasty for chronic heart failure has been studied less than for acute MI, but represents a potentially important alternative for this disease.
Heart attacks are a leading cause of death in both men and women in the United States. When a person has a heart attack, blood is unable to reach a certain area of the heart, and if the blood supply is not re-established quickly, that area of the heart can suffer permanent damage. While recovery from a heart attack can be managed through medications and lifestyle changes, these treatments can not reverse the original damage to the heart. Current research is focusing on the development of cell-based therapies using stem cells to repair organs that have been irreversibly damaged by disease. A specific form of stem cells, called adult mesenchymal stem cells (MSCs), has shown promise for heart repair. This study will evaluate the safety and effectiveness of injecting MSCs into the heart to repair and restore heart function in people who have had a heart attack and who are having heart surgery for coronary artery bypass grafting (CABG).
Coronary artery disease (CAD) is a common disorder that can lead to heart failure. Not all people with CAD are eligible for today's standard treatments. One new treatment approach uses stem cells-specialized cells capable of developing into other types of cells-to stimulate growth of new blood vessels for the heart. This study will determine the safety and effectiveness of withdrawing stem cells from someone's bone marrow and injecting those cells into the person's heart as a way of treating people with CAD and heart failure.
A double blinded and placebo-controlled, dose escalation, single-center safety and preliminary efficacy study of cardiospheres delivered via NOGA MYOSTAR injection catheter in subjects with chronic ischemic cardiomyopathy. The objective is to achieve and document myocardial regeneration in patients with chronic scar.
The primary objective of this study is to determine whether transendocardial delivery of allogeneic human bone marrow-derived mesenchymal precursor cells (MPCs \[rexlemestrocel-L\]) is effective in the treatment of chronic heart failure (HF) due to left ventricular (LV) systolic dysfunction.
Continuous-flow (CF) left ventricular assist devices (LVADs) are an important tool in the treatment of end-stage heart failure, affording patients significantly improved quantity and quality of life. In recent years, tens of thousands of LVADs have been implanted worldwide, with nearly 1,000 at the Texas Heart Institute (THI). Despite the benefits from LVAD therapy, one major weakness is the high frequency of late strokes, reported up to 19%. CF LVADs minimize or remove the pulsatility within the blood system, introducing a new and incompletely understood physiology. Increased sympathetic ("fight or flight" nervous system) tone secondary to lack of pulse in the blood system can cause high blood pressure, with subsequent hemorrhaging strokes (bleeding into the brain) are one possible explanation for this high adverse event rate in CF LVAD patients. A simple intervention to decrease the increased sympathetic tone is called "ischemic conditioning"; a sphygmomanometer (blood pressure cuff) is placed on the patient's arm to compress a major artery (ischemia) with subsequent release of the cuff (reperfusion) for set periods of time. This has been shown to reduce blood pressure and major adverse cardiovascular events in other patient populations. We plan to conduct a trial to evaluate this intervention, ischemic conditioning, in patients with CF LVADs. We hypothesize that IC will cause a reduction in blood pressure and strokes in this patient population.