View clinical trials related to LVAD.
Filter by:This is a 22-subject prospective, multicenter, single-arm clinical trial to evaluate the safety and effectiveness of the Jarvik 2015 left ventricular assist device (LVAD) as a bridge to heart transplant in children weighing 8 to 30 kilograms. Data generated from the study will be used to support FDA review and potential approval of the device under the Humanitarian Device Exemption (HDE) regulation, the FDA approval pathway for devices intended to treat rare and orphan diseases.
Durable left ventricular assist devices (dLVAD) have been increasingly utilized since the mid to late 1990s, with an uptick of utility starting in 2010 following expanded indications for therapy to not only include a bridge to transplantation strategy, but also for those individuals who suffer from advanced heart failure (HF) and do not qualify for cardiac transplantation. Despite the decreasing size of the newest generation devices leading to a lessened occurrence of adverse events, bleeding and infection still remain a concern for clinicians, as well as a general lack of predictability towards adverse events in individuals with a dLVAD in place. There is a lack of description in the literature currently, regarding the interface between what the pump data provides and what is seen in clinical practice. There also is little known about the effects of what is provided in the pump data, in correlation to quality-of-life following dLVAD implantation. Therefore, the purpose of this study is to prospectively analyze normal and abnormal pump data through pump operations such as suction events, low flow alarms as well as other adventitious alarms, PI events and power cable disconnects greater than 20 seconds, from the HeartMate 3 ® dLVAD in order to clinically correlate this data to quality of life, frailty and other various medical conditions and adverse events as defined by the Interagency Registry for Mechanically Assisted Circulatory Support (Intermacs). This will be achieved through two aims: 1) Evaluate the effectiveness of dLVAD pump operations data on clinical practice application (quality of life, frailty and various medical conditions, and adverse events such as GIB, RHF, infection, hypertension, arrhythmias and stroke); and 2) Evaluate correlations and relationships of longitudinal normal and abnormal dLVAD pump operations data, to demographic and clinical variables. This study is the first study to evaluate HeartMate 3 ® dLVAD pump operations data over time for effectiveness in the clinical practice.
The pathophysiology of HF is highly variable, with overlapping pathogenic mechanisms that complicates any attempt to create a simple and unified conceptual model. Left ventricular (LV) ejection fraction (EF), assessed as the fraction of the end-diastolic volume that is ejected upon contraction, has been the cornerstone metric for characterization of LV systolic function in patients with HF. LVEF demonstrates a strong inverse relationship with clinical outcomes in HF in patients with reduced EF (HFrEF). Current management options for the treatment of HFrEF include medical management, mechanical circulatory support, and cardiac transplantation. In the setting of refractory end stage HFrEF, the standard of care is heart transplantation. Since limited organ procurement is a significant constraint to the treatment of patients with advanced disease, durable mechanical circulatory support (MCS) with left ventricular assist devices (LVAD) were developed as a safe and efficacious treatment strategy for patients with advanced HF that is refractory to medical therapy. The advances in LVAD engineering and design, tailored towards defined physiological goals, have resulted in the creation of much smaller continuous-flow (CF) pumps that possess technical superiority, pump durability, and ease of implantation compared to the older and larger pulsatile-flow pumps. The addition of speed modulation algorithms to the next generation centrifugal CF LVADs, has decreased the incidence of device related adverse events. Our interest lies in the impact of continuous flow hemodynamics on endothelial function and the cardiac and end-organ responses to this novel therapy. Current knowledge of the impact of these specific advances in LVAD therapy is however limited by the relative youth of the field. Thus, the goal of this research project is to study human LVAD patients and to determine the impact of speed modulation algorithms in CF physiology on microvascular and endothelial function and its association with cardiac and peripheral organ function. The investigators hypothesize that restoration of cardiac output using an LVAD with modern speed modulation algorithm improves vascular endothelial function. In addition, these changes would have a positive correlation with functional outcomes.
The purpose of this study is to compare adverse events after off-pump LVAD surgery or on-pump LVAD surgery.