View clinical trials related to Leg Ulcer.
Filter by:The purpose of the project is to investigate the agreement with Bland-Altman plots between an AI-supported automatic digital measurement method of wound area and depth and existing manual measurement methods in patients with arterial ulcers on the lower leg. The expectation is that the digital measurement tool can provide healthcare providers with better opportunities to objectively monitor and detect changes in the wound healing process in patients with peripheral arterial disease.
Collect data on various wound treatments and their related wound healing process, in real life settings. Analyze the safety and efficacy of wound treatments, including: advanced biological/synthetic grafts and standard of wound care treatments.
This study will compare the efficacy of using standard compression therapy for treatment of chronic venous leg ulcers vs. the standard compression therapy with the additional use of the application of a human allograft (Theraskin)
This is an observational, longitudinal real world registry of venous leg ulcers created from electronic health record data obtained in the course of clinical care. Data from certified electronic health records transmit data as part of the requirement to share data with a specialty registry under Objective 10 of Meaningful Use of an EHR.
The purpose of this study is to evaluate the safety and efficacy of autologous bone marrow stem cell implantation for the treatment of leg ulcer in adult patients with sickle cell disease.
Given the propensity for venous leg ulcers to become refractory, long standing lesions, incorporating active biologic grafts into the standard compression therapy, has shown to accelerate wound healing. The two products to be compared in this study are both commonly used for the treatment of venous leg ulcers. Apligraf is considered a medical device by the FDA, and was cleared for the treatment of venous leg ulcers in 1998. It is a staple for the treatment of venous leg ulcers, and is widely used throughout the United States. It is composed of a type 1 collagen matrix in which human foreskin-derived neonatal fibroblasts are grown, and over which human foreskin-derived neonatal keratinocytes are then cultured and allowed to stratify. TheraSkin is composed of a split thickness skin graft harvested within 24 hours post-mortem, from an organ donor who has cleared the standard safety screenings. It is classified by the FDA as a donated tissue. Once harvested, the graft is sanitized according to FDA specifications, and cryopreserved, until it is delivered to the clinic for application to the foot ulcer. It is also a widely used treatment for diabetic foot ulcers. TREATMENT RATIONALE FOR THIS STUDY Chronic wounds of the lower extremities affect a substantial proportion of the population. Venous leg ulcers (VLU) account for 40-70% of lower extremity wounds. The standard of care for treatment of VLU's in wound centers in the United States is compression therapy combined with application of biologic graft materials to the wound bed. This study may assist physicians who treat VLU's by comparing efficacy and costs of two commonly used biologic graft materials for VLU's in a randomized prospective study. In addition to standard compression therapy, this investigation will be a head-to-head study comparing widely used bio-engineered skin substitute (Apligraf) to cryopreserved, human skin allograft (Theraskin). There is no randomized, prospective data comparing these two graft options in the treatment of VLU's.