Murad Melhem

Hemodialysis Vascular Access Dysfunction: From Pathophysiology to Novel Therapies

Hemodialysis vascular access dysfunction is a major cause of morbidity and hospitalization in the hemodialysis population at a cost of over USD 1 billion per annum. Most hemodialysis grafts fail due to a venous stenosis (venous neointimal hyperplasia) which then results in thrombosis of the graft. Despite the magnitude of the clinical problem there are currently no effective therapies for this condition. The current review (a) describes the pathogenesis and pathology of venous stenosis in dialysis access grafts and (b) discusses the development and application of novel therapeutic interventions for this difficult clinical problem. Special emphasis is laid on the fact that PTFE dialysis access grafts could be the ideal clinical model for testing out novel local therapies to block neointimal hyperplasia.

Novel Therapies for Hemodialysis Vascular Access Dysfunction: Fact or Fiction!

Hemodialysis vascular access dysfunction is a major cause of morbidity in the hemodialysis population and contributes significantly to the overall cost of end-stage renal disease programs. At a histological level, most hemodialysis vascular access dysfunction (in both native arteriovenous fistulae and PTFE dialysis access grafts) is due to venous stenosis and thrombosis, secondary to venous neointimal hyperplasia. However, despite a wealth of experimental and clinical data on the use of novel therapeutic interventions that target neointimal hyperplasia in the setting of coronary artery disease, there are unfortunately no effective therapeutic interventions for hemodialysis vascular access dysfunction at the present time. This is particularly unfortunate, since neointimal hyperplasia in the setting of hemodialysis vascular access fistulae and grafts could be the ideal clinical model to test novel therapeutic interventions for neointimal hyperplasia.

Development of a local perivascular paclitaxel delivery system for hemodialysis vascular access dysfunction: polymer preparation and in vitro activity.

Hemodialysis vascular access dysfunction (HVAD) is currently a huge clinical problem. The major cause of HVAD is venous stenosis (as a result of venous neointimal hyperplasia) which leads to thrombosis in polytetrafluoroethylene dialysis access grafts and fistulae. Despite the magnitude of the clinical problem there are currently no effective therapeutic interventions for this condition. In an attempt to reduce the morbidity associated with HVAD, we have developed and validated a local perivascular paclitaxel release system for use in a pig model of arteriovenous graft stenosis. Ethylene vinyl acetate polymers with 5% paclitaxel were formulated. The release profile of paclitaxel was then manipulated to maximize its biological impact in the in vivo situation. In vitro experiments were performed to confirm that the paclitaxel released from the polymer was biologically active against cell types that were similar to those present in the in vivo lesion of neointimal hyperplasia. Our results demonstrate that the paclitaxel polymer wraps which we have developed are mechanically stable with a burst release phase followed by a slower continuous release phase. The paclitaxel released from these polymeric wraps retains its physicochemical and biological properties and is able to inhibit the proliferation of smooth muscle cells, endothelial cells and fibroblasts in vitro. We believe that these paclitaxel-loaded polymeric wraps could be ideally suited for perivascular drug delivery in the context of dialysis access grafts and fistulae.

In vitro Paclitaxel and Radiation Effects on the Cell Types Responsible for Vascular Stenosis: A Preliminary Analysis

Hemodialysis vascular access dysfunction as a result of venous neointimal hyperplasia in dialysis access grafts and fistulae is currently a huge clinical problem. The aim of this study was to assess the effects of paclitaxel and radiation, both singly and in combination on the proliferation of cell types present within the lesion of venous neointimal hyperplasia (vascular smooth muscle cells, fibroblasts and endothelial cells within the neointimal microvessels). Vascular smooth muscle cells, fibroblasts and endothelial cells were plated onto 96-well plates and exposed to different concentrations and doses of paclitaxel and radiation, respectively (both individually and in combination). Growth inhibition was assessed with an MTT assay. Both paclitaxel and radiation resulted in significant growth inhibition of all three cell types. However, even small doses of paclitaxel appeared to attenuate the antiproliferative effect of radiation on these cell types. Further experiments to elucidate the mechanism behind these findings could result in a better understanding of combination antiproliferative therapies.

Controlled Drug Releasing Intravitreal Implant Using Biodegradable PLGA

The goal of this work is to compare the in vitro drug (Nimodipine) release rate from three different types (matrix, reservoir, and combination types) of intravitreal implants using a biodegradable polymer (PLGA). The matrix implants were prepared by a solvent cast method and the reservoir implants were fabricated by using a pellet press. The combination implants were a mixed type of matrix and reservoir implants. Each implant was placed in a vial with 7mL of Phosphate Buffered Saline (PBS) containing 0.4 g/L of Bovine Serum Albumin (BSA) and 0.5 mL aliquots were removed for the drug assay for 25 days. The sample was analyzed to determine the concentration using High Performance Liquid Chromatography (HPLC). Over 20 days, the average steady state release rate in vitro is 13.05±6.17, 2.66±1.98, 8.85±6.36 μg/day for matrix, reservoir, and combination implants, respectively.Copyright