Abstract
Bacterial colonization of drivelines represents a major adverse event in the implantation of left ventricular assist devices (L-VADs) for the treatment of congestive heart failure. From the external driveline interface and through the skin breach, pathogens can ascend to the pump pocket, endangering the device function and the patient’s life. Surface Micro-Engineered Biosynthesized cellulose (BC) is an implantable biomaterial, which minimizes fibrotic tissue deposition and promotes healthy tissue regeneration. The topographic arrangement of cellulose fibers and the typical material porosity support its potential protective function against bacterial permeation; however, this application has not been tested in clinically relevant animal models. Here, a goat model was adopted to evaluate the barrier function of BC membranes. The external silicone mantle of commercial L-VAD drivelines was implanted percutaneously with an intervening layer of BC to separate them from the surrounding soft tissue. End-point evaluation at 6 and 12 weeks of two separate animal groups revealed the local bacterial colonization at the different interfaces in comparison with unprotected driveline mantle controls. The results demonstrate that the BC membranes established an effective barrier against the bacterial colonization of the outer driveline interface. The containment of pathogen infiltration, in combination with the known anti-fibrotic effect of BC, may promote a more efficient immune clearance upon driveline implantation and support the efficacy of local antibiotic treatments, therefore mitigating the risk connected to their percutaneous deployment.
Highlights
Bacterial colonization of drivelines represents a major adverse event in the implantation of left ventricular assist devices (L-VADs) for the treatment of congestive heart failure
To demonstrate that the Biosynthesized cellulose (BC) membranes under study establish an effective physical barrier against bacterial pathogens we initially evaluated their exclusion size in a permeation test in vitro
These data demonstrate that the BC membrane structure is compatible with a barrier function against particles of this size or larger
Summary
Bacterial colonization of drivelines represents a major adverse event in the implantation of left ventricular assist devices (L-VADs) for the treatment of congestive heart failure. From the external driveline interface and through the skin breach, pathogens can ascend to the pump pocket, endangering the device function and the patient’s life. Patients treated with continuous flow L-VADs have 1-year survival rates comparable to those patients receiving an orthotopic heart t ransplant[6,7]. These figures diverge at 3 years, with patients under mechanical support showing significantly reduced s urvival[6,7]. These infections are mostly caused by Gram-positive or Gram-negative bacteria such as Staphylococcus aureus, Staphylococcus epidermidis and Pseudomonas aeruginosa[12], whereas fungal infections only account for a small fraction of them
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