Method for preclinical pathology evaluation and analysis of cardiovascular implantable electronic device implant sites.

Cardiovascular implantable electronic devices (CIEDs) typically incorporate leads that directly contact the endocardium. Post-explant pathology evaluation of formalin-fixed CIED lead implant sites and downstream organs (i.e., lungs) can provide useful safety data to the US Food and Drug Administration; however, current regulatory guidelines do not mandate how the safety data are collected. In this paper, we outline a protocol for preclinical pathology evaluation of leads associated with CIEDs, which includes formalin fixation of the heart and lungs, gross evaluation, and qualitative and quantitative histologic evaluation. We recommend fixation of the whole heart with leads in situ alongside intratracheal formalin infusion; this enables rapid and effective preservation of target tissues and increases histologic quality to allow for accurate qualitative and quantitative pathology evaluation. Overall, we believe that our approach to pathology evaluation of leads may maximize information acquired from preclinical studies, leading to more accurate safety assessments. SUMMARY: This article introduces an established method for pathology evaluation and analysis of cardiac leads recommended for companies and researchers that seek approval from a regulatory body.

Design and verification of a shape memory polymer peripheral occlusion device.

Shape memory polymer foams have been previously investigated for their safety and efficacy in treating a porcine aneurysm model. Their biocompatibility, rapid thrombus formation, and ability for endovascular catheter-based delivery to a variety of vascular beds makes these foams ideal candidates for use in numerous embolic applications, particularly within the peripheral vasculature. This study sought to investigate the material properties, safety, and efficacy of a shape memory polymer peripheral embolization device in vitro. The material characteristics of the device were analyzed to show tunability of the glass transition temperature (Tg) and the expansion rate of the polymer to ensure adequate time to deliver the device through a catheter prior to excessive foam expansion. Mechanical analysis and flow migration studies were performed to ensure minimal risk of vessel perforation and undesired thromboembolism upon device deployment. The efficacy of the device was verified by performing blood flow studies that established affinity for thrombus formation and blood penetration throughout the foam and by delivery of the device in an ultrasound phantom that demonstrated flow stagnation and diversion of flow to collateral pathways.