Advances in remote and cloud-based simulation through web conferencing platforms.

INTRODUCTION: Simulation-based learning has become an essential element in entry-level perfusion education. While the use of simulation has been demonstrated to improve patient outcomes, few institutions possess the budgetary resources to build and maintain a high-fidelity simulation environment. This project aims to identify novel uses of web conferencing platforms to support in-person, remote, and virtual simulation exercises. METHODS: The Zoom Virtual Meeting platform (Zoom Video Communications, Inc.) was incorporated into the perfusion simulation curriculum at the Medical University of South Carolina CVP Program. Among the observed benefits of incorporating meeting platform software included high-definition audio/visual outputs and recording capabilities, 3-D remote simulation, remote simulation proctoring, and classroom-based learning. Additional Zoom features included remote controlled screen access and sharing, annotations, and break-out rooms and activities. CONCLUSION: The combination of high-fidelity simulation with virtual and remote features may enhance the learning experience in healthcare education. Future developments in technology and software, simulation education, and instructions through virtual/remote learning may provide a pathway for the future of cardiovascular perfusion education.

The Design and Implementation of a Convertible Extracorporeal Circuit for Lung Transplantation.

Intraoperative management for patients during orthotopic lung transplantation may be performed without mechanical circulatory support, with veno-arterial extracorporeal membrane oxygenation (VA-ECMO), or cardiopulmonary bypass (CPB). For certain patients, an intraoperative conversion from VA-ECMO to CPB may be indicated. If a VA-ECMO patient requires CPB conversion, the previous model at our institution used two separate machines and was overall inefficient. The primary aim of this project was to develop a CPB pack modification to create a circuit that easily converts from VA-ECMO to CPB if indicated. The secondary aim was to create new supportive protocols and a comprehensive education and training curriculum for our large perfusion department to enhance patient safety. The new circuit was carefully designed and evaluated to minimize changes to the current CPB circuit while allowing for the safest configuration of VA-ECMO. A new protocol was designed with multi-disciplinary collaboration. A comprehensive education and training curriculum, as well as an objective competency assessment tool, were created. The circuit was subjectively evaluated by perfusionists and outscored our previous model in the areas of ease of setup, use, and CPB conversion. It received positive feedback from cardiothoracic surgeons and anesthesiologists as well. Lastly, it provided a financial benefit to our institution.

Sustained Total All-Region (STAR) Perfusion: An Optimized Perfusion Strategy for Norwood Reconstruction.

Early iterations of the Norwood procedure used aortic cross-clamping, myocardial arrest, and, sometimes, deep hypothermic circulatory arrest. The resulting hypothermia and prolonged ischemia caused frequent cardiac, neurologic, renal, and other end-organ dysfunctions. Our group describes a novel technique, sustained total all-region (STAR) perfusion, which circumvents these issues by providing continuous perfusion to the head, heart, and coronaries at temperatures of 32-34°C. A single DLP® straight venous cannula (Medtronic, Minneapolis, MN) is placed in the right atrium, and a DLP® pediatric arterial cannula, with a high-flow stopcock attached, is placed in the ascending aorta or innominate artery to provide flow to the head. A cardioplegia needle with walrus tubing is connected to the stopcock to provide flow to the coronary arteries. For lower body perfusion, an olive tip cannula is placed into the descending aorta lumen and attached to the 1/8″ line from the cardioplegia system which provides warm arterial blood flow. STAR perfusion allows the Norwood procedure to be completed with mild hypothermia and continuous perfusion to all vascular beds with reduced cardiopulmonary bypass as well as total operative times. This technique is successfully achieved with minimal changes to circuitry, minor modifications to heart-lung machine servoregulation and few additional cannulation disposables.