TITLE:
Development and Implementation of a Project Using IoMT Technology for Monitoring, Remote Control, and Tracking of a Left Ventricular Assist Device: Reduction of Adverse Events Caused by Malfunction Leading to Critical and Catastrophic Failures
AUTHORS:
Jeferson Cerqueira Dias, Millena Victoria Azevedo De Souza, Jônatas Cerqueira Dias, Luiz Carlos Da Silva, Diolino José Dos Santos Filho
KEYWORDS:
Ventricular Assist Device, Adverse Events, Malfunction, IoMT, Remote Control
JOURNAL NAME:
Journal of Biomedical Science and Engineering,
Vol.18 No.6,
June
27,
2025
ABSTRACT: This electronic document is a “live” template. The various components of your paper [title, text, heads, etc.] are already defined on the style sheet, as illustrated by the portions given in this document. Ventricular Assist Devices (VADs) have emerged as an effective alternative in destination therapy, offering increased longevity to implanted patients. However, survival rates remain a concern, with only 49% of patients surviving after four years of use, mainly due to adverse events, including critical or catastrophic failures caused by device malfunction. This study presents partial results from a project aimed at developing and implementing IoMT technologies for the monitoring, remote control, and georeferenced tracking of VADs, targeting the early detection of critical and catastrophic failures. Tests will be conducted using an automated bench setup with blood pump or VAD prototypes, enabling the construction of performance curves and the execution of reliability and risk analyses to improve prototype designs. The initial prototypes will be manufactured using PETG, with potential future upgrades to metal versions, and will be equipped with magnetic motors, Arduino-controlled drives, and cloud connectivity to assess the efficacy of cloud integration and the use of an application for monitoring data and controlling parameters—initially focusing on speed regulation. The embedded system is expected to remotely adjust operational parameters and detect failures in real time, within the projected efficacy range, by comparing performance data against standard curves and indicating corrective parameter adjustments. Partial results achieved so far include the identification of key technologies used in medical device monitoring and control, as well as the design of the electrical schematic for the main components involved in the monitoring, control, and georeferenced tracking of VADs. These findings contribute to the technological development addressing the proposed research problem.