Biomedical & Healthcare
Innovative Solutions for Your Business
In the ever-evolving Biomedical & Healthcare sector, innovation, precision, and patient-centric solutions are at the heart of progress. We partner with healthcare providers, research institutions, and biomedical companies to navigate the complex regulatory landscape, integrate cutting-edge technologies, and streamline operations. We tailor strategic initiatives that drive advancements in medical research, improve patient outcomes, and foster sustainable growth across the industry. Backed by a robust history of transformative projects and collaborative success, our approach is designed to empower your organization to excel in developing innovative healthcare solutions and achieving operational excellence in a rapidly changing environment.
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Past Projects & Collaborations
A NEW DEVICE PREVENTING AIR EMBOLISM DURING THE ANGIOGRAPHY, VIRTUAL HEMODYNAMIC STUDY
Air embolism is a serious complication of catheterization and may cause mortality and morbidity. Currently, there is no used for air embolism prevention during angiography and angioplasty procedures. In this study, we tested the flow dynamics and efficiency of a new air holder device in virtual hemodynamic conditions.
INVESTIGATION OF HEMODYNAMICS IN THE INFLOW CANNULA IN VENTRICULAR ASSIST SYSTEMS TO PREVENT COMPLICATIONS
Our study focused on optimizing the geometry of a Left Ventricular Assist Device (LVAD) to enhance blood flow while minimizing shear-induced damage to blood cells. Various designs were analyzed through computational fluid dynamics (CFD) simulations, evaluating wall shear stress distribution and flow efficiency. The objective was to identify a geometry that ensures sufficient perfusion at a lower Reynolds number regime while reducing the risk of hemolysis. This research contributes to the development of safer and more efficient LVAD designs for patients requiring cardiac support.
EFFECT OF PERMEABILITY ON FLOW CONDITIONS IN A BI-FLOW SYSTEM SEPARATED BY A POROUS MEMBRANE IN AN ARTIFICIAL LIVER CELL MODEL
Artificial liver systems have gained significant attention as potential solutions for temporary liver support, particularly in cases of acute liver failure. These systems often rely on membrane-based bioreactors to facilitate mass transfer between blood plasma and a biological component, mimicking natural liver functions. In this study, we investigate the impact of membrane permeability on the flow conditions within a bi-flow system, where two fluid streams interact through a porous membrane in an artificial liver cell model. The permeability of the membrane plays a crucial role in determining the efficiency of mass transport, shear stress distribution, and overall fluid dynamics within the system. By employing computational fluid dynamics (CFD) simulations and experimental validation, this research aims to optimize membrane properties to enhance performance, ultimately contributing to the development of more effective bioartificial liver devices.
