Next Generation Surgical Navigation System
Revolutionizing the world of surgeries with cutting-edge technology
About EVA
Our Mission
At EVA, our mission is to advance neurosurgical practice with cutting-edge technology. Our system stands out for the integration of advanced surgical imaging and mechano-biology. We are committed to developing innovative solutions to some of the most pressing healthcare challenges of our time.
Our Technology
EVA’s Enhanced Physics Informed Navigation System (φNaS) redefines precision in neurosurgery with advanced surgical imaging and real-time data analytics. This technology seamlessly integrates into surgical workflows, offering critical, dynamic updates during operations. φNaS’s capability to adapt to brain deformations ensures that neurosurgeons can operate with unmatched accuracy, significantly improving patient outcomes.
Our Expertise
At EVA, our expertise lies in the development of state-of-the-art neurosurgical navigation systems. Our team, skilled in biomedical engineering and regulatory compliance, is committed to enhancing surgical outcomes through innovative solutions. We excel in mechano-biological modeling and advanced imaging technologies, ensuring our products surpass industry standards and improve global patient care.
Founders
Dr. Anas Obeidat
Specialises in computational solid and fluid dynamics (CSFD) for biological applications. A realistic estimation of brain fluid flow and deformation is central to the Physics-Informed Navigation System (φNaS), crucial for simulating surgical interventions and predicting outcomes with high accuracy. CSFD integrates advanced modelling techniques for both solid components (e.g., brain tissues) and fluid components (e.g., blood flow, cerebrospinal fluid) within the brain. By employing state-of-the-art computational dynamics, CSFD enables the simulation of complex interactions between tissues and fluids under various conditions. This integration bridges the gap between clinical imaging and real-time surgical navigation, providing actionable data during procedures through rapid complex simulations.
Dr. Stephane Urcun
Dr. Urcun's research focuses on the physics of living tissue, an intrinsic field in medicine that relies on experiments in vitro, ex vivo, and in situ, reinforced by neurosurgeons' clinical experience. Physical systems describing living tissue behaviours aid oncologists and surgeons in measuring patients' physiological status and planning treatments, especially in cancer.
Mr. Morris Ayek
M.Sc. Morris Ayek, M.Sc. in Electrical and Information Technology.
M.Sc. Morris Ayek is an expert in Sensor fusion and perception for Advanced Driver Assistance Systems (ADAC) and autonomous driving applications. His work focuses on the design and implementation of perception layers to support ADAC’s applications (L2 – L4). Perception layer consists of different components which describe moving and stationary environments around the vehicle (object tracking, computer vision, maps generating and localization) based on using of different kinds of sensors, like RADARs, Cameras, Ultrasonics and Lidars.