Woxsen University introduces new AI Necrobotic Surgery System

In a significant stride toward AI-enabled healthcare innovation, Woxsen University’s AI Research Centre has developed a first-of-its-kind AI-Driven Bio-Induced Necrobotic System aimed at redefining surgical precision and promoting sustainability in medical technology.

This next-gen robotic system blends biologically sourced actuators—such as spider exoskeletons and silk fibers—with adaptive artificial intelligence to perform minimally invasive surgeries. Designed to reduce post-operative trauma by 50% and improve surgical accuracy by up to 70%, the innovation addresses the growing demand for precision-driven, sustainable healthcare solutions.

What sets the system apart is its use of biodegradable components over conventional polymers and metals, significantly lowering its carbon footprint. This eco-conscious design aligns with emerging global mandates on sustainable medical practices and positions Woxsen’s platform as a frontrunner in green health tech.

The AI-driven necrobotic system is tailored for high-precision domains including neurosurgery, ophthalmology, and cardiovascular microsurgeries. Leveraging real-time feedback and predictive AI modeling, it allows surgeons to execute complex procedures with enhanced accuracy—whether removing brain tumors with minimal tissue disruption or performing delicate microvascular repairs.

A key differentiator is the platform’s support for AI-powered telesurgery. Surgeons can now operate remotely using real-time imaging, machine learning, and latency-reduction protocols—opening new possibilities for high-quality care in rural and underserved regions. The system also features manual override capabilities, ensuring surgeon control in critical scenarios.

“Innovation in surgery must go beyond clinical excellence—it must also be responsible and inclusive,” said Dr. Hemachandran K, Director of the AI Research Centre at Woxsen University. “This system is a convergence of sustainable design, AI adaptability, and surgical precision, signaling what the future of healthcare can and should be.”

Woxsen is currently collaborating with hospitals and research institutions to test the system in clinical environments, with the goal of obtaining regulatory clearance and initiating pilot programs in surgical departments. To support industry adoption, the university will also launch a certification program in AI-Driven Surgical Robotics, combining virtual simulations, hands-on labs, and mentorship.

As the healthcare sector accelerates its digital transformation journey, Woxsen’s necrobotic system marks a notable step in the integration of AI, robotics, and sustainability. The development underscores the potential of academia-led innovation in shaping next-gen healthcare infrastructure.