Featured Projects

Exploring new possibilities, transforming the world with R&D and tech power

Image-guided Surgical Robot for Percutaneous Surgery

TEP-MAID

TEP-Measurement and Insertion Device (TEP-MAID) offers a revolutionary solution for surgeons to provide immediate voice restoration for patients who have lost the use of their voice box. Current methods in voice restoration surgeries are long and tedious. Surgeons are thus looking for new methods that would reduce the risk and complications while making the process more efficient. With our solution, the voice restoration surgery can be completed in 10 minutes with minimal trauma, blood loss and immediate voice recovery. ReVoice’s products will dramatically reduce surgery time and risk while bringing comfort to patients.

AI models significantly improve medical image diagnosis by analyzing X-rays, MRIs, and CT scans to detect diseases, enhance image quality, and segment structures like tumors with greater speed and accuracy than traditional methods. These models aid in personalized medicine, offering intelligent, tailored treatment suggestions by combining image data with other patient information. Key applications include early disease detection, accurate image segmentation for precise treatment, and providing insights to support faster clinical workflows and improved patient outcomes.

Medical Image Diagnosis with AI Models

Smart Wearable Device for Continuous Health Sensing and AI-Based Diagnosis

Minimally invasive interventions are rapidly advancing with the integration of robotics and real-time imaging. An image-guided surgical robot for percutaneous surgery combines high-precision robotic manipulation with CT, MRI, or ultrasound imaging to enable accurate instrument placement through small skin punctures. By integrating advanced path-planning algorithms, automated registration of patient anatomy, and real-time navigation feedback, the system achieves sub-millimeter accuracy while dynamically adapting to organ movement and tissue deformation. With its ability to transform complex interventions such as tumor ablation, biopsy, and targeted therapy, the image-guided percutaneous surgical robot represents a new standard in precision medicine—empowering clinicians to perform safer, faster, and more effective minimally invasive surgeries.

Imagine a future where a simple walk can provide a comprehensive health check-up. This is the vision behind the Smart Insole Device for Continuous Health Sensing and AI-Based Diagnosis of Sarcopenia. By embedding intelligent sensors within an everyday object, we can non-invasively collect critical data on a user's physical well-being. This information, combined with an advanced AI model, offers a powerful tool for the early detection of Sarcopenia, a condition that severely impacts mobility. The ultimate goal is to empower individuals with the knowledge to manage their health proactively, enabling them to lead more mobile, independent lives.

Tele-operative Robot Control for Laparoscopy Surgery

Tele-operative robot control brings a transformative dimension to minimally invasive laparoscopy by allowing surgeons to operate through robotic interfaces that translate precise hand movements into instrument actions inside the patient. Equipped with advanced robotic arms, 3D visualization, and haptic feedback, the system enhances dexterity, precision, and stability compared to manual laparoscopy. By decoupling surgeon input from the operative field, tele-operation enables motion scaling, tremor reduction, and improved access to confined anatomical regions.

Direct Augmented Reality Projection for Image-Guided Surgery

Direct augmented reality (AR) in surgery enables 3D anatomical organ models—derived from CT, MRI, or ultrasound imaging—to be projected directly onto the patient’s body surface in real time. Unlike traditional image guidance displayed on separate monitors, this technique overlays virtual anatomical structures on the physical operative field, aligning them precisely with the patient’s anatomy through advanced registration and tracking algorithms. Surgeons gain an intuitive, “x-ray vision” perspective that enhances spatial awareness, improves accuracy in locating critical structures, and reduces the cognitive load of shifting between images and the operative site.