Intelligent Systems and Robotics in Urology

To harness this potential, we gather and analyze information accumulated from various devices during surgeries. After thorough processing by means of segmentation and annotation, valuable surgical datasets are created. These datasets serve as the foundation for creating and testing models that offer surgical assistance and decision-making support.

One additional focus of our research lies in augmented intraoperative tissue assessment, where we employ cutting-edge biophotonics technologies such as hyperspectral imaging and fluorescence. These techniques enable real-time analysis of oxygen saturation and perfusion, empowering surgeons with enhanced abilities to evaluate tissue properties on the spot and make well-informed decisions during surgery.

However, the integration of these advanced techniques into daily surgical practice is still limited due to the lack of high-level evidence supporting their effectiveness. To overcome this barrier, our research group is committed to conducting large-scale clinical trials to rigorously test these technologies. This will enable safe and meaningful implementation of intelligent systems into routine care for more precise oncological surgery. This will ultimately benefit both patients and caregivers, ensuring better outcomes and improved healthcare services.