IMPO Basic Attachment
IMPO Basic is a patented bidirectional controllable orthopedic impactor attachment designed to convert rotational power from surgical handpieces into controlled reciprocating impact motion for orthopedic procedures such as total hip arthroplasty (THA). The system is intended to support broaching and implant seating procedures with improved control, consistency, and surgical ergonomics compared to traditional manual mallet techniques. By utilizing a controlled push-pull impact mechanism rather than repetitive unidirectional hammering, the IMPO platform is being developed to potentially reduce uncontrolled stress transfer, improve implant preparation consistency, and support more efficient surgical workflows. The device is designed for compatibility with existing powered surgical systems and future robotic-assisted orthopedic platforms.
Smart IMPO Attachment
Smart IMPO is the next-generation intelligent orthopedic impactor platform integrating real-time sensing, controllable powered impaction, and future robotic communication capabilities for advanced orthopedic procedures. The system is being developed to provide adaptive bidirectional impact control, force monitoring, procedural data collection, and smart surgical feedback during broaching and implant seating procedures in THA and other orthopedic surgeries. The long-term vision of Smart IMPO includes integration with robotic-assisted surgical systems, AI-supported surgical planning, and real-time adaptive force control technologies intended to improve surgical precision, consistency, and safety. By combining smart instrumentation with controlled reciprocating impaction technology, Smart IMPO aims to support the future evolution of intelligent and partially automated orthopedic surgical procedures.
Screwdriver Attachment with Torque Adjustment System
The Screwdriver Attachment with Torque Adjustment System is an advanced orthopedic and surgical fastening platform designed to provide controlled torque delivery during screw insertion and fixation procedures. The system is intended to improve fastening consistency, reduce overtightening risk, and support more precise screw placement in orthopedic, trauma, spine, and robotic-assisted surgical applications. The attachment is being developed to integrate with powered surgical handpieces and future robotic surgical systems while providing adjustable torque control and improved ergonomic operation for surgeons. Key planned features include: Adjustable torque control system Controlled screw insertion and fastening Real-time torque monitoring capability Quick-connect surgical interface Smart sensor integration potential Compatibility with manual and robotic-assisted procedures Data monitoring and future AI-assisted control capability The long-term vision of the platform includes development of intelligent surgical fastening systems capable of adaptive torque control, procedural monitoring, and integration with next-generation robotic orthopedic technologies.