FDA Radiology AI Devices

The xvision Spine system by Augmedics Ltd. is an advanced surgical navigation system that helps surgeons precisely locate anatomical structures in the spine during open or percutaneous procedures. By integrating near-eye augmented reality displays with fluoroscopic and CT images, it enables real-time visualization of tracked surgical instruments overlaid on patient anatomy, improving accuracy for procedures such as pedicle screw and iliosacral screw placement. This technology enhances surgical precision and safety, aiding clinicians in complex spine surgeries.

The SPINEART Navigation Instrument System is a surgical tool used in thoracolumbar spinal surgery to help surgeons accurately locate anatomical structures for the placement of spinal screws. It integrates with the eCential Op.n PERLA® TL Navigation System, which uses intraoperative 3D imaging, to improve surgical precision in both open and minimally invasive procedures.

The Mako Total Hip Application 5.0 is a surgical assistive system that uses CT image data to create a 3D model of a patient's hip anatomy, helping surgeons plan and perform total hip replacement surgeries with high precision. It incorporates a robotic arm and software to guide implant placement within software-defined boundaries, improving surgical accuracy and patient outcomes.

The Paradigm System is a surgical navigation device that helps surgeons accurately place spinal surgical instruments during open procedures. It integrates real-time high-resolution camera images of the surgical site with preoperative CT imagery to create a 3D model of the spine, enabling precise instrument placement and improving surgical accuracy and safety from thoracic to sacrum vertebrae.

The Primus Spinal Fixation System is a spinal fixation device designed to provide stabilization and immobilization for the thoracic, lumbar, and sacral spine regions. It includes screws, rods, and connectors that can be precisely placed with the aid of navigation instruments compatible with the Medtronic StealthStation System, which uses medical imaging data like CT and MRI scans to assist surgeons in accurate screw placement during spinal surgeries.

MyShoulder Planner is a software tool designed for surgeons to plan total shoulder replacement surgeries. It processes CT scans to create 3D models of the patient's shoulder anatomy using machine learning algorithms, helping surgeons decide implant size and positioning before surgery. It also generates patient-specific reports and allows ordering of patient-matched guides to assist in surgery.

The Precision AI Surgical Planning System (PAI-SPS) is an AI-enhanced medical device that assists surgeons in planning and performing shoulder joint replacements. It uses CT scan images to create a 3D model of the patient's shoulder, helps surgeons simulate and optimize implant positioning, and can produce custom surgical guides for use during the procedure. This system helps improve surgical accuracy and outcomes for shoulder arthroplasty patients.

The ARVIS® Shoulder is an AI-powered computer navigation system designed for shoulder replacement surgery. It helps surgeons accurately position implants by using preoperative CT imaging and provides augmented reality visual guidance during the procedure, enhancing surgical precision and patient outcomes.

The NuVasive Pulse System is a medical device that helps surgeons precisely locate anatomical structures during spinal surgeries using intraoperative 3D imaging and computer-assisted navigation. It tracks surgical instruments in real-time and overlays their virtual positions on patient images, enhancing surgical accuracy and safety in procedures like pedicle screw placement and iliosacral screw placement.

The TMINI Miniature Robotic System is a robotic-assisted surgical device designed to help surgeons accurately plan and execute total knee replacement surgeries. It uses preoperative CT scans to create 3D bone models, allowing precise implant positioning through software planning and robotic guidance. The system enhances surgical accuracy and efficiency by using AI-enhanced image segmentation, intraoperative tracking, and spatial boundary definition during surgery.