Top 50 Surgical Navigation System

The startup has developed a gyroscope-on-chip surgical navigation system that enhances surgical efficiency and can be integrated with any implant system. This technology enables surgeons to reduce surgery time and associated costs, ultimately improving clinical outcomes.

The startup develops a medical and dental implant surgery navigation system along with custom-made surgical support systems to enhance precision in surgical procedures. By improving the accuracy of implant placements, the technology aims to reduce the risk of complications and promote patient safety.

Proprio develops a surgical navigation platform that integrates light field technology and computer vision to provide real-time anatomical alignment and data intelligence during procedures. This technology enhances surgical accuracy, reduces complications, and minimizes operating room time, ultimately improving patient outcomes and hospital efficiency.

The startup develops computer-assisted surgical navigation tools that utilize computer vision and artificial intelligence to achieve millimeter precision in locating objects during orthopedic surgeries. This technology enables surgeons to perform procedures more accurately and affordably, addressing the need for enhanced precision in a cost-sensitive healthcare environment.

Illuminant Surgical develops augmented reality technology for medical procedures using AI and computer vision. Their Skylight system projects real-time anatomical imaging directly onto the patient, eliminating the need to look away from the surgical field. This projection mapping simplifies workflows and brings advanced image guidance to various care settings, including spine surgery and interventional radiology.

Augmedics provides augmented reality surgical navigation solutions specifically designed for spine surgery, allowing surgeons to visualize patient anatomy in 3D without diverting their attention from the surgical field. This technology enhances accuracy and efficiency in pedicle screw placement while minimizing radiation exposure during procedures.

Redefine Surgery offers a visual navigation and robotics platform that uses AI trained by expert surgeons to provide trackerless, computer‑vision guidance with millimeter‑level precision, enabling faster and more accurate orthopedic procedures. The system integrates compact robotic adjustments and can be licensed to OEM partners, while surgeons and patients benefit from improved outcomes and data ownership. Revenue is generated through product sales, OEM integration deals, and ongoing service contracts.

Andromeda Surgical develops an AI-guided spatial navigation platform designed to enhance surgical precision, starting within endourology. This software provides surgeons with GPS-like guidance and an intuitive interface to streamline complex procedures. The platform integrates proprietary AI models to support surgeon-in-the-loop autonomous tasks, aiming to improve daily procedure volume and optimize patient outcomes.

Incremed develops mixed reality software that overlays patient scans and data onto the physical body to guide medical procedures. Their platform uses machine learning to enhance diagnostic accuracy and improve the precision of therapeutic interventions.

Caira Surgical develops sub-millimeter-accurate Radar Surgical Tracking technology to replace traditional optical tracking systems in orthopedic surgeries, eliminating line-of-sight issues and reducing setup time by five times. This technology enhances surgical precision and usability, ultimately improving patient outcomes and making robotic and navigated procedures more accessible.

Capla provides an AI‑enhanced neuronavigation platform that generates real‑time, high‑fidelity 3D reconstructions of patient anatomy from CT/MRI with sub‑10 ms latency using NVIDIA GPU acceleration. The software delivers radiation‑free, sub‑second registration and on‑the‑fly diffusion‑MRI fiber tractography, integrated via cloud‑based storage and DICOM‑compatible APIs for seamless OR workflow. It is offered to neurosurgical teams on a subscription basis with optional per‑procedure usage fees.

The startup develops surgical robots equipped with fully articulated robotic arms and three-dimensional augmented reality-based image navigation software, enabling precise microsurgical tasks. This technology enhances intraoperative control and navigation, addressing the need for greater accuracy in complex surgical procedures.

This health tech company develops AI-powered software for medical imaging, diagnostics, and surgical navigation. Their platform integrates deep learning and machine vision to enhance the accuracy and efficiency of healthcare procedures.

Aoda Zhisheng develops an AI-driven ultrasound-guided robotic platform that automates preoperative planning and intraoperative navigation for minimally invasive procedures. This technology reduces reliance on surgeon experience, enhancing precision and effectiveness in puncture and ablation treatments.

Keyin Tech develops a surgical robotics platform that integrates preoperative planning, intraoperative navigation, and robotic assistance to enhance surgical precision and reduce risks associated with traditional procedures. By utilizing advanced imaging data fusion and real-time tracking, the platform minimizes errors and improves patient outcomes during complex surgeries.

Scopia Tech utilizes real-time artificial intelligence image processing to enhance visibility during minimally invasive surgeries, enabling surgeons to navigate complex anatomy with precision. This technology addresses the challenge of misidentifying anatomical structures, which can lead to surgical errors and complications.

Medivis develops augmented reality software that transforms 2D medical imaging, such as MRI and CT scans, into real-time 3D visualizations for surgical applications, enhancing precision during procedures. This technology improves surgical outcomes and reduces costs for medical institutions by enabling faster access to critical patient data and facilitating better planning and navigation.

SURGAR develops a plug-and-play augmented reality software suite for minimally invasive laparoscopic and robot-assisted surgeries, utilizing real-time 3D models derived from patient MRI and CT scans. This technology enhances surgical precision and visualization, addressing the challenges of navigating mobile and deformable organs during procedures.

Computational Surgery offers a software platform that fuses pre‑operative CT/MRI data with live endoscopic video to deliver real‑time 3D reconstruction, sub‑millimeter spatial registration, and augmented‑reality overlays for minimally invasive procedures. The system generates deterministic tool trajectories and integrates via API with existing robotic and endoscopic hardware, enabling hospitals and device OEMs to improve navigation accuracy and reduce operative time.

Anaut develops AI-based surgical instruments that utilize real-time data analysis and precision mapping to enhance the safety and effectiveness of surgical procedures. Their technology addresses the challenge of accurately visualizing complex internal structures during surgery, thereby improving patient outcomes.

SaphireX Surgicals develops the NeuroSAPHIREX system, an AI-powered neuro-navigation platform for surgical guidance. This system integrates advanced imaging AI and robotics to provide neurosurgeons with high-accuracy cranial and spine navigation. The platform aims to enhance surgical precision, reduce radiation exposure, and facilitate minimally invasive procedures for improved patient outcomes.

HoloRay develops mixed-reality applications for healthcare, creating immersive and patient-specific experiences for medical education, diagnostics, and treatment planning. Their technology aims to improve surgical precision and patient outcomes by providing medical professionals with advanced visualization tools.

Surgical Automations develops the Vāsuki Robotic System, an advanced platform utilizing AI-guided automation for endoscopic procedures. This system integrates precision engineering to enhance physician control and navigation within complex anatomical structures. The core value lies in transforming endoscopy through reliable automation for improved patient care outcomes.

MediView XR develops augmented reality systems, including the XR90 and OmnifyXR, to provide real-time, 3D visualization and navigation for minimally invasive surgical procedures. This technology enhances procedural accuracy and collaboration, addressing the challenges of limited visibility and communication in complex medical environments.

This company provides laser-guided robotic arm support to enhance clarity and structure within CT-guided workflows. Their system integrates proprietary software with CT/CBCT scans to offer visual guidance for treatment planning and precise needle trajectory alignment. The technology assists physicians in achieving faster, more accurate manual interventions while maintaining full clinical decision-making control.

Point Robotics Medtech develops the POINT™ Kinguide Robotic-Assisted Surgical System, which enhances precision in minimally invasive spinal surgeries through advanced robotic assistance. This technology reduces surgical variability and improves clinical outcomes for both patients and physicians.

Elucent Medical develops a breast cancer detection system that utilizes SmartClip technology and the EnVisio Navigation system to accurately locate tumor margins in real-time during surgical excision. This approach eliminates the need for metal clips, enhances surgical precision, and minimizes tissue removal, ultimately improving patient outcomes and satisfaction.

Centerline Biomedical has developed the Intra-Operative Positioning System (IOPS®), an FDA-cleared endovascular navigation technology that provides real-time 3D color image guidance while significantly reducing radiation exposure during procedures. This portable system enhances accuracy in vascular interventions, addressing the risks associated with traditional X-ray fluoroscopy methods.

This startup develops an AI surgical system for orthopedics that uses machine learning to analyze surgical data and provide real-time guidance. The system aims to reduce errors, shorten surgery times, and enable minimally invasive procedures by leveraging data-driven insights.

The startup operates a spinal robotics platform that focuses on the design and commercialization of navigation and robotic targeting solutions specifically for spine surgery. By providing cost-effective surgical robotics technologies, the company enhances precision in spinal procedures, ultimately improving patient outcomes and reducing operational costs for healthcare providers.

The startup has developed a smart surgical needle that utilizes real-time X-ray guidance and ultrasound energy for minimally invasive tumor detection and ablation. This technology enables precise tumor treatment near critical anatomy while minimizing damage to surrounding vital organs and tissue.

The Surgical Robotics Lab designs custom flexible robotic platforms that navigate confined anatomical pathways using magnetic, pneumatic, or tendon‑driven actuation. Its systems integrate real‑time ultrasound, CT, or MRI guidance with closed‑loop visual servoing, and the lab provides end‑to‑end development and licensing of proprietary actuation and control technologies for medical‑device manufacturers and research institutions.

This company develops steerable drilling technology for orthopedic and neurosurgical procedures, enabling surgeons to access hard-to-reach areas with greater precision. Their device improves accuracy in complex procedures, potentially leading to better patient outcomes.

ソラメドは、病院の手術室における遊休時間を解消するためのシステムを提供しています。予定手術早期実施支援システム「オペプロ」は、診療科間で分断された手術スケジューリング情報を全科で共有し、空き枠のマッチングを促進します。これにより、手術の早期実施を支援し、医療資源の有効活用と病院収益の向上に貢献します。

The company provides the ROPA orthopedic intelligent surgical robot, an AI‑driven platform that generates patient‑specific joint replacement plans from pre‑operative imaging and executes bone resections with sub‑millimeter accuracy using a six‑degree‑of‑freedom robotic arm and real‑time optical navigation. Integrated force/torque sensors and haptic feedback reduce operative time while preserving surgeon control, and all intra‑operative data are logged to a cloud analytics service for outcome tracking and model refinement. The system supports standard DICOM and HL7 interfaces and is backed by a dedicated clinical training center for orthopedic surgeons and hospital departments.

OsteobotiX provides a robot‑assisted orthopedic trauma platform that delivers real‑time, sub‑millimeter guidance for fracture fixation, removing the need for intra‑operative X‑ray imaging. The solution combines a six‑degree‑of‑freedom robotic arm, optical navigation, AI‑based trajectory planning, and a haptic console to align screws, plates, and pins according to pre‑operative CT/MRI models while securely logging data for analytics. It enables trauma surgeons and hospitals to lower radiation exposure, shorten procedure times, and improve implant accuracy.

The startup develops mixed-reality surgical systems that integrate holographic overlays with patient-specific anatomy, enhancing real-time visualization and interaction for surgeons. This technology improves surgical precision and efficiency by providing intuitive digital tools that facilitate better decision-making during procedures.

Symphony Robotics creates AI-powered micro‑robotic platforms for neurosurgery, combining real‑time imaging, machine‑learning navigation, and miniature actuators to target sub‑millimeter brain regions. The system is sold directly to hospitals and surgical centers with service contracts and consumable components.

Activ Surgical develops the ActivSight™ Intelligent Light, which utilizes augmented reality and machine learning to provide real-time visual insights into critical physiological structures during surgery. This technology addresses the high incidence of preventable surgical errors by enhancing surgeons' visibility beyond the naked eye, ultimately improving patient outcomes and surgical efficiency.

Clee Medical develops an innovative imaging and sensing technology to enhance neurosurgical precision and efficiency. This platform provides real-time, ultra-high-resolution visualization during brain surgery, integrating seamlessly with existing equipment. The technology aims to improve patient outcomes and increase surgical capacity by bridging the gap between preoperative diagnostics and intraoperative guidance.

SpinEM Robotics develops and provides robotics solutions, though the specific nature of these solutions is not detailed in the provided text. The company manages user data according to privacy regulations for administrative and commercial purposes. The website serves as an informational portal outlining terms of use and data handling policies.

The startup has developed an AI-powered surgical guidance platform that transforms static preoperative imaging into real-time anatomical insights, enhancing surgical precision. By integrating preoperative data into the surgical workflow, the platform improves decision-making during complex procedures.

XARlabs develops mixed reality technology for surgical applications. Their platform overlays 3D anatomical models onto a patient during surgery, providing surgeons with enhanced visualization and navigation capabilities to improve precision and outcomes.

nView medical’s nView s1™ delivers sub‑millimeter 3D volumes at < 0.1 mSv radiation dose directly in the operating room, removing the need for patient transport and minimizing exposure. The system’s true‑map navigation™ combines optical tracking and AI‑driven segmentation to provide a GPS‑style anatomical map with real‑time trajectory alerts, integrating via DICOM and OpenIGTLink with existing OR imaging and navigation hardware.

Zeta Surgical develops the RealTrack computer vision system, which provides sub-millimeter precision in surgical navigation and eliminates the need for traditional skull fixation and anesthesia. This technology enhances the safety and efficiency of image-guided procedures, reducing operation times and improving patient outcomes.

METHOD AI develops an image-guided surgical navigation platform that provides physicians with continuous deep tissue imaging and real-time guidance during robotic procedures. This technology addresses the incomplete visualization faced by surgeons, particularly in oncology, by integrating AI-generated surgical plans. The platform aims to enhance the precision of robotic surgery, leading to improved patient outcomes by ensuring complete resection of the surgical target.

PathKeeper Surgical provides an FDA-cleared, AI-driven 3D optical navigation system for spine surgery. This technology synthesizes preoperative planning with intraoperative intelligence for submillimeter tracking during implant placement. The system delivers radiation-free, efficient surgical navigation, streamlining workflow and enhancing precision.

The startup develops a non-invasive three-dimensional optical vision system that provides accurate and continuous surgical navigation for neurosurgeons. This technology addresses surgical errors related to anatomical feature registration and shape changes, enabling fully automated robotic procedures and in-vivo optical tissue diagnosis.

Ignis develops electromagnetic tracking systems for precise, real-time instrument localization in medical and industrial applications. Their technology enables accurate navigation and positioning of tools within a defined field, enhancing procedural safety and efficiency.

noVRel develops augmented reality solutions specifically for neurosurgery, integrating seamlessly into the operating room workflow. The platform provides surgeons with variable magnification loupes, intelligent headlights, and fluorescence-guided surgery capabilities via AR headsets. This technology enhances visualization and efficiency during complex surgical procedures.