Neuro Navigation

Tailored for neurosurgery, enhancing precision and safety during complex procedures. It utilises cutting-edge imaging and real-time data integration to guide surgeons with unparalleled accuracy.

Smart solution for enhanced productivity

The intuitive interface streamlines workflows, allowing for better decision-making in the operating room. With Claronav, neurosurgeons can navigate intricate anatomical structures with confidence, improving patient outcomes.

Key features

Navient is an innovative image-guided navigation system, utilising the latest technologies in the field and bringing simplicity, accuracy and affordability to the surgical navigation system.

For spine, cranial, biopsy and ENT procedures
Sleek, compact and portable cart
Large touch screen for natural interaction
Powerful and intuitive software features
Pre-calibrated navigation probes
Fast registration and precise navigation
Affordable and no consumables

Tracking system

Infrared optical tracking system
0.2mm calibration accuracy
Live video stream
Instrument tip accuracy verification
Permanent markers
Reusable and sterilisable instruments
Foldable tracker arm with variable height

All-in-one computer

27” WQHD ultra bright touchscreen monitor
Ultra-thin Bezel, glass front and stainless steel back
Light weight, thin and easily detachable
Adjustable mount Tilt/Swivel/Rotation
Intel® Core™ i7 quad core processor
32GB 3200MHz DDR4 RAM
1TB NVMe PCIe M.2 SSD Drive
Nvidia GeForce RTX 3070 graphics

Software

For cranial, spine and ENT procedures
Loads DICOM images from DVD, USB, PACS
Image fusion
Automatic segmentation and 3D modeling
Virtual craniotomy
Biopsy trajectory planning and navigation
Pre-op and Intra-op pedicle screw planning
Landmark and trace registration
Automatic registration using intra-op CT and C-arm
Anatomical, trajectory and probe eye views
Video documentation of surgical operation

Cart

Light weight: 30kg
Small footprint: 40 (W) x 50 (D) x 135 (H) cm (when extended: 190 (H) cm)
Omni directional wheels with brakes
100V – 240V, 50/60Hz, 2.2A

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Surgeon insight

“The return of range of motion is much faster, they get much better motion and they get it quicker. They're out of the hospital sooner, their pain is better and they seem to get back to the activities that they want to do at a much quicker rate.”

Resources

Macheras GA et al A long term clinical outcome of the Medial Pivot Knee Arthroplasty System. Knee. 2017 Mar;24(2):447-453
Dennis DA, Komistek RD, Mahfouz MR, Haas BD, Stiehl JB. Multicenter determination of in vivo kinematics after total knee arthroplasty. Clin Orthop Relat Res. 2003
Schmidt R, Komistek RD, Blaha JD, Penenberg BL, Maloney WJ. Fluoroscopic analyses of cruciate-retaining and medial pivot knee implants. Nov;(416):37-57.
Walker PS. Factors affecting the impingement angle of fixed- and mobile bearing total knee replacement, a laboratory study. J Arthroplasty.2007;22(5):745-52.
Bindleglass DF. Current principles of design for cemented and cementless knees. Tech Orthop. 1991;6:80.
Banks S. Knee motions during maximum flexion in fixed and mobile-bearing arthroplasties. Clin Orthop Relat Res. 2003;410:131-8.
MPO Data on file
Dennis DA, Komistek RD, Mahfouz MR, Haas BD, Stiehl JB. Multicenter determination of in vivo kinematics after total kneearthroplasty. Clin Orthop Relat Res. 2003
Freeman MA, Pinskerova V. The movement of the knee studied by magnetic resonance imaging. Clin Orthop Relat Res. 2003;410:35-43