Worldwide Distribution: US (Nationwide) including Puerto Rico; and countries of: Algeria, Argentina, Australia, Austria, Bahrain, Belarus, Belgium, Bolivia, Brazil, Canada, Chile, China, Colombia, Czech Republic, Denmark, Dominican Republic, Ecuador, Egypt, Estonia, Finland, France, Germany, Greece, Honduras, Hong Kong, Hungary, India, Iran, Iraq, Ireland, Israel, Italy, Jamaica, Japan, Jordan, Latvia, Lithuania, Malaysia, Mexico, Morocco, Netherlands, Norway, Oman, Pakistan, Panama, Philippines, Poland, Portugal, Qatar, Russian Federation, Saudi Arabia, Singapore, Slovakia, Slovenia, South Africa, South Korea, Spain, Sweden, Switzerland, Taiwan, Thailand, Trinidad and Tobago, Turkey, Ukraine, United Arab Emirates, United Kingdom, Venezuela, and Vietnam.
Description du dispositif
Brainlab Cranial Navigation System: An Image Guided Surgery System / Stereotactic. Radiology Departments. || The BrainLAB Cranial IGS System is intended to be an intra-operative image guided localization system to enable minimally invasive surgery.
ExacTrac versions 6.5 through 6.5 intended to be used to place patients at an accurately defined point within the treatment beam of a medical accelerator for stereotactic radiosurgery or radiotherapy procedures, in order to treat lesions, tumors and conditions anywhere in the body when radiation treatment is indicated. ExacTrac may also be used to monitor the patient position during the treatment.
Worldwide Distribution - US Nationwide in the U.S. States: of AK, AZ, CA, CO, FL, GA, IL, KY, LA, MD, MA, MI, MN, MT, MO, NJ, NY, NC, OH, PA, RI, TN, TX, UT, VA, WA, and WV; and the countries of Argentina, Australia, Austria, Belgium, Canada, Egypt, France, Germany, India, Italy, Japan, Kazakhstan, Lithuania, Netherlands, Saudi Arabia, Spain, Switzerland, United Arab Emirates, and Uzbekistan.
Description du dispositif
AIRO Mobile CT System, Model Number: MobiCT-32 || Product Usage: || The AIRO is intended to be used for X-ray computed tomography applications for anatomy that can be imaged in the 107cm aperture excluding pediatric patients and patients weighing over 400 lbs. (182 kg).
Model No. 19154, UDI GTIN 04056481132187. Model No. 19154-04, UDI No. GTIN 04056481113926. Serial No. range 7459316001 - 7459316027 and 7714816001 - 7714816017.
Distributed in the US to Kansas. Distributed internationally to Australia, Finland, France, Germany, Hong Kong, Ireland, Japan, Netherlands, Norway, Sweden, Switzerland, Taiwan, Turkey, United Kingdom.
Description du dispositif
Brainlab Navigation System Spine & Trauma 3D with component Brainlab DrapeLink Registration Kit for C-arm Zeihm Vision RFD: Adapter Left
Potentially affected are ExacTrac Vero versions 3.x. Currently only ExacTrac Vero SW versions 3.5(.x) are installed for use on existing ExacTrac Vero Systems (only ExacTrac Vero v.3.5 exist in the field). UDI: 04056481132446
Worldwide Distribution - US Distribution and to the countries of : Belgium, Canada, France, Germany, Italy, Japan and S. Korea
Description du dispositif
BRAINLAB EXACTRAC VERO, Model/Catalog Numbers: || 46228 EXACTRAC VERO 3.5 || 46238 EXACTRAC VERO 3.5 || 46216 EXACTRAC VERO SW UPDATE 3.5.2 TO 3.5.3 || 46218 EXACTRAC VERO SW UPDATE 3.5.3 TO 3.5.4 || The ExacTrac Vero system is intended to be used in conjunction with the MHI-TM2000 Radiation Therapy Linear Accelerator System manufactured by Mitsubishi Heavy Industries, Ltd. ExacTrac Vero uses the images received from the MHI-TM2000 linear accelerator for analyzing the current patient position and calculating - when applicable - a necessary correction shift. The correction shift is then exported to the MHI-TM2000 linear accelerator. The ExacTrac Vero system uses stereoscopic X-ray or Cone Beam CT registration and optical tracking of infrared reflective markers in order to localize and correct the patient position before and during treatment. Optionally ExacTrac Vero provides position data for the pan/tilt motion of the MHI-TM2000 gantry head to the MHITM2000 controller for continuous alignment of the beam orientation with a moving target. The position data is based on target detection via X-ray imaging and IR tracking of external surrogate markers.