OREM, Utah, March 3, 2025 /PRNewswire / – The Alpine Spine & Orthopedics Institute has implemented the new Ciatic Move 3D imaging system, a cutting-edge imaging system of this kind that provides ultra-high resolution 3D imaging that provides robot guide movement. Workflow during orthopedic procedures. Siemens 3D Ciatic Move is a low profile mobile imaging device that allows 3D navigation with a robotic holonomic mechanism to move like it floats around a surgical field. “This technology will guide us into the future due to minimally invasive image-guided procedures,” says MSC Dr. Richard J. McMurtry MD. “It is the most advanced robotic 3D C-ARM cone beam scanner and it exists to see the intervention procedure and approach at the highest resolution. We are grateful to be the first Utah to implement this kind of innovative device.”
The Ciatic Mobile 3D imaging system introduces a new era of mobile imaging and advances a wide array of complex and complex minimal procedures and interventions in spine, orthopedics, and trauma by bringing together the most advanced technologies from 3D computed tomography (CT) with spine, orthopedics, and trauma. Magnification, Digital Subtraction Angiography (DSA), Low-Dose Radiation Settings, and Autonomous Driving Robot Guidance automates robot guidance with automated positioning at the touch of a button. “As a doctor and an engineer, it’s rewarding to combine the best of these fields to provide the most cutting edge and most invasive care possible,” says Dr. McMurtrey.
Altar spine and orthopedics are recognized for their innovative approaches to tissue engineering and regenerative procedures, but this 3D scanner further enhances high-resolution visualization and optimized minimal visualization, as well as low-resolution visualization and precise targeting optimized for the treatment of a variety of ortopedics, joints, spines and nerve injuries. The clinic has already implemented the system in many steps, gaining new insights into the nuances of each injury and the unique perspective on the nuances of each injury, as well as the unique aspects of each injury, including defects in the spinal PAR, sacroiliac dysfunction, spinal bone dysfunction, spinal musculospermymuscularis, abdominal abdominal abdominal abdominal abdominal abdominal muscleization, parathyroid disorders, and other important features of each injury and a pain-related approach. Pathology, degenerative disc defects, facet arthritis affecting nerve roots and branches. In the first week of implementing the system, MRI imaging allowed for clear visualization of complex problems that could not be fully clear. This includes stress fractures in the spine and fractures in the scapula, sarcasal, metatarsals, and the clavicle bones in the sloped bones of the foot. Patients were patched with a corrective scaffold containing platelet-rich fibrin (PRF), bone marrow stem cells, and other regenerative agents. Furthermore, this technique is extremely valuable for checking the placement of needles at small joints such as the spine’s Atlantic Axial Joint, Atlantocoquipital Joint, and Facet joint.
“We focus on repairing as directly as possible to repair the underlying injury with minimal image-guided procedures that can be targeted by looking at many types of orthopedic and neurological problems from all angles.” Many patients are forced to resort to steroid injections that further weaken and degenerate cartilage, bones, ligaments and tendons, leading to further problems in the long run. Instead, our practice focuses on regenerative interventions targeting underlying tissue damage and pain generators, rather than hiding drug problems, rather than relying on larger surgeries that can result in many severe complications and irreversible lifelong consequences. Surgery syndrome failed. “The goal is to get the most repair, healing and function directly with a combination of regenerative agents that include custom designed autologous stem cell patches, biomaterial scaffolds and other factors that allow patients to function more quickly, using the most targeted and minimal approach possible.
Dr. McMurtrey has studied the application of stem cell and tissue engineering in many types of injuries and conditions using knowledge and training in neurosurgery, orthopedic surgery, trauma surgery, critical care, and intervention procedures. He works with surgeons from inner city trauma centers to academic surgical programs, and he is one of the only physicians in the world, receiving such unique surgical training and extensive experience in tissue engineering and stem cell research at top universities. “I managed multiple trauma, complex surgeries, and emergency services with over 100 patients a day at a busy Level I trauma center. “It was heartbreaking to have so many injuries that there were no medical or surgical solutions. I was able to stitch the spine and screw bones under standard fluorescent images, but I was unable to repair many other damage to the brain, spinal cord, nerves, discs, facets, cartilage and joints.” Because of these limitations, Dr. McMurtrey used his bioengineering and molecular and cell biology research experience in cell signaling mechanisms to study stem cell and tissue engineering in several laboratories around the world. “We have discovered a way to construct 3D tissues from stem cells containing nanopatterned neural architecture from patient stem cells with functionalized biomaterial scaffolds at Oxford University.
“We also applied 3D tissue engineering techniques to orthopaedic tissue damage, combining mesenchymal stem cells with biomaterial scaffold architectures that can be designed with many types of spatially compartmentalized signaling factors.” This approach created a powerful triple combination of regenerative agents packed in biocompatible patches that integrates into defects in injured tissues and helps stimulate repair and reconstruct the appropriate tissue architecture, and the final part of the puzzle was to place these regenerative patches in the damaged location in a minimally invasive way. “We are at the forefront of regenerative medicine interventions, and the movement of CIARTIC allows the best combination of minimally invasive procedures to ultimately enable the best combination targeting injuries, lesions, cysts, defects, lacerations, tears and fractures.”
Dr. McMurtrey described the number of patients with painful conditions that the surgery cannot handle at all, or many who have already undergone spinal fusion or joint surgery, as well as many who still maintain significant pain and dysfunction, as well as the problems that surgery can do more harm than good. “The Ciatic Move device is a powerful tool that helps you directly treat a variety of injuries with minimal invasive techniques that will help you find and target the cause of these pain, promote long-term recovery and promote more generative options that will help you directly repair tissue injuries and defects.
Alpine Spine & Orthopedics Institute
www.alpineorthopedics.com
About the Alpine Spine & Orthopedics Institute:
The Alpine Spine & Orthopedics Institute specializes in interventional orthopedics, spine, nerve, pain and sports medicine, focusing on regenerative procedures and minimal image guided techniques, and aims to implement and provide research and innovative advances in regenerative medicine and tissue engineering. For more information, please visit https://www.alpineorthopedics.com/.
Contact: info@alpineorthopedics.com
See: https://www.alpineorthopedics.com/3dimaging
Source Alpine Spine & Orthopedics Institute
