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Writer's pictureAmanda Sacino, MD, PhD

The Use of Robotics in Brain and Spine Surgery: Revolutionizing Precision and Patient Outcomes

Advancements in medical technology have transformed the way surgeries are performed, with robotics emerging as one of the most significant innovations in the field. In particular, the use of robotic systems in brain and spine surgery has revolutionized the precision, efficiency, and safety of complex procedures. These robotic technologies are not only enhancing the capabilities of surgeons but also improving patient outcomes, reducing recovery times, and minimizing the risk of complications.



Robotics in Brain and Spine Surgery


The Role of Robotics in Brain and Spine Surgery

Both brain and spine surgeries involve intricate procedures where precision is critical. The human nervous system is delicate and highly sensitive, requiring surgeons to navigate through narrow spaces and avoid damaging surrounding tissues. Robotics offers a solution to these challenges by providing enhanced visualization, greater accuracy, and improved control during procedures.

One of the most significant advancements in robotic-assisted surgery is the development of minimally invasive techniques. Traditionally, brain and spine surgeries often required large incisions, which could lead to longer recovery times and increased risk of infection. Robotic systems allow surgeons to perform these complex surgeries through smaller incisions, reducing trauma to the body and enhancing recovery rates.


Robotic Systems in Brain Surgery

In Neurosurgery, robotic systems have gained prominence in procedures like brain tumor removal, aneurysms, hemorrhagic stroke, deep brain stimulation (DBS), and epilepsy surgery. The complexity of these surgeries often involves navigating the brain's intricate anatomy while avoiding critical structures, such as blood vessels and nerves. Robotics provides a level of precision that human hands alone cannot match.

The ExcelsiusGPS robotic system provides a 3D high-definition view of the surgical area and allows for precise, controlled movements of instruments, even in challenging locations. This system is particularly valuable in guiding surgeons during brain tumor resections, as well as in procedures like stereotactic biopsies and DBS implantations. It uses a combination of pre-operative imaging and real-time navigation to map the brain and assist surgeons in achieving accurate and optimal results. This robotic assistance allows for smaller incisions, less tissue disruption, and a more precise removal of tumors, ultimately improving the chances of preserving healthy brain tissue.


Robotic Systems in Spine Surgery

Spine surgery is another area where robotics is making a transformative impact. Spine procedures, including spinal fusions, disc replacements, and scoliosis correction, often require the surgeon to align the spine with millimeter precision. Traditional methods of spinal surgery rely on the surgeon's skill and experience to manually guide instruments into place, which can be challenging due to the complexity of the spinal column and the surrounding nerves.

The ExcelsiusGPS robotic system has become a game-changer in the field of spine surgery. This system integrate advanced imaging and navigation capabilities with robotic assistance to enhance the surgeon's precision during the procedure. It provides real-time feedback based on 3D imaging and enables the surgeon to place screws and other implants with unparalleled accuracy.

One of the primary benefits of robotic spine surgery is the ability to perform minimally invasive procedures. Surgeons can plan and execute the surgery with increased accuracy, whether they are performing a simple disc replacement or a more complex spinal deformity correction. Using smaller incisions and precise robotic control, surgeons can access the spine with less disruption to surrounding tissues. This translates into reduced blood loss, shorter hospital stays, and faster recovery times. Additionally, the reduced risk of complications, such as nerve damage or misplacement of screws, enhances patient outcomes.


Advantages of Robotic-Assisted Brain and Spine Surgery

The use of robotics in brain and spine surgery offers several key advantages:

  1. Enhanced Precision: Robotic-assisted procedures provide a level of precision that is difficult to achieve with human hands alone. The ability to make minute adjustments and operate with extreme accuracy is crucial in delicate areas like the brain and spine.

  2. Minimally Invasive Approaches: With smaller incisions, robotic systems reduce trauma to the body, leading to less pain, reduced risk of infection, and faster recovery times for patients.

  3. Better Visualization: Robotic platforms often come with advanced imaging systems, such as 3D visualization and real-time tracking, which allow surgeons to view the surgical site in greater detail and make informed decisions during the procedure.

  4. Reduced Risk of Complications: By improving the accuracy of surgical procedures, robotics can reduce the likelihood of complications, such as nerve damage, blood loss, or misplacement of surgical instruments.

  5. Improved Outcomes: Minimally invasive surgery, faster recovery times, and reduced risks of complications all contribute to better long-term patient outcomes, including shorter hospital stays, less postoperative pain, and quicker returns to normal activities.


The Future of Robotics in Neurosurgery

While robotic systems have already demonstrated significant benefits in brain and spine surgery, the future promises even more innovations. As technology continues to evolve, we can expect robots to become more autonomous, with artificial intelligence (AI) playing an increasing role in decision-making and surgical planning. AI-powered robotic systems may assist surgeons in predicting outcomes, optimizing surgical approaches, and personalizing treatment plans for each patient.

Moreover, the integration of robotics with other emerging technologies, such as augmented reality (AR) and advanced imaging techniques, will further enhance the precision and effectiveness of brain and spine surgeries. Surgeons may one day use AR to visualize the patient’s anatomy in 3D during the procedure, allowing for even more accurate navigation and real-time adjustments.


Robotics in Brain and Spine Surgery

The integration of robotics into brain and spine surgery has undoubtedly transformed the landscape of these complex procedures. With its ability to enhance precision, reduce recovery times, and minimize risks, robotic-assisted surgery is improving patient outcomes and shaping the future of Neurosurgery. As technology continues to evolve, the role of robotics in healthcare will only expand, offering even greater opportunities for innovation and advancement in brain and spine surgery.


About Amanda Sacino MD, PhD

Dr. Sacino completed her neurosurgical training at Johns Hopkins Hospital. During that time she pursued extensive training in brain, spine, and peripheral nerve surgery. From there, she completed two spine fellowships at Johns Hopkins Hospital and Swedish Neuroscience Institute. She trained under Dr. Nicholas Theodore, the inventor of the Globus ExcelsiusGPS robot. She was present during the first robotic spine and DBS surgeries at Johns Hopkins Hospital and trained extensively with the robot for both brain and spine surgeries. She is in the top 1% internationally for number of robotic cases completed. She has also written research papers and given lectures on robotics for Neurosurgery. Her goal is to provide patients with case-specific solutions so they have all the information and options they need to make informed decisions.




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