Scrubbing in together: Surgical robots and the future of the operating room

The field of surgery has undergone a revolution with the integration of advanced technologies such as optoelectronics, robotics, and digital systems. This convergence has led to the development of minimally invasive (MI) surgery, which uses specialised instruments inserted through tiny incisions¹. Compared to traditional open surgery, MI techniques reduce blood loss, speed up healing, and improve recovery outcomes.

Robot-assisted surgery

Robot-assisted surgery (RAS), is a form of minimally invasive surgery that leverages robotic systems to perform complex procedures with heightened precision. Robotic technology in orthopedics was incorporated as far back as 1992, with the ROBODOC, for total hip replacement surgery².

Robotic systems can enable greater precision, overcoming human limitations like hand tremors or fatigue, and providing better access to challenging anatomical areas. Patients benefit from shorter hospital stays, reduced psychological stress, and lower radiation exposure through advanced navigation technologies3. However, challenges such as high equipment costs, extensive training requirements and occasional technical glitches remain.

Spinal applications

Now picture this, a cage like structure that grows and changes over time and is a conduit for over one million electrical messages per day.

The human spine is a complex structure and contains 120 muscles, around 220 ligaments, and 100 joints⁴. In fact people can be taller by 0.5 to 1.5 cm upon waking in the morning and become shorter over the day due to spinal compression⁵.

Using minimally invasive techniques and laparoscopes allows the surgeon to separate the muscles surrounding the spine with small incisions rather than cutting through them. When using manual laparoscopic instruments, surgeons carry out opposing movements within tiny incisions, often leaning, stooping or stretched out at awkward angles leading to fatigue, strain and injury.

Robotic assistance enhances these procedures by translating surgeons' hand movements into precise actions, smoothing tremors, and allowing for finer manipulations. Advanced imaging systems, including CT and MRI scans, help create detailed 3D models of the spine, enabling surgeons to pre-plan procedures and guide robotic arms during surgery. This approach minimizes damage to nearby nerves, blood vessels, and organs, making it particularly effective for complex surgeries like spinal fusions or instrumentation placement⁶.

Globus Medical

A recent entrant in the WHEB portfolio is Globus Medical, a leader in innovative spinal surgery systems. The company specialises in spinal implant systems, scoliosis correction tools, disc replacement technologies and advanced material technologies. Its flagship product, ExcelsiusGPS™, integrates robotics and navigation technologies to enhance surgical accuracy. This system allows surgeons to customise procedures based on each patient’s anatomy, reducing operative time and improving safety.

By 2021, over 20,000 spinal procedures had been performed using the ExcelsiusGPS™ system⁷. In the UK, the NHS and Globus Medical have a partnership to introduce robotic navigation in spinal surgeries that started with the Oxford University Hospitals NHS Foundation Trust and the Walton Centre NHS Foundation Trust Liverpool⁸ in 2022.

We expect Globus Medical’s revenues to grow by mid to high single-digits percentage over the coming years. This is mainly based on the expected double-digit growth of its “Enabling Technologies” segment that includes the ExcelsiusGPS™ product suite. In addition, the successful post-merger integration of NuVasive is expected to allow for a steady margin expansion during the same period. With a focus on continuous innovation, Globus is exploring artificial intelligence and advanced navigation systems to refine surgical techniques further.

The future

The next frontier in robotic surgery could be telesurgery—where surgeons operate remotely on patients in different locations. The first telesurgery took place in 2001, when a surgical team in New York used the ZEUS robotic system to perform surgery on a patient in France⁹.

Future advancements in augmented reality (AR) and virtual reality (VR) could enhance success by providing real-time overlays of medical imaging and anatomical structures for greater precision¹⁰. While a number of pre-clinical testing surgeries have been conducted on live humans and animals¹¹, challenges such as data latency, cybersecurity, data privacy and the danger of technical malfunction still need to be addressed before these futuristic technologies become routine in healthcare settings. 

The robotic arm retracts as the procedure concludes, the monitors dim. Yet, the future of the operating room is far from silent—it hums with the promise of what human and technological collaborations can achieve.