Why Visualization Is Central to the OR
What was once a single monitor in the corner of an OR has evolved into a multidisplay network: high-resolution, ultra-responsive and tightly integrated with imaging, data and robotic systems. Surgeons today depend on Ultra High Definition 4K and 8K monitors to distinguish tissue boundaries, identify microstructures and work with a degree of precision that was unthinkable just a decade ago. The slightest delay or visual inaccuracy can compromise an outcome, making clarity, contrast, latency and durability nonnegotiable standards.
Biomedical engineers manage these standards. From choosing the right display technologies to ensuring seamless interoperability, they define how visualization technology serves surgical performance. Whether it’s in-pane switching panels for color accuracy across viewing angles, ultralow latency monitors for procedures, or fanless, sealed displays that meet stringent sterilization protocols, engineers are tailoring solutions to the demands of each OR.
Supporting Collaboration in the OR
Modern ORs aren’t just smarter, they’re more collaborative. Large-format displays on walls and boom arms now provide teamwide visibility into surgical workflows. Split-screen and multisource capabilities allow for simultaneous viewing of live camera feeds, ultrasound, fluoroscopy, radiologic images, patient monitoring and more. In teaching hospitals and high-stakes hybrid rooms, this visibility enhances coordination and reduces delays.
Biomedical engineers orchestrate this complexity, working with technologists at leading manufacturers such as LG for identifying displays that support high-bandwidth image feeds, integrating artificial intelligence overlays for anatomical mapping and ensuring that visualization tools deliver actionable information in real time, without lag or resolution loss.
EXPLORE: Interactive displays elevate the patient experience and simplify clinical workflows.
Making Space for Innovation in the OR
The display is now a platform for innovation. Surgeons are increasingly relying on augmented reality, AI-guided procedures and image fusion. To support this, biomedical engineers are specifying displays with advanced processing power, modular connectivity and compatibility with next-generation software and imaging modalities.
They’re also advancing display design, deploying mini-LED and OLED technology for its deeper shades of black and better contrast in procedures, and management considerations for high-volume ORs. Wireless display systems are also gaining traction, improving OR flexibility.
Redundancy is another key engineering focus: Multiple video pathways, power backups and failover networks ensure that display systems don’t fail, especially when lives are on the line.
The Role of the Biomedical Engineer Expands
As ORs become more intelligent, biomedical engineers become more integral. These professionals are not only enabling current workflows but also preparing hospitals for a future defined by real-time data sharing, AI-enhanced procedures and remote collaboration.
They are, in effect, engineering the visual infrastructure of modern surgery — translating surgical needs into system requirements, matching clinical priorities with display performance and ensuring that every pixel supports precision, safety and success.
For healthcare organizations undergoing a digital transformation, the takeaway is simple: Investing in surgical displays will enable a new level of surgical performance, supported not just by technology but by the biomedical engineers who make it all work. Because in today’s high-performance OR, clarity isn’t just seen — it’s engineered.
