Seeing New Opportunities in Training

FundamentalVR is expanding its surgical specialty capabilities with the addition of ophthalmology. Powered by the company’s HapticVRTM technology architecture that mimics the physical cues of surgical actions, medical tools, and tissue variations, FundamentalVR can now create immersive, data-driven medical educational simulations for ophthalmology as well as orthopedic device and pharmaceutical brands.

Traditional ophthalmology teaching methods and the way Life Science brands, medical institutions, and students interact, typically include; classroom lectures, instructional videos, medical meetings, operating room (OR) observations, and tissue-based wet lab training, which is considered the gold standard for medical training. Low-cost immersive simulations now offer solutions to continue remote, socially distant learning, while accelerating skills transfers, thanks to the ability to collect and objectively measure performance data previously unattainable.

Every user interaction from the surgical gaze, respect for tissue, and movement efficiency is measured and recorded to provide a level of analysis and measurement. In addition to increasing knowledge transfer, this detailed, data insight enables life science businesses to drive consistency and compliance for their medical devices and procedures.

The knowledge has been used to create tailored solutions for Life Sciences companies and a cataract surgical simulator for the global eye care NGO Orbis International.  The organization works to end avoidable blindness by training eye care teams in low and middle-income countries so they can save and restore vision in their communities. Orbis is deploying FundamentalVR’s educational simulation for cataract surgery in select residency training programs and prospective digital training hubs to evaluate the impact on residents’ surgical skills and obtain user feedback to inform further software developments.

Simulations, featuring the interactions with human tissue essential for learning, can be created to cover various ophthalmology procedures. These interactions include incisions, trocar placement, scleral tissue manipulation, lens manipulation, lens implant insertion, posterior chamber manipulations, bimanual manipulation of the eyeball, and subretinal injections.