Ryan K Orosco1, Benjamin Lurie2, Tokio Matsuzaki3, Emily K Funk2, Vasu Divi4, F Christopher Holsinger4, Steven Hong5, Florian Richter6, Nikhil Das6, Michael Yip6. 1. Division of Head and Neck Surgery, Department of Surgery, Moores Cancer Center, University of California San Diego, San Diego, CA, USA. rorosco@health.ucsd.edu. 2. Division of Head and Neck Surgery, Department of Surgery, Moores Cancer Center, University of California San Diego, San Diego, CA, USA. 3. Department of Cardiac Surgery, Japan Biodesign Program, The University of Tokyo, Tokyo, Japan. 4. Department of Otolaryngology, Stanford University, Stanford, CA, USA. 5. Division of Otolaryngology, Walter Reed National Military Medical Center, Bethesda, MD, USA. 6. Department of Electrical and Computer Engineering, University of California San Diego, San Diego, CA, USA.
Abstract
BACKGROUND: Round trip signal latency, or time delay, is an unavoidable constraint that currently stands as a major barrier to safe and efficient remote telesurgery. While there have been significant technological advancements aimed at reducing the time delay, studies evaluating methods of mitigating the negative effects of time delay are needed. Herein, we explored instrument motion scaling as a method to improve performance in time-delayed robotic surgery. METHODS: This was a robotic surgery user study using the da Vinci Research Kit system. A ring transfer task was performed under normal circumstances (no added time delay), and with 250 ms, 500 ms, and 750 ms delay. Robotic instrument motion scaling was modulated across a range of values (- 0.15, - 0.1, 0, + 0.1, + 0.15), with negative values indicating less instrument displacement for a given amount of operator movement. The primary outcomes were task completion time and total errors. Three-dimensional instrument movement was compared against different motion scales using dynamic time warping to demonstrate the effects of scaling. RESULTS: Performance declined with increasing time delay. Statistically significant increases in task time and number of errors were seen at 500 ms and 750 ms delay (p < 0.05). Total errors were positively correlated with task time on linear regression (R = 0.79, p < 0.001). Under 750 ms delay, negative instrument motion scaling improved error rates. Negative motion scaling trended toward improving task times toward those seen in non-delayed scenarios. Improvements in instrument path motion were seen with the implementation of negative motion scaling. CONCLUSIONS: Under time-delayed conditions, negative robotic instrument motion scaling yielded fewer surgical errors with slight improvement in task time. Motion scaling is a promising method of improving the safety and efficiency of time-delayed robotic surgery and warrants further investigation.
BACKGROUND: Round trip signal latency, or time delay, is an unavoidable constraint that currently stands as a major barrier to safe and efficient remote telesurgery. While there have been significant technological advancements aimed at reducing the time delay, studies evaluating methods of mitigating the negative effects of time delay are needed. Herein, we explored instrument motion scaling as a method to improve performance in time-delayed robotic surgery. METHODS: This was a robotic surgery user study using the da Vinci Research Kit system. A ring transfer task was performed under normal circumstances (no added time delay), and with 250 ms, 500 ms, and 750 ms delay. Robotic instrument motion scaling was modulated across a range of values (- 0.15, - 0.1, 0, + 0.1, + 0.15), with negative values indicating less instrument displacement for a given amount of operator movement. The primary outcomes were task completion time and total errors. Three-dimensional instrument movement was compared against different motion scales using dynamic time warping to demonstrate the effects of scaling. RESULTS: Performance declined with increasing time delay. Statistically significant increases in task time and number of errors were seen at 500 ms and 750 ms delay (p < 0.05). Total errors were positively correlated with task time on linear regression (R = 0.79, p < 0.001). Under 750 ms delay, negative instrument motion scaling improved error rates. Negative motion scaling trended toward improving task times toward those seen in non-delayed scenarios. Improvements in instrument path motion were seen with the implementation of negative motion scaling. CONCLUSIONS: Under time-delayed conditions, negative robotic instrument motion scaling yielded fewer surgical errors with slight improvement in task time. Motion scaling is a promising method of improving the safety and efficiency of time-delayed robotic surgery and warrants further investigation.
Entities:
Keywords:
Motion scaling; Robotic surgery; Signal latency; Telerobotics; Telesurgery
Authors: Paolo Fiorini; Ken Y Goldberg; Yunhui Liu; Russell H Taylor Journal: Proc IEEE Inst Electr Electron Eng Date: 2022-06-23 Impact factor: 14.910