Measuring interaction forces in surgical telemanipulation using conventional instruments

• Published in: Robotica Vol. 41; no. 4; pp. 1335 - 1347
• Main Authors: Schäfer, Max B., Glöckner, Anja M., Friedrich, Gerrit R., Meiringer, Johannes G., Pott, Peter P.
• Format: Journal Article
• Language: English
• Published: Cambridge, UK Cambridge University Press 01.04.2023
• Subjects: Actuation; Advances in Medical Robotics; Haptics; Kinematics; Laparoscopy; Measurement methods; Measuring instruments; Range of motion; Robotics; Sensors; Standard components; Strain gauges; Surgery; Surgical apparatus & instruments; Surgical instruments; Telesurgery; United States > US; robot-assisted surgery; haptics; force feedback; laparoscopic instruments; minimally invasive surgery; haptic feedback; telemanipulation; interaction forces
• ISSN: 0263-5747; 1469-8668
• DOI: 10.1017/S0263574722001758

Minimally invasive surgery (MIS) has been an essential tool in the surgical sector for many years due to its crucial advantages compared to open surgery. To overcome remaining limitations, teleoperated MIS experienced a strong emergence. However, the widespread usage of such systems is hindered by the enormous financial hurdle. The use of standard components and conventional tools for teleoperated MIS can facilitate integration into existing hospital workflows and can be a cost-efficient and versatile approach for research purposes. To compensate for the lack of haptic feedback, some teleoperation setups inherit a sensor system allowing them to record interaction forces and display them at the user interface. In research and in commercially available systems, different positions for the sensor can be found. In this paper, mechanical interfaces for the guidance and actuation of non-wristed and wristed standard instruments are presented. Furthermore, a method for the extracorporeal measurement of interaction forces is presented, characterized, and discussed. The overall mean relative error of the magnitude of the interaction force is 9.4%, while the overall mean absolute error of the force vector is 14.4 $^{\circ }$ , both below the respective human differential perception threshold. The presented measurement method is a simple, yet sufficiently accurate approach to measure interaction forces in surgical telemanipulation.