EndoForce: Development of an Intuitive Axial Force Measurement Device for Endoscopic Robotic Systems

TL;DR

EndoForce is a novel, intuitive axial force measurement device for endoscopic robotic systems that improves safety and accuracy during procedures, addressing limitations of previous methods.

Contribution

This paper introduces EndoForce, a streamlined, cost-effective axial force sensor compatible with clinical environments, validated through experiments simulating human ureter conditions.

Findings

High accuracy in axial force measurement during insertion

Effective performance in both straight and curved pathways

Compatibility with clinical endoscopic procedures

Abstract

Robotic endoscopic systems provide intuitive control and eliminate radiation exposure, making them a promising alternative to conventional methods. However, the lack of axial force measurement from the robot remains a major challenge, as it can lead to excessive colonic elongation, perforation, or ureteral complications. Although various methods have been proposed in previous studies, limitations such as model dependency, bulkiness, and environmental sensitivity remain challenges that should be addressed before clinical application. In this study, we propose EndoForce, a device designed for intuitive and accurate axial force measurement in endoscopic robotic systems. Inspired by the insertion motion performed by medical doctors during ureteroscopy and gastrointestinal (GI) endoscopy, EndoForce ensures precise force measuring while maintaining compatibility with clinical environments. The device features a streamlined design, allowing for the easy attachment and detachment of a sterile cover, and incorporates a commercial load cell to enhance cost-effectiveness and facilitate practical implementation in real medical applications. To validate the effectiveness of the proposed EndoForce, physical experiments were performed using a testbed that simulates the ureter. We show that the axial force generated during insertion was measured with high accuracy, regardless of whether the pathway was straight or curved, in a testbed simulating the human ureter.