Comprehending finger flexor tendon pulley system using a computational analysis

TL;DR

This study uses a computational model to analyze the finger's tendon-pulley system, aiming to identify configurations that minimize tension and stress, thereby informing prosthetic design and surgical reconstruction.

Contribution

It introduces a parametric, compliant computational model of the finger's tendon-pulley system to determine optimal configurations for reduced tension and stress.

Findings

Optimal pulley configurations identified for minimal tension.

Analysis explains biological TPS configuration aspects.

Model aids in designing customized hand exoskeletons.

Abstract

Existing prosthetic/orthotic designs are rarely based on kinetostatics of a biological finger, especially its tendon-pulley system (TPS) which helps render a set of extraordinary functionalities. Studies on computational models or cadaver experiments do exist. However, they provide little information on TPS configurations that lead to lower tendon tension, bowstringing, and pulley stresses, all of which a biological finger may be employing after all. A priori knowledge of such configurations and associated trade-offs is helpful not only from the design viewpoint of, say, an exoskeleton but also for surgical reconstruction procedures. We present a parametric study to determine optimal TPS configurations for the flexor mechanism. A compliant, flexure-based computational model is developed and simulated using the pseudo rigid body method, with various combinations of pulley/tendon attachment point locations, pulley heights, and widths. Deductions are drawn from the data collected to recommend the most suitable configuration. Many aspects of the biological TPS configuration are explained through the presented analysis. We reckon that the analytical approach herein will be useful in arriving at customized (optimized) hand exoskeletal designs.