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Updated: Feb 27, 2026

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An Optimization Method for an Active Multi-Unit Prosthetic Socket with Dynamic Adaptability in Multi-Task Scenarios.

Yawen Hu1, Li Jiang1, Chunying Zou2

  • 1State Key Laboratory of Robotics and System, Harbin Institute of Technology, Harbin 150008, China.

Biomimetics (Basel, Switzerland)
|February 26, 2026
PubMed
Summary
This summary is machine-generated.

This study introduces an intelligent design for active upper-limb prosthetic sockets, optimizing comfort and stability. The new design balances pressure distribution and adaptability for better prosthetic performance.

Keywords:
artificial limbsbiomechanical phenomenaoptimizationprosthetic interface

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Area of Science:

  • Biomedical Engineering
  • Rehabilitation Engineering
  • Prosthetics and Orthotics

Background:

  • Prosthetic socket adaptability is crucial for performance, comfort, and safety.
  • Traditional sockets exhibit poor pressure distribution, air permeability, and adaptability.
  • Individual residual limb morphology presents challenges for socket design.

Purpose of the Study:

  • To propose an intelligent, physiologically adapted optimal design for active upper-limb prosthetic sockets.
  • To enhance socket adaptability for multi-task scenarios.
  • To improve prosthetic socket comfort and stability.

Main Methods:

  • Dynamic force optimization algorithm for multi-contact units in prosthetic manipulation tasks.
  • Biomechanical experiments to determine pain threshold distribution of forearm soft tissues.
  • Evaluation of mechanical performance of socket structures under various task scenarios using comfort indices (peak/mean normal force, force distribution variance).

Main Results:

  • The proposed active multi-unit socket design optimizes output force for stable suspension and minimal interface pressure.
  • Biomechanical data informed the spatial layout of contact units based on pain thresholds.
  • The double-layered eight-unit symmetric radial staggered configuration demonstrated a balance between comfort and stability.

Conclusions:

  • The intelligent physiological adaptation-based design method offers an effective and scalable paradigm for adaptive prosthetic sockets.
  • The optimized active multi-unit socket enhances user comfort and prosthetic stability across diverse tasks.
  • This approach addresses limitations of traditional prosthetic sockets for improved long-term use.