Characterisation of dynamic couplings at lower limb residuum/socket interface using 3D motion capture

• A new 3D motion based biomechanical model is developed to measure dynamic coupling at residuum/socket interface.
• Up to 12° of angular and 36mm of axial coupling is obtained from multiple clinical case study sessions on a trans-femoral amputee.
• The results suggest non-rigid coupling may play an important role in the analysis of 3D kinematics and interface biomechanics.

Design and fitting of artificial limbs to lower limb amputees are largely based on the subjective judgement of the prosthetist. Understanding the science of three-dimensional (3D) dynamic coupling at the residuum/socket interface could potentially aid the design and fitting of the socket.A new method has been developed to characterise the 3D dynamic coupling at the residuum/socket interface using 3D motion capture based on a single case study of a trans-femoral amputee. The new model incorporated a Virtual Residuum Segment (VRS) and a Socket Segment (SS) which combined to form the residuum/socket interface. Angular and axial couplings between the two segments were subsequently determined. Results indicated a non-rigid angular coupling in excess of 10° in the quasi-sagittal plane and an axial coupling of between 21 and 35 mm. The corresponding angular couplings of less than 4° and 2° were estimated in the quasi-coronal and quasi-transverse plane, respectively.We propose that the combined experimental and analytical approach adopted in this case study could aid the iterative socket fitting process and could potentially lead to a new socket design.