TY - JOUR
T1 - Artificial Knee Joint and Ski Load Simulator for the Evaluation of Knee Braces and Ski Bindings
AU - Nusser, Michaela
AU - Hermann, Aljoscha
AU - Senner, Veit
N1 - Publisher Copyright:
© 2016 The Authors. Published by Elsevier Ltd.
PY - 2016
Y1 - 2016
N2 - Introduction Epidemiological studies show that severe knee injuries are prevalent in alpine skiing. Their incidence is related to ski boot and ski binding concept-both designed to prevent tibia fractures. To reliably protect the knee, ski bindings need a release mechanism which follows different release principles. Therefore, attempts are made to develop mechatronic concepts implementing additional criteria and to release the foot when critical loads at the knee are reached. One possibility to systematically manipulate external loads and to investigate the resulting stresses in the joint are experiments using an artificial leg. This paper describes the development and the evaluation of such kind of model ("leg surrogate") including a complex artificial knee joint. The evaluation includes tests concerning the reliability, sensitivity and plausibility of the surrogate. Method Tibia and femur consist of an aluminum bone imitate and are reconstructed based on human computerized tomography data. Human endoprosthesis are used as articulating surfaces for the tibial plateau, the femoral condyles, the trochlea as well as the patella. Ten steel ropes connected to a force measuring cell are incorporated simulating the muscle. The muscle volume is imitated by a three layer coat of thermoplastic. The artificial knee ligaments are instrumented with custom made elongation and force sensors. Leg surrogate presetting's can be varied trough the knee angle, hip angle, varus or valgus position, tension of the muscle and pretension of the ligaments. A test rig enables t quasi static application of external loads to the leg surrogate in any combination about the x, y and z-axis. Results The leg surrogate delivers reproducible measurements with a maximum variation of 2.7%. It allows to simulate different conditions like muscle tension or hip angles and to record their influence on the knee ligaments. The plausibility checks performed indicate, that the leg surrogate represents the behavior of the human knee to a large extend. Conclusion The new leg surrogate allows to simulate not only alpine skiing injury but also other load situations. It therefore can be used to systematically investigate critical load situations to the knee and the prevention effect of safety devices such as mechatronic ski bindings or knee protection devices like preventive knee braces.
AB - Introduction Epidemiological studies show that severe knee injuries are prevalent in alpine skiing. Their incidence is related to ski boot and ski binding concept-both designed to prevent tibia fractures. To reliably protect the knee, ski bindings need a release mechanism which follows different release principles. Therefore, attempts are made to develop mechatronic concepts implementing additional criteria and to release the foot when critical loads at the knee are reached. One possibility to systematically manipulate external loads and to investigate the resulting stresses in the joint are experiments using an artificial leg. This paper describes the development and the evaluation of such kind of model ("leg surrogate") including a complex artificial knee joint. The evaluation includes tests concerning the reliability, sensitivity and plausibility of the surrogate. Method Tibia and femur consist of an aluminum bone imitate and are reconstructed based on human computerized tomography data. Human endoprosthesis are used as articulating surfaces for the tibial plateau, the femoral condyles, the trochlea as well as the patella. Ten steel ropes connected to a force measuring cell are incorporated simulating the muscle. The muscle volume is imitated by a three layer coat of thermoplastic. The artificial knee ligaments are instrumented with custom made elongation and force sensors. Leg surrogate presetting's can be varied trough the knee angle, hip angle, varus or valgus position, tension of the muscle and pretension of the ligaments. A test rig enables t quasi static application of external loads to the leg surrogate in any combination about the x, y and z-axis. Results The leg surrogate delivers reproducible measurements with a maximum variation of 2.7%. It allows to simulate different conditions like muscle tension or hip angles and to record their influence on the knee ligaments. The plausibility checks performed indicate, that the leg surrogate represents the behavior of the human knee to a large extend. Conclusion The new leg surrogate allows to simulate not only alpine skiing injury but also other load situations. It therefore can be used to systematically investigate critical load situations to the knee and the prevention effect of safety devices such as mechatronic ski bindings or knee protection devices like preventive knee braces.
KW - ACL
KW - knee injury
KW - knee joint
KW - leg surrogate
KW - load simulation
KW - skiing
UR - http://www.scopus.com/inward/record.url?scp=84982995407&partnerID=8YFLogxK
U2 - 10.1016/j.proeng.2016.06.217
DO - 10.1016/j.proeng.2016.06.217
M3 - Conference article
AN - SCOPUS:84982995407
SN - 1877-7058
VL - 147
SP - 220
EP - 227
JO - Procedia Engineering
JF - Procedia Engineering
T2 - 11th conference of the International Sports Engineering Association, ISEA 2016
Y2 - 11 July 2016 through 14 July 2016
ER -