BACKGROUND: Lack of primary stability of cementless hip stems prevents bone ingrowth and may lead to loosening of the stem. Direct measures of the implant stability require drilled holes in the bone at the measuring site. These holes weaken the cortical bone, limit the number of possible measuring points and inhibit other biomechanical measurements. This in vitro study aimed to develop a method for indirect measurement of primary stability of femoral stems, leaving the specimen intact. The method was used to compare the primary stability of two uncemented femoral stems with different proximal fit and fill and different stem length. METHODS: An in vitro method for indirect full three-dimensional measurement of implant-bone interface motion was developed. Uncemented customized (n=10) and anatomical stems (n=10) were inserted in human cadaver femora and the primary stability during one leg stance and stair climbing was measured. FINDINGS: The method had high precision, and the errors due to necessary assumption of rigid body components were minimal. The customized stem with optimal proximal fit and fill provided the best initial stability for rotation in retroversion. The anatomical stem with longer stem length was more resistant to permanent rotation in varus. INTERPRETATION: During stem design development the primary stability can be measured at all wanted measuring sites with the presented method, leaving the specimen intact for further analyses. Copyright 2010 Elsevier Ltd. All rights reserved.
BACKGROUND: Lack of primary stability of cementless hip stems prevents bone ingrowth and may lead to loosening of the stem. Direct measures of the implant stability require drilled holes in the bone at the measuring site. These holes weaken the cortical bone, limit the number of possible measuring points and inhibit other biomechanical measurements. This in vitro study aimed to develop a method for indirect measurement of primary stability of femoral stems, leaving the specimen intact. The method was used to compare the primary stability of two uncemented femoral stems with different proximal fit and fill and different stem length. METHODS: An in vitro method for indirect full three-dimensional measurement of implant-bone interface motion was developed. Uncemented customized (n=10) and anatomical stems (n=10) were inserted in human cadaver femora and the primary stability during one leg stance and stair climbing was measured. FINDINGS: The method had high precision, and the errors due to necessary assumption of rigid body components were minimal. The customized stem with optimal proximal fit and fill provided the best initial stability for rotation in retroversion. The anatomical stem with longer stem length was more resistant to permanent rotation in varus. INTERPRETATION: During stem design development the primary stability can be measured at all wanted measuring sites with the presented method, leaving the specimen intact for further analyses. Copyright 2010 Elsevier Ltd. All rights reserved.
Authors: Steven Leuridan; Quentin Goossens; Leonard Cezar Pastrav; Michiel Mulier; Wim Desmet; Jos Vander Sloten; Kathleen Denis Journal: IEEE J Transl Eng Health Med Date: 2021-11-15 Impact factor: 3.316
Authors: I Tatani; P Megas; A Panagopoulos; I Diamantakos; Ph Nanopoulos; Sp Pantelakis Journal: Biomed Eng Online Date: 2020-08-19 Impact factor: 2.819