Analysis of the Basic Stress Pathway Above Acetabular Dome_Journal of Biomedical Engineering

Authors：

NIEYong , MAJun , HUANGQiang , HUQinsheng , SHIXiaojun ,  PEIFuxing

Department of Orthopedics, West China Hospital, Sichuan University, Chengdu 610041, China;

Corresponding author：

PEIFuxing, Email: peifuxing@vip.163.com

Keywords：

total hip arthroplasty; acetabular reconstruction; acetabular dome; basic stress pathway

DOI：

10.7507/1001-5515.20150145

Video：

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The basic stress pathway above the acetabular dome is important for the maintenance of implant stability in acetabular reconstruction of total hip arthroplasty (THA). The purpose of this study was to describe the basic stress pathway to provide evidence for clinical acetabular reconstruction guidance of THA. A subject-specific finite element (FE) model was developed from CT data to generate 3 normal hip models and a convergence study was conducted to determine the number of pelvic trabecular bone material properties using 5 material assignment plans. In addition, in the range of 0 to 20 mm above the acetabular dome, the models were sectioned and the stress pathway was defined as two parts, i.e. 3D trabecular bone stress distribution and quantified cortical bone stress level. The results showed that using 100 materials to define the material property of pelvic trabecular bone could assure both the accuracy and efficiency of the FE model. Under the same body weight condition, the 3D trabecular bone stress distributions above the acetabular dome were consistent, and especially the quantified cortical bone stress levels were all above 20 MPa and showed no statistically significant difference (P>0.05). Therefore, defining the basic stress pathway above the acetabular dome under certain body weight condition contributes to design accurate preoperative plan for acetabular reconstruction, thus helping restore the normal hip biomechanics and preserve the stability of the implants.

Citation： NIEYong, MAJun, HUANGQiang, HUQinsheng, SHIXiaojun, PEIFuxing. Analysis of the Basic Stress Pathway Above Acetabular Dome. Journal of Biomedical Engineering, 2015, 32(4): 802-807. doi: 10.7507/1001-5515.20150145 Copy

1.	张先龙,蒋垚,陈云苏.人工髋关节外科学[M].北京:人民军医出版社,2009:252-253.
2.	MOW V C,HUISKES R.骨科生物力学暨力学生物学[M].山东:山东科技出版社,2009:567-568.
3.	KIM Y H,YOON S H,KIM J S.Changes in the bone mineral density in the acetabulum and proximal femur after cementless total hip replacement:alumina-on-alumina versus alumina-on-polyethylene articulation[J].J Bone Joint Surg Br,2007,89(2):174-179.
4.	LERCH M,VON DER HAAR-TRAN A,WINDHAGEN H,et al.Bone remodelling around the Metha short stem in total hip arthroplasty:a prospective dual-energy X-ray absorptiometry study[J].Int Orthop,2012,36(3):533-538.
5.	FLOERKEMEIER T,GRONEWOLD J,BERNER S,et al.The influence of resection height on proximal femoral strain patterns after Metha short stem hip arthroplasty:an experimental study on composite femora[J].Int Orthop,2013,37(3):369-377.
6.	HUISKES R.Finite element analysis of acetabular reconstruction.Noncemented threaded cups[J].Acta Orthop Scand,1987,58(6):620-625.
7.	LEVENSTON M E,BEAUPRÉ G S,SCHURMAN D J,et al.Computer simulations of stress-related bone remodeling around noncemented acetabular components[J].J Arthroplasty,1993,8(6):595-605.
8.	DIGAS G,KÄRRHOLM J,THANNER J.Different loss of BMD using uncemented press-fit and whole polyethylene cups fixed with cement:repeated DXA studies in 96 hips randomized to 3 types of fixation[J].Acta Orthop,2006,77(2):218-226.
9.	LAURSEN M B,NIELSEN P T,SØBALLE K.Bone remodelling around HA-coated acetabular cups:a DEXA study with a 3-year follow-up in a randomised trial[J].Int Orthop,2007,31(2):199-204.
10.	PITTO R P,BHARGAVA A,PANDIT S,et al.Retroacetabular stress-shielding in THA[J].Clin Orthop Relat Res,2008,466(2):353-358.
11.	MUELLER L A,SCHMIDT R,EHRMANN C,et al.Modes of periacetabular load transfer to cortical and cancellous bone after cemented versus uncemented total hip arthroplasty:a prospective study using computed tomography-assisted osteodensitometry[J].J Orthop Res,2009,27(2):176-182.
12.	STEPNIEWSKI A S,EGAWA H,SYCHTERZ-TEREFENKO C,et al.Periacetabular bone density after total hip arthroplasty[J].J Arthroplasty,2008,23(4):593-599.
13.	MENEGHINI R M,FORD K S,MCCOLLOUGH C H,et al.Bone remodeling around porous metal cementless acetabular components[J].J Arthroplasty,2010,25(5):741-747.
14.	ANDERSON A E,PETERS C L,TUTTLE B D,et al.Subject-specific finite element model of the pelvis:development,validation and sensitivity studies[J].J Biomech Eng,2005,127(3):364-373.
15.	DALSTRA M.Biomechanical aspects of the pelvic bone and design criteria for acetabular prostheses[D].The Netherlands:University of Njemegen,1993.
16.	BERGMANN G,DEURETZBACHER G,HELLER M,et al.Hip contact forces and gait patterns from routine activities[J].J Biomech,2001,34(7):859-871.
17.	GHOSH R,GUPTA S,DICKINSON A,et al.Experimental validation of finite element models of intact and implanted composite hemipelvises using digital image correlation[J].J Biomech Eng,2012,134(8):1-9.
18.	KEⅡCHI K,HARUHIKO A,KOJI G,et al.Load dispersion effects of acetabular reinforcement devices used in revision total hip arthroplasty[J].J Arthroplasty,2011,26(7):1061-1066.
19.	ZHANG Q H,WANG J Y,LUPTON C,et al.A subject-specific pelvic bone model and its application to cemented acetabular replacements[J].J Biomech,2010,43(14):2722-2727.

1. 张先龙,蒋垚,陈云苏.人工髋关节外科学[M].北京:人民军医出版社,2009:252-253.
2. MOW V C,HUISKES R.骨科生物力学暨力学生物学[M].山东:山东科技出版社,2009:567-568.
3. KIM Y H,YOON S H,KIM J S.Changes in the bone mineral density in the acetabulum and proximal femur after cementless total hip replacement:alumina-on-alumina versus alumina-on-polyethylene articulation[J].J Bone Joint Surg Br,2007,89(2):174-179.
4. LERCH M,VON DER HAAR-TRAN A,WINDHAGEN H,et al.Bone remodelling around the Metha short stem in total hip arthroplasty:a prospective dual-energy X-ray absorptiometry study[J].Int Orthop,2012,36(3):533-538.
5. FLOERKEMEIER T,GRONEWOLD J,BERNER S,et al.The influence of resection height on proximal femoral strain patterns after Metha short stem hip arthroplasty:an experimental study on composite femora[J].Int Orthop,2013,37(3):369-377.
6. HUISKES R.Finite element analysis of acetabular reconstruction.Noncemented threaded cups[J].Acta Orthop Scand,1987,58(6):620-625.
7. LEVENSTON M E,BEAUPRÉ G S,SCHURMAN D J,et al.Computer simulations of stress-related bone remodeling around noncemented acetabular components[J].J Arthroplasty,1993,8(6):595-605.
8. DIGAS G,KÄRRHOLM J,THANNER J.Different loss of BMD using uncemented press-fit and whole polyethylene cups fixed with cement:repeated DXA studies in 96 hips randomized to 3 types of fixation[J].Acta Orthop,2006,77(2):218-226.
9. LAURSEN M B,NIELSEN P T,SØBALLE K.Bone remodelling around HA-coated acetabular cups:a DEXA study with a 3-year follow-up in a randomised trial[J].Int Orthop,2007,31(2):199-204.
10. PITTO R P,BHARGAVA A,PANDIT S,et al.Retroacetabular stress-shielding in THA[J].Clin Orthop Relat Res,2008,466(2):353-358.
11. MUELLER L A,SCHMIDT R,EHRMANN C,et al.Modes of periacetabular load transfer to cortical and cancellous bone after cemented versus uncemented total hip arthroplasty:a prospective study using computed tomography-assisted osteodensitometry[J].J Orthop Res,2009,27(2):176-182.
12. STEPNIEWSKI A S,EGAWA H,SYCHTERZ-TEREFENKO C,et al.Periacetabular bone density after total hip arthroplasty[J].J Arthroplasty,2008,23(4):593-599.
13. MENEGHINI R M,FORD K S,MCCOLLOUGH C H,et al.Bone remodeling around porous metal cementless acetabular components[J].J Arthroplasty,2010,25(5):741-747.
14. ANDERSON A E,PETERS C L,TUTTLE B D,et al.Subject-specific finite element model of the pelvis:development,validation and sensitivity studies[J].J Biomech Eng,2005,127(3):364-373.
15. DALSTRA M.Biomechanical aspects of the pelvic bone and design criteria for acetabular prostheses[D].The Netherlands:University of Njemegen,1993.
16. BERGMANN G,DEURETZBACHER G,HELLER M,et al.Hip contact forces and gait patterns from routine activities[J].J Biomech,2001,34(7):859-871.
17. GHOSH R,GUPTA S,DICKINSON A,et al.Experimental validation of finite element models of intact and implanted composite hemipelvises using digital image correlation[J].J Biomech Eng,2012,134(8):1-9.
18. KEⅡCHI K,HARUHIKO A,KOJI G,et al.Load dispersion effects of acetabular reinforcement devices used in revision total hip arthroplasty[J].J Arthroplasty,2011,26(7):1061-1066.
19. ZHANG Q H,WANG J Y,LUPTON C,et al.A subject-specific pelvic bone model and its application to cemented acetabular replacements[J].J Biomech,2010,43(14):2722-2727.

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