Three-dimensional finite element analysis of Swanson prosthesis-arthroplasty of the first metatarsophalangeal joint combined with osteotomy and bone grafting of the first metatarsal bone for hallux valgus_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

ZHENG Wenyuan ¹ ,  LU Yun ²

1. Department of Orthopaedics, Yulin First People’s Hospital, Yulin Guangxi, 537000, P. R. China;
2. Department of Hand and Foot Surgery and Repair and Reconstruction Surgery, Tianjin People’s Hospital, Tianjin, 300121, P. R. China;

Corresponding author：

LU Yun, Email: chinayunlu@hotmail.com

Keywords：

Hallux valgus; the 1st metatarsophalangeal joint; Swanson prosthesis-arthroplasty; osteotomy and bone grafting of the 1st metatarsal bone; three-dimensional finite element analysis; biomechanics

DOI：

10.7507/1002-1892.202204126

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Objective To analyze the biomechanical changes of hallux valus after Swanson prosthesis-arthroplasty of the 1st metatarsophalangeal joint combined with osteotomy and bone grafting of the 1st metatarsal bone by three-dimensional finite element analysis, so as to provide data basis for studying the changes of foot morphology and physiological function after hallux valus correction surgery. Methods A 65-year-old female patient with severe hallux valus admitted in January 2013 was selected as the research object. The CT data of the right foot was obtained, and the three-dimensional finite element models before and after Swanson prosthesis-arthroplasty of the 1st metatarsophalangeal joint combined with osteotomy and bone grafting of the 1st metatarsal bone were established by Mimics10.01, Geomagic Studio, and ANSYS12.0 software. ANSYS 12.0 software was used for nonlinear static stress analysis, and the hallux valgus angle (HVA), the intermetatarsal angle (IMA), and the von Mises stress distributions of the forefoot plantar surface and the 1st to 5th metatarsal bones were observed before and after operation. Results The HVA and IMA were 56.3° and 16.3° before operation and 9.2° and 9.8° after operation, respectively. Before operation, the stress on the forefoot was the largest in the 4th metatarsal head zone and the smallest in the 1st metatarsal head zone; the stress on the medial side of the forefoot was significantly smaller than that on the lateral side, and the center of forefoot pressure was located on the lateral side. After operation, the stress on the forefoot was the largest in the 1st metatarsal head zone and the smallest in the 5th metatarsal head zone; the stress on the lateral side of the forefoot was significantly smaller than that on the medial side, and the center of forefoot pressure was located on the medial side. Before operation, the stress of the 5th metatarsal bone was the largest, and the 1st metatarsal bone was the smallest. After operation, the stress of the 1st metatarsal bone was the largest, and the 4th metatarsal bone was the smallest. Conclusion Swanson prosthesis-arthroplasty of the 1st metatarsophalangeal joint combined with osteotomy and bone grafting of the 1st metatarsal bone can effectively correct hallux valgus and make HVA, IMA, and plantar pressure distribution close to normal. However, postoperative stresses of the 1st to 5th metatarsal bones elevate, which may lead to associated complications.

Citation： ZHENG Wenyuan, LU Yun. Three-dimensional finite element analysis of Swanson prosthesis-arthroplasty of the first metatarsophalangeal joint combined with osteotomy and bone grafting of the first metatarsal bone for hallux valgus. Chinese Journal of Reparative and Reconstructive Surgery, 2022, 36(9): 1114-1118. doi: 10.7507/1002-1892.202204126 Copy

1.	中华医学会骨科学分会足踝外科学组, 中国医师协会骨科医师分会足踝外科专业委员会. 踇外翻诊疗专家共识. 中国医学前沿杂志 (电子版), 2017, 9(10): 30-42.
2.	Hardy RH, Clapham JCR. Observations on hallux valgus. J Bone Joint Surg (Br), 1951, 33(3): 376-391.
3.	Buckwalter JA, Einhorn TA, Simon SR. Orthopaedic basic science: biology and biomechanics of the musculoskeletal system. USA: American Academy of Orthopaedic Surgeons, 2000: 873.
4.	Büchler P, Ramaniraka NA, Rakotomanana LR, et al. A finite element model of the shoulder: application to the comparison of normal and osteoarthritic joints. Clin Biomech (Bristol, Avon), 2002, 17(9-10): 630-639.
5.	Cheung JT, Zhang M, Leung AK, et al. Three-dimensional finite element analysis of the foot during standing—a material sensitivity study. J Biomech, 2005, 38(5): 1045-1054.
6.	Maganaris CN. Tensile properties of in vivo human tendinous tissue. J Biomech, 2002, 35(8): 1019-1027.
7.	孙卫东. 中西医结合治疗踇外翻生物力学机制的有限元分析. 北京: 中国中医科学院, 2010.
8.	Lewis G, Jonathan V, Kambhampati S. Effect of material property representation on stresses in endoprostheses. Bio-Medical Materials and Engineering, 1998, 8(1): 11-13.
9.	Shi K, Hayashida K, Owaki H, et al. Replacement of the first metatarsophalangeal joint with a Swanson implant accompanied by open-wedge osteotomy of the first metatarsal bone for hallux valgus in rheumatoid arthritis. Modern Rheumatology, 2007, 17(2): 110-114.
10.	Zhang M, Mak AF. In vivo friction properties of human skin. Prosthet Orthot Int, 1999, 23(2): 135-141.
11.	Simkin A, Arcan M, Brull M. A structural model of the human foot. Journal of Biomechanics, 1982. doi:10.1016/0021-9290(85)90730-4.
12.	Wang C, He X, Zhang Z, et al. Three-dimensional finite element analysis and biomechanical analysis of midfoot von Mises stress levels in flatfoot, clubfoot, and Lisfranc joint injury. Med Sci Monit, 2021, 27: e931969. doi: 10.12659/MSM.931969.
13.	Brilakis EV, Kaselouris E, Markatos K, et al. Mitchell’s osteotomy augmented with bio-absorbable pins for the treatment of hallux valgus: A comparative finite element study. J Musculoskelet Neuronal Interact, 2019, 19(2): 234-244.
14.	毕春强, 温建民, 孙卫东, 等. 静态有限元法分析基于 “裹帘” 法外固定踇外翻术后截骨端的稳定性. 中国组织工程研究, 2016, 20(22): 3294-3300.
15.	李晏乐, 常程, 岳肖华, 等. 踇外翻微创截骨联合 “8” 字绷带外固定的生物力学分析. 中国组织工程研究, 2018, 22(23): 3659-3664.
16.	白子兴, 曹旭含, 孙承颐, 等. 微创治疗踇外翻术后绷带外固定: 有限元分析截骨端稳定性. 中国组织工程研究, 2020, 24(18): 2811-2816.
17.	温建民, 钟红刚, 蒋科卫, 等. 正常足与踇外翻足的足底压力研究. 中华骨科杂志, 1999, 19(6): 346-348.
18.	张致媛. 跖骨远端截骨术治疗踇外翻的X线测量、前足底压力改变及有限元分析. 北京: 北京协和医学院, 2009.
19.	Ebina K, Hirao M, Takagi K, et al. Comparison of the effects of forefoot joint-preserving arthroplasty and resection-replacement arthroplasty on walking plantar pressure distribution and patient-based outcomes in patients with rheumatoid arthritis. PLoS One, 2017, 12(8): e0183805. doi: 10.1371/journal.pone.0183805.
20.	Clarke GR, Thomas MJ, Rathod-Mistry T, et al. Hallux valgus severity, great toe pain, and plantar pressures during gait: A cross-sectional study of community-dwelling adults. Musculoskeletal Care, 2020, 18(3): 383-390.
21.	Zhang Y, Awrejcewicz J, Szymanowska O, et al. Effects of severe hallux valgus on metatarsal stress and the metatarsophalangeal loading during balanced standing: A finite element analysis. Comput Biol Med, 2018, 97: 1-7.
22.	Lee H, Ishikawa H, Shibuya T, et al. Changes in radiographic findings and plantar pressure distribution following forefoot reconstructive surgery for patients with rheumatoid arthritis. Mod Rheumatol, 2020, 30(6): 967-974.
23.	Filardi V. Hallux valgus (HV): A multi-approach investigation analysis. J Orthop, 2019, 18: 166-170.
24.	Hida T, Okuda R, Yasuda T, et al. Comparison of plantar pressure distribution in patients with hallux valgus and healthy matched controls. J Orthop Sci, 2017, 22(6): 1054-1059.
25.	Xiang L, Mei Q, Fernandez J, et al. A biomechanical assessment of the acute hallux abduction manipulation intervention. Gait Posture, 2020, 76: 210-217.
26.	Guo J, Wang L, Mao R, et al. Biomechanical evaluation of the first ray in pre-/post-operative hallux valgus: A comparative study. Clin Biomech (Bristol, Avon), 2018, 60: 1-8.
27.	陶凯, 王冬梅, 王成焘, 等. 基于三维有限元静态分析的人体足部生物力学研究. 中国生物医学工程学报, 2007, 26(5): 763-766, 780.
28.	Xiang L, Mei Q, Fernandez J, et al. Minimalist shoes running intervention can alter the plantar loading distribution and deformation of hallux valgus: A pilot study. Gait Posture, 2018, 65: 65-71.
29.	Verdu Roman C, Martinez Gimenez E, Bustamante Suarez de Puga D, et al. Hallux valgus with and without metatarsalgia in women: a matched-cohort study of plantar pressure measurements. Indian J Orthop, 2021, 55(Suppl 2): 436-444.
30.	Lee H, Ishikawa H, Miyagawa Y, et al. Plantar pressure and surgical indication of toe arthroplasty for rheumatoid forefoot deformity. Mod Rheumatol, 2017, 27(6): 990-994.
31.	Martínez Bocanegra MA, Bayod Lopez J, Vidal-Lesso A, et al. Structural interaction between bone and implants due to arthroplasty of the first metatarsophalangeal joint. Foot Ankle Surg, 2019, 25(2): 150-157.

1. 中华医学会骨科学分会足踝外科学组, 中国医师协会骨科医师分会足踝外科专业委员会. 踇外翻诊疗专家共识. 中国医学前沿杂志 (电子版), 2017, 9(10): 30-42.
2. Hardy RH, Clapham JCR. Observations on hallux valgus. J Bone Joint Surg (Br), 1951, 33(3): 376-391.
3. Buckwalter JA, Einhorn TA, Simon SR. Orthopaedic basic science: biology and biomechanics of the musculoskeletal system. USA: American Academy of Orthopaedic Surgeons, 2000: 873.
4. Büchler P, Ramaniraka NA, Rakotomanana LR, et al. A finite element model of the shoulder: application to the comparison of normal and osteoarthritic joints. Clin Biomech (Bristol, Avon), 2002, 17(9-10): 630-639.
5. Cheung JT, Zhang M, Leung AK, et al. Three-dimensional finite element analysis of the foot during standing—a material sensitivity study. J Biomech, 2005, 38(5): 1045-1054.
6. Maganaris CN. Tensile properties of in vivo human tendinous tissue. J Biomech, 2002, 35(8): 1019-1027.
7. 孙卫东. 中西医结合治疗踇外翻生物力学机制的有限元分析. 北京: 中国中医科学院, 2010.
8. Lewis G, Jonathan V, Kambhampati S. Effect of material property representation on stresses in endoprostheses. Bio-Medical Materials and Engineering, 1998, 8(1): 11-13.
9. Shi K, Hayashida K, Owaki H, et al. Replacement of the first metatarsophalangeal joint with a Swanson implant accompanied by open-wedge osteotomy of the first metatarsal bone for hallux valgus in rheumatoid arthritis. Modern Rheumatology, 2007, 17(2): 110-114.
10. Zhang M, Mak AF. In vivo friction properties of human skin. Prosthet Orthot Int, 1999, 23(2): 135-141.
11. Simkin A, Arcan M, Brull M. A structural model of the human foot. Journal of Biomechanics, 1982. doi:10.1016/0021-9290(85)90730-4.
12. Wang C, He X, Zhang Z, et al. Three-dimensional finite element analysis and biomechanical analysis of midfoot von Mises stress levels in flatfoot, clubfoot, and Lisfranc joint injury. Med Sci Monit, 2021, 27: e931969. doi: 10.12659/MSM.931969.
13. Brilakis EV, Kaselouris E, Markatos K, et al. Mitchell’s osteotomy augmented with bio-absorbable pins for the treatment of hallux valgus: A comparative finite element study. J Musculoskelet Neuronal Interact, 2019, 19(2): 234-244.
14. 毕春强, 温建民, 孙卫东, 等. 静态有限元法分析基于 “裹帘” 法外固定踇外翻术后截骨端的稳定性. 中国组织工程研究, 2016, 20(22): 3294-3300.
15. 李晏乐, 常程, 岳肖华, 等. 踇外翻微创截骨联合 “8” 字绷带外固定的生物力学分析. 中国组织工程研究, 2018, 22(23): 3659-3664.
16. 白子兴, 曹旭含, 孙承颐, 等. 微创治疗踇外翻术后绷带外固定: 有限元分析截骨端稳定性. 中国组织工程研究, 2020, 24(18): 2811-2816.
17. 温建民, 钟红刚, 蒋科卫, 等. 正常足与踇外翻足的足底压力研究. 中华骨科杂志, 1999, 19(6): 346-348.
18. 张致媛. 跖骨远端截骨术治疗踇外翻的X线测量、前足底压力改变及有限元分析. 北京: 北京协和医学院, 2009.
19. Ebina K, Hirao M, Takagi K, et al. Comparison of the effects of forefoot joint-preserving arthroplasty and resection-replacement arthroplasty on walking plantar pressure distribution and patient-based outcomes in patients with rheumatoid arthritis. PLoS One, 2017, 12(8): e0183805. doi: 10.1371/journal.pone.0183805.
20. Clarke GR, Thomas MJ, Rathod-Mistry T, et al. Hallux valgus severity, great toe pain, and plantar pressures during gait: A cross-sectional study of community-dwelling adults. Musculoskeletal Care, 2020, 18(3): 383-390.
21. Zhang Y, Awrejcewicz J, Szymanowska O, et al. Effects of severe hallux valgus on metatarsal stress and the metatarsophalangeal loading during balanced standing: A finite element analysis. Comput Biol Med, 2018, 97: 1-7.
22. Lee H, Ishikawa H, Shibuya T, et al. Changes in radiographic findings and plantar pressure distribution following forefoot reconstructive surgery for patients with rheumatoid arthritis. Mod Rheumatol, 2020, 30(6): 967-974.
23. Filardi V. Hallux valgus (HV): A multi-approach investigation analysis. J Orthop, 2019, 18: 166-170.
24. Hida T, Okuda R, Yasuda T, et al. Comparison of plantar pressure distribution in patients with hallux valgus and healthy matched controls. J Orthop Sci, 2017, 22(6): 1054-1059.
25. Xiang L, Mei Q, Fernandez J, et al. A biomechanical assessment of the acute hallux abduction manipulation intervention. Gait Posture, 2020, 76: 210-217.
26. Guo J, Wang L, Mao R, et al. Biomechanical evaluation of the first ray in pre-/post-operative hallux valgus: A comparative study. Clin Biomech (Bristol, Avon), 2018, 60: 1-8.
27. 陶凯, 王冬梅, 王成焘, 等. 基于三维有限元静态分析的人体足部生物力学研究. 中国生物医学工程学报, 2007, 26(5): 763-766, 780.
28. Xiang L, Mei Q, Fernandez J, et al. Minimalist shoes running intervention can alter the plantar loading distribution and deformation of hallux valgus: A pilot study. Gait Posture, 2018, 65: 65-71.
29. Verdu Roman C, Martinez Gimenez E, Bustamante Suarez de Puga D, et al. Hallux valgus with and without metatarsalgia in women: a matched-cohort study of plantar pressure measurements. Indian J Orthop, 2021, 55(Suppl 2): 436-444.
30. Lee H, Ishikawa H, Miyagawa Y, et al. Plantar pressure and surgical indication of toe arthroplasty for rheumatoid forefoot deformity. Mod Rheumatol, 2017, 27(6): 990-994.
31. Martínez Bocanegra MA, Bayod Lopez J, Vidal-Lesso A, et al. Structural interaction between bone and implants due to arthroplasty of the first metatarsophalangeal joint. Foot Ankle Surg, 2019, 25(2): 150-157.

Chinese Journal of Reparative and Reconstructive Surgery

Three-dimensional finite element analysis of Swanson prosthesis-arthroplasty of the first metatarsophalangeal joint combined with osteotomy and bone grafting of the first metatarsal bone for hallux valgus

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content