J Shanghai Jiaotong Univ Sci ›› 2021, Vol. 26 ›› Issue (3): 361-367.doi: 10.1007/s12204-021-2305-5
Design and Application of 3D Printing Based Personalised Pelvic Prostheses
WU Junxianga (吴钧翔), LUO Dinghaoa (罗丁豪), XIE Kaia (谢凯), WANG Leia (王磊), HAO Yongqianga,b (郝永强)
- (a. Department of Orthopaedic Surgery; b. Medical 3D Printing Innovation Research Center for Technology,
Shanghai Ninth People’s Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai 200011, China)
-
出版日期:2021-06-28发布日期:2021-06-02 -
通讯作者:HAO Yongqiang(郝永强) E-mail:hyq 9hospital@hotmail.com -
基金资助:the National Key Research and Development
Program of China (No. 2016YFC1100600), the
Multicenter Clinical Research Project of Shanghai Jiao
Tong University School of Medicine (No. DLY201506),
the National Natural Science Foundation of China
(Nos. 81972058, and 81902194), and the Multidisciplinary
Team Clinical Research Project of Shanghai
Ninth People’s Hospital (No. 201701003)
Design and Application of 3D Printing Based Personalised Pelvic Prostheses
WU Junxianga (吴钧翔), LUO Dinghaoa (罗丁豪), XIE Kaia (谢凯), WANG Leia (王磊), HAO Yongqianga,b (郝永强)
- (a. Department of Orthopaedic Surgery; b. Medical 3D Printing Innovation Research Center for Technology,
Shanghai Ninth People’s Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai 200011, China)
-
Online:2021-06-28Published:2021-06-02 -
Contact:HAO Yongqiang(郝永强) E-mail:hyq 9hospital@hotmail.com -
Supported by:the National Key Research and Development
Program of China (No. 2016YFC1100600), the
Multicenter Clinical Research Project of Shanghai Jiao
Tong University School of Medicine (No. DLY201506),
the National Natural Science Foundation of China
(Nos. 81972058, and 81902194), and the Multidisciplinary
Team Clinical Research Project of Shanghai
Ninth People’s Hospital (No. 201701003)
摘要: In this paper, we describe the design and
surgical process of personalised pelvic prostheses fixation through 3D
printing according to different Enneking pelvic tumour zones: the ilium (Zone
I), acetabulum (Zone II), and pubis and ischium (Zone III). A 3D model of
the pelvis was reconstructed using imaging data, and the parameters on
the planes of the acetabulum and pelvic incisal margin were measured. The main
body of the pelvic prosthesis was constructed, a porous structure was
designed on the bone-prosthesis interface, and the movement paths,
lengths, and diameters of screws were planned. By combining the pathological
model and osteotomy guide, limb salvage reconstruction was performed in patients
with pelvic tumours. Preoperative and postoperative data were compared
to verify the prosthesis stability. Our investigation revealed that the
long-term survival of pelvic reconstruction prostheses depends on accurate matching
with the bone defect area, good initial stability, and a porous
structure to allow bone ingrowth.
中图分类号:
引用本文
WU Junxiang (吴钧翔), LUO Dinghao(罗丁豪), XIE Kai (谢凯), WANG Lei (王磊), HAO Yongqiang (郝永强). Design and Application of 3D Printing Based Personalised Pelvic Prostheses[J]. J Shanghai Jiaotong Univ Sci, 2021, 26(3): 361-367.
WU Junxiang (吴钧翔), LUO Dinghao(罗丁豪), XIE Kai (谢凯), WANG Lei (王磊), HAO Yongqiang (郝永强). Design and Application of 3D Printing Based Personalised Pelvic Prostheses[J]. J Shanghai Jiaotong Univ Sci, 2021, 26(3): 361-367.
| [1] | |
| FR¨OHLICH B, H¨OTZINGER H, FRITSCH H. Tomographical anatomy of the pelvis, | |
| pelvic floor, and related structures [J]. Clinical Anatomy, 1997, 10(4): 223-230. | |
| [2] | |
| YASKO A W, RUTLEDGE J, LEWIS V O, et al. Disease- and recurrence-free survival | |
| after surgical resection of solitary bone metastases of the pelvis [J]. Clinical | |
| Orthopaedics and Related Research, 2007, 459: 128-132. | |
| [3] | |
| ENNEKING W F, DUNHAM W K. Resection and reconstruction for primary neoplasms | |
| involving the innominate bone [J]. The Journal of Bone and Joint Surgery - | |
| American Volume, 1978, 60(6): 731-746. | |
| [4] | |
| FARFALLI G L, ALBERGO J I, RITACCO L E, et al. Oncologic and clinical outcomes | |
| in pelvic primary bone sarcomas treated with limb salvage surgery [J]. Musculoskeletal | |
| Surgery, 2015, 99(3): 237-242. | |
| [5] | |
| FUCHS B, O’CONNOR M I, KAUFMAN K R, et al. Iliofemoral arthrodesis and | |
| pseudarthrosis: A longterm functional outcome evaluation [J]. Clinical | |
| Orthopaedics and Related Research, 2002 (397): 29-35. | |
| [6] | BELL |
| R S, DAVIS A M, WUNDER J S, et al. Allograft reconstruction of the acetabulum | |
| after resection of stage-IIB sarcoma [J]. The Journal of Bone and Joint Surgery | |
| - American Volume, 1997, 79(11): 1663-1674. | |
| [7] | JEON |
| D G, KIM M S, CHO W H, et al. Reconstruction with pasteurized autograft-total | |
| hip prosthesis composite for periacetabular tumors [J]. Journal of Surgical | |
| Oncology, 2007, 96(6): 493-502. | |
| [8] | |
| AYVAZ M, BEKMEZ S, MERMERKAYA M U, et al. Long-term results of reconstruction | |
| with pelvic allografts after wide resection of pelvic sarcomas [J]. The Scientific | |
| World Journal, 2014, 2014: 605019. | |
| [9] | |
| WILSON R J, FREEMAN T H, HALPERN J L, et al. Surgical outcomes after | |
| limb-sparing resection and reconstruction for pelvic sarcoma: A systematic | |
| review [J]. JBJS Reviews, 2018, 6(4): e10. | |
| [10] | |
| ABOULAFIA A J, BUCH R, MATHEWS J, et al. Reconstruction using the saddle | |
| prosthesis following excision of primary and metastatic periacetabular tumors [J]. | |
| Clinical Orthopaedics and Related Research, 1995 (314): 203-213. | |
| [11] | BUS |
| M P, BOERHOUT E J, BRAMER J A, et al. Clinical outcome of pedestal cup | |
| endoprosthetic reconstruction after resection of a peri-acetabular tumour [J]. | |
| The Bone & Joint Journal, 2014, 96-B(12): 1706- 1712. | |
| [12] | GUO |
| W, LI D, TANG X, et al. Reconstruction with modular hemipelvic prostheses for | |
| periacetabular tumor [J]. Clinical Orthopaedics and Related Research, 2007, | |
| 46 | 1: 180-188. [13] DAI K R, YAN M N, ZHU Z N, et al. Computer-aided custom-made |
| hemipelvic prosthesis used in extensive pelvic lesions [J]. The Journal of | |
| Arthroplasty, 2007, 22(7): 981-986. | |
| [14] | LIU |
| D X, HUA Z K, YAN X Y, et al. Design and biomechanical study of a novel | |
| adjustable hemipelvic prosthesis [J]. Medical Engineering & Physics, 2016, 38(12): | |
| 14 | 16-1425. |
| [15] | |
| WANG B C, HAO Y Q, PU F F, et al. Computeraided designed, three | |
| dimensional-printed hemipelvic prosthesis for peri-acetabular malignant bone | |
| tumour [J]. International Orthopaedics, 2018, 42(3): 687-694. | |
| [16] | JI |
| T, YANG Y, TANG X D, et al. 3D-printed modular hemipelvic endoprosthetic | |
| reconstruction following periacetabular tumor resection: Early results of 80 consecutive | |
| cases [J]. The Journal of Bone and Joint Surgery - American Volume, 2020, | |
| 10 | 2(17): 1530- 1541. |
| [17] | |
| WANG J, MIN L, LU M, et al. Three-dimensionalprinted custom-made hemipelvic | |
| endoprosthesis for primary malignancies involving acetabulum: The design solution | |
| and surgical techniques [J]. Journal of Orthopaedic Surgery and Research, 2019, | |
| 14 | (1): 389. |
| [18] | |
| MCKIBBIN B. Anatomical factors in the stability of the hip joint in the newborn | |
| [J] | The Journal of Bone and Joint Surgery - British Volume, 1970, 52(1): 148- 159. |
| [19] | |
| MURTHA P E, HAFEZ M A, JARAMAZ B, et al. Variations in acetabular anatomy with | |
| reference to total hip replacement [J]. The Journal of Bone and Joint Surgery - | |
| British Volume, 2008, 90(3): 308-313. | |
| [20] | |
| HIGGINS S W, SPRATLEY E M, BOE R A, et al. A novel approach for determining | |
| three-dimensional acetabular orientation: Results from two hundred subjects [J]. | |
| The Journal of Bone and Joint Surgery - American Volume, 2014, 96(21): | |
| 17 | 76-1784. |
| [21] | LI G, WANG L, PAN W, et al. In vitro and in |
| vivo study of additive manufactured porous Ti6Al4V scaffolds for repairing bone | |
| defects [J]. Scientific Reports, 2016, 6: 34072. |
| No related articles found! |
| 阅读次数 | ||||||
|
全文 |
|
|||||
|
摘要 |
|
|||||