vetmaster小动物髋关节置换培训招新啦

vetmaster小动物陶瓷双动髋关节置换培训，10月末（上海）和10月末（广州）班，还有少量名额。如有需要参加的兽医朋友快加客服微信了解报名。

Vetmaster客服联系方式

Vetmaster髋关节置换系统做了大量基础和临床研究工作，保证了系统的可靠性和科学性。这里为大家简单介绍一下。

Vetmaster小动物双动髋的优势：

1 Vetmaster使用自主研发的黑晶陶瓷球头的小动物双动髋关节系统，使用SLM加工多孔结构商品化小动物髋关节植入物，在其他商品化的髋关节系统中未见报道

3 进口内衬，高端关节领域专用。符合ISO5834, part 2, type 1

4 使用过盈配合快速固定，防止术后松动。

5 双动髋有低并发症优势，更适合活跃的小动物

植入物介绍：Vetmester小动物髋关节置换系统(Total Hip Replacement, THR)由张君副教授团队发明，并与科学院联合开发的。通过数年基础研究和临床试验的更新迭代，能够最大程度满足医师手术严格的要求，该系统由拥有卓越品质的进口医用植入物材料制备，并由符合医用植入物生产的德国3D打印设备制造。

股骨柄假体（钛合金多孔结构）：

1 范围广：型号范围1-13号

2 骨长入：股骨近段为多孔骨长入结构

3 强度高：德国医用级钛合金制作

4 性能优：生物相容性和材料安全性满足要求

5 多选择：搭配多型号（长度与直径）的股骨颈

6 多场景：可灵活应用于不同体型的小动物

双动髋臼杯 （钛合金多孔结构）：

10mm-32mm，适合猫和小型犬到大型犬的几乎所有体型

通过过盈配合达到早期稳定

钛合金多孔结构快速骨长入

组配股骨颈假体

5种规格，每种规格5个长度，灵活运用。

骨诱导3D打印多孔结构，并不是随便拍个脑袋拿个打印机就能做出来：

3D打印一体化构筑的植入物多孔结构，具有特定的三维结构、孔隙率和孔径，可有效诱导成骨细胞短期内增殖与分化。经过数年的基础研究（理化物理性能及生物性能），Vetmaster成功研制出最适合小动物髋关节置换的植入物系统，系统表面具有骨诱导3D打印多孔结构，为实现植入物系统术后快速骨长入提供了物理条件。

多孔结构强度应力分析

3D打印植入物系统中多孔结构直接承受骨组织载荷，对所制备的多孔结构进行破坏性测试及分析，经过基础试验与生物试验研究，弹性模量与松质骨一致且其机械性远高于皮质骨。

临床研究：

通过大量临床试验（试验过程符合GLP管理，且具有CNAS认证），术后CT检查和病理检查，Vetmaster所开发的3D打印小动物髋关节置换系统显示出卓越的骨长入性能。

多中心临床试验：

经过多中心临床研究，统计获取临床数据，并不断优化手术方式，更新迭代手术工具和植入物，精益求精。

摩擦学研究：

摩擦界面具有高硬度低摩擦系数和耐磨损性能。经过100万次对磨后，COF保持0.1，且摩擦面粗糙度为2.87微米，展示出卓越的耐磨性能。

双动髋防脱结构：

通过各种基础试验保证机械强度前提下，双动髋能实现最大跳跃脱位距离和最大髋关节活动范围（ROM）。

骨柄荷载及验证：

采用荷载及循环加载试验和有限元模拟，对3D打印骨柄的机械性能进行评估，3D打印骨柄具有足够的机械安全性能够承受植入犬体内后的循环载荷。

威马系统相关内容，研发过程中已发表的高水平SCI收录论文如下：

1、Yan X, Yin S, Chen C, et al. Effect of heat treatment on the phase transformation and mechanical properties of Ti6Al4V fabricated by selective laser melting[J]. Journal of Alloys and Compounds, 2018, 764: 1056-1071.

2、Yan X, Li Q, Yin S, et al. Mechanical and in vitro study of an isotropic Ti6Al4V lattice structure fabricated using selective laser melting[J]. Journal of Alloys and Compounds, 2019, 782: 209-223.

3、Yan X, Yin S, Chen C, et al. Fatigue strength improvement of selective laser melted Ti6Al4V using ultrasonic surface mechanical attrition[J]. Materials Research Letters, 2019, 7(8): 327-333.

4、Chen Z, Yan X, Yin S, et al. Influence of the pore size and porosity of selective laser melted Ti6Al4V ELI porous scaffold on cell proliferation, osteogenesis and bone ingrowth[J]. Materials Science and Engineering: C, 2020, 106: 110289.

5、Chen Z, Yan X, Chang Y, et al. Effect of polarization voltage on the surface componentization and biocompatibility of micro-arc oxidation modified selective laser melted Ti6Al4V[J]. Materials Research Express, 2019, 6(8): 086425.

6、Yan X, Lupoi R, Wu H, et al. Effect of hot isostatic pressing (HIP) treatment on the compressive properties of Ti6Al4V lattice structure fabricated by selective laser melting[J]. Materials Letters, 2019, 255: 126537.

7、Zhang X Y, Yan X C, Fang G, et al. Biomechanical influence of structural variation strategies on functionally graded scaffolds constructed with triply periodic minimal surface[J]. Additive Manufacturing, 2020, 32: 101015.

8、Yan X, Chen C, Bolot R, et al. Improvement of tribological performance by micro-arc oxidation treatment on selective laser melting Ti6Al4V alloy[J]. Materials Research Express, 2019, 6(9): 096509.

9、Yan X, Shi C, Liu T, et al. Effect of heat treatment on the corrosion resistance behavior of selective laser melted Ti6Al4V ELI[J]. Surface and Coatings Technology, 2020: 125955.

威马系统研发过程中额外参考文献如下：

《小动物全关节置换进展》，主译1，审稿，张君 副教授

白璧辉, 谢兴文, 徐世红, et al. 2018. 3D打印辅助复杂髋关节置换术附1例报道. 中国医学工程 [J], v.26: 41-44.

陈世柱 2019. 3D打印技术在成人DDH人工全髋关节置换术中的应用效果. 临床医学研究与实践 [J], 4: 15-16.

兰天, 史占军, 陈国奋, et al. 2012. 金属对聚乙烯与陶瓷对聚乙烯人工髋关节负重界面的抗磨损性能比较. 中国组织工程研究 [J], 016: P.6498-6502.

孙久一 2014. Large-diameter ceramic head articulation against highly cross-linked polyethylene in young patients:2-year wear rate%使用大直径陶瓷头全髋关节年轻患者高交联聚乙烯的2年磨损率. 中国组织工程研究 [J], 000: 5595-5599.

王涛, 张育民, 王军伟, et al. 2017. 3D打印技术对复杂全髋关节置换术前计划指导的初步研究. 美中国际创伤杂志 [J]: 20.

姚海峰, 王贵强, 黄坚, et al. 2009. 犬全髋置换临床试验8例报道.中国畜牧兽医学会小动物医学分会第四次学术研讨会暨中国畜牧兽医学会兽医外科学分会第十六次学术研讨会.

余方新, 谢佑卿, 李小波, et al. 2004. 金属钒,铌,钽的电子结构和物理性质. 稀有金属 [J]: 921-925.

余新林, 陈庆泉, 王万明 股骨偏心距在髋关节置换术中的影响. 中国医药指南 [J]: 24-26.

袁占奎, 陈宏武, 董悦农, et al. 2006. 犬股骨头和股骨颈切除术. 中国兽医杂志 [J].

张国强, 王岩, 陈继营, et al. 2010. 陶瓷对聚乙烯和金属对聚乙烯在全髋关节置换术后磨损的随访研究. 中华关节外科杂志(电子版) [J]: 11-15.

周金, 刘炯, 杨砥, et al. 2017. 3D打印技术辅助成人DDH初次THA的髋臼置入. 中国矫形外科杂志 [J], v.25;No.433: 2182-2186.

AGINS H J, ALCOCK N W, BANSAL M, et al. 1998. Metallic wear in failed titanium-alloy hip replacements. The Journal of Bone and Joint Surgery [J], 70: 347-356.

ANDREONI A A, GUERRERO T G, HURTER K, et al. 2010. Revision of an unstable HELICA endoprosthesis with a Zurich cementless total hip replacement. Vet Comp Orthop Traumatol [J], 23: 177-181.

BAL B S, RAHAMAN M N 2012. Orthopedic applications of silicon nitride ceramics. Acta Biomaterialia [J], 8: 2889-2898.

BALLAND B, GLACHANT A 1999. Chapter 1 Silica, silicon nitride and oxynitride thin films: An overview of fabrication techniques, properties and applications [M] //G. BARBOTTIN, A. VAPAILLE, Instabilities in Silicon Devices. North-Holland: 3-144.

BASTIR M, ROSAS A, O’HIGGINS P 2006. Craniofacial levels and the morphological maturation of the human skull. J Anat [J], 209: 637-654.

BELLAMY N, CAMPBELL J, WELCH V, et al. 2006. Viscosupplementation for the treatment of osteoarthritis of the knee. Cochrane Database of Systematic Reviews [J].

BERGH M S, S. G R, S. S F, et al. Complications and radiographic findings following cemented total hip replacement. Veterinary & Comparative Orthopaedics & Traumatology V.c.o.t [J], 19: 172-179.

BUKS Y, WENDELBURG K L, STOVER S M, et al. 2016. The Effects of Interlocking a Universal Hip Cementless Stem on Implant Subsidence and Mechanical Properties of Cadaveric Canine Femora. Veterinary Surgery [J], 45: 155-164.

CHEN P Q, TURNER T M, RONNIGEN H, et al.1983. A Canine Cementless Total Hip Prosthesis Model. Clinical Orthopaedics & Related Research [J], &NA;: 24???33.

CHEN S, CHEN C, LIANG X, et al. 2019. Effect of cellulose additive on the silicon carbide film by decomposition and conversion of silicon nitride. Ceramics International [J].

CHEN Z, YAN X, YIN S, et al. 2020. Influence of the pore size and porosity of selective laser melted Ti6Al4V ELI porous scaffold on cell proliferation, osteogenesis and bone ingrowth. Materials Science and Engineering: C [J], 106: 110289.

CHRISTIAN R, KOLJA B C, FLORIAN D, et al. 2018. Femoral stem subsidence in cementless total hip arthroplasty: a retrospective single-centre study. International Orthopaedics [J].

CROSSE K R, WORTH A J 2010. Computer-assisted surgical correction of an antebrachial deformity in a dog. Veterinary & Comparative Orthopaedics & Traumatology V.c.o.t [J], 23: 354-361.

D'ANGELO F, MURENA L, ZATTI G, et al. 2008. The unstable total hip replacement. Indian Journal of Orthopaedics [J], 42: 252-259.

DE OLIVEIRA B J S, CAMPANELLI L C, OLIVEIRA D P, et al. 2017. Surface characterization and fatigue performance of a chemical-etched Ti-6Al-4V femoral stem for cementless hip arthroplasty. Surface and Coatings Technology [J], 309: 1126-1134.

DELIKANLI Y E, KAYACAN M C 2019. Design, manufacture, and fatigue analysis of lightweight hip implants. J Appl Biomater Funct Mater [J], 17: 2280800019836830.

DENIS, J., MARCELLIN-LITTLE, et al. 2004. Canine Uncemented Porous-Coated Anatomic Total Hip Arthroplasty: Results of a Long-Term Prospective Evaluation of 50 Consecutive Cases.

DEYOUNG D J, DEYOUNG B A, ABERMAN H A, et al.1992 Implantation of an Uncemented Total Hip Prosthesis Technique and Initial Results of 100 Arthroplasties. Veterinary Surgery [J], 21: 168-177.

DOWD J E, SCHWENDEMAN L J, MACAULAY W, et al. 1995Aseptic Loosening in Uncemented Total Hip Arthroplasty in a Canine Model. Clin Orthop Relat Res [J], &NA;: 106???121.

DUTTA B, FROES F H 2017. The Additive Manufacturing (AM) of titanium alloys. Metal Powder Report [J], 72: 96-106.

DYCE J, WISNER E R, QIANG W, et al. 2000. Evaluation of Risk Factors for Luxation After Total Hip Replacement in Dogs. Veterinary Surgery Vs [J], 29: 524-532.

EDWARDS M R, EGGER E L, SCHWARZ P D 1997. Aseptic loosening of the femoral implant after cemented total hip arthroplasty in dogs: 11 cases in 10 dogs (1991-1995). 211: 580.

EMMELMANN C, SCHEINEMANN P, MUNSCH M, et al. 2011. Laser Additive Manufacturing of Modified Implant Surfaces with Osseointegrative Characteristics. Physics Procedia [J], 12: 375-384.

FAGUNDES A P, DA SILVA A F V, MACUVELE D L P, et al. 2019. Ultra-High-Molecular-Weight polyethylene-based nanocomposite for removal of tetracycline in aqueous systems. Journal of Environmental Chemical Engineering [J]: 103630.

FAN H, FU J, LI X, et al. 2015a. Implantation of customized 3-D printed titanium prosthesis in limb salvage surgery: a case series and review of the literature. World J Surg Oncol [J], 13: 308.

FAN H, FU J, LI X, et al. 2015b. Implantation of customized 3-D printed titanium prosthesis in limb salvage surgery: a case series and review of the literature. World J Surg Oncol [J], 13: 308.

FAN H, GUO Z, FU J, et al. 2017. Surgical management of pelvic Ewing's sarcoma in children and adolescents. Oncol Lett [J], 14: 3917-3926.

FITZPATRICK N, SMITH T J, PENDEGRASS C J, et al. 2011. Intraosseous Transcutaneous Amputation Prosthesis (ITAP) for Limb Salvage in 4 Dogs. Veterinary Surgery [J], 40: 909-925.

GEBHARDT A, SCHMIDT F-M, H TTER J-S, et al. 2010. Additive Manufacturing by selective laser melting the realizer desktop machine and its application for the dental industry. Physics Procedia [J], 5: 543-549.

GINJA M, GONZALO-ORDEN J M, JESUS S S, et al. 2007.Measurement of the femoral neck anteversion angle in the dog using computed tomography. Veterinary Journal [J], 174: 378-383.

GITELIS S, CHEN P-Q, ANDERSON G B J, et al.1982. The Influence of Early Weight-bearing on Experimental Total Hip Arthroplasties in Dogs. Clinical Orthopaedics & Related Research [J], &NA;: 291???302.

GOLDRING S R 1983. The synovial-like membrane at the bone-cement interface in loose total hip replacements and its proposed role in bone lysis. Journal of Bone & Joint Surgery American Volume [J], 65.

GONG H, RAFI K, STARR T, et al. Effect of defects on fatigue tests of as-built Ti-6Al-4V parts fabricated by selective laser melting [C] //; City.

GORMAN H A 1957. A new prosthetic hip joint; experiences in its use in the dog, and its probable application to man. Military Medicine [J], 121: 91-93.

GU D, HAGEDORN Y-C, MEINERS W, et al. 2012. Densification behavior, microstructure evolution, and wear performance of selective laser melting processed commercially pure titanium. Acta Materialia [J], 60: 3849-3860.

GUERRERO T G, MONTAVON P M 2009. Zurich Cementless Total Hip Replacement: Retrospective Evaluation of 2nd Generation Implants in 60 Dogs. Veterinary Surgery [J], 38: 70-80.

GUILLAUMOT P, A. A, S. P, et al. 2012. Dual mobility canine total hip prosthesis: Implant characteristics and surgical procedure. Veterinary & Comparative Orthopaedics & Traumatology [J], 25: 506-510.

GUO W-M, YU J-J, XIONG M, et al. 2016. High-toughness Lu2O3-doped Si3N4 ceramics by seeding. Ceramics International [J], 42: 6495-6499.

HADI A, VIGNAT F, VILLENEUVE F 2015. Design configurations and creation of lattice structures for metallic additive manufacturing [C] //; City.

HAEFELI M, SCHAEFER D, SCHUMACHER R, et al. 2015. Titanium template for scaphoid reconstruction. Journal of Hand Surgery (European Volume) [J], 40: 526-533.

HALL R M, BANKES M J K, BLUNN G 2001. Biotribology for joint replacement. 15: 281-290.

HAN J, YANG J, YU H, et al. 2017. Microstructure and mechanical property of selective laser melted Ti6Al4V dependence on laser energy density. Rapid Prototyping Journal [J], 23: 217-226.

HARRYSSON O L A, CANSIZOGLU O, MARCELLIN-LITTLE D J, et al. 2008. Direct metal fabrication of titanium implants with tailored materials and mechanical properties using electron beam melting technology. Materials Science & Engineering C [J], 28: 366-373.

HOEFLE W D 1974. A Surgical procedure for prosthetic total hip replacement in the dog. Journal of the American Animal Hospital Association [J], 10: 269-276.

HUMMEL D W, LANZ O I, WERRE S R Complications of cementless total hip replacement. Vet Comp Orthop Traumatol [J], 23: 424-432.

IVEKOVIĆ A, OMIDVARI N, VRANCKEN B, et al. 2018. Selective laser melting of tungsten and tungsten alloys. International Journal of Refractory Metals and Hard Materials [J], 72: 27-32.

KOSASHVILI Y, BACKSTEIN D, SAFIR O, et al. 2009. Acetabular revision using an anti-protrusion (ilio-ischial) cage and trabecular metal acetabular component for severe acetabular bone loss associated with pelvic discontinuity. The Journal of Bone and Joint Surgery. British volume [J], 91-B: 870-876.

KOUTSOUKIS T, ZINELIS S, ELIADES G, et al. 2015a. Selective Laser Melting Technique of Co-Cr Dental Alloys: A Review of Structure and Properties and Comparative Analysis with Other Available Techniques. J Prosthodont [J], 24: 303-312.

KOUTSOUKIS T, ZINELIS S, ELIADES G, et al. 2015b. Selective laser melting technique of Co‐Cr dental alloys: a review of structure and properties and comparative analysis with other available techniques. Journal of Prosthodontics [J], 24: 303-312.

KRUTH J-P, VANDENBROUCKE B, VAN VAERENBERGH J, et al. 2005. Digital manufacturing of biocompatible metal frameworks for complex dental prostheses by means of SLS/SLM. Proc. VRAP, Leiria [J]: 139-146.

LEE J M J, SALVATI E A E, BETTS F F, et al. 1992. Size of metallic and polyethylene debris particles in failed cemented total hip replacements. 74: 380.

LEIGHTON R L 1979. The Richards II canine total hip prosthesis. Journal of the American Animal Hospital Association [J], 15: 73-76.

LEWIS R H, JONES JR. J P 1980. A Clinical Study of Canine Total Hip Arthroplasty. Veterinary Surgery [J], 9: 20-23.

LI G, WANG L, PAN W, et al. 2016. In vitro and in vivo study of additive manufactured porous Ti6Al4V scaffolds for repairing bone defects. Sci Rep [J], 6: 34072.

LI S J, XU Q S, WANG Z, et al. 2014. Influence of cell shape on mechanical properties of Ti-6Al-4V meshes fabricated by electron beam melting method. Acta Biomater [J], 10: 4537-4547.

LISKA W D, DOYLE N D 2015. Use of an Electron Beam Melting Manufactured Titanium Collared Cementless Femoral Stem to Resist Subsidence After Canine Total Hip Replacement. Veterinary Surgery [J], 44: 883-894.

LIU M, WU L, ZHANG F, et al. 2016. Influence of molecular weight of modified ultrahigh-molecular-weight polyethylene with Cu(II) chelate of bissalicylaldehydeethylenediamine on wear-resistant materials. Friction [J], 4: 116-123.

LUKIANOVA O A, PARKHOMENKO A A, KRASILNIKOV V V, et al. 2019. New method of free silicon determination in pressureless sintered silicon nitride by Raman spectroscopy and XRD. Ceramics International [J], 45: 14338-14346.

MARCELLIN-LITTLE D J, DEYOUNG D J, THRALL D E, et al. 1999. Osteosarcoma at the Site of Bone Infarction Associated with Total Hip Arthroplasty in a Dog. Veterinary Surgery Vs [J], 28: 54-60.

MASSAT B J, VASSEUR P B 1994. Clinical and radiographic results of total hip arthroplasty in dogs: 96 cases (1986-1992). 205: 448-454.

MATTEI L, DI PUCCIO F, CIULLI E, et al. 2020. Experimental investigation on wear map evolution of ceramic-on-UHMWPE hip prosthesis. Tribology International [J], 143: 106068.

MEL NDEZ-MARTı́NEZ J J, DOMı́NGUEZ-RODRı́GUEZ A 2004. Creep of silicon nitride. Progress in Materials Science [J], 49: 19-107.

MONTAVON P M, HOHN R B, OLMSTEAD M L, et al. 1985. Inclination and Anteversion Angles of the Femoral Head and Neck in the Dog Evaluation of a Standard Method of Measurement. Veterinary Surgery [J], 14: 277-282.

MURR L E, AMATO K N, LI S J, et al. 2011. Microstructure and mechanical properties of open-cellular biomaterials prototypes for total knee replacement implants fabricated by electron beam melting. J Mech Behav Biomed Mater [J], 4: 1396-1411.

MURR L E, QUINONES S A, GAYTAN S M, et al. 2009. Microstructure and mechanical behavior of Ti-6Al-4V produced by rapid-layer manufacturing, for biomedical applications. J Mech Behav Biomed Mater [J], 2: 20-32.

NATARAJAN M V, SAMEER M M, BOSE J C, et al. 2010. Surgical management of pelvic Ewing’s sarcoma. Indian journal of orthopaedics [J], 44: 397.

NISHIMURA T, XU X, KIMOTO K, et al. 2007. Fabrication of silicon nitride nanoceramics—Powder preparation and sintering: A review. Sci Technol Adv Mater [J], 8: 635-643.

OLMSTEAD M L 1983. A five year study of 221 total hip replacements in dog. J Am Vet Med Assoc [J], 183.

OLMSTEAD M L 1987. Total hip replacement in the dog. Semin Vet Med Surg [J], 2: 131-140.

OLMSTEAD M L 1995. The canine cemented modular total hip prosthesis. Journal of the American Animal Hospital Association [J], 31: 109-124.

OVIDIU G M, MIRELA T-T, RADU P, et al. 2010. Influence of the Lattice Structures on the Mechanical Behavior of Hip Endoprostheses. 6-11.

PARK S-J, SEO M-K 2011. Chapter 6 - Element and Processing [M] //S.-J. PARK, M.-K. SEO, Interface Science and Technology. Elsevier: 431-499.

PARTHASARATHY J 2014. 3D modeling, custom implants and its future perspectives in craniofacial surgery. Ann Maxillofac Surg [J], 4: 9.

PARTHASARATHY J, STARLY B, RAMAN S, et al. 2010. Mechanical evaluation of porous titanium (Ti6Al4V) structures with electron beam melting (EBM). J Mech Behav Biomed Mater [J], 3: 249-259.

PATTERSON A E, MESSIMER S L, FARRINGTON P A 2017. Overhanging Features and the SLM/DMLS Residual Stresses Problem: Review and Future Research Need. Technologies [J], 5: 15.

PAUL H A, BARGAR W L, MITTLESTADT B, et al. Development of a Surgical Robot for Cementless Total Hip Arthroplasty. Clin Orthop Relat Res [J], &NA;: 57???66.

PEKEDIS M, YILDIZ H 2011. Comparison of fatigue behaviour of eight different hip stems: a numerical and experimental study. Journal of Biomedical Science and Engineering [J], 04: 643-650.

PLOEG H-L, B RGI M, WYSS U P 2009. Hip stem fatigue test prediction. International Journal of Fatigue [J], 31: 894-905.

POBLOTH A-M, CHECA S, RAZI H, et al. 2018. Mechanobiologically optimized 3D titanium-mesh scaffolds enhance bone regeneration in critical segmental defects in sheep. Science Translational Medicine [J], 10: eaam8828.

POPRAWE R, HINKE C, MEINERS W, et al. 2015. SLM production systems: recent developments in process development, machine concepts and component design. Advances in Production Technology [J]: 49-65.

PRESTON C A, SCHULZ K S, VASSEUR P B 1999. Total Hip Arthroplasty in Nine Canine Hind Limb Amputees: A Retrospective Study. Veterinary Surgery [J], 28.

QIN X, LI S, ZHAO L, et al. 2020. Silicon nitride ceramics consolidated by oscillatory pressure sintering. Ceramics International [J].

QIU C, ADKINS N J E, ATTALLAH M M 2013. Microstructure and tensile properties of selectively laser-melted and of HIPed laser-melted Ti–6Al–4V. Materials Science and Engineering: A [J], 578: 230-239.

ROE S C, DEYOUNG D D, WEINSTOCK D, et al. 1996. Osteosarcoma Eight Years After Total Hip Arthroplasty. Veterinary Surgery [J], 25: 70-74.

RUDERT M, HOLZAPFEL B, PILGE H, et al. 2012. Partial pelvic resection (internal hemipelvectomy) and endoprosthetic replacement in periacetabular tumors. Oper Orthop Traumatol [J], 24: 196-214.

SEBESTYEN P, MARCELLIN‐LITTLE D J, DEYOUNG B A 2000. Femoral Medullary Infarction Secondary to Canine Total Hip Arthroplasty. Veterinary Surgery [J], 29.

SIMONELLI M, TSE Y Y, TUCK C 2014. On the Texture Formation of Selective Laser Melted Ti-6Al-4V. Metallurgical and Materials Transactions A [J], 45: 2863-2872.

SKURLA C P, PLUHAR G E, FRANKEL D J, et al. 2005. Assessing the dog as a model for human total hip replacement. Analysis of 38 canine cemented femoral components retrieved at post-mortem. 73B: 260–270.

SONG C, YANG Y, WANG Y, et al. 2014. Research on rapid manufacturing of CoCrMo alloy femoral component based on selective laser melting. The International Journal of Advanced Manufacturing Technology [J], 75: 445-453.

SUARD M, LHUISSIER P, DENDIEVEL R, et al. 2014. Towards stiffness prediction of cellular structures made by electron beam melting (EBM). Powder Metallurgy [J], 57: 190-195.

THIJS L, VERHAEGHE F, CRAEGHS T, et al. 2010. A study of the microstructural evolution during selective laser melting of Ti–6Al–4V. Acta Materialia [J], 58: 3303-3312.

TOWNSEND S, KIM S E, POZZI A 2017. Effect of stem sizing and position on short-term complications with canine press fit cementless total hip arthroplasty. Veterinary Surgery [J].

UHLMANN E, KERSTING R, KLEIN T B, et al. 2015. Additive Manufacturing of Titanium Alloy for Aircraft Components. Procedia CIRP [J], 35: 55-60.

VEZZONI L, BAZZO S, VEZZONI A 2016. Revision of a BFX total hip replacement stem using a Kyon stem and a head adaptor in two dogs. Vet Comp Orthop Traumatol [J], 30: 81-87.

VILARO T, COLIN C, BARTOUT J D 2011. As-Fabricated and Heat-Treated Microstructures of the Ti-6Al-4V Alloy Processed by Selective Laser Melting. Metallurgical and Materials Transactions A [J], 42: 3190-3199.

WANG L, QI Q, ZHANG H, et al. 2019. High tough W-added silicon nitride ceramics. Ceramics International [J], 45: 19055-19059.

WANG M, WU Y, LU S, et al. 2016. Fabrication and characterization of selective laser melting printed Ti–6Al–4V alloys subjected to heat treatment for customized implants design. Progress in Natural Science: Materials International [J], 26: 671-677.

XIANG L, CHENGTAO W, WENGUANG Z, et al. 2010. Fabrication and compressive properties of Ti6Al4V implant with honeycomb‐like structure for biomedical applications. Rapid Prototyping Journal [J], 16: 44-49.

YU J-J, GUO W-M, WEI W-X, et al. 2018. Fabrication and wear behaviors of graded Si3N4 ceramics by the combination of two-step sintering and β-Si3N4 seeds. Journal of the European Ceramic Society [J], 38: 3457-3462.

YU J-J, WEI W-X, GUO W-M, et al. 2019. Enhanced mechanical properties of Si3N4 ceramics with ZrB2-B binary additives prepared at low temperature. Journal of the European Ceramic Society [J], 39: 5102-5105.

ZERBST U, MADIA M, KLINGER C, et al. 2019. Defects as a root cause of fatigue failure of metallic components. III: Cavities, dents, corrosion pits, scratches. Engineering Failure Analysis [J], 97: 759-776.

ZHANG B, HUANG Q, GAO Y, et al. 2012. Preliminary study on some properties of Co-Cr dental alloy formed by selective laser melting technique. Journal of Wuhan University of Technology-Mater. Sci. Ed. [J], 27: 665-668.

ZHANG X-Y, FANG G, LEEFLANG S, et al. 2018. Effect of subtransus heat treatment on the microstructure and mechanical properties of additively manufactured Ti-6Al-4V alloy. Journal of Alloys and Compounds [J], 735: 1562-1575.

ZHOU Y, GUO W, LI T 2019. A review on transition metal nitrides as electrode materials for supercapacitors. Ceramics International [J], 45: 21062-21076.

上述试验背景和文字材料，由张君副教授和华南农业大学兽医学院临床系博士及科学院研究所教授团队以及法国与爱尔兰合作实验室博士提供，并保证上述研究材料真实性、严谨性与科学性。