Alphonsa Joseph, and , Vijayalakshmi Uthirapathy*,
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Metals, polymers, biocrystals, composites, and bio-HEA materials are used for implant fabrication for various applications. A wide variety of polymer implants are fabricated using additive manufacturing for nonload-bearing applications, and β-tricalcium phosphate, hydroxyapatite, bioactive glass, etc. are mainly used as ceramic materials in additive manufacturing due to the biological properties that could be imparted by the latter. For decades metals have played a major role in implant fabrication, and additive manufacturing of metals provides an easy approach to implant fabrication with augmented qualities. Various challenges and setbacks faced in the fabrication need postprocessing such as sintering, coating, surface polishing, etc. The emergence of bio-HEA materials, printing of shape memory implants, and five-dimensional printing are the trends of the era in additive manufacturing.</p>","PeriodicalId":3,"journal":{"name":"ACS Applied Electronic Materials","volume":null,"pages":null},"PeriodicalIF":4.3000,"publicationDate":"2024-10-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://pubs.acs.org/doi/epdf/10.1021/acsomega.4c04870","citationCount":"0","resultStr":"{\"title\":\"A Systematic Review of the Contribution of Additive Manufacturing toward Orthopedic Applications\",\"authors\":\"Alphonsa Joseph, and , Vijayalakshmi Uthirapathy*, \",\"doi\":\"10.1021/acsomega.4c0487010.1021/acsomega.4c04870\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p >Human bone holds an inherent capacity for repairing itself from trauma and damage, but concerning the severity of the defect, the choice of implant placement is a must. 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For decades metals have played a major role in implant fabrication, and additive manufacturing of metals provides an easy approach to implant fabrication with augmented qualities. 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引用次数: 0
摘要
人体骨骼本身具有从创伤和损伤中自我修复的能力,但根据缺损的严重程度,选择植入物的位置是必须的。与多年来使用的传统方法相比,快速成型技术具有多种规格,例如可根据患者的具体情况定制开发植入物,而且易于制造,因此已成为一种精英选择。增材制造允许定制孔隙大小、孔隙率、各种机械性能以及复杂的结构设计和配方。选择性激光熔融、粉末床熔融、电子束熔融和熔融沉积建模是广泛用于植入物制造的各种快速成型方法。金属、聚合物、生物晶体、复合材料和生物高分子材料被广泛应用于植入物的制造。在非承重应用中,可使用增材制造法制造各种聚合物植入体;β-磷酸三钙、羟基磷灰石、生物活性玻璃等主要用作增材制造法中的陶瓷材料,因为后者可赋予其生物特性。几十年来,金属在植入物制造中一直扮演着重要角色,而金属的增材制造则为植入物制造提供了一种简便的方法,并可提高植入物的质量。制造过程中面临的各种挑战和挫折需要后处理,如烧结、涂层、表面抛光等。生物 HEA 材料、形状记忆植入体打印和五维打印的出现是增材制造的时代趋势。
A Systematic Review of the Contribution of Additive Manufacturing toward Orthopedic Applications
Human bone holds an inherent capacity for repairing itself from trauma and damage, but concerning the severity of the defect, the choice of implant placement is a must. Additive manufacturing has become an elite option due to its various specifications such as patient-specific custom development of implants and its easy fabrication rather than the conventional methods used over the years. Additive manufacturing allows customization of the pore size, porosity, various mechanical properties, and complex structure design and formulation. Selective laser melting, powder bed fusion, electron beam melting, and fused deposition modeling are the various AM methods used extensively for implant fabrication. Metals, polymers, biocrystals, composites, and bio-HEA materials are used for implant fabrication for various applications. A wide variety of polymer implants are fabricated using additive manufacturing for nonload-bearing applications, and β-tricalcium phosphate, hydroxyapatite, bioactive glass, etc. are mainly used as ceramic materials in additive manufacturing due to the biological properties that could be imparted by the latter. For decades metals have played a major role in implant fabrication, and additive manufacturing of metals provides an easy approach to implant fabrication with augmented qualities. Various challenges and setbacks faced in the fabrication need postprocessing such as sintering, coating, surface polishing, etc. The emergence of bio-HEA materials, printing of shape memory implants, and five-dimensional printing are the trends of the era in additive manufacturing.