Additive manufacturing of metallic biomaterials: a concise review

Mahajan, Anupama; Singh, Gurmeet; Devgan, Sandeep

doi:10.1007/s43452-023-00730-7

Cited by 9 publications

(3 citation statements)

References 97 publications

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“…By leveraging specialized techniques such as lithography, etching, deposition, and self-assembly, micro-nano-scale fabrication enables the development of miniaturized systems with unique properties and functionalities. These systems find applications in a wide range of fields, including electronics, photonics, biotechnology, medicine, energy, and environmental sciences [221][222][223][224]. With the ability to manipulate matter at the smallest scales, micro-nano-scale fabrication opens new frontiers for scientific research, technological advancements, and the creation of innovative devices that push the limits of what is possible at the micro and nano level [225,226].…”

Section: Micro-nano-scale Fabricationmentioning

confidence: 99%

Recent Inventions in Additive Manufacturing: Holistic Review

Fidan,

Huseynov,

Ali

et al. 2023

Inventions

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This general review paper presents a condensed view of recent inventions in the Additive Manufacturing (AM) field. It outlines factors affecting the development and commercialization of inventions via research collaboration and discusses breakthroughs in materials and AM technologies and their integration with emerging technologies. The paper explores the impact of AM across various sectors, including the aerospace, automotive, healthcare, food, and construction industries, since the 1970s. It also addresses challenges and future directions, such as hybrid manufacturing and bio-printing, along with socio-economic and environmental implications. This collaborative study provides a concise understanding of the latest inventions in AM, offering valuable insights for researchers, practitioners, and decision makers in diverse industries and institutions.

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Section: Micro-nano-scale Fabricationmentioning

confidence: 99%

Recent Inventions in Additive Manufacturing: Holistic Review

Fidan,

Huseynov,

Ali

et al. 2023

Inventions

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show abstract

“…However, the prevailing number of studies related to ET is aimed at reducing their wear or compensating for modification. It is possible to single out the main directions of modification: selection of new nontraditional materials [17,103,137,138], processing or coating [17,97,98,[139][140][141], creation of non-traditional geometric shapes [49,137,[142][143][144], using modern methods of additive manufacturing [145][146][147][148], creation of original structures [146,148], etc.…”

Section: Experimental Datamentioning

confidence: 99%

Recent Trends and Developments in the Electrical Discharge Machining Industry: A Review

Kamenskikh,

Muratov,

Shlykov

et al. 2023

JMMP

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Electrical discharge machining (EDM) is a highly precise technology that not only facilitates the machining of components into desired shapes but also enables the alteration of the physical and chemical properties of workpieces. The complexity of the process is due to a number of regulating factors such as the material of the workpiece and tools, dielectric medium, and other process parameters. Based on the material type, electrode shape, and process configuration, various shapes and degrees of accuracy can be generated. The study of erosion is based on research into processing techniques, which are the primary tools for using EDM. Empirical knowledge with subsequent optimization of technological parameters is one of the ways to obtain the required surface quality of the workpiece with defect minimization, as well as mathematical and numerical modeling of the EDM process. This article critically examines all key aspects of EDM, reflecting both the early foundations of electrical erosion and the current state of the industry, noting the current trends towards the transition of EDM to the 5.0 industry zone in terms of safety and minimizing the impact of the process on the environment.

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“…While there have been several studies on the topic, there are still some critical comments and shortcomings that need to be addressed. For instance, some studies have focused on the corrosion and wear behavior of specific alloys [34,35], while others have provided a brief overview of the processes of wear generation and corrosion [36][37][38]. However, there is a need for more comprehensive studies that investigate the effects of different factors such as the manufacturing process, surface finish, and environmental conditions on the corrosion and wear behavior of additively manufactured metal parts in biomedical applications.…”

Section: Introductionmentioning

confidence: 99%

Corrosion and Wear Behavior of Additively Manufactured Metallic Parts in Biomedical Applications

Wei,

Attarilar,

Ebrahimi

et al. 2024

Metals

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Today, parts made by additive manufacturing (AM) methods have found many applications in the medical industry, the main reasons for which are the ability to custom design and manufacture complex structures, their short production cycle, their ease of utilization, and on-site fabrication, leading to the fabrication of next-generation intricate patient-specific biomedical implants. These parts should fulfill numerous requirements, such as having acceptable mechanical strength, biocompatibility, satisfactory surface characteristics, and excellent corrosion and wear performance. It was known that AM techniques may lead to some uncertainties influencing part properties and causing significant evaluation conflicts in corrosion outcomes. Meanwhile, the corrosion and wear behavior of additively manufactured materials are not comprehensively discussed. In this regard, the present work is a review of the state-of-the-art knowledge dedicated to reviewing the actual scientific knowledge about the corrosion and wear response of additively manufactured biomedical components, elucidating the relevant mechanism and influential factors to enhance the performance of AM-manufactured implants specifically for the physiological human body fluids. Furthermore, there is a focus on the use of reinforced composites, surface engineering, and a preparation stage that can considerably affect the tribocorrosion behavior of AM-produced parts. The improvement of tribocorrosion performance can have a key role in the production of advanced AM implants and the present study can pave the way toward facile production of high-throughput AM biomedical parts that have very high resistance to corrosion and wear.

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Additive manufacturing of metallic biomaterials: a concise review

Cited by 9 publications

References 97 publications

Recent Inventions in Additive Manufacturing: Holistic Review

Recent Inventions in Additive Manufacturing: Holistic Review

Recent Trends and Developments in the Electrical Discharge Machining Industry: A Review

Corrosion and Wear Behavior of Additively Manufactured Metallic Parts in Biomedical Applications

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