Additive Manufacturing of Bio-Implants Design and Synthesis

Mahajan, Amit Devgan, Sandeep Zitoune Redouane
Heftet / 2025 / Engelsk

Produktdetaljer

ISBN
9789819969685
Publisert
2025-03-11
Utgiver
Vendor
Springer Verlag, Singapore
Høyde
235 mm
Bredde
155 mm
Aldersnivå
Research, P, 06
Språk
Product language
Engelsk
Format
Product format
Heftet

Redaktør
Mahajan, Amit
Devgan, Sandeep
Zitoune Redouane

Biographical note

Dr. Amit Mahajan is Associate Professor at Khalsa College of Engineering & Technology, Amritsar, India. His research interests include additive manufacturing, surface modification of biomaterials, and electrical discharge machining. In his Ph.D., he profitably fabricated the nano-structured bio-favorable coatings on metallic biomaterials using powder mixed electrical discharge machining technique. His research aimed to design the carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) mixed coatings on β-type titanium alloy. He investigated the biological responses in terms of hydrophobicity and hydrophilicity tribological properties, corrosion inertness, bioactivity, etc. Currently, he works on the fabrication of alloys with proper fraction composition of carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) via additive manufacturing. He has contributed 23 research papers and chapters to leading international journals, books, and conferences. He also serves as Reviewer for several national and international journals of repute. 

Dr. Sandeep Devgan is Associate Professor at Khalsa College of Engineering & Technology, Amritsar, India. His research interests include CNTs-based nanotechnology, surface modification of biomaterials, and powder-mixed electrical discharge machining. In his Ph.D., he profitably fabricated the nano-structured bio-favorable coatings on the metallic biomaterials using powder mixed electrical discharge machining technique. His research was aimed to design the carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) mixed coatings on β-type titanium alloy. He investigated the biological responses in terms of hydrophobicity and hydrophilicity tribological properties, corrosion inertness, bioactivity, etc. Currently, he works on alloy fabrication with the proper fraction composition of carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) via additive manufacturing. He has contributed 22 research papers and chapters to leading international journals, books, and conferences.

Dr. Redouane Zitoune is Full Professor in Mechanical Engineering at Clement Ader Institute (ICA UMR 5312) of Paul Sabatier University (Toulouse, France) and heads the composite research group since 2020. His research activities focus on the manufacturing and machining of aerospace materials. His current research interests include damage analysis during the manufacturing of composite materials. He is also interested in the thermal analysis of composite structures using numerical and experimental approaches with different techniques of instrumentation, such as optical fibers, infrared cameras, etc. He has published more than 160 technical papers in national and international journals and conferences. In the area of machining of composite materials, he has organized the first national conference and served as Guest Editor of several referenced international journals and Co-editor of three books.

Additive Manufacturing of Bio-Implants Design and Synthesis

Mahajan, Amit Devgan, Sandeep Zitoune Redouane
Heftet / 2025 / Engelsk
Mahajan, Amit Devgan, Sandeep Zitoune Redouane
Heftet / 2025 / Engelsk
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This contributed volume presents the latest research on additive manufacturing (AM) or 3D printing, one of the key techniques of novel medical devices, which can process complicated or customized structures to match the properties of human tissues. AM allows for the fabrication of devices with optimal architectures, complicated morphologies, surface integrity, and regulated porosity and chemical composition. Various AM methods can now consistently fabricate dense products for a variety of materials, comprising steels, titanium alloys, Co-Cr alloys, metal-based composites, and nanocomposites. This book elucidates the chronology of various techniques that are categorized under additive manufacturing. Moreover, the futuristic techniques or advancements in this area are also described. The available literature focuses on the microstructure and various properties of 3D-printed alloys. However, the research on the wear characteristics, corrosion resistance, and biocompatibility of 3D-printed technology for biomedical applications is limited. This book comprises the helicopter view of different surface analysis trends of additive manufactured alloys. The book can be a valuable reference for beginners, researchers, and professionals interested in bioimplant manufacturing and allied fields.
Les mer
This contributed volume presents the latest research on additive manufacturing (AM) or 3D printing, one of the key techniques of novel medical devices, which can process complicated or customized structures to match the properties of human tissues.
Les mer
Chapter 1: Challenges in Additive Manufacturing: Influence of Process Parameters on Induced Physical Properties of Printed Parts.- Chapter 2: Additive Manufacturing Incorporated Carbon Nanotubes (CNTs); Advances in biomedical domain.- Chapter 3: Formation, testing, and deposition of bioactive material using thermal spray additive manufacturing technique.- Chapter 4: Controlled Oxide Deposition Improves Mechanical and Biomedical Applications of Titanium Alloy.- Chapter 5: Instrumentation and Monitoring of Additive Manufacturing Processes for the Biomedical Applications.- Chapter 6: A Concise Study on Tribological Properties of Additive Manufactured Biomaterials.- Chapter 7: Role and Scope of OEE to Improve Additive Manufacturing Processes in Bio-Medical Industries.- Chapter 8: Corrosion Performance of Additively Manufactured Metallic Biomaterials: A Review.- Chapter 9: Emerging Functionally Graded Materials for Bio-Implant Applications- Design and Manufacturing.- Chapter 10: Biomechanical Evaluation of Load Transfer and Stability in a Corrugated Hip Stem: A Comparative Analysis.- Chapter 11: Applications of 3D Printing in Medical, Engineering, Agricultural and Other Sectors.
Les mer
This contributed volume presents the latest research on additive manufacturing (AM) or 3D printing, one of the key techniques of novel medical devices, which can process complicated or customized structures to match the properties of human tissues. AM allows for the fabrication of devices with optimal architectures, complicated morphologies, surface integrity, and regulated porosity and chemical composition. Various AM methods can now consistently fabricate dense products for a variety of materials, comprising steels, titanium alloys, Co-Cr alloys, metal-based composites, and nanocomposites. This book elucidates the chronology of various techniques that are categorized under additive manufacturing. Moreover, the futuristic techniques or advancements in this area are also described. The available literature focuses on the microstructure and various properties of 3D-printed alloys. However, the research on the wear characteristics, corrosion resistance, and biocompatibility of 3D-printed technology for biomedical applications is limited. This book comprises the helicopter view of different surface analysis trends of additive manufactured alloys. The book can be a valuable reference for beginners, researchers, and professionals interested in bioimplant manufacturing and allied fields.
Les mer
Elucidates the futuristic techniques for fabrication of bioimplantsInvestigates mechanical and tribological properties of the additive manufactured different bioimplantsDiscusses biocompatibility and wettability characteristics of additive manufactured biomedical alloys
Les mer

Relaterte produkter

This contributed volume presents the latest research on additive manufacturing (AM) or 3D printing, one of the key techniques of novel medical devices, which can process complicated or customized structures to match the properties of human tissues. AM allows for the fabrication of devices with optimal architectures, complicated morphologies, surface integrity, and regulated porosity and chemical composition. Various AM methods can now consistently fabricate dense products for a variety of materials, comprising steels, titanium alloys, Co-Cr alloys, metal-based composites, and nanocomposites. This book elucidates the chronology of various techniques that are categorized under additive manufacturing. Moreover, the futuristic techniques or advancements in this area are also described. The available literature focuses on the microstructure and various properties of 3D-printed alloys. However, the research on the wear characteristics, corrosion resistance, and biocompatibility of 3D-printed technology for biomedical applications is limited. This book comprises the helicopter view of different surface analysis trends of additive manufactured alloys. The book can be a valuable reference for beginners, researchers, and professionals interested in bioimplant manufacturing and allied fields.
Les mer
This contributed volume presents the latest research on additive manufacturing (AM) or 3D printing, one of the key techniques of novel medical devices, which can process complicated or customized structures to match the properties of human tissues.
Les mer
Chapter 1: Challenges in Additive Manufacturing: Influence of Process Parameters on Induced Physical Properties of Printed Parts.- Chapter 2: Additive Manufacturing Incorporated Carbon Nanotubes (CNTs); Advances in biomedical domain.- Chapter 3: Formation, testing, and deposition of bioactive material using thermal spray additive manufacturing technique.- Chapter 4: Controlled Oxide Deposition Improves Mechanical and Biomedical Applications of Titanium Alloy.- Chapter 5: Instrumentation and Monitoring of Additive Manufacturing Processes for the Biomedical Applications.- Chapter 6: A Concise Study on Tribological Properties of Additive Manufactured Biomaterials.- Chapter 7: Role and Scope of OEE to Improve Additive Manufacturing Processes in Bio-Medical Industries.- Chapter 8: Corrosion Performance of Additively Manufactured Metallic Biomaterials: A Review.- Chapter 9: Emerging Functionally Graded Materials for Bio-Implant Applications- Design and Manufacturing.- Chapter 10: Biomechanical Evaluation of Load Transfer and Stability in a Corrugated Hip Stem: A Comparative Analysis.- Chapter 11: Applications of 3D Printing in Medical, Engineering, Agricultural and Other Sectors.
Les mer
This contributed volume presents the latest research on additive manufacturing (AM) or 3D printing, one of the key techniques of novel medical devices, which can process complicated or customized structures to match the properties of human tissues. AM allows for the fabrication of devices with optimal architectures, complicated morphologies, surface integrity, and regulated porosity and chemical composition. Various AM methods can now consistently fabricate dense products for a variety of materials, comprising steels, titanium alloys, Co-Cr alloys, metal-based composites, and nanocomposites. This book elucidates the chronology of various techniques that are categorized under additive manufacturing. Moreover, the futuristic techniques or advancements in this area are also described. The available literature focuses on the microstructure and various properties of 3D-printed alloys. However, the research on the wear characteristics, corrosion resistance, and biocompatibility of 3D-printed technology for biomedical applications is limited. This book comprises the helicopter view of different surface analysis trends of additive manufactured alloys. The book can be a valuable reference for beginners, researchers, and professionals interested in bioimplant manufacturing and allied fields.
Les mer
Elucidates the futuristic techniques for fabrication of bioimplantsInvestigates mechanical and tribological properties of the additive manufactured different bioimplantsDiscusses biocompatibility and wettability characteristics of additive manufactured biomedical alloys
Les mer

Produktdetaljer

ISBN
9789819969685
Publisert
2025-03-11
Utgiver
Vendor
Springer Verlag, Singapore
Høyde
235 mm
Bredde
155 mm
Aldersnivå
Research, P, 06
Språk
Product language
Engelsk
Format
Product format
Heftet

Redaktør
Mahajan, Amit
Devgan, Sandeep
Zitoune Redouane

Biographical note

Dr. Amit Mahajan is Associate Professor at Khalsa College of Engineering & Technology, Amritsar, India. His research interests include additive manufacturing, surface modification of biomaterials, and electrical discharge machining. In his Ph.D., he profitably fabricated the nano-structured bio-favorable coatings on metallic biomaterials using powder mixed electrical discharge machining technique. His research aimed to design the carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) mixed coatings on β-type titanium alloy. He investigated the biological responses in terms of hydrophobicity and hydrophilicity tribological properties, corrosion inertness, bioactivity, etc. Currently, he works on the fabrication of alloys with proper fraction composition of carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) via additive manufacturing. He has contributed 23 research papers and chapters to leading international journals, books, and conferences. He also serves as Reviewer for several national and international journals of repute. 

Dr. Sandeep Devgan is Associate Professor at Khalsa College of Engineering & Technology, Amritsar, India. His research interests include CNTs-based nanotechnology, surface modification of biomaterials, and powder-mixed electrical discharge machining. In his Ph.D., he profitably fabricated the nano-structured bio-favorable coatings on the metallic biomaterials using powder mixed electrical discharge machining technique. His research was aimed to design the carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) mixed coatings on β-type titanium alloy. He investigated the biological responses in terms of hydrophobicity and hydrophilicity tribological properties, corrosion inertness, bioactivity, etc. Currently, he works on alloy fabrication with the proper fraction composition of carbon nanotubes (CNTs) and μ-hydroxyapatite (μHAp) via additive manufacturing. He has contributed 22 research papers and chapters to leading international journals, books, and conferences.

Dr. Redouane Zitoune is Full Professor in Mechanical Engineering at Clement Ader Institute (ICA UMR 5312) of Paul Sabatier University (Toulouse, France) and heads the composite research group since 2020. His research activities focus on the manufacturing and machining of aerospace materials. His current research interests include damage analysis during the manufacturing of composite materials. He is also interested in the thermal analysis of composite structures using numerical and experimental approaches with different techniques of instrumentation, such as optical fibers, infrared cameras, etc. He has published more than 160 technical papers in national and international journals and conferences. In the area of machining of composite materials, he has organized the first national conference and served as Guest Editor of several referenced international journals and Co-editor of three books.

Relaterte produkter