5 Advanced bioprinting processes using additive manufacturing technologies: revolutionizing tissue engineering
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Sampath Boopathi
Abstract
Advanced bioprinting processes enable precise deposition of cells, biomaterials, and bioactive agents to fabricate complex three-dimensional structures that mimic native tissues. Key advancements include multimaterial bioprinting, integration of microfluidics and nanotechnology, 4D bioprinting, and scaffold design and optimization techniques. It has revolutionized tissue engineering and regenerative medicine by providing spatial control over cell placement, creating biomimetic architectures, and incorporating bioactive cues. It has also enabled the development of disease models for drug screening, tissue models for studying biological processes, and the potential for organ transplantation. Advanced bioprinting processes have revolutionized tissue engineering and regenerative medicine, offering unprecedented control over tissue fabrication. The future of bioprinting is bright, as it has great potential applications in areas like customized medicine and organ transplantation.
Abstract
Advanced bioprinting processes enable precise deposition of cells, biomaterials, and bioactive agents to fabricate complex three-dimensional structures that mimic native tissues. Key advancements include multimaterial bioprinting, integration of microfluidics and nanotechnology, 4D bioprinting, and scaffold design and optimization techniques. It has revolutionized tissue engineering and regenerative medicine by providing spatial control over cell placement, creating biomimetic architectures, and incorporating bioactive cues. It has also enabled the development of disease models for drug screening, tissue models for studying biological processes, and the potential for organ transplantation. Advanced bioprinting processes have revolutionized tissue engineering and regenerative medicine, offering unprecedented control over tissue fabrication. The future of bioprinting is bright, as it has great potential applications in areas like customized medicine and organ transplantation.
Chapters in this book
- Frontmatter I
- Acknowledgments V
- Preface VII
- Contents XI
- List of contributors XV
- 1 3D-printed antennas 1
- 2 The recent developments in 3D bioprinting: a general bibliometric study and thematic investigation 39
- 3 Additive manufacturing of compositionally complex alloys: trends, challenges, and future perspectives 61
- 4 Adoptability of additive manufacturing process: design perceptive 77
- 5 Advanced bioprinting processes using additive manufacturing technologies: revolutionizing tissue engineering 95
- 6 Comparative analysis of thermal characteristics and optimizing laminar flow within medical-grade 3D printers for fabrication of sterile patientspecific implants (PSIs) using computational fluid dynamics 119
- 7 Review of 4D printing and materials enabling Industry 4.0 for implementation in manufacturing: an Indian context 143
- 8 Processing of smart materials by additive manufacturing and 4D printing 181
- 9 A comprehensive review on effect of DMLS process parameters and post-processing on quality of product in biomedical field 197
- 10 Finite element method investigation on delamination of 3D printed hybrid composites during the drilling operation 223
- 11 Analyzing the dimensional stability in direct ink written composite ink: a machine learning approach 235
- 12 Recent applications of rapid prototyping with 3D printing: a review 245
- 13 3D printing insight: techniques, application, and transformation 259
- 14 Additive manufacturing and 4D printing applications for Industry 4.0-enabled digital biomedical and pharmaceutical sectors 289
- 15 Application of three-dimensional printing in medical, agriculture, engineering, and other sectors 311
- 16 Recent developments in 3D printing: a critical analysis and deep dive into innovative real-world applications 335
- 17 Exploring design strategies for enhanced 3D printing performance 353
- Biographies 371
- Index 375
Chapters in this book
- Frontmatter I
- Acknowledgments V
- Preface VII
- Contents XI
- List of contributors XV
- 1 3D-printed antennas 1
- 2 The recent developments in 3D bioprinting: a general bibliometric study and thematic investigation 39
- 3 Additive manufacturing of compositionally complex alloys: trends, challenges, and future perspectives 61
- 4 Adoptability of additive manufacturing process: design perceptive 77
- 5 Advanced bioprinting processes using additive manufacturing technologies: revolutionizing tissue engineering 95
- 6 Comparative analysis of thermal characteristics and optimizing laminar flow within medical-grade 3D printers for fabrication of sterile patientspecific implants (PSIs) using computational fluid dynamics 119
- 7 Review of 4D printing and materials enabling Industry 4.0 for implementation in manufacturing: an Indian context 143
- 8 Processing of smart materials by additive manufacturing and 4D printing 181
- 9 A comprehensive review on effect of DMLS process parameters and post-processing on quality of product in biomedical field 197
- 10 Finite element method investigation on delamination of 3D printed hybrid composites during the drilling operation 223
- 11 Analyzing the dimensional stability in direct ink written composite ink: a machine learning approach 235
- 12 Recent applications of rapid prototyping with 3D printing: a review 245
- 13 3D printing insight: techniques, application, and transformation 259
- 14 Additive manufacturing and 4D printing applications for Industry 4.0-enabled digital biomedical and pharmaceutical sectors 289
- 15 Application of three-dimensional printing in medical, agriculture, engineering, and other sectors 311
- 16 Recent developments in 3D printing: a critical analysis and deep dive into innovative real-world applications 335
- 17 Exploring design strategies for enhanced 3D printing performance 353
- Biographies 371
- Index 375
