Tissue Engineering Using Ceramics and Polymers

Tissue Engineering Using Ceramics and Polymers, Third Edition is a comprehensive reference tool for academic researchers and scientists involved in biomaterials or tissue engineering, covering the latest research and advances in this area, including nanobiomaterials, drug delivery, advanced imaging, and MRI.

Format: Paperback / softback
Length: 888 pages
Publication date: 28 October 2021
Publisher: Elsevier Science Publishing Co Inc

Tissue Engineering Using Ceramics and Polymers, Third Edition serves as an invaluable resource for academic researchers and scientists engaged in the fields of biomaterials and tissue engineering, encompassing areas such as bone and soft-tissue reconstruction, repair, and organ regeneration. This comprehensive book, edited by renowned experts and comprising a diverse international team of contributors, delves into the latest research and advancements in this rapidly evolving domain, exploring how they can be applied to develop effective treatments for various disease states. In addition to reviewing cutting-edge developments, the book includes new sections that cover crucial topics such as nanobiomaterials, drug delivery systems, advanced imaging techniques, and MRI for tissue engineering. Furthermore, it provides in-depth characterization of vascularized scaffolds, which are essential components in tissue regeneration processes. The field of tissue engineering has witnessed a remarkable surge in technological and research advancements in recent years, reaching a point where the potential exists to regenerate almost every tissue and organ in the human body through the use of biomaterials. This transformative progress has opened up new avenues for medical treatments and therapies, offering hope to individuals suffering from various diseases and conditions. The use of ceramics and polymers in tissue engineering has played a pivotal role in these developments, providing materials with unique properties that can enhance tissue growth, repair, and regeneration. Ceramics, known for their high strength, durability, and biocompatibility, have been utilized in various applications, including bone implants, dental prostheses, and tissue scaffolds. Polymers, on the other hand, offer flexibility, adaptability, and biodegradability, making them suitable for applications such as drug delivery systems, tissue mimics, and cell culture substrates. By combining the strengths of ceramics and polymers, tissue engineers can create innovative solutions that address the complex challenges faced in tissue regeneration. One of the key areas of focus in tissue engineering is the development of biomaterials that mimic the natural properties of tissues. This involves designing materials that possess the appropriate mechanical, biological, and chemical properties to promote tissue growth, differentiation, and integration. Ceramics and polymers are particularly well-suited for this purpose, as they can be tailored to exhibit specific properties that are essential for tissue regeneration. For instance, ceramics can be designed to have a porous structure that allows for the infiltration of cells and nutrients, while polymers can be modified to have specific chemical properties that promote cell adhesion and proliferation. Another important area of research in tissue engineering is the development of drug delivery systems that can effectively deliver therapeutic agents to target tissues. Ceramics and polymers are particularly useful in this context, as they can be modified to have specific properties that enhance drug release and stability. For example, ceramics can be coated with drug-releasing polymers, while polymers can be designed to have a slow release rate that allows for sustained drug delivery over an extended period. In addition to their use in tissue engineering, ceramics and polymers have also been explored for other applications, such as biomedical devices, electronics, and energy storage. For instance, ceramics have been used in the development of medical implants, such as hip and knee replacements, while polymers have been used in the production of flexible electronic devices and energy-storage materials. Overall, the integration of ceramics and polymers in tissue engineering has opened up new possibilities for medical treatments and therapies. By leveraging the unique properties of these materials, tissue engineers can create innovative solutions that address the complex challenges faced in tissue regeneration and improve the quality of life for individuals with various diseases and conditions. As the field of tissue engineering continues to evolve, it is likely that we will see further advancements in the development of biomaterials, drug delivery systems, and advanced imaging techniques, leading to even more effective and personalized treatments for patients.
Tissue engineering is a rapidly advancing field that involves the use of ceramics and polymers to create artificial tissues and organs. This third edition of Tissue Engineering Using Ceramics and Polymers is a valuable resource for both academic researchers and scientists involved in biomaterials and tissue engineering, including the areas of bone and soft-tissue reconstruction, repair, and organ regeneration. With its distinguished editors and international team of contributors, this book reviews the latest research and advances in this thriving area and how they can be used to develop treatments for disease states.

New sections cover nanobiomaterials, drug delivery, advanced imaging and MRI for tissue engineering, and characterization of vascularized scaffolds.

Technology and research in the field of tissue engineering have drastically increased within the last few years to the extent that almost every tissue and organ of the human body could potentially be regenerated with the aid of biomaterials.

The use of ceramics and polymers in tissue engineering has played a pivotal role in these developments, providing materials with unique properties that can enhance tissue growth, repair, and regeneration. Ceramics, known for their high strength, durability, and biocompatibility, have been utilized in various applications, including bone implants, dental prostheses, and tissue scaffolds. Polymers, on the other hand, offer flexibility, adaptability, and biodegradability, making them suitable for applications such as drug delivery systems, tissue mimics, and cell culture substrates. By combining the strengths of ceramics and polymers, tissue engineers can create innovative solutions that address the complex challenges faced in tissue regeneration.

One of the key areas of focus in tissue engineering is the development of biomaterials that mimic the natural properties of tissues. This involves designing materials that possess the appropriate mechanical, biological, and chemical properties to promote tissue growth, differentiation, and integration. Ceramics and polymers are particularly well-suited for this purpose, as they can be tailored to exhibit specific properties that are essential for tissue regeneration. For instance, ceramics can be designed to have a porous structure that allows for the infiltration of cells and nutrients, while polymers can be modified to have specific chemical properties that promote cell adhesion and proliferation. Another important area of research in tissue engineering is the development of drug delivery systems that can effectively deliver therapeutic agents to target tissues. Ceramics and polymers are particularly useful in this context, as they can be modified to have specific properties that enhance drug release and stability. For example, ceramics can be coated with drug-releasing polymers, while polymers can be designed to have a slow release rate that allows for sustained drug delivery over an extended period.

In addition to their use in tissue engineering, ceramics and polymers have also been explored for other applications, such as biomedical devices, electronics, and energy storage. For instance, ceramics have been used in the development of medical implants, such as hip and knee replacements, while polymers have been used in the production of flexible electronic devices and energy-storage materials.

Overall, the integration of ceramics and polymers in tissue engineering has opened up new possibilities for medical treatments and therapies. By leveraging the unique properties of these materials, tissue engineers can create innovative solutions that address the complex challenges faced in tissue regeneration and improve the quality of life for individuals with various diseases and conditions.

As the field of tissue engineering continues to evolve, it is likely that we will see further advancements in the development of biomaterials, drug delivery systems, and advanced imaging techniques, leading to even more effective and personalized treatments for patients.

Weight: 1000g
Dimension: 229 x 152 (mm)
ISBN-13: 9780128205082
Edition number: 3 ed