A useful collection of information, not readily available in a concentrated and convenient form on the market
Provides a comprehensive overview of the field
This is the 3rd volume in a series of reviews centered on the single major topic of bone replacement, discussing the biology of stem cells and cell signals, the knowledge needed to make stem cell-engineered bone tissue a reality, and how to prevent bone allograft infection. Useful as a followup to its predecessors, and as a stand-alone reference, it will interest a broad audience from orthopedists and bioengineers to dentists.
|The science of bone replacement has greatly advanced in recent decades, but replacing bone with bone tissue rather than with metallic components remains in early development. The current volume, third in the series Topics in Bone Biology, deals with problems inherent in inducing the body cells to accomplish bone tissue repair, to degrade devices introduced to provide initial mechanical support, and to attract and stimulate bone f- mation. It is therefore logical that Chapter 1, by Hicok and Hedrick, deals with stem cells, i. e. , pluripotential cells that may differentiate into cartilage and bone cells. The chapter begins with a deillegalscription of how stem cells may be harvested; the limitations of autologous, embryonic, and adult stem cells; and the need to expand the harvested cells in culture. The authors then discuss the in? uences of the body environment on implanted cells and on the scaffolds that need to be introduced. They emphasize the need for adequate oxygenation and for rapid integration with the vascular system of the host/patient. Stem-cell-engineered cartilage is discussed at some length, along with the need for stem-cell-engineered ligaments and tendons. The chapter concludes with an analysis of what needs to be learned to make stem-cell-engineered bone tissue a reality. In Chapter 2, Gerstenfeld and colleagues review osteogenic growth factors and cytokines, soluble proteins that regulate postnatal bone repair. These molecules are of importance because many are targets of efforts to promote therapeutic bone healing and repair.
Stem Cells and the Art of Mesenchymal Maintenance.- Osteogenic Growth Factors and Cytokines and Their Role in Bone Repair.- Bone Allograft Safety and Performance.- Biodegradable Orthopedic Implants.- Titanium Fiber Mesh: A Nondegradable Scaffold Material.- Engineering Polymeric Scaffolds for Bone Grafts.- Injectable Scaffolds for Bone and Cartilage Regeneration.- Motion and Bone Regeneration.- Dental Applications of Bone Biology.- Multiscale Computational Engineering of Bones: State-of-the-Art Insights for the Future.
This volume, the third in the series Topics in Bone Biology, discusses current knowledge of bone replacement. It is designed to integrate biological and engineering knowledge.
The biology of stem cells and cell signals, knowledge needed to make stem cell engineered bone tissue a reality and how to prevent bone allograft infection is discussed. In addition, non-degradable and biodegradable scaffolds, necessary implants to attract bone cells and to build suitable bone replacements follows. Other topics include motion and bone degeneration analysis and how mechanical factors affect bone healing, implants and how they have become a major tool in reparative dentistry and the application of computational modeling to prosthesis design.
Written by acknowledged authorities in their fields, this volume, like the others in the series, has extensive lists of references, many illustrations and tables. The book is of interest to bioengineers, orthopedists, reconstructive surgeons, dentists, physiotherapists and all who work in the fields of skeletal and dental tissue engineering and rehabilitation, as well as basic bone scientists interested in translational research.
This is the 3rd volume in a series of reviews centered on the single major topic of bone replacement, discussing the biology of stem cells and cell signals, the knowledge needed to make stem cell-engineered bone tissue a reality, and how to prevent bone allograft infection. Useful as a followup to its predecessors, and as a stand-alone reference, it will interest a broad audience from orthopedists and bioengineers to dentists.
Stem cells and the art of mesenchymal maintenance.- Osteogenic growth factors and cytokines and their role in bone repair.- Bone allograft safety and performance.- Biodegradable orthopaedic implants.- Titanium fiber mesh, a non-degradable scaffold material.- Engineering polymeric scaffolds for bone grafts.- Injectable scaffolds for bone and cartilage regeneration.- Motion and bone regeneration.- Dental applications of bone biology.- Multi-scale computational engineering of bones: State of the art insights for the future.
Inhaltsverzeichnis
Stem Cells and the Art of Mesenchymal Maintenance.- Osteogenic Growth Factors and Cytokines and Their Role in Bone Repair.- Bone Allograft Safety and Performance.- Biodegradable Orthopedic Implants.- Titanium Fiber Mesh: A Nondegradable Scaffold Material.- Engineering Polymeric Scaffolds for Bone Grafts.- Injectable Scaffolds for Bone and Cartilage Regeneration.- Motion and Bone Regeneration.- Dental Applications of Bone Biology.- Multiscale Computational Engineering of Bones: State-of-the-Art Insights for the Future.
Klappentext
This is the 3rd volume in a series of reviews centered on the single major topic of bone replacement, discussing the biology of stem cells and cell signals, the knowledge needed to make stem cell-engineered bone tissue a reality, and how to prevent bone allograft infection. Useful as a followup to its predecessors, and as a stand-alone reference, it will interest a broad audience from orthopedists and bioengineers to dentists.
A useful collection of information, not readily available in a concentrated and convenient form on the market
Provides a comprehensive overview of the field
Includes supplementary material: sn.pub/extras
