Vertebrates
著者
書誌事項
Vertebrates
(Biologically-inspired systems / series editor Stanislav N. Gorb, v. 4 . Biological materials of marine origin)
Springer, c2015
- : hbk
大学図書館所蔵 全1件
  青森
  岩手
  宮城
  秋田
  山形
  福島
  茨城
  栃木
  群馬
  埼玉
  千葉
  東京
  神奈川
  新潟
  富山
  石川
  福井
  山梨
  長野
  岐阜
  静岡
  愛知
  三重
  滋賀
  京都
  大阪
  兵庫
  奈良
  和歌山
  鳥取
  島根
  岡山
  広島
  山口
  徳島
  香川
  愛媛
  高知
  福岡
  佐賀
  長崎
  熊本
  大分
  宮崎
  鹿児島
  沖縄
  韓国
  中国
  タイ
  イギリス
  ドイツ
  スイス
  フランス
  ベルギー
  オランダ
  スウェーデン
  ノルウェー
  アメリカ
注記
Includes bibliographical references and index
内容説明・目次
内容説明
This is the second monograph by the author on biological materials of marine origin. The initial book is dedicated to the biological materials of marine invertebrates. This work is a source of modern knowledge on biomineralization, biomimetics and materials science with respect to marine vertebrates. For the first time in scientific literature the author gives the most coherent analysis of the nature, origin and evolution of biocomposites and biopolymers isolated from and observed in the broad variety of marine vertebrate organisms (fish, reptilian, birds and mammals) and within their unique hierarchically organized structural formations. There is a wealth of new and newly synthesized information, including dozens of previously unpublished images of unique marine creatures including extinct, extant and living taxa and their biocomposite-based structures from nano- to micro - and macroscale. This monograph reviews the most relevant advances in the marine biological materials research field, pointing out several approaches being introduced and explored by distinct modern laboratories.
目次
Introduction
Species Richness and Diversity of Marine Vertebrates
Part I: Biomaterials of Vertebrates Origin. An Overview
Conclusion
References
Part II: Biomineralization in Marine Vertebrates
2. Cartilage of marine vertebrates
2.1. From non-mineralized to mineralized cartilage
2.1.1. Marine cartilage: Biomechanics and Material Properties
2.1.2. Marine cartilage: Tissue Engineering
2.1.3. Shark cartilage: Medical Aspect
2.1.4. Conclusion
References
3. Biocomposites and Mineralized Tissues
3.1. Bone
3.1.1. Whale Bone: Size, Chemistry And Material Properties
3.1.2. Whale Bone Haus
3.1.3. Conclusion
References
3.3. Tooth
3.3.1. Tooth-Like Structures
3.3.2. Keratinized Teeth
3.3.3. Rostral Teeth
3.3.4. Pharyngeal Denticles And Teeth
3.3.5. Extra-Oral And Extra-Mandibular Teeth
3.3.6. Vertebrate Oral Teeth
3.3.6.1. Folded Teeth
3.3.6.2. Hypermineralized Tooth Plates
3.3.6.3. Shark Teeth
3.3.6.4. Whale Teeth
3.3.6.5. Narwhal Tusk
3.3.6.6. Walrus Tusk
3.3.7. Conclusion
References
3.4. Otoconia And Otoliths
3.4.1. Chemistry and Biochemistry Of Otoconia And Otoliths
3.4.2. Practical Applications Of The Fish Otoliths
3.4.3. Conclusion
References
3.5. Egg Shells Of Marine Vertebrates
3.5.1. Egg Shells Of Marine Reptilia
3.5.2. Egg Shells Of Sea Birds
3.5.3. Conclusion
References
3.6. Biomagnetite in Marine Vertebrates
3.6.1. Magnetite in Marine Fish
3.6.2. Magnetite in Marine Reptiles
3.6.3. Magnetite in Sea Birds
3.6.4. Magnetite in Cetaceans
3.6.5. Conclusion
References
3.7. Biohalite
3.7.1. Diversity and Origin of Salt Glands in Marine Vertebrates
3.7.2. Salt Glands: From Anatomy To Cellular Level
3.7.3. Conclusion
References
3.8. Pathological Biomineralization in Marine Vertebrates
3.8.1. Conclusion
References
3.9. Silica-based Minerals in Marine Vertebrates
3.9.1. Conclusion
References
Part III: Marine Fishes as Source of Unique Biocomposites
4. Fish Scales as Mineral-based Composites
4.1. Enamel and Enameloid
4.2. Dentine and Dentine-based Composite
4.3. Fish Scales, Scutes And Denticles: Diversity And Structure
4.4. Conclusion
References
5. Materials Design Principles of Fish Scales and Armor
5.1. Biomechanics of Fish Scales
5.2. Fish Swimming And The Surface Shape Of Fish Scale
5.2.1 Superoleophobicity of Fish Scale Surfaces
5.2.2 Selfcleaning of Fish Scales and Biomimetic Applitions
5.3. Conclusion
References
6. Fish Skin: From Clothing to Tissue Engineering
6.1. Fish Skin Clothing and Leather
6.2. Shagreen
6.3. Fish Scales and Skin as Scaffolds for Tissue Engineering
6.4. Conclusion
References
7. Fish Fins and Rays as Inspiration for Materials Engineering and Robotics
7.1. Fish Fins and Rays: Diversity, Structure and Function
7.1.1. Fish Wings: Fins of Flying Fish
7.2. Fish Fin Spines and Rays
7.3. Chemistry of Fish Fin: Elastoidin
7.4. Fin Regeneration and Fin Cell Culture
7.5. Robotic Fish-Like Devices
7.5.1. Fish and Designing of Smart Materials
7.5.2. Fish Biorobotics
7.6. Conclusion
References
Part IV: Marine Biopolymers of Vertebrate Origin
8. Marine Collagens
8.1. Isolation and properties of fish collagens
8.2. Fish collagen as Biomaterial
8.3. Conclusion
References
9. Marine Gelatins
9.1. Fish Gelatin-based Films
9.2. Shark skin and Cartilage Gelatin
9.3. Conclusion
References
10. Marine Elastin
10.1. Elastin-like Proteins in Lamprey
10.2. Fish Elastin
10.3. Cetacean Elastin
10.4. Conclusion
References
11. Marine Keratins
11.1. Intermediate Filaments
11.2. Hagfish Slime
11.3. Whale Baleen
11.4. Conclusion
References
12. Egg-capsule Proteins of Selachians
12.1. Collagen
12.2. Polyphenol-containing Proteins
12.3. Conclusion
References
13. Marine Structural Proteins in Biomedicine and Tissue Engineering
13.1. Conclusion
References
Epilogue
References
Addendum
8. Marine Collagens
8.1. Isolation and properties of fish collagens
8.2. Fish collagen as Biomaterial
8.3. Conclusion
References
9. Marine Gelatins
9.1. Fish Gelatin-based Films
9.2. Shark skin and Cartilage Gelatin
9.3. Conclusion
References
10. Marine Elastin
10.1. Elastin-like Proteins in Lamprey
10.2. Fish Elastin
10.3. Cetacean Elastin
10.4. Conclusion
References
11. Marine Keratins
11.1. Intermediate Filaments
11.2. Hagfish Slime
11.3. Whale Baleen
11.4. Conclusion
References
12. Egg-capsule Proteins of Selachians
12.1. Collagen
12.2. Polyphenol-containing Proteins
12.3. Conclusion
References
13. Marine Structural Proteins in Biomedicine and Tissue Engineering
13.1. Conclusion
References
Epilogue
References
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