Advanced Biomaterials: Fundamentals, Processing, and by Bikramjit Basu, Dhirendra S. Katti, Ashok Kumar

By Bikramjit Basu, Dhirendra S. Katti, Ashok Kumar

Content material:
Chapter 1 basics of Biomaterials and Biocompatibility (pages 1–18): Bikramjit Basu and Shekhar Nath
Chapter 2 basics of Hydroxyapatite and comparable Calcium Phosphates (pages 19–52): Racquel Zapanta LeGeros, Atsuo Ito, Kunio Ishikawa, Toshiro Sakae and John P. LeGeros
Chapter three fabrics for Orthopedic purposes (pages 53–100): Shekhar Nath and Bikramjit Basu
Chapter four The Micro Macroporous Biphasic Calcium Phosphate thought for Bone Reconstruction and Tissue Engineering (pages 101–141): man Daculsi, Franck Jegoux and Pierre Layrolle
Chapter five technology and know-how built-in Titanium Dental Implant structures (pages 143–177): Yoshiki Oshida and Elif Bahar Tuna
Chapter 6 Injectable Hydrogels as Biomaterials (pages 179–203): Lakshmi S. Nair, Cato T. Laurencin and Mayank Tandon
Chapter 7 Nanomaterials for greater Orthopedic and Bone Tissue Engineering functions (pages 205–241): Lijie Zhang, Sirinrath Sirivisoot, Ganesh Balasundaram and Thomas J. Webster
Chapter eight advent to Processing of Biomaterials (pages 243–276): Dhirendra S. Katti, Shaunak Pandya, Meghali Bora and Rakesh Mahida
Chapter nine Laser Processing of Orthopedic Biomaterials (pages 277–322): Rajarshi Banerjee and Soumya Nag
Chapter 10 Functionally Graded All Ceramic HIP Joint (pages 323–356): Omer Van der Biest, man Anne, Kim Vanmeensel and Jef Vleugels
Chapter eleven clinical units in line with Bioinspired Ceramics (pages 357–409): Pio Gonzalez, Julian Martinez?Fernandez, Antonio R. de Arellano?Lopez and Mrityunjay Singh
Chapter 12 Ionomer Glasses: layout and Characterization (pages 411–433): Artemis Stamboulis and Fei Wang
Chapter thirteen Designing Nanofibrous Scaffolds for Tissue Engineering (pages 435–497): Neha Arya, Poonam Sharma and Dhirendra S. Katti
Chapter 14 layout of Supermacroporous Biomaterials through Gelation at Subzero Temperatures—Cryogelation (pages 499–531): Fatima M. Plieva, Ashok Kumar, Igor Yu. Galaev and Bo Mattiasson
Chapter 15 Biomaterial functions (pages 533–550): Ashok Kumar, Akshay Srivastava and period Jain
Chapter sixteen Cell?Based Nanocomposites and Biomolecules for Bone Tissue Engineering (pages 551–588): Michelle Ngiam, Susan Liao, Casey Chan and S. Ramakrishna
Chapter 17 Orthopedic Interface Tissue Engineering: development the Bridge to built-in Musculoskeletal Tissue platforms (pages 589–611): Helen H. Lu, Kristen L. Moffat and Jeffrey P. Spalazzi
Chapter 18 Cells of the fearful procedure and electric Stimulation (pages 613–642): Carlos Atico Ariza and Surya okay. Mallapragada
Chapter 19 Placental Umbilical twine Blood: a real Blood replacement (pages 643–662): Niranjan Bhattacharya
Chapter 20 Supported mobilephone Mimetic Monolayers and their Blood Compatibility (pages 663–676): ok. Kaladhar and Chandra P. Sharma
Chapter 21 Titanium Nitride and Diamond Like Carbon Coatings for Cardiovascular purposes (pages 677–705): C. V. Muraleedharan and G. S. Bhuvaneshwar

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Extra resources for Advanced Biomaterials: Fundamentals, Processing, and Applications

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In this context, the chapter contributed by T. J. Webster focuses on the contemporary development of nanomaterials for orthopedic applications. ), the results obtained with synthesized novel nanophase composites (that is, materials with dimensions less than 100 nm in at least one direction) of metals, ceramics, biodegradable polymers, injectable hydrogels are presented. It is demonstrated that the increased regeneration of bone, cartilage, vascular, and bladder tissue in vivo is achievable on nanophase compared to conventional materials.

REFERENCES 1. B. D. Ratner, A. S. Hoffman, F. J. Schoen and J. E. 526, Academic Press, New York, 2004. 18 FUNDAMENTALS OF BIOMATERIALS AND BIOCOMPATIBILITY 2. Joon B. Park, Joseph D. Bronzino, Biomaterials: Principles and Applications, CRC press, New York, 2003. 3. L. L. Hench, J. Wilson, An Introduction to Bioceramics, Vol. 1, World Scientific, 1993. 4. C. Piconi and G. Maccauro, “Zirconia as a ceramic biomaterial,” Biomaterials, 20 [1] 1–25 (1999). 5. L. L. Hench, “Bioceramics,” J. Am. Ceram.

In the presence of Na+ ions in solution, a coupled substitution Na-for-Ca and CO3-for-PO4 occurs [26,57,59,64,126]. For this report, apatite with CO3-for-PO4 substitution (Type B) will be referred to as CHA; with CO3-for-OH (Type A) substitution, as CA. The two types of substitution have opposite effects on the lattice parameters. Type A substitution, in which larger planar CO3 group substitutes for OH group, causes an expansion in the a-axis and contraction in the c-axis dimensions. 3). CO3-apatite prepared by hydrothermal reactions appear to allow simultaneous CO3-for-OH and CO3-for-PO4 substitution, as evidenced by the larger a-axis for similar amount of CO3 incorporation compared to the a-axis dimension of CHA.

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