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More About This Title Biomedical Applications of Polymeric Materials andComposites
English
Following an introduction listing various functional polymers, including conductive, biocompatible and conjugated polymers, the book goes on to discuss different synthetic polymers that can be used, for example, as hydrogels, biochemical sensors, functional surfaces, and natural degradable materials. Throughout, the focus is on applications, with worked examples for training purposes as well as case studies included. The whole is rounded off with a look at future trends.
English
D. Sakthi Kumar is professor in the Graduate School of Interdisciplinary New Science and Deputy Director of the Bio Nano Electronics Research Center of Toyo University, Japan. He obtained his PhD in physics from the Mahatma Gandhi University in Kottayam, India, in 1998. After completing his postdoc at the Thin Film Lab at the Indian Institute of Technology in New Delhi, India, he moved to Toyo University. His research interests include nanodrug delivery, polymers and nanomaterials for biomedical applications, Bio Nano Electronics and Bio/Chemical sensors.
English
List of Contributors XV
Preface XIX
1 Biomaterials for Biomedical Applications 1
Brahatheeswaran Dhandayuthapani and Dasappan Sakthi kumar
1.1 Introduction 1
1.2 Polymers as Hydrogels in Cell Encapsulation and Soft Tissue Replacement 2
1.3 Biomaterials for Drug Delivery Systems 4
1.4 Biomaterials for Heart Valves and Arteries 7
1.5 Biomaterials for Bone Repair 9
1.6 Conclusion 11
Abbreviations 12
References 13
2 Conducting Polymers: An Introduction 21
Nidhin Joy, Joby Eldho, and Raju Francis
2.1 Introduction 21
2.2 Types of Conducting Polymers 24
2.3 Synthesis of Conducting Polymers 28
2.4 Surface Functionalization of Conducting Polymers 28
Abbreviations 30
References 31
3 Conducting Polymers: Biomedical Applications 37
Nidhin Joy, Geethy P. Gopalan, Joby Eldho, and Raju Francis
3.1 Applications 37
3.2 Conclusions 72
Abbreviations 72
References 73
4 Plasma-Assisted Fabrication and Processing of Biomaterials 91
Kateryna Bazaka, Daniel S. Grant, Surjith Alancherry, and Mohan V. Jacob
4.1 Introduction 91
4.2 Conclusion 113
References 114
5 Smart Electroactive Polymers and Composite Materials 125
T.P.D. Rajan and J. Mary Gladis
5.1 Introduction 125
5.2 Types of Electroactive Polymers 126
5.3 Polymer Gels 126
5.4 Conducting Polymers 129
5.5 Ionic Polymer–Metal Composites (IPMC) 131
5.6 Conjugated Polymer 132
5.7 Piezoelectric and Electrostrictive Polymers 133
5.8 Dielectric Elastomers 135
5.9 Summary 137
References 137
6 Synthetic Polymer Hydrogels 141
Anitha C. Kumar and Harikrishna Erothu
6.1 Introduction 141
6.2 Polymer Hydrogels 141
6.3 Synthetic Polymer Hydrogels 142
6.4 Applications of Synthetic Polymer Hydrogels 155
6.5 Conclusion 156
Abbreviations 156
References 157
7 Hydrophilic Polymers 163
Harikrishna Erothu and Anitha C. Kumar
7.1 Introduction 163
7.2 Classification 163
7.3 Applications of Hydrophilic Polymers 175
7.4 Conclusions 177
Abbreviations 177
References 178
8 Properties of Stimuli-Responsive Polymers 187
Raju Francis, Geethy P. Gopalan, Anjaly Sivadas, and Nidhin Joy
8.1 Introduction 187
8.2 Physically Dependent Stimuli 188
8.3 Chemically Dependent Stimuli 203
8.4 Biologically Dependant Stimuli 207
8.5 Dual Stimuli 209
8.6 MultiStimuli-Responsive Materials 213
8.7 Conclusion 217
Abbreviations 218
References 220
9 Stimuli-Responsive Polymers: Biomedical Applications 233
Raju Francis, Nidhin Joy, Anjaly Sivadas, Geethy P. Gopalan, and Deepa K. Baby
9.1 Introduction 233
9.2 Imaging 235
9.3 Sensing 238
9.4 Delivery ofTherapeutic Molecules 241
9.5 Other Applications 249
9.6 Conclusion 252
Abbreviations 252
References 253
10 Functionally Engineered Sol–Gel Derived Inorganic Gels and Hybrid Nanoarchitectures for Biomedical Applications 261
Vazhayal Linsha, Kallyadan Veettil Mahesh, and Solaiappan Ananthakumar
10.1 Introduction 261
10.2 Some of the Useful Definitions of Various Gel Forms 263
10.3 Inorganic Metal-Oxide Gels and Hybrid Nanoarchitectures 267
10.4 Sol–Gel Synthesis of Inorganic Metal-Oxide Gels 267
10.5 Physically Cross-Linked Inorganic and Hybrid Gel 271
10.6 Sol–Gel Derived Hybrid Metal-Oxides Nanostructures 273
10.7 Biomedical Applications of Sol–Gel Derived Inorganic and Hybrid Nanoarchitectures for Both Therapeutic and Diagnostic (Theranostics) Functions 275
10.8 Sol–Gel Matrices for Controlled Drug Delivery 276
10.9 Stimuli-Responsive Drug Delivery Systems 282
10.10 Sol–Gel Matrix Targeted CancerTherapy 286
10.11 Sol–Gel Matrices for Imaging and Radiotherapy (Radiolabeling) 288
10.12 Concluding Remarks and Future Perspectives 294
Acknowledgment 296
Abbreviations 296
References 297
11 Relevance of Natural Degradable Polymers in the Biomedical Field 303
Raju Francis, Nidhin Joy, and Anjaly Sivadas
11.1 Introduction 303
11.2 Natural Biopolymers and its Application 304
11.3 Conclusion 342
Abbreviations 343
References 344
12 Synthetic Biodegradable Polymers for Medical and Clinical Applications 361
Raju Francis, Nidhin Joy, and Anjaly Sivadas
12.1 Introduction 361
12.2 Polyesters/Poly(α-hydroxy acids) 363
12.3 Poly(glycolide) 364
12.4 Polylactide 364
12.5 Poly(lactic-co-glycolic) Acid 365
12.6 Poly(ε-caprolactone) 366
12.7 Polyurethanes 366
12.8 Polyanhydrides 367
12.9 Polyphosphazenes 367
12.10 Polyhydroxyalkanoates 368
12.11 Polyorthoesters 368
12.12 Poly(propylene fumarate) 369
12.13 Polyacetals 369
12.14 Polycarbonates 369
12.15 Polyphosphoesters 370
12.16 Synthesis and Application of Different Modified Synthetic Biopolymer 371
12.17 Conclusion 376
Abbreviations 377
References 377
Index 383
English
"[R]esearchers with a chemical background who are entering the biomedical field are the ones who will get the most out of this book. Others, coming from a more mechanical background will still find the book very useful owing to the number of concise comparisons of the materials within the various classes which will facilitate material selection and design of biomedical technologies. Indeed, it is an excellent picture of the current state and direction of research in this area, well supported by a wealth of references in each chapter (there are between 40 300 references per chapter) with pertinent and well-presented figures throughout." (Applied Rheology June 2017)
