Description

Book Synopsis

The present book is covers the recent advances in the development on the regulation of such theragnosis system and their biomedical perspectives to act as a future nanomedicine. Advanced Theranostics Materialsis written by a distinguished group of contributors and provides comprehensive coverage of the current literature, up-to-date overview of all aspects of advanced theranostics materials ranging from system biology, diagnostics, imaging, image-guided therapy, therapeutics, biosensors, and translational medicine and personalized medicine, as well as the much broader task of covering most topics of biomedical research. The books focusses on the following topics:

Part 1: System biology and translational medicine

  • Aberrant Signaling Pathways: Hallmark of Cancer Cells and Target for Nanotherapeutics
  • Application of Nanoparticles in Cancer Treatment
  • Biomacromolecule-Gated Mesoporous Silica Drug Delivery Systems
  • Construction of

    Table of Contents

    Preface xiii

    Part 1: System Biology and Translational Medicine

    1 Aberrant Signaling Pathways 3
    Gulnaz T. Javan, Sheree J. Finley, Ismail Can, Amandeep Salhotra, Ashinm Malhotra, and Shivani Soni

    1.1 Cancer 4

    1.2 Pathways Deregulated in Cancer: Introduction 4

    1.3 Introduction to Nanotechnology 6

    1.3.1 Overview of Clinical Nanotechnology 9

    1.3.2 Current Usage in Cancer Treatment 13

    1.4 Current Uses in Cancer Diagnostic 14

    1.4.1 The Phosphatidylinositol 3-Kinase-AKT Pathway 15

    1.4.2 The MAPK Pathway 18

    1.4.3 mTOR Pathway 20

    1.4.4 Receptor Tyrosine Kinase 23

    Acknowledgment 26

    References 27

    2 Application of Nanoparticles in Cancer Treatment 37
    Behnoud Hormozi

    2.1 Introduction 38

    2.1.1 Nanotechnology 38

    2.1.2 Nanobiotechnology 38

    2.1.3 Nanotechnology in Medicine 39

    2.1.4 Cancer and Nano in Medicine 41

    2.2 Nanoparticles in Cancer Treatment 41

    2.3 Nanoparticle Platforms as Drug Delivery Systems for Cancer Therapy 43

    2.3.1 Lipid-based Nanoparticle Platforms 44

    2.3.2 Polymer-based Nanoparticle Platforms 45

    2.3.3 Protein-based Nanoparticle Platforms 47

    2.3.4 Inorganic Nanoparticle Platforms 47

    2.4 Theranostic Nanomedicine 50

    2.4.1 Theranostic Nanomedicine for Cancer Therapy 54

    2.5 Selective Drug Delivery and Encapsulation for Chemotherapy 54

    2.6 Stimuli-Sensitive Nanopreparations 55

    2.7 Multifunctional Nanopreparations 56

    2.8 Cancer Nanotechnology: Future and Challenges 58

    References 59

    3 Biomacromolecule-Gated Mesoporous Silica Drug Delivery Systems for Stimuli-Responsive Controlled Release 67
    Xuezhong Du

    3.1 Introduction 68

    3.2 Protein-Gated MSN Drug Delivery Systems 69

    3.2.1 Ligand-Binding Protein-Gated MSN Systems 70

    3.2.2 Metal-Chelating Protein-Gated MSN Systems 74

    3.3 DNA-Gated MSN Drug Delivery Systems 75

    3.3.1 Single-Stranded DNA-Gated MSN Systems 76

    3.3.2 Double-Stranded DNA-Gated MSN Systems 77

    3.3.3 Hairpin or Quadruplex DNA-Gated MSN Systems 80

    3.3.4 Native DNA-Gated MSN Systems 83

    3.3.5 Near-Infrared Light-Triggered DNA-Gated MSN Systems 87

    3.4 Conclusions and Perspectives 89

    Acknowledgments 90

    References 90

    4 Construction of Functional DNA Nanostructures for Theranostic Applications 93
    Jiang Li, Fan Li, Hao Pei, Lihua Wang, Qing Huang, and Chunhai Fan

    4.1 The Progress of Structural DNA Nanotechnology 94

    4.2 DNA Nanostructures for Diagnostics 96

    4.3 DNA Nanostructures for Diagnostics on the Interface 96

    4.4 Diagnostic in Homogeneous Solution 99

    4.4.1 Spherical Nucleic Acids (SNA) Probes for Detections in Solution 99

    4.4.2 Nanochips in Solution 100

    4.4.3 Intracellular/In Vivo Diagnosis 103

    4.5 DNA Nanostructures for Therapeutics 106

    4.5.1 Delivery of Small-Molecular Drugs 107

    4.5.2 Delivery of CpG DNAs 109

    4.5.3 RNA Interference (RNAi) 111

    4.5.4 Delivery of Proteins 114

    4.6 Integration of Diagnosis and Therapy: Smart DNA Theranostic Nanodevices 115

    4.7 Targeted Delivery 115

    4.8 Controlled/Triggered Release 117

    4.9 Summary and Perspectives 119

    4.9.1 The Bioeffects of DNA Nanostructures 119

    4.9.2 Purity and Yield 120

    4.9.3 Dynamic Structures for Theranostic 120

    References 121

    Part 2: Imaging and Therapeutics

    5 Dimercaptosuccinic Acid-Coated Magnetic Nanoparticles as a Localized Delivery System in Cancer Immunotherapy 133
    Raquel Mejías, Lucía Gutiérrez, María P. Morales, and Domingo F. Barber

    5.1 Introduction 134

    5.1.1 Nanoparticle-based Drug Delivery Systems 134

    5.1.2 Nanoparticles for Drug Delivery in Cancer Treatment 135

    5.1.3 Magnetic Nanoparticles (MNP) 135

    5.1.4 Nanoparticle Biodistribution and Degradation 136

    5.2 Nanoparticle Detection and Quantification: In Vitro and In Vivo Techniques 137

    5.2.1 Optical Microscopy 137

    5.2.2 Colorimetric Assays 137

    5.2.3 Transmission Electron Microscopy 138

    5.2.4 Magnetic Methods 140

    5.2.5 Elemental Analysis 142

    5.2.6 Nuclear Magnetic Resonance (NMR) 143

    5.3 Evaluation of Nanoparticle-Induced Toxicity 143

    5.3.1 In Vitro Toxicity 143

    5.4 Magnetic Targeting of Nanoparticles 147

    5.5 A Specific Example: DMSA-Coated Magnetic Nanoparticles 148

    5.5.1 In Vitro DMSA-MNP Uptake and Intracellular Localization 148

    5.5.2 In Vitro DMSA-MNP Toxicity 149

    5.5.3 In Vitro DMSA-MNP-Induced Cell Stress and Apoptosis 150

    5.5.4 In Vivo DMSA-MNP Distribution 150

    5.5.5 In Vivo DMSA-MNP-Induced Toxicity 152

    5.5.6 In Vivo DMSA-MNP Biotransformation 152

    5.6 Conclusions 153

    Acknowledgments 154

    References 154

    6 Cardiovascular Nanomedicine 159
    Suryyani Deb and Hirak Kumar Patra

    6.1 Introduction 160

    6.2 Nanoscale Cardiovascular Diagnostics 160

    6.2.1 Cardiac Molecular Biomarker Detection from Peripheral Blood 161

    6.2.2 Diagnosis through Nano-based Molecular Imaging 163

    6.2.3 Determination of Stem Cell Delivery 165

    6.3 Nanotechnology in Cardiovascular Therapeutics 167

    6.3.1 Drug Delivery 167

    6.3.2 Gene Delivery 169

    6.3.3 Tissue Engineering 169

    6.4 Nanotechnology in the Surgery of Cardiovascular Disease 170

    6.5 Conclusion 172

    References 173

    7 Chitosan-based Interpenetrating Polymeric Network Systems for Sustained Drug Release 183
    Amit Kumar Nayak and Dilipkumar Pal

    7.1 Introduction 184

    7.2 IPNs and Their Uses in Drug Delivery 185

    7.3 Chitosan 187

    7.4 Chitosan-Tamarind Seed Polysaccharide IPN Microparticles and Matrix Tablets for Sustained Release of Aceclofenac 189

    7.5 Chitosan-Hydroxyethyl Cellulose IPN Microspheres of Isoniazid 193

    7.6 Chitosan-Methyl Cellulose IPN Microspheres of Theophylline 194

    7.7 Chitosan-Acrylamide-Grafted-Poly(Vinyl Alcohol) and Hydrolyzed Acrylamide-Grafted-Poly(Vinyl Alcohol) IPN Microgels of Cefadroxil 198

    7.8 Chitosan-Poly(N-Isopropylacrylamide) IPN Discs of Diclofenac Sodium 199

    7.9 Chitosan-Poly(Ethylene Oxide-Grafted-Acrylamide) Semi-IPN Hydrogel Microspheres of Capecitabine 200

    7.10 Acrylamide-Grafted Dextran-Chitosan Semi-IPN Microspheres of Acyclovir 201

    7.11 Chitosan-Acrylamide-Grafted Hydroxyethylcellulose Semi-IPN Microspheres of Diclofenac Sodium 202

    7.12 Poly [N-Acryloylglycine-Chitosan] IPN Hydrogel of 5-Fluorouracil 202

    7.13 Chitosan-N,N′-Dimethylacrylamide Semi-IPN Microspheres of Chlorothiazide 203

    7.14 Conclusion 203

    References 204

    8 Nanocapsules in Biomedicine 209
    Frank J. Hernandez, Murat Kavruk, Luiza I. Hernandez, and Veli C. Ozalp

    8.1 Nanocapsules: A Novel Nano-Drug Delivery System 210

    8.2 Magic Bullets: Nanocapsules in Future Medicine 211

    8.3 In Vitro Applications of Nanocapsules 212

    8.3.1 Functionalized Mesoporous Silica Materials for Controlled Drug Delivery 212

    8.3.2 Cationic Polymer Nanocapsules for Controlled Multi-drug Delivery 220

    8.3.3 Lipid Nanocapsules 221

    8.4 In Vivo Applications of Nanocapsules 224

    8.4.1 In Vivo Diagnostic Imaging 225

    8.4.2 In Vivo Therapeutics 226

    8.5 Conclusions 228

    References 228

    9 Chitosan-based Polyelectrolyte Complexes 235
    Bojan Èalija, Nebojša Cekiæ, and Jela Miliæ

    9.1 Introduction 236

    9.2 Chitosans: Chemical Structure, Physicochemical Properties, and Toxicological and Regulatory Aspects 237

    9.2.1 Chemical Structure and Source 237

    9.2.2 Physicochemical Properties 238

    9.2.3 Toxicological and Regulatory Aspects 239

    9.3 Polyelectrolyte Complexes: Theoretical Background, Structure, and Basic Properties 240

    9.4 Chitosan-based Polyelectrolyte Complexes in Particulate Drug Carriers 242

    9.4.1 PECs Comprised of Chitosans and Natural or Semisynthetic Polyanions 243

    9.4.2 PECs Comprised of Chitosans and Synthetic Polyanions 249

    9.4.3 Influence of Chitosans Functional Properties and Experimental Conditions on Polyelectrolyte Complexation 254

    9.5 Characterization of Chitosan-Based PECs and Chitosan-based PEC Particulate Drug Carriers 258

    9.5.1 Size and Morphology 258

    9.5.2 Zeta Potential 259

    9.5.3 Structural Analysis 259

    9.5.4 Encapsulation Efficiency and Drug Loading Capacity 261

    9.5.5 In Vitro Swelling Studies 262

    9.5.6 In Vitro Drug Release Studies 263

    9.6 Conclusion 263

    Acknowledgment 264

    References 264

    Part 3: Diagnostics and Featured Prognostics

    10. Non-invasive Glucose Biosensors Based on Nanomaterials 273
    Farnoush Faridbod, Mohammad Reza Ganjali, Bagher Larijani and Parviz Norouzi

    10.1 Diabetes and Its Prevalence 274

    10.2 Importance of Glucose Monitoring 274

    10.3 Glucose Measurement Methods 275

    10.4 Non-invasive Glucose Determination 275

    10.4.1 Non-invasive Glucose Determination Using Tissues 276

    10.4.2 Non-invasive Glucose Determination Method Using Fluids 277

    10.5 Glucose Biosensors 279

    10.6 New Generation of Non-invasive Glucose Biosensors-Based Nanomaterials 281

    10.7 Future Perspective in Glucose Monitoring 290

    10.8 Conclusion 292

    References 292

    11 Self-Directed Assembly of Nanoparticles 297
    Arun Prakash Upadhyay, Dilip Kumar Behara, Gyan Prakash Sharma, Raj Ganesh S. Pala, and Sri Sivakumar

    11.1 Introduction 297

    11.2 Self-Assembly through Molecular Interactions/Forces 298

    11.2.1 Van der Waals Interactions 298

    11.2.2 Electrostatic Interaction 301

    11.3 Hydrogen-Bonding Interactions 304

    11.3.1 Covalent Interactions 306

    11.3.2 DNA-Based Cross-Linking Interactions 311

    11.4 Directed Self-Assembly by External Forces 315

    11.4.1 Magnetic Field-Driven Directed Self-Assembly 315

    11.4.2 Electric Field-Driven Directed Self-Assembly 319

    11.4.3 Flow Field-Driven Directed Self-Assembly 321

    11.5 Conclusion 325

    Acknowledgment 326

    References 326

    Index 337

Advanced Theranostic Materials

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    A Hardback by Ashutosh Tiwari, Hirak K. Patra, Jeong-Woo Choi

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      Publisher: John Wiley & Sons Inc
      Publication Date: 08/09/2015
      ISBN13: 9781118998298, 978-1118998298
      ISBN10: 1118998294
      Also in:
      Biotechnology Mechanical engineering and materials

      Description

      Book Synopsis

      The present book is covers the recent advances in the development on the regulation of such theragnosis system and their biomedical perspectives to act as a future nanomedicine. Advanced Theranostics Materialsis written by a distinguished group of contributors and provides comprehensive coverage of the current literature, up-to-date overview of all aspects of advanced theranostics materials ranging from system biology, diagnostics, imaging, image-guided therapy, therapeutics, biosensors, and translational medicine and personalized medicine, as well as the much broader task of covering most topics of biomedical research. The books focusses on the following topics:

      Part 1: System biology and translational medicine

      • Aberrant Signaling Pathways: Hallmark of Cancer Cells and Target for Nanotherapeutics
      • Application of Nanoparticles in Cancer Treatment
      • Biomacromolecule-Gated Mesoporous Silica Drug Delivery Systems
      • Construction of

        Table of Contents

        Preface xiii

        Part 1: System Biology and Translational Medicine

        1 Aberrant Signaling Pathways 3
        Gulnaz T. Javan, Sheree J. Finley, Ismail Can, Amandeep Salhotra, Ashinm Malhotra, and Shivani Soni

        1.1 Cancer 4

        1.2 Pathways Deregulated in Cancer: Introduction 4

        1.3 Introduction to Nanotechnology 6

        1.3.1 Overview of Clinical Nanotechnology 9

        1.3.2 Current Usage in Cancer Treatment 13

        1.4 Current Uses in Cancer Diagnostic 14

        1.4.1 The Phosphatidylinositol 3-Kinase-AKT Pathway 15

        1.4.2 The MAPK Pathway 18

        1.4.3 mTOR Pathway 20

        1.4.4 Receptor Tyrosine Kinase 23

        Acknowledgment 26

        References 27

        2 Application of Nanoparticles in Cancer Treatment 37
        Behnoud Hormozi

        2.1 Introduction 38

        2.1.1 Nanotechnology 38

        2.1.2 Nanobiotechnology 38

        2.1.3 Nanotechnology in Medicine 39

        2.1.4 Cancer and Nano in Medicine 41

        2.2 Nanoparticles in Cancer Treatment 41

        2.3 Nanoparticle Platforms as Drug Delivery Systems for Cancer Therapy 43

        2.3.1 Lipid-based Nanoparticle Platforms 44

        2.3.2 Polymer-based Nanoparticle Platforms 45

        2.3.3 Protein-based Nanoparticle Platforms 47

        2.3.4 Inorganic Nanoparticle Platforms 47

        2.4 Theranostic Nanomedicine 50

        2.4.1 Theranostic Nanomedicine for Cancer Therapy 54

        2.5 Selective Drug Delivery and Encapsulation for Chemotherapy 54

        2.6 Stimuli-Sensitive Nanopreparations 55

        2.7 Multifunctional Nanopreparations 56

        2.8 Cancer Nanotechnology: Future and Challenges 58

        References 59

        3 Biomacromolecule-Gated Mesoporous Silica Drug Delivery Systems for Stimuli-Responsive Controlled Release 67
        Xuezhong Du

        3.1 Introduction 68

        3.2 Protein-Gated MSN Drug Delivery Systems 69

        3.2.1 Ligand-Binding Protein-Gated MSN Systems 70

        3.2.2 Metal-Chelating Protein-Gated MSN Systems 74

        3.3 DNA-Gated MSN Drug Delivery Systems 75

        3.3.1 Single-Stranded DNA-Gated MSN Systems 76

        3.3.2 Double-Stranded DNA-Gated MSN Systems 77

        3.3.3 Hairpin or Quadruplex DNA-Gated MSN Systems 80

        3.3.4 Native DNA-Gated MSN Systems 83

        3.3.5 Near-Infrared Light-Triggered DNA-Gated MSN Systems 87

        3.4 Conclusions and Perspectives 89

        Acknowledgments 90

        References 90

        4 Construction of Functional DNA Nanostructures for Theranostic Applications 93
        Jiang Li, Fan Li, Hao Pei, Lihua Wang, Qing Huang, and Chunhai Fan

        4.1 The Progress of Structural DNA Nanotechnology 94

        4.2 DNA Nanostructures for Diagnostics 96

        4.3 DNA Nanostructures for Diagnostics on the Interface 96

        4.4 Diagnostic in Homogeneous Solution 99

        4.4.1 Spherical Nucleic Acids (SNA) Probes for Detections in Solution 99

        4.4.2 Nanochips in Solution 100

        4.4.3 Intracellular/In Vivo Diagnosis 103

        4.5 DNA Nanostructures for Therapeutics 106

        4.5.1 Delivery of Small-Molecular Drugs 107

        4.5.2 Delivery of CpG DNAs 109

        4.5.3 RNA Interference (RNAi) 111

        4.5.4 Delivery of Proteins 114

        4.6 Integration of Diagnosis and Therapy: Smart DNA Theranostic Nanodevices 115

        4.7 Targeted Delivery 115

        4.8 Controlled/Triggered Release 117

        4.9 Summary and Perspectives 119

        4.9.1 The Bioeffects of DNA Nanostructures 119

        4.9.2 Purity and Yield 120

        4.9.3 Dynamic Structures for Theranostic 120

        References 121

        Part 2: Imaging and Therapeutics

        5 Dimercaptosuccinic Acid-Coated Magnetic Nanoparticles as a Localized Delivery System in Cancer Immunotherapy 133
        Raquel Mejías, Lucía Gutiérrez, María P. Morales, and Domingo F. Barber

        5.1 Introduction 134

        5.1.1 Nanoparticle-based Drug Delivery Systems 134

        5.1.2 Nanoparticles for Drug Delivery in Cancer Treatment 135

        5.1.3 Magnetic Nanoparticles (MNP) 135

        5.1.4 Nanoparticle Biodistribution and Degradation 136

        5.2 Nanoparticle Detection and Quantification: In Vitro and In Vivo Techniques 137

        5.2.1 Optical Microscopy 137

        5.2.2 Colorimetric Assays 137

        5.2.3 Transmission Electron Microscopy 138

        5.2.4 Magnetic Methods 140

        5.2.5 Elemental Analysis 142

        5.2.6 Nuclear Magnetic Resonance (NMR) 143

        5.3 Evaluation of Nanoparticle-Induced Toxicity 143

        5.3.1 In Vitro Toxicity 143

        5.4 Magnetic Targeting of Nanoparticles 147

        5.5 A Specific Example: DMSA-Coated Magnetic Nanoparticles 148

        5.5.1 In Vitro DMSA-MNP Uptake and Intracellular Localization 148

        5.5.2 In Vitro DMSA-MNP Toxicity 149

        5.5.3 In Vitro DMSA-MNP-Induced Cell Stress and Apoptosis 150

        5.5.4 In Vivo DMSA-MNP Distribution 150

        5.5.5 In Vivo DMSA-MNP-Induced Toxicity 152

        5.5.6 In Vivo DMSA-MNP Biotransformation 152

        5.6 Conclusions 153

        Acknowledgments 154

        References 154

        6 Cardiovascular Nanomedicine 159
        Suryyani Deb and Hirak Kumar Patra

        6.1 Introduction 160

        6.2 Nanoscale Cardiovascular Diagnostics 160

        6.2.1 Cardiac Molecular Biomarker Detection from Peripheral Blood 161

        6.2.2 Diagnosis through Nano-based Molecular Imaging 163

        6.2.3 Determination of Stem Cell Delivery 165

        6.3 Nanotechnology in Cardiovascular Therapeutics 167

        6.3.1 Drug Delivery 167

        6.3.2 Gene Delivery 169

        6.3.3 Tissue Engineering 169

        6.4 Nanotechnology in the Surgery of Cardiovascular Disease 170

        6.5 Conclusion 172

        References 173

        7 Chitosan-based Interpenetrating Polymeric Network Systems for Sustained Drug Release 183
        Amit Kumar Nayak and Dilipkumar Pal

        7.1 Introduction 184

        7.2 IPNs and Their Uses in Drug Delivery 185

        7.3 Chitosan 187

        7.4 Chitosan-Tamarind Seed Polysaccharide IPN Microparticles and Matrix Tablets for Sustained Release of Aceclofenac 189

        7.5 Chitosan-Hydroxyethyl Cellulose IPN Microspheres of Isoniazid 193

        7.6 Chitosan-Methyl Cellulose IPN Microspheres of Theophylline 194

        7.7 Chitosan-Acrylamide-Grafted-Poly(Vinyl Alcohol) and Hydrolyzed Acrylamide-Grafted-Poly(Vinyl Alcohol) IPN Microgels of Cefadroxil 198

        7.8 Chitosan-Poly(N-Isopropylacrylamide) IPN Discs of Diclofenac Sodium 199

        7.9 Chitosan-Poly(Ethylene Oxide-Grafted-Acrylamide) Semi-IPN Hydrogel Microspheres of Capecitabine 200

        7.10 Acrylamide-Grafted Dextran-Chitosan Semi-IPN Microspheres of Acyclovir 201

        7.11 Chitosan-Acrylamide-Grafted Hydroxyethylcellulose Semi-IPN Microspheres of Diclofenac Sodium 202

        7.12 Poly [N-Acryloylglycine-Chitosan] IPN Hydrogel of 5-Fluorouracil 202

        7.13 Chitosan-N,N′-Dimethylacrylamide Semi-IPN Microspheres of Chlorothiazide 203

        7.14 Conclusion 203

        References 204

        8 Nanocapsules in Biomedicine 209
        Frank J. Hernandez, Murat Kavruk, Luiza I. Hernandez, and Veli C. Ozalp

        8.1 Nanocapsules: A Novel Nano-Drug Delivery System 210

        8.2 Magic Bullets: Nanocapsules in Future Medicine 211

        8.3 In Vitro Applications of Nanocapsules 212

        8.3.1 Functionalized Mesoporous Silica Materials for Controlled Drug Delivery 212

        8.3.2 Cationic Polymer Nanocapsules for Controlled Multi-drug Delivery 220

        8.3.3 Lipid Nanocapsules 221

        8.4 In Vivo Applications of Nanocapsules 224

        8.4.1 In Vivo Diagnostic Imaging 225

        8.4.2 In Vivo Therapeutics 226

        8.5 Conclusions 228

        References 228

        9 Chitosan-based Polyelectrolyte Complexes 235
        Bojan Èalija, Nebojša Cekiæ, and Jela Miliæ

        9.1 Introduction 236

        9.2 Chitosans: Chemical Structure, Physicochemical Properties, and Toxicological and Regulatory Aspects 237

        9.2.1 Chemical Structure and Source 237

        9.2.2 Physicochemical Properties 238

        9.2.3 Toxicological and Regulatory Aspects 239

        9.3 Polyelectrolyte Complexes: Theoretical Background, Structure, and Basic Properties 240

        9.4 Chitosan-based Polyelectrolyte Complexes in Particulate Drug Carriers 242

        9.4.1 PECs Comprised of Chitosans and Natural or Semisynthetic Polyanions 243

        9.4.2 PECs Comprised of Chitosans and Synthetic Polyanions 249

        9.4.3 Influence of Chitosans Functional Properties and Experimental Conditions on Polyelectrolyte Complexation 254

        9.5 Characterization of Chitosan-Based PECs and Chitosan-based PEC Particulate Drug Carriers 258

        9.5.1 Size and Morphology 258

        9.5.2 Zeta Potential 259

        9.5.3 Structural Analysis 259

        9.5.4 Encapsulation Efficiency and Drug Loading Capacity 261

        9.5.5 In Vitro Swelling Studies 262

        9.5.6 In Vitro Drug Release Studies 263

        9.6 Conclusion 263

        Acknowledgment 264

        References 264

        Part 3: Diagnostics and Featured Prognostics

        10. Non-invasive Glucose Biosensors Based on Nanomaterials 273
        Farnoush Faridbod, Mohammad Reza Ganjali, Bagher Larijani and Parviz Norouzi

        10.1 Diabetes and Its Prevalence 274

        10.2 Importance of Glucose Monitoring 274

        10.3 Glucose Measurement Methods 275

        10.4 Non-invasive Glucose Determination 275

        10.4.1 Non-invasive Glucose Determination Using Tissues 276

        10.4.2 Non-invasive Glucose Determination Method Using Fluids 277

        10.5 Glucose Biosensors 279

        10.6 New Generation of Non-invasive Glucose Biosensors-Based Nanomaterials 281

        10.7 Future Perspective in Glucose Monitoring 290

        10.8 Conclusion 292

        References 292

        11 Self-Directed Assembly of Nanoparticles 297
        Arun Prakash Upadhyay, Dilip Kumar Behara, Gyan Prakash Sharma, Raj Ganesh S. Pala, and Sri Sivakumar

        11.1 Introduction 297

        11.2 Self-Assembly through Molecular Interactions/Forces 298

        11.2.1 Van der Waals Interactions 298

        11.2.2 Electrostatic Interaction 301

        11.3 Hydrogen-Bonding Interactions 304

        11.3.1 Covalent Interactions 306

        11.3.2 DNA-Based Cross-Linking Interactions 311

        11.4 Directed Self-Assembly by External Forces 315

        11.4.1 Magnetic Field-Driven Directed Self-Assembly 315

        11.4.2 Electric Field-Driven Directed Self-Assembly 319

        11.4.3 Flow Field-Driven Directed Self-Assembly 321

        11.5 Conclusion 325

        Acknowledgment 326

        References 326

        Index 337

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