The ELSI Handbook of Nanotechnology. Risk, Safety, ELSI and Commercialization. Edition No. 1

Table of Contents

Preface xv

1 Nanomaterials and the Environment 1
Shivani Rastogi, Gaurav Sharma and Balasubramanian Kandasubramanian

1.1 Introduction 1

1.1.1 Overview of Nanomaterials 1

1.1.2 Overview of Environmental Health 4

1.1.2.1 Use of NMs in Environmental Health (Nanoremediation) 4

1.2 Applications of Nanomaterials for Environment 6

1.2.1 Nanomaterials for Detection of Environmental Contaminants 6

1.2.2 Nanomaterials for Air Purification 9

1.2.3 Nanomaterials for Water Treatment 10

1.2.4 Nanomaterials for Energy Storage 11

1.2.5 Nanomaterials for Degradation of Land Waste 12

1.3 Limitations of Environmental Nanomaterials 13

1.3.1 Toxicity of Nanomaterials 13

1.3.2 Toxic Effect on Environmental Health 14

1.3.3 Effect of Toxicity on Human Health 15

1.4 Future Scope of Environmental Nanomaterials 17

1.4.1 In Wastewater and Land Waste Treatment 17

1.4.2 In Biomedicine and Air Purification 17

1.4.3 In Electronics and IT Applications 18

1.5 Conclusion 18

References 19

2 Highly Efficient Graphene-Based Nanocomposites for Environmental Application 25
A.E. Burakov, I.V. Burakova, E.V. Galunin, E.S. Mkrtchyan and A.V. Melezhik

2.1 Features of the Organic Pollutants Adsorption 25

2.1.1 Introduction 25

2.1.2 Types of Organic Pollutants 26

2.1.3 Methods for Removing Organic Pollutants 27

2.1.4 Materials to Extract Organic Pollutants 28

2.2 Adsorption Materials - Graphene-Based Nanocomposites 37

2.2.1 Synthesis of the Sorption Materials 37

2.2.2 Physicochemical Properties of the Sorption Materials 38

2.3 Determining the Adsorption Activity 41

2.3.1 Kinetic Studies under Static Conditions 41

2.3.2 Kinetic Studies under Dynamic Conditions 41

2.3.3 Mathematical Processing of Experimental Data 42

2.4 Conclusion 44

Acknowledgment 44

References 44

3 A Concise Account of the Studies Conducted on the Transport, Fate, Transformation and Toxicity of Engineered Nanomaterials 51
Sauvik Raha and Md. Ahmaruzzam

3.1 Introduction 52

3.2 Transport of Engineered Nanomaterials 52

3.2.1 Transport in Air 52

3.2.2 Transport in Water 53

3.2.3 Transport in Terrestrial Compartment 54

3.3 Fate and Transformation of Engineered Nanomaterials 55

3.3.1 Fate and Transformation in Air 55

3.3.2 Fate and Transformation in Terrestrial and Aquatic Compartments 56

3.4 Toxicity 57

3.4.1 Toxicity in Aquatic Biomes 57

3.4.2 Toxicity in Terrestrial Biomes 58

3.5 Existing Challenges 58

3.6 Conclusion 59

References 59

4 Nanotechnologies and Advanced Smart Materials: The Case of Architecture and Civil Engineering 67
Paolo Di Sia

4.1 Introduction 67

4.2 Management of Complexity 69

4.3 Advanced Materials: Definitions, Characteristics, Properties 71

4.4 Classification Criteria: High Performance and Smart Materials 73

4.5 Innovations in the Nanotechnology Field for Building Materials 76

4.6 Applications of Nanostructured Materials in Architecture 79

4.7 Nanostructured Cementitious Materials: High Performance and Ecoefficiency 81

4.8 Conclusions 84

References 85

5 Life Cycle Environmental Implications of Nanomanufacturing 89
Asmaa Nady Mohammed

5.1 Introduction 89

5.2 Manufacturing of Nanomaterials 90

5.3 Nanomaterials and Their Entry into the Environment 91

5.4 How is the Environment Subjected to Nanomaterials? 91

5.5 Implications of Nanomaterials in the Environment 92

5.6 Potential Health Risks and Environmental Impact of Nanomaterials 92

5.7 Impact of Long-Term Exposure to Graphene-Based Materials In Vivo 93

5.8 Antimicrobial Activity of Graphene and Graphene Oxide Particles 93

5.9 Interaction between Two-Dimension (2D) Nanomaterials and the Environment 93

5.10 Positive Effects of Nanomaterials on the Environment 94

5.11 Negative Effects of Nanomaterials on the Environment 94

5.12 Life Cycle Assessment (LCA) 94

5.13 Four Phases of Life Cycle Assessment (LCA) 95

5.14 Environmental Nanomaterials (ENMs) Life Cycle 97

5.15 Application of LCA to Nanomaterials 97

5.16 Conclusions 98

References 98

6 Addressing Nanotoxicity: Green Nanotechnology for a Sustainable Future 103
Dipyaman Mohanta and Md. Ahmaruzzaman

6.1 Introduction 103

6.2 Nanotoxicity: A Multifaceted Challenge 104

6.3 Physicochemical Properties of Nanomaterials Influencing Nanotoxicity 105

6.4 Green Nanotechnology: A Proactive Approach to Minimize Nanotoxicity 106

6.4.1 Biosynthesis of Nanomaterials 107

6.4.2 Surface Coating of Nanomaterials to Minimize Biological Interaction 107

6.4.3 Sulfidation of Metal Nanoparticles 108

6.5 Conclusion 108

Acknowledgment 109

References 109

7 Nanotechnology: Occupational Health Hazards of Nanoparticles and Legalization Challenges 113
Mohadeseh Zarei Ghobadi, Elaheh Afsaneh and Hedayatolah Ghourchian

7.1 Introduction 113

7.2 Hazard and Toxicology of Nanoparticles 115

7.2.1 Size 115

7.2.2 Shape 116

7.2.3 Specific Surface Area 116

7.2.4 Aggregation/Agglomeration 116

7.2.5 Crystallinity 116

7.2.6 Chemical Composition 117

7.2.7 Surface Charge and Modification 117

7.3 Nanoparticle Absorption 117

7.3.1 Dermal Absorption 117

7.3.2 Pulmonary Absorption 118

7.3.3 Eye Absorption 119

7.4 Instruments and Methods for Detection of Nanoparticles 119

7.4.1 Direct Methods 120

7.4.1.1 Optical Particle Sizer (OPS) 120

7.4.1.2 Condensation Particle Counter (CPC) 120

7.4.1.3 Fast Mobility Particle Sizer (FMPS) 120

7.4.1.4 Size-Selective Static Sampler 120

7.4.1.5 Diffusion Charger (DC) 120

7.4.1.6 Electrostatic Low Pressure Impactor (ELPI) 121

7.4.1.7 Electron Microscopy 121

7.4.2 Indirect Methods 121

7.5 Hazard Assessment of Nanoparticles 121

7.6 Risk Assessment and Management of Nanoparticles 122

7.7 Hazard Control 124

7.8 Federal Regulatory Compliance 128

7.8.1 OSHA 128

7.8.2 EPA 129

7.8.3 REACH 129

7.8.4 NIOSH 130

7.9 Summary 130

References 130

8 Bringing Awareness to the Darker Side of Nanoparticles 135
Paramita Karfa, Kartick Chandra Majhi and Rashmi Madhuri

8.1 What is Nano-Sized Particle or Nanoparticle? 136

8.1.1 Classification and Wide Applications of Nanoparticles 137

8.1.1.1 Classification of Nanoparticles According to Their Origin 138

8.1.1.2 Classification of Nanoparticles According to Dimension 138

8.1.1.3 Classification of Nanoparticles According to Their Composition 139

8.1.1.4 Classification of Nanoparticles According to Their Size/Shape/Morphology 139

8.1.2 Synthesis of Nanoparticles 140

8.1.3 The Other Side of the Coin: Darker Side of Nanoparticles 141

8.1.3.1 Size of the Nanoparticle 143

8.1.3.2 Morphology of the Nanoparticle 143

8.1.3.3 Composition of the Nanoparticle 144

8.1.3.4 Surface Charge of the Nanoparticle 144

8.2 Interaction of Nanoparticle with Living System: Its Effects and Mechanism 144

8.2.1 Generation of Reactive Oxygen Species (ROS) or Oxidative Stress 145

8.2.2 Inflammation in the Exposed Body Part 145

8.2.3 Genotoxicity 146

8.2.4 Probable Mechanism for Toxicity of Nanoparticle 147

8.3 Toxicological Study of Different Nanoparticles 148

8.3.1 Effect of Silver Nanoparticles (AgNPs) 148

8.3.2 Effect of Gold Nanoparticles (AuNPs) 150

8.3.3 Effect of TiO2 Nanoparticles (TiO2 NPs) 153

8.3.4 Effect of Carbon-Based Nanoparticles 154

8.4 Future Aspect 157

Acknowledgment 158

References 158

9 Mode of Transfer, Toxicity and Negative Impacts of Engineered Nanoparticles on Environment, Human and Animal Health 165
Duraiarasan Surendhiran, Haiying Cui and Lin Lin

9.1 Introduction 165

9.2 Different Engineered Nanoparticles (ENPs) and Their Commercial Uses 166

9.3 Exposure of ENPs to the Environment 167

9.3.1 Exposure of ENPs to Air 172

9.3.2 Exposure of ENPs to Soil 173

9.3.3 Exposure of ENPs to Water 174

9.4 Hazards and Nanotoxicity of ENPs on Soil Communities 175

9.4.1 Microorganisms 175

9.4.2 Earthworms 180

9.4.3 Plants 181

9.5 Health Effects on Humans and Animals 187

9.5.1 Dermal 187

9.5.2 Inhalation 188

9.5.3 Ingestion 190

9.6 Detection of Nanotoxicity and Its Challenges 192

9.7 Conclusion and Future Needs 194

References 194

10 The Impact of Nanomaterials in Aquatic Systems 205
Nhamo Chaukura, Tatenda C Madzokere, Nyembezi Mgochekim and Thato M Masilompane

10.1 Introduction 205

10.2 Sources of Nanomaterials 207

10.2.1 Engineered and Non-Engineered Nanomaterials 207

10.2.2 Carbon- and Metal-Based Nanomaterials -Synthesis and Applications 208

10.3 Transport and Environmental Fate of Nanomaterials 209

10.4 The Toxicity of Nanomaterials in Aquatic Systems 210

10.4.1 Toxicity in Plants 211

10.4.2 Toxicity in Animals 212

10.4.3 Methods for the Evaluation of Nanotoxicity 213

10.4.4 Toxicity Mechanisms 215

10.5 Future Research Directions 216

10.6 Conclusion 217

References 217

11 Nanotechnology in the Dairy Industry: Benefits and Risks 223
I.T. Smykov

11.1 Introduction 223

11.2 Associated Colloids (Micelles) 227

11.3 Nanoemulsions 227

11.4 Nanoparticles 228

11.5 Biopolymers 229

11.6 Nanofibers 229

11.7 Nanocapsules 230

11.8 Nanotubes 230

11.9 Nanofilter and Nanofiltration 231

11.10 Food Packaging 232

11.10.1 Nanosensors 233

11.10.2 Nano-Coatings 234

11.11 Toxicity and Risks 234

11.12 Part 1: Dairy Production Using Natural Nanoparticles 238

11.12.1 Casein Micelles 238

11.12.2 Milk Fat Globule 240

11.13 Part 2: The Use of Nanoparticles of Abiotic Origin for Dairy Production 250

11.13.1 Hydroxyapatite Nanoparticles 250

11.13.2 Silver Nanoparticles 253

11.13.3 Radiation Technologies in the Food Industry 256

11.14 Part 3: Toxicity and Risks Related to Nanotechnology 258

11.14.1 Block Morphometric Risks 262

11.14.2 Block Physicochemical Risks 263

11.14.3 Block Molecular Biological Risks 264

11.14.4 Block Cytological Risks 264

11.14.5 Block Physiological Risks 264

11.14.6 Block Environmental Risks 265

11.14.7 Block Risk Analysis 266

Acknowledgment 267

References 267

12 A Survey of Nanotechnology for Rocket Propulsion: Promises and Challenges 277
Luigi T. DeLuca

Glossary 277

12.1 Background 280

12.2 Introduction to Nanoenergetic Materials 281

12.2.1 Historical Excursus and Chemical Energy 281

12.2.2 Ultrafine vs. Nano-Sized Particles 281

12.2.3 Scope of Energetic Applications 282

12.2.4 A Word of Caution 282

12.3 Objectives and Contents 282

12.3.1 Reading Map 284

12.3.2 First Generation vs. Advanced nEM 285

12.4 nMe Production and Active Al Content 285

12.4.1 Active Al Content 286

12.4.2 Comments on Active Al Content 286

12.5 Particle Passivation and Coating 286

12.5.1 Native Al2O3 Thickness 288

12.5.2 Particle Passivation 288

12.5.3 Particle Coating 290

12.5.4 Comments on Particle Passivation and Coating 292

12.6 Chemical and Mechanical Activation 292

12.6.1 Roadmap on Chemical Activation 293

12.6.2 Roadmap on Chemical Self-Activation 293

12.6.3 Roadmap on Mechanical Activation 294

12.6.4 Comments on Chemical and Mechanical Activation 296

12.7 Rheology and Mechanical Properties 296

12.7.1 Roadmap on Rheology and Mechanical Properties 296

12.7.2 Comments on Rheology and Mechanical Properties 300

12.8 CCP Formation, Agglomeration, and Clustering 300

12.8.1 Roadmap on CCP Formation, Agglomeration, and Clustering 301

12.8.2 Comments on CCP Formation, Agglomeration, and Clustering 304

12.9 Augmented Steady Ballistic Properties 304

12.10 Effects of nAl on Unsteady Burning and Ignition 307

12.10.1 Unsteady Propellant Burning 307

12.10.2 Ignition of Energetic Particles and Formulations 308

12.11 Safety of Energetic Particles and Formulations 309

12.11.1 nMe and Metalized Energetic Formulations 309

12.11.2 AP/HTPB-Based Solid Propellants 310

12.11.3 Advanced Compositions 311

12.11.4 ESD Hazards 312

12.11.5 Comments on Safety 314

12.12 Aging of Energetic Particles and Formulations 315

12.12.1 Background on Aging 315

12.12.2 nMe 315

12.12.3 Solid Propellants 318

12.12.4 Comments on Aging 319

12.13 Concluding Remarks 319

Acknowledgments 321

References 321

13 Toxicity and Regulatory Concerns for Nanoformulations in Medicine 333
Nimisha Gaur, Navneet Sharma, Aditya Dahiya, Pooja Yadav, Himanshu Ojha, Ramesh K Goyal and Rakesh Kumar Sharma

13.1 Introduction 334

13.2 Definition of Nanomedicine - Crucial for Regulation 334

13.3 Epidemiological Studies on the Health Hazard 336

13.4 Deposition of Particles in the Organism 336

13.5 Occupational Safety in Medical Facilities 338

13.6 Studies on Biological Effects of TiO2 Nanoparticles 340

13.7 Studies on Biological Effects of Fe2O3 Nanoparticles 340

13.8 Studies on Biological Effects of SiO2 Particles 340

13.9 Effect of Nanoparticles at the Cellular and Molecular Level 341

13.10 Toxicity of Dendrimers 342

13.11 Toxicity of Quantum Dots 343

13.12 Environmental Issues 343

13.12.1 Handling Solid Waste 344

13.12.2 Wastewater Treatment 344

13.12.3 Combustion 345

13.13 Regulatory Measures 345

13.13.1 Medicines or Medical Devices 345

13.13.2 Register and Labeling 346

13.13.3 Better Work Safety 346

13.13.4 Nanowaste 347

13.13.5 Future Directions Required for Developing Regulations 347

13.14 Conclusions 349

References 350

14 A Way to Create Sustainable Environment: Green Nanotechnology -With an Emphasis on Noble Metals 359
Sirajunnisa Abdul Razack and Surendhiran Duraiarasan

14.1 Introduction 360

14.2 Nanoparticles 360

14.2.1 Properties of Nanoparticles 361

14.2.1.1 Electronic and Optical Properties 362

14.2.1.2 Mechanical Properties 362

14.2.1.3 Thermal Properties 363

14.2.2 Characterization of Nanoparticles 364

14.3 Fabrication 366

14.3.1 Chemical Synthesis 367

14.3.2 Biological Synthesis 370

14.3.2.1 Silver 371

14.3.2.2 Gold 379

14.3.2.3 Platinum 391

14.3.2.4 Platinum Group Metals 394

14.4 Applications of Noble NPs 396

14.4.1 Gold Nanoparticles 396

14.4.2 Silver Nanoparticles 402

14.4.3 Platinum and Platinum Group Metals 404

14.5 Conclusion and Future Perspectives 405

References 406

15 Modern Development with Green Polymer Nanocomposites: An Overview 427
Pratibha Singh, Chandra Shekhar Kushwaha and S.K. Shukla

15.1 Introduction 427

15.2 Classification 428

15.2.1 Natural Polymer 429

15.2.1.1 Cellulose 429

15.2.1.2 Chitin 430

15.2.1.3 Chitosan 431

15.2.2 Synthetic Green Polymer 431

15.2.2.1 PLA 431

15.2.2.2 PVA 432

15.3 Methods of Preparation 432

15.4 Properties 433

15.4.1 Biological Properties 433

15.4.1.1 Biocompatibility 433

15.4.1.2 Biodegradation 434

15.4.1.3 Antimicrobial 434

15.4.2 Physical Properties 435

15.4.2.1 Mechanical Properties 435

15.4.2.2 Magnetic Properties 435

15.5 Applications of Green Polymer Nanocomposite 437

15.5.1 Food Packaging 437

15.5.2 Biomedical 438

15.5.2.1 Biosensor 438

15.5.2.2 Tissue Engineering 441

15.5.2.3 Drug Delivery 443

15.5.2.4 Bone and Cartilage Tissue Regeneration 444

15.5.3 Water Treatment 445

15.5.4 Crop Protection 445

15.5.5 Electronic Devices 447

15.6 Conclusion and Future Prospects 448

Acknowledgments 448

References 448

Index 459

Authors