Natural Materials for Food Packaging Application

Natural Materials for Food Packaging Application

Analyze the future of biodegradable food packaging with this cutting-edge overview

Packaging plays an essential role in the production of food and its movement through the global supply chain. Food packaging has been a significant site of innovation recently, allowing consumers better access to natural and organic foods, extended shelf lives, and more. However, food packaging has become an increasingly serious environmental hazard, with the result that biodegradable food packaging has become a vital and growing area of research.

Natural Materials for Food Packaging Application provides a thorough and detailed introduction to natural packaging and its applications in food transportation. Treating both recent innovations and prospective future developments, it provides readers with extensive insights into the current state of research in this field. The result is a volume designed to meet the aspirational needs of a sustainable food industry.

Natural Materials for Food Packaging Application readers will also find:

• Detailed treatment of biodegradable packaging materials including thermo-plastic starch, polybutylene succinate, and more
• Discussion of subjects including chitosan-based food packaging films, clay-based packaging films, and more
• An authorial team with vast expertise in the field of biological polymer production

Natural Materials for Food Packaging Applications is a useful reference for chemists, materials scientists, and food scientists, as well as for any industry professionals working in food distribution and the food supply chain.

Preface xiii

About the Editors xv

1 Introduction to Natural Materials for Food Packaging 1
Manickam Ramesh, Lakshminarasimhan Rajeshkumar, Venkateswaran Bhuvaneswari, and Devarajan Balaji

1.1 Introduction 1

1.2 Natural Biodegradable Polymers 4

1.2.1 Starch-Based Natural Materials 4

1.2.2 Poly-Lactic Acid-Based Natural Materials 5

1.2.3 Poly-Caprolactone (PCL)-Based Natural Materials 5

1.2.4 Poly-Hydroxy Alkanoate-Based Natural Materials 6

1.2.5 Polyglycolide-Based Natural Materials 6

1.2.6 Polycarbonate-Based Natural Materials 7

1.2.7 Soy-Based Bio-degradable Polymers 7

1.2.8 Polyurethanes 7

1.2.9 Polyanhydrides 7

1.3 Biodegradable Polymer Blends and Composites 8

1.3.1 Polylactic Acid and Polyethylene Blends 8

1.3.2 PLA and Acrylobutadiene Styrene (ABS) Blends 8

1.3.3 PCL and Polyethylene Blends 8

1.3.4 PCL and Polyvinyl Chloride Blends 9

1.3.5 TPS and Polypropylene Blends 9

1.3.6 TPS/PE Blends 9

1.3.7 Poly(Butylene Succinate) Blends 10

1.4 Properties of Natural Materials for Food Packaging 10

1.4.1 Barrier Properties 10

1.4.2 Biodegradation Properties 11

1.4.3 Consequences of Storage Time 12

1.5 Environmental Impact of Food Packaging Materials 14

1.6 Conclusion 14

References 15

2 Plant Extracts-Based Food Packaging Films 23
Aris E. Giannakas

2.1 Introduction 23

2.2 Extraction Methods for Plant Extracts 24

2.3 Research Investigation of Bibliographic Data 25

2.4 Chitosan Plant Extract-Based Food Packaging Films 27

2.5 Starch/Extract-Based Food Packaging Films 30

2.6 Cellulose and Cellulosic Derivatives-Based Food Packaging Films Modified with Plant Extract 32

2.7 Gelatin and Alginate/Plant Extract-Based Food Packaging Films 34

2.8 Composites/Plant Extract-Based Food Packaging Films 35

2.8.1 Chitosan Composites/Plant Extract-Based Food Packaging Films 36

2.8.2 Starch Composites/Extract-Based Food Packaging Films 38

2.8.3 Other Composites Plant Extract-Based Food Packaging Films 39

2.9 Conclusion 41

­Acknowledgment 41

References 42

3 Essential Oils in Food Packaging Applications 51
Madhushree Hegde, Akshatha Chandrashekar, Mouna Nataraja, Niranjana Prabhu, Jineesh A. Gopi, and Jyotishkumar Parameswaranpillai

3.1 Introduction 51

3.2 Chemistry and Classification of Essential Oils 52

3.3 Essential Oils in Food Packaging Applications 55

3.3.1 Effect of Essential Oil on the Mechanical, Barrier, and Other Physical Properties of Food Packaging Materials 55

3.3.1.1 Tensile Properties 55

3.3.1.2 Barrier Properties 56

3.3.1.3 Other Physical Properties 56

3.3.2 Antioxidant Properties of Essential Oil Incorporated Food Packaging Materials 58

3.3.3 Antibacterial Properties of Essential Oil Incorporated Food Packaging Materials 61

3.4 Challenges and Future Trends Associated with the Use of Essential Oil in Food Packaging Applications and Future Trends 65

3.5 Conclusions 65

References 66

4 Agro-Waste Residue-Based Food Packaging Films 75
Rajarathinam Nithya and Arunachalam Thirunavukkarasu

4.1 Introduction 75

4.2 Agro-Waste-Based Biopolymers 76

4.2.1 Cellulose 76

4.2.2 Hemicellulose 77

4.2.3 Lignin 77

4.2.4 Starch 78

4.2.5 Pectin 79

4.3 Edible Coatings and Films – Classification and Properties 80

4.4 Conclusion and Future Prospects 83

References 83

5 Hydrogel-Based Food Packaging Films 89
Kunal Singha and Kumar Rohit

5.1 Introduction 89

5.2 Hydrogel Nature, Definition 91

5.2.1 Hydrogel Types and Features 91

5.2.1.1 Classification According to Polymeric Composition 91

5.2.1.2 Classification Based on Configuration: Classification is Done Based on the Setting 91

5.2.1.3 Classification Based on the Type of Cross-Linking 91

5.2.1.4 Classification Based on Physical Appearance 92

5.2.1.5 Classification According to Network Electrical Charge 92

5.3 Preparation of Hydrogel Film 92

5.4 Hydrogel as Food Packaging Material 92

5.4.1 Hydrogels Functional Properties 93

5.5 Classification of Hydrogel 93

5.6 Hydrogels Functional Properties 93

5.7 Potential Application of Hydrogel in Food Packaging Systems 95

5.7.1 Applications of Hydrogels in Vitro and Food Matrices 96

5.7.2 Biodegradable Packaging 96

5.7.3 Biodegradability 97

5.7.4 Other Potential Applications in the Food Industry 98

5.8 Latest Development in the Hydrogel in the Field of Food Packaging 98

5.9 Futuristic Uses of Hydrogel in Miscellaneous Process 99

5.10 Conclusions 100

References 101

6 Natural Fiber-Based Food Packaging Films 105
G. Rajeshkumar, M. Karthick, A.K. Aseel Ahmed, T. Vikram Raj, V. Abinaya, K. Madhu Mitha, and R. Ronia Richelle

6.1 Introduction 105

6.2 Manufacturing of Fiber-Reinforced Biofilms 107

6.3 Rice Straw-Based Films 109

6.4 Wheat Straw-Based Films 109

6.5 Jute-Based Films 111

6.6 Pineapple-Based Films 112

6.7 Flax-Based Films 113

6.8 Kenaf-Based Films 114

6.9 Hemp-Based Films 115

6.10 Conclusions 115

References 116

7 Natural Clay-Based Food Packaging Films 121
Ram Kumar Deshmukh, Dakuri Ramakanth, Konala Akhila, and Kirtiraj K. Gaikwad

7.1 Introduction 121

7.2 Clay Materials Classification 127

7.2.1 TO or 1:1 Type (One‐One Tetra‐octahedral Layer) 127

7.2.2 TOT or 2:1 Type (One‐Octahedral in Between Two Tetrahedral Layers) 128

7.2.3 2:1:1 or TOTO Type (Two Tetrahedral with Two Octahedral) 128

7.3 Preparation of Natural Clay Nanocomposites 128

7.3.1 In situ Polymerization Method 130

7.3.2 Solution‐Induced Intercalation 130

7.3.3 Melt Processing 130

7.4 Properties of Natural Clay‐Based Nanocomposite Polymer 130

7.4.1 Mechanical Properties 131

7.4.2 Barrier Properties 132

7.4.3 Thermal Stability of Clay‐Based Polymer Composites 133

7.4.4 Oxygen and Ethylene Scavenging Activity of Nano‐Clay Polymer Composite 133

7.5 Application of Natural Clay in Food Packaging Film 135

7.5.1 Montmorillonite (MMT)‐Based Nanocomposite 139

7.5.2 Laponite‐Reinforced Polymer Nanocomposite 141

7.5.3 Sepiolite‐Reinforced PNC 141

7.5.4 Bentonite‐Reinforced Polymer Nanocomposite 142

7.5.5 Hectorite‐Reinforced Polymer Nanocomposite 143

7.5.6 Rectorite‐Reinforced Polymer Nanocomposite 144

7.5.7 Other Nanoclay Materials‐Based Nanocomposites 145

7.6 Challenges of Using Clay in Food Packaging Applications 145

7.6.1 Migration and Exposure of Nanoclay Materials to Humans and the Environment 146

7.6.2 Toxicity of Nanoclay 148

7.7 Future Outlook and Conclusion 149

References 150

8 Curcumin-Based Food Packaging Material 165
Leidy T. Sanchez, Andres F. Cañon-Ibarra, J. Alejandro Arboleda-Murillo, and Cristian C. Villa

8.1 Structural Characteristics of Curcumin 165

8.2 Antimicrobial, Antifungal, and Antioxidant Properties of Curcumin 166

8.3 Nanoencapsulation of Curcumin 167

8.4 Curcumin-Based Food Packaging 168

8.5 Curcumin-Based Nanocomposite Food Packaging 169

8.6 Curcumin-Based Active Food Packaging 169

8.7 Curcumin-Based Intelligent Food Packaging 170

8.8 Perspectives 171

References 171

9 Sustainable Materials from Starch-Based Plastics 179
Asanda Mtibe and Maya J. John

9.1 Introduction 179

9.1.1 Starch 179

9.1.2 Preparation of Thermoplastic Starch (TPS) 180

9.1.3 Plasticization of Starch 180

9.1.4 Processing of TPS 183

9.1.5 Properties of TPS 185

9.1.5.1 Mechanical Properties 185

9.1.5.2 Thermal Properties 186

9.1.5.3 Barrier Properties 186

9.2 TPS-Biopolymer Blends 187

9.3 TPS-Biopolymer Composites 188

9.4 Global Producers, Market Volumes, and Applications of Starch-Based Plastics 191

9.5 Conclusions 193

References 193

10 Main Marine Biopolymers for Food Packaging Film Applications 199
Jesús Rubén Rodríguez-Núñez, Diana Gabriela Montoya-Anaya, Judith Fortiz-Hernández, Yolanda Freile-Pelegrín, and Tomás Jesús Madera-Santana

10.1 Introduction 199

10.2 Polysaccharides from Seaweeds 200

10.2.1 Main Seaweed Polysaccharides 201

10.2.2 Alginate 202

10.2.2.1 Properties and Limitations of Alginate 204

10.2.2.2 Applications of Alginate in Edible Films and Coatings 205

10.2.3 Agar 205

10.2.3.1 Applications of Agar in Edible Films and Coatings 210

10.2.4 Carrageenan 213

10.2.5 Fucoidan 216

10.2.6 Ulvan 218

10.3 Modified Chitosan for Food Film Applications 220

10.3.1 Chemical Modifications of Chitosan for Food Packaging 220

10.3.2 Chitosan Blends/Composites for Films and Coating for Food Applications 222

10.3.3 Nanomaterials of Chitosan for Food Packaging 224

10.4 Conclusions and Future Trends 226

References 227

11 Chitosan-Based Food Packaging Films 241
Kunal Singha and Kumar Rohit

11.1 Introduction 241

11.1.1 A Brief History of Food Packaging Materials Used 241

11.1.2 Characteristics of Typical Food Packaging Materials 242

11.1.3 Need for Biodegradable Food Packaging Materials 242

11.2 Chitin and Chitosan Chemical Structure 243

11.3 Chitosan as a Potential Biodegradable Food Packaging Material 243

11.3.1 Chitosan as Food Packaging Material 244

11.3.2 Chitosan Film in Food Packaging and Their Types 244

11.3.2.1 Chitosan-Based Films 245

11.3.2.2 Flexible Packaging Films 245

11.3.3 Chitosan Film in Food Packaging 245

11.3.4 Films Embedded with Nanomaterials 245

11.3.5 Films Embedded with Clays 246

11.3.6 Films Embedded with Polysaccharide Particles, Fibres, and Whiskers 247

11.3.7 Films Embedded with Natural Oils and Extracts 247

11.4 Future Research Directions and Developments 249

11.4.1 Chitin/Chitosan Derivatives and Their Interactions with Microorganisms: A Comprehensive Review and Future Perspectives 249

11.4.2 A Future Perspective in Crop Protection: Chitosan and its Oligosaccharides 249

11.4.3 Chitosan in Molecularly-Imprinted Polymers: Current and Future Prospects 250

11.4.4 Crosstalk Between Chitosan and Cell Signaling Pathways 250

11.4.5 Resorbable Chitosan Matrix – As a Promising Biomaterial for the Future 250

11.5 Conclusions 251

References 251

12 Effect of Natural Materials on Thermal Properties of Food Packaging Film: An Overview 255
H. M. Prathibhani C. Kumarihami, Nishant Kumar, Pratibha, Anka T. Petkoska, and Neeraj

Abbreviations 255

12.1 Introduction 256

12.2 Biodegradable Films: An Alternative for Food Packaging 257

12.2.1 Biodegradable Polymers 258

12.3 Thermal Properties of Food Packaging 259

12.4 Effects of Natural Materials on the Thermal Stability of Food Packaging 260

12.4.1 Effects of Plant Extract 260

12.4.2 Effects of Essential Oils 261

12.4.3 Effects of Color Agent 262

12.4.4 Effects of Nanomaterials 263

12.4.5 Effects of Plasticizers 265

12.4.6 Effects of Emulsifiers 266

12.5 Conclusions 266

References 267

13 Mechanical Properties of Natural Material-Based Packaging Films: Current Scenario 275
Johnsy George, Muhammed Navaf, Aksalamol P. Raju, Ranganathan Kumar, and Kappat V. Sunooj

13.1 Introduction 275

13.2 Mechanical Properties of Packaging Films 276

13.2.1 Tensile Strength (TS) 277

13.2.2 Young’s Modulus (Y) 277

13.2.3 Elongation at Break (EB) 278

13.2.4 Seal Strength 278

13.2.5 Tear Resistance 278

13.2.6 Puncture Resistance 279

13.2.7 Impact Resistance 279

13.2.8 Burst Strength 279

13.3 Mechanical Properties of Natural Polymer-Based Packaging Films 279

13.3.1 Naturally Occurring Polymers 280

13.3.1.1 Starch 280

13.3.1.2 Cellulose 283

13.3.1.3 Chitosan 284

13.3.1.4 Alginates 285

13.3.1.5 Pectin 285

13.3.1.6 Casein 286

13.3.1.7 Whey Protein 287

13.3.1.8 Collagen 287

13.3.1.9 Gelatin 288

13.3.1.10 Zein Protein 289

13.3.1.11 Soy Protein 290

13.3.1.12 Gluten Protein 291

13.3.2 Polymers Synthesized from Natural/Bioderived Monomers 292

13.3.2.1 Polylactic Acid (PLA) 292

13.3.2.2 Polyethylene Furanoate (PEF) 295

13.3.2.3 Polybutylene Succinate (PBS) 295

13.3.2.4 Poly(Butylene Adipate-­co-Terephthalate) 296

13.3.2.5 Bio-based Polyethylene 296

13.3.2.6 Bio-Based Polypropylene (Bio-PP) 296

13.4 Mechanical Properties of Natural Polymers Synthesized from Microorganisms-Based Packaging Films 296

13.4.1 Polymer Processed from Microorganisms 296

13.4.1.1 Polyhydroxyalkanoate (PHA) 296

13.4.1.2 Bacterial Cellulose 298

13.4.1.3 Xanthan 299

13.4.1.4 Pullulan 299

13.4.1.5 Gellan 300

13.4.1.6 Levan 300

13.5 Conclusion 300

References 301

14 Effects of Natural Materials on Food Preservation and Storage 313
Subhanki Padhi and Winny Routray

14.1 Introduction 313

14.1.1 Major Objective of Food Preservation and Storage 313

14.1.2 Available Solutions from the Natural Resources and Combination with Technology 314

14.2 Biomolecules Utilized for Preservation,Their Properties, and Uses 315

14.2.1 Polysaccharides 315

14.2.2 Essential Oil 316

14.2.3 Phenolic Compounds 318

14.2.4 Aromatic Compounds 319

14.2.5 Proteins 320

14.2.6 Bacteriocins 320

14.2.7 Other Animal-Based Antimicrobials 321

14.3 Different Extraction Processes Employed for Natural Materials 321

14.4 Effects of Natural Materials on Different Product Quality and Storage 323

14.4.1 Drying Methods and Corresponding Properties 323

14.4.2 Enhancement of Packaging Characteristics 323

14.4.3 Maintenance of Physiochemical Properties of Raw and Processed Products 324

14.5 Conclusion 325

References 326

15 Marketing, Environmental, and Future Perspectives of Natural Materials in Packaging 333
Prakash Binu, Sasi Arun Sasi, Velamparambil Gopalakrishnan Gopikrishna, Abdul Shukkur, Balu Balachandran, and Mahesh Mohan

15.1 Introduction 333

15.2 Biodegradable Food Packaging 334

15.3 Different Bio-Based Packaging Materials 336

15.3.1 Bioplastics 336

15.3.2 Biopolymers 336

15.4 Nano Food Packaging 338

15.5 Natural Antimicrobial Agents in Food Packaging 338

15.6 Edible Films in Food Packaging 339

15.7 Environment and Food Packaging 341

15.8 Sustainable Packaging 342

15.9 Marketing of Natural Materials in Packaging 343

15.10 Future Perspectives of Natural Materials in Packaging 344

15.11 Conclusion 345

References 345

Index 353

Chapter 1 Introduction to natural materials for food packaging
Chapter 2 Curcumin based food packaging material
Chapter 3 Plant extract-based food packaging films
Chapter 4 Hydrogel based food packaging films
Chapter 5 Thermoplastic starch-based food packaging films
Chapter 6 Natural fiber based food packaging films
Chapter 7 Natural clay-based food packaging films
Chapter 8 Polysaccharide (starch/cellulose) based food packaging films
Chapter 9 Chitosan based food packaging films
Chapter 10 Chitin based food packaging films
Chapter 11 Agrowaste residue (rice straw, shrimp waste) based food packaging films
Chapter 12 Natural material based edible films
Chapter 13 Essential oil-based packaging films
Chapter 14 Antimicrobial mechanisms and efficiency exhibited by natural materials in food packaging films
Chapter 15 Effect of natural materials on thermal properties of packaging films
Chapter 16 Influence of natural materials on water barrier properties of packaging films
Chapter 17 Influence of natural materials on thickness and mechanical behaviour of packaging films
Chapter 18 Effects of natural materials on food preservation and storage
Chapter 19 Natural material-based films as a function of pH indication/ pH indicating nanocomposite-based films
Chapter 20 Marketing, environmental and future perspectives of natural materials in packaging

Jyotishkumar Parameswaranpillai, PhD, is an Associate Professor in the Department of Science at Alliance University, Karnataka, India. He has postdoctoral experience in laboratories on multiple continents, and has published enormously widely on biological polymer research subjects.

Aswathy Jayakumar, PhD, is a Postdoctoral Fellow in the Department of Food and Nutrition at Kyung Hee University, Seoul, South Korea. She received the 2019 Best Paper Award at the Kerala Science Congress, and her research concerns the functional biology of endophytic microorganisms.

E. K. Radhakrishnan, PhD, is an Assistant Professor in the School of Biosciences and Joint Director of the Inter-University Centre for Organic Farming and Sustainable Agriculture, Mahatma Gandhi University, Kottayam, India. He has published extensively on plant microbe interactions, polymer-based nanocomposites for food packaging, and related subjects.

Suchart Siengchin, PhD, is a Lecturer and Researcher in the Thai-German Graduate School of Engineering, King Mongkut’s University of Technology, North Bangkok, Thailand (KMUTNB). He is a three-time winner of the Outstanding Researcher Award at KMUTNB, and has published and presented extensive research on engineering and materials science subjects.

Sabarish Radoor, PhD, is a Postdoctoral Researcher at King Mongkut's University of Technology, North Bangkok, Thailand (KMUTNB). He has published roughly 25 research papers.

Dr. Jyotishkumar Parameswaranpillai earned a Ph.D. in polymer science and technology (chemistry) at the Mahatma Gandhi University, India. He has research experience at various international laboratories, such as the Leibniz Institute of Polymer Research Dresden (IPF), Germany; Catholic University of Leuven, Belgium; University of Potsdam, Germany and King Mongkut?s University of Technology North Bangkok, Thailand. He has published more than 110 papers, 40 book chapters, and 25 books as editor. Most of his books are best-selling in the field.

Ms. Aswathy Jayakumar completed her Ph.D in Biotechnology at the School of Biosciences, Mahatma Gandhi University, Kottayam, India. After her MSc. in Biotechnology, she has completed M.Phil in Biosciences and has authored seventeen publications (including book chapters). She received best paper award in Biotechnology 2019 at the Kerala Science Congress (Kerala State Award). Her area of research is functional biology of endophytic microorganisms and nanotechnology-based food packaging systems.

Dr. Radhakrishnan E.K. is currently working as Assistant Professor at the School of Biosciences, Mahatma Gandhi University, Kottayam, India as Director of Business Innovation and Incubation Centre (BIIC) and as Joint Director of Inter University Centre for Organic Farming and Sustainable Agriculture (IUCOFSA), Mahatma Gandhi University, Kottayam, India. He completed his doctoral degree at the Rajiv Gandhi Centre for Biotechnology, Thiruvananthapuram, Kerala, India in 2008 and Post-doctoral studies at the Tokyo Biochemical Research Foundation, The University of Tokyo, Japan in 2010. During his 16 years of research, he has more than 121 research publications, book chapters and review papers. So far twelve Ph.Ds have been completed under his guidance. He has completed four major research projects from various funding agencies. His research area includes plant microbe interactions, microbial natural products microbial synthesis of metal nanoparticles, Polymer based nanocomposites for food packaging and medical materials with antimicrobial effects.

Prof. Dr.-Ing. habil. Suchart Siengchin received his Dipl.-Ing. in Mechanical Engineering at the University of Applied Sciences Giessen/Friedberg, Germany in 1999, M.Sc. in Polymer Technology at the University of Applied Sciences Aalen, Germany in 2002, M.Sc. in Material Science at the Erlangen-Nuernberg University, Germany in 2004, Doctor of Philosophy in Engineering (Dr.-Ing.) at the Institute for Composite Materials, University of Kaiserslautern, Germany in 2008 and Postdoctoral Research at Kaiserslautern University, Germany and School of Materials Engineering, Purdue University, USA. In 2016 he received the habilitation at the Chemnitz University, Germany. He worked as a Lecturer for Production and Material Engineering Department at The Sirindhorn International Thai-German Graduate School of Engineering (TGGS), KMUTNB. He has been full Professor at KMUTNB and became the President of KMUTNB. He won the Outstanding Researcher Award in 2010, 2012 and 2013 at KMUTNB. His research interest lies in Polymer Processing and Composite Material. He is Editor-in-Chief: KMUTNB International Journal of Applied Science and Technology and the author of more than 100 peer reviewed journal articles. He has participated with presentations in more than 39 International and National Conferences with respect to Materials Science and Engineering topics.

Dr. Sabarish Radoor is currently working as a postdoctoral researcher at the King Mongkut?s University of Technology North Bangkok. He has published around 25 research papers.

Analyze the future of biodegradable food packaging with this cutting-edge overview

Packaging plays an essential role in the production of food and its movement through the global supply chain. Food packaging has been a significant site of innovation recently, allowing consumers better access to natural and organic foods, extended shelf lives, and more. However, food packaging has become an increasingly serious environmental hazard, with the result that biodegradable food packaging has become a vital and growing area of research.

Natural Materials for Food Packaging Application provides a thorough and detailed introduction to natural packaging and its applications in food transportation. Treating both recent innovations and prospective future developments, it provides readers with extensive insights into the current state of research in this field. The result is a volume designed to meet the aspirational needs of a sustainable food industry.

Natural Materials for Food Packaging Application readers will also find:

• Detailed treatment of biodegradable packaging materials including thermo-plastic starch, polybutylene succinate, and more
• Discussion of subjects including chitosan-based food packaging films, clay-based packaging films, and more
• An authorial team with vast expertise in the field of biological polymer production

Natural Materials for Food Packaging Applications is a useful reference for chemists, materials scientists, and food scientists, as well as for any industry professionals working in food distribution and the food supply chain.