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A timely overview of techniques for involving biological organisms in the remediation of polluted ecosystems As a result of worldwide industry, urbanization, and population growth, many harmful organic and inorganic pollutants have been introduced into the environment. With bioremediation, we can use fungi, bacteria, and plants-along with their secondary metabolites-to clean up areas that have been affected by industrial and commercial activities. Biotechnology in Environmental Remediation presents a thorough consideration of the most important biologically-based remediation methods in use today. Environmental biotechnology is a more sustainable alternative to chemical and mechanical remediation methods, which explains the rapidly growing popularity of these techniques. This edited volume summarizes our current understanding of bioremediation approaches and presents research outcomes from a diverse selection of geographies and ecosystems. Chapters cover remediation techniques for pollutants affecting soil, water, air, and sediments, as well as tools for addressing these issues, including tools for assessment and monitoring. Uniquely, Biotechnology in Environmental Remediation emphasizes the latest findings on the use of secondary metabolites in bioremediation. Other topics covered include chemical sustainability, nanotechnology, and biofuels. Readers will gain an understanding of issues including: How biological organisms and their secondary metabolites are currently being used in environmental remediation projects worldwide New applications for phytomolecules, lichens, nanoparticles, rhizobacteria, and other technologies, as well as future directions for bioremediation The steps in the process of biotechnology-driven remediation, including detection, investigation, assessment, cleanup, redevelopment, and monitoring Remediation of petroleum hydrocarbons, algal carbon sequestration, wastewater management, and the role of fatty acid and proteins in remediation The investigations in this book provide important knowledge for researchers in biotechnology, ecology, environmental science, and related disciplines. Additionally, policymakers and NGOs with an interest in remediating environmental contaminants will gain valuable context. Biotechnology in Environmental Remediation is a foundation for future research on biotechnological interventions for a clean planet.

Preface xiii 1 Biotechnology and Various Environmental Concerns: An Introduction 1 Ravi K. Gangwar, Rajesh Bajpai, and Jaspal Singh 1.1 Introduction 1 References 7 2 Plant Biotechnology: Its Importance, Contribution to Agriculture and Environment, and Its Future Prospects 9 Jeny Jose and Csaba Eva 2.1 Where do Environment and Biotechnology Meet? 9 2.2 Understanding Agricultural Biotechnology 11 2.3 Animal and Plant Biotechnology 13 3 Recent Advances in the Remediation of Petroleum Hydrocarbon Contamination with Microbes 31 Parvaze A. Wani and Salami O. Rahman 3.1 Introduction 31 3.2 Sources of Petroleum Hydrocarbons 32 3.3 Composition of Petroleum Pollutants 32 3.4 Toxic Effects of Petroleum Hydrocarbons 33 3.5 Hydrocarbon-Degrading Microorganisms 34 3.6 Mechanism of Petroleum Hydrocarbon Degradation 36 3.7 Types of Hydrocarbon Degradation 38 3.8 Factors Affecting Hydrocarbon Degradation by Microorganisms 39 3.9 Conclusion 41 4 Remediation of Heavy Metals: Tools and Techniques 47 Ankita Singh and Amit Kumar Tripathi 4.1 Introduction 47 4.2 Bioremediation 48 4.3 Organism of Bioremediation 49 4.4 Techniques of Bioremediation 51 4.5 Types of Bioremediation 52 4.6 Prospects of Bioremediation 56 4.7 Advantages and Disadvantages of Bioremediation 57 4.8 Conclusion 59 5 Soil Biodiversity and Environmental Sustainability 69 Tsedekech G. Weldmichael 5.1 Introduction 69 5.2 Importance of Soil Biodiversity in Supporting Terrestrial Life and Diversity 71 5.3 Soil Biodiversity and Climate Change 75 5.4 Soil Biodiversity and Hydrological Cycle 77 5.5 Soil Biodiversity and Environmental Remediation 79 5.6 Conclusion 80 6 Plant Growth-Promoting Rhizobacteria: Role, Applications, and Biotechnology 89 Induja Mishra, Pashupati Nath, Namita Joshi, and Bishwambhar D. Joshi 6.1 Introduction 89 6.2 Functions and Role of PGPR 90 6.3 Range and Different Diversity of PGPR 91 6.4 Mechanisms of Plant Growth Promotion by PGPR 94 6.5 Biotechnological Effects of PGPR 95 6.6 PGPR Cometabolism 100 6.7 Classification and Assortment of PGPR Strains 101 6.8 Commercial Significance of PGPR 101 6.9 Future Prospects of PGPR 102 6.10 Concluding Remarks of PGPR 103 7 A Green Approach for CO2 Fixation Using Microalgae Adsorption: Biotechnological Approach 115 Priyanka Raviraj and Syed Atif Ali 7.1 Introduction 115 7.2 Effect of CO2 Emissions on Environment 116 7.3 Advanced CO2-Capturing Methods 117 7.4 Biological Methods for CO2 Capturing 118 7.5 Earlier Technologies of Carbon Dioxide Capturing 119 7.6 Natural Carbon Capture Technology: Photosynthesis 120 7.7 Microalgae as the Modern Tool to Capture CO2 121 7.8 Biology of Microalgae as Photosynthetic Organisms and CO2 Absorbers 122 7.9 Conclusion 123 8 Assessment of In-Vitro Culture as a Sustainable and Eco-friendly Approach of Propagating Lichens and Their Constituent Organisms for Bioprospecting Applications 129 Amrita Kumari, Himani Joshi, Ankita H. Tripathi, Garima Chand, Penny Joshi, Lalit M. Tewari, Yogesh Joshi, Dalip K. Upreti, Rajesh Bajpai, and Santosh K. Upadhyay 8.1 Lichens and Their Structural Organization 129 8.2 Lichens and Bioprospection 131 8.3 Lichens as Sources of Unique Metabolites 132 8.4 Need of In Vitro Culture of Lichen and Lichen Components and Its Utility in Environment Conservation 134 8.5 In Vitro Culture of Lichens/Constituent Organisms 135 8.6 Use of In Vitro Lichen Culture for Bioprospecting 139 8.7 Challenges Associated 145 8.8 Conclusion 145 9 Bioprospection Potential of Indian Cladoniaceae Together with Its Distribution, Habitat Preference, and Biotechnological Prospects 155 Rajesh Bajpai, Upasana Pandey, Brahma N. Singh, Veena Pande, Chandra P. Singh, and Dalip K. Upreti 9.1 Introduction 155 9.2 Materials and Methods 159 9.3 Results and Discussion 160 9.4 Conclusions 182 10 Biotechnological Approach for the Wastewater Management 193 Anamika Agrawal, Sameer Chandra, Anand K. Gupta, Rajendra Singh, and Jaspal Singh 10.1 Introduction 193 10.2 Effects ofWater Pollution 195 10.3 Role of Biotechnology to ControlWater Pollution 196 10.4 Role of Biotechnology in Phytoremediation 205 10.5 Conclusion 207 11 The Application of Biotechnology in the Realm of Bioenergy and Biofuels 209 Manvi Singh, Namira Arif, and Anil Bhatia 11.1 Introduction 209 11.2 Bioenergy (Biomass Energy) 210 11.3 Conclusions 217 12 Nanotechnological Approach for the Abatement of Environmental Pollution: A Way Forward Toward a Clean Environment 221 Manzari Kushwaha, Anuradha Mishra, Divya Goel, and Shiv Shankar 12.1 Introduction 221 12.2 Nanoparticles: Properties, Types, and Route of Synthesis 222 12.3 Nanoremediation for Environment Cleanup 227 12.4 Challenges in Nanoremediation of the Environment and Solution 236 12.5 Conclusion and Future Prospects 238 13 Role of Fatty Acids and Proteins in Alteration of Microbial Cell Surface Hydrophobicity: A Regulatory Factor of Environmental Biodegradation 249 Babita Kumari, Kriti Kriti, and Gayatri Singh 13.1 Introduction 249 13.2 Cell Surface Fatty Acids and Alteration in CSH 250 13.3 Proteins/Genes Responsible in CSH Modulation 253 13.4 Eicosapentaenoic Acid (EPA) 256 13.5 Factors that Influence Cell Surface Hydrophobicity 257 13.6 Conclusion 260 14 Chemical Sustainability for a Nontoxic Environment -- A Healthy Future 269 Puneet Khare, Shashi K. Tiwari, and Lakshmi Bala 14.1 Introduction 269 14.2 Basis of Sustainable Chemistry 271 14.3 Challenges in Front of Sustainable Chemistry 272 14.4 Green Chemistry: A Sustainable Approach at a Minor Level 273 14.5 Research and Education in Green and Sustainable Chemistry 274 14.6 Scope of the Concerned Field 274 14.7 Role of OECD Toward Sustainable Chemistry 275 14.8 Difference Between Green and Sustainable Chemistry 275 14.9 The 12 Principles of Green Chemistry (EPA) 276 14.10 Applications and Innovations of Sustainable Chemistry 277 14.11 In the Pharmaceutical Industry 277 14.12 Intense Use of Renewable Resources 278 14.13 Improvement in Catalytic Methods 278 14.14 Encouragement of the Use of Biomass 278 14.15 Improvement of Lignocellulose Extraction Technology 278 14.16 Improvement in Solvents 278 14.17 Biocatalyst Advancement 279 14.18 Improvement in Plastic Technology 279 14.19 Techniques for Assessing Environmentally Friendly Chemical Processes and Products 280 14.20 R&D in Sustainable Chemical Fields 280 14.21 Benefits of Sustainable Chemistry 280 14.22 Conclusion 281 Acknowledgment 281 References 281 Index 285