Biogenic nanoparticles : interplay with climate change and implications for human health /

Biogenic Nanoparticles: Interplay with Climate Change and Implications for Human Health provides an exhaustive exploration on the genesis, characteristics, and dynamic transformations of biogenic nanoparticles, unravelling the intricate mechanisms underpinning their far-reaching influence on the eve...

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Bibliographic Details
Corporate Author:	ScienceDirect (Online service)
Other Authors:	Rajput, Vishnu D. (Editor), Singh, Abhishek (Editor), Ghazaryan, Karen (Editor), Alexiou, Athanasios (Editor), Minkina, Tatiana M. (Editor)
Format:	eBook
Language:	English
Published:	Amsterdam, Netherlands ; London, United Kingdom ; Cambridge, MA, United States : Elsevier, [2025]
Subjects:	Nanoparticles. Biotechnology. Bioactive compounds. Nanoparticules. Biotechnologie. Composés bioactifs. bioengineering. Electronic books.
Online Access:	Connect to the full text of this electronic book

Table of Contents:

Front Cover
Biogenic Nanoparticles
Copyright Page
Contents
List of contributors
About the editors
Preface
Acknowledgments
I. Biogenic nanomaterials
formation,characterization, and fate
1 A comprehensive introduction on biogenic nanoparticles: fabrication, implementation, and environmental concern
1.1 Introduction
1.2 Biomedical applications
1.2.1 Antibacterial applications
1.2.2 Generalized applications
1.2.3 Disease therapy and drug delivery
1.2.3.1 Criteria of nanoparticles for anticancer application
1.2.3.2 Drug delivery system
1.2.3.3 Mechanism of antitumor activity
1.2.3.4 Antitumor drugs
1.3 Petroleum industry
1.4 Pest management
1.5 Eradication of salinity and drought stress
1.6 Wastewater treatment
1.6.1 Heavy metal removal
1.6.2 Removal of dyes
1.7 Promotion of plant growth
1.8 Formulation of cosmetics
1.9 Future perspectives and myths
1.10 Conclusion
References
2 Realistic application of biogenic nanoparticles: future perspectives and myth
2.1 Introduction
2.2 Synthesis process of BNPs
2.3 Applications of biogenic nanoparticle
2.3.1 Agricultural applications of BNPs
2.3.2 Biomedical applications
2.3.2.1 Role of biogenic nanoparticles in drug delivery systems
2.3.2.2 Therapeutic applications in cancer treatment and targeted therapy
2.3.3 Environmental remediation
2.3.4 Bioimaging and sensors
2.3.4.1 Biogenic nanoparticles as contrast agents in biomedical imaging
2.4 Case studies of successful use of biogenic nanoparticles
2.4.1 Enhanced antimicrobial activity of BSNPs
2.4.2 Mechanisms of bacterial cell disintegration
2.5 Challenges and limitations
2.5.1 Regulatory challenges and safety considerations
2.5.2 Scalability and reproducibility issues in nanoparticle synthesis.
2.6 Public perception and myths
2.6.1 Common misconceptions about biogenic nanoparticles
2.6.2 Addressing concerns regarding safety and environmental impact
2.7 Future perspectives
2.8 Conclusion
References
3 Beyond science: ethical and societal considerations in the era of biogenic nanoparticles
3.1 Introduction
3.2 Defining biogenic nanoparticles: what and how in a nutshell
3.3 Applications of biogenic nanoparticles and their multifaceted aspects
3.3.1 Biomedical sciences
3.3.2 Agricultural sciences
3.3.3 Cosmetics industry
3.3.4 Food preservation and packaging
3.3.5 Environmental sciences
3.3.6 Textile industry
3.4 Getting an edge over others: advantages of biogenic synthesis
3.5 Challenges of biogenic nanoparticles: potential toxicity, ethics, and regulations
3.6 Conclusion: the perception of biogenic nanoparticles and future prospects
Acknowledgments
References
II. Interaction of biogenic nanomaterials and the environment
4 Nanotechnology for improved crop resilience in challenging environments
4.1 Introduction
4.2 Nanotechnology?
4.3 Nano-material-mediated crop resilience against changing environments
4.4 Potential of nanotechnology for biotic stress management
4.5 Potential of nanotechnology for abiotic stress management
4.6 Nano-mediated genome editing and nanocarriers
4.7 Challenges
4.8 Future outlook and conclusion
References
5 Nanomaterial interactions with plant systems: uptake, transport, and accumulation
5.1 Introduction
5.2 Uptake and mechanism of different NPs within plant system
5.3 Foliar exposure
5.3.1 Foliar exposure
5.3.2 Root uptake
5.3.2.1 Size and chemic composition's effect
5.3.3 Surface charge of nanoparticles
5.4 Nanoparticles types
5.4.1 Metal-based nanoparticles
5.4.1.1 Silica-based nanoparticles.
5.4.1.2 Zinc-based nanoparticles
5.4.1.3 Titanium dioxide-based nanoparticles
5.4.1.4 Copper-based nanoparticles
5.4.1.5 Cerium-based nanoparticles
5.4.1.6 Iron-based nanoparticles
5.4.1.7 Nickel-based nanoparticles
5.4.1.8 Aluminum-based nanoparticles
5.4.1.9 Carbon-based nanoparticles
5.4.1.10 Fullerene nanoparticles
5.4.1.11 Single-walled carbon nanotubes
5.4.1.12 Multiwalled carbon nanotubes
5.5 Top of form
5.5.1 Translocation of NPs within plant system
5.5.2 Plant cell wall pore size
5.5.3 Nanoparticles and cell wall interaction
5.5.4 Nanoparticle and cell membrane interaction
5.6 Effect of nanoparticles on plant system
5.7 Imporatnce of sustainable goals in agriculture
5.8 Conclusion and gap analysis
Acknowledgment
References
6 Nanoparticle-induced stress in crops: impact on growth, yield, and human nutrition
6.1 Introduction
6.2 Definition and characteristics of nanoparticles
6.3 The positive implications of NPs on crop yield
6.3.1 Enhancement of crop quality and quantity
6.3.1.1 Nanofertilizers
6.3.1.2 Nanopesticides
6.3.1.3 Nanoherbicides
6.3.1.4 Nanofungicides
6.3.1.5 Nanoemulsions
6.4 Types of stress
6.4.1 Drought stress
6.4.2 Temperature stress
6.4.3 Salinity
6.4.4 Heavy metals (HMs)
6.5 Mechanism of NPs interaction
6.6 Overview of NP absorption by plants
6.6.1 Nanoparticle absorption within plant roots
6.6.2 Nanoparticle absorption in plant leaves: mechanisms for foliar uptake
6.7 Variables influencing the assimilation and intake of nutrients
6.7.1 Impact of size and chemical composition and its impacts on interactions
6.7.2 Impact of shape and surface charge
6.8 Translocation and interaction within plant system
6.8.1 Efficient translocation of NP through plant systems
6.8.2 Impact on plant pathways.
6.8.3 Potential impact of nanoparticles on photosynthesis
6.9 Adaptation to stressful environmental factors and stressful conditions caused by living organisms induced by living organisms
6.10 Mechanism of nanoparticles in alleviating environmental stresses at the molecular level
6.11 Toxicity of nanoparticles to plants
6.12 Altered structures, form and functions of plants: changes in plant morphology due to NPs interactions
6.12.1 Anatomical alterations caused by nanoparticles
6.12.2 Functional modifications in response to NPs exposure
6.12.3 Significant biochemical alterations to withstand abiotic stress
6.13 Potential threats of inadvertent NPs release
6.14 Potential threats to human health
6.15 Risk posed to plant systems and ecosystem
6.16 Controlled applications and mitigation strategies
6.17 Conclusion
6.18 Future perspective
Acknowledgment
References
7 Metal resilience: biogenic nanomaterials and interaction with heavy metal stress
7.1 Introduction
7.2 Nanotechnology and defined engineering
7.3 Class of nanoparticles
7.3.1 Carbon-based nanoparticles
7.3.1.1 Fullerenes
7.3.1.2 Graphene
7.3.1.3 Carbon nanotubes (CNTs)
7.3.1.4 Carbon nanofibers
7.3.1.5 Carbon black
7.3.1.6 Metal nanoparticles
7.3.1.7 Organic nanoparticles
7.3.1.8 Inorganic nanoparticles
7.4 Classification by dimension
7.4.1 One-dimensional nanomaterials
7.4.2 Two-dimensional nanomaterials
7.4.3 Three-dimensional nanomaterials
7.5 Biogenic nanoparticles
7.5.1 Bacteria
7.5.1.1 Biochemical mechanisms
7.5.2 Fungi
7.5.3 Algae
7.6 Applications
7.6.1 Medical applications
7.6.2 Materials and mechanical applications
7.6.3 Environmental applications
7.6.4 Applications in energy technology
7.6.5 Applications in the petroleum industry
7.7 Recommendation.
7.8 Conclusion
References
8 Mitigating drought stress: biogenic nanoparticles in agriculture and their interaction with the environmental components
8.1 Introduction
8.2 Types of nanoparticles
8.2.1 Silver
8.2.2 Gold
8.2.3 Metal oxides
8.3 Biogenic synthesis of nanoparticles
8.3.1 Plant-based (green) synthesis of nanoparticles
8.3.2 Mechanism of uptake and transport of nanoparticles
8.4 Interaction of NPs with phytohormone
8.5 Effects of biogenic NPs at the biochemical and molecular level
8.6 The promising role of nanoparticles in mitigating drought stress
8.6.1 Improvement of membrane stability
8.6.2 Nanoparticles improve phenolic compounds accumulation
8.6.3 Enhancement of plant-water relationship
8.6.4 Nanoparticles improve growth, yield, and quality
8.7 Nanoparticles/nanofertilizers in agriculture
8.7.1 Methods of nanoparticles application in agriculture
8.7.1.1 Foliar application
8.7.1.2 Root application
8.7.1.3 Stem injection or stem feeding
8.8 Interaction of nanoparticles with the environment component
8.8.1 Nanoparticle emission to the environment
8.8.1.1 Manufacture and employment
8.8.1.2 Disposal
8.8.1.3 Recycling process
8.8.2 Impact of nanoparticles on the outdoor
8.8.2.1 Mechanisms of toxicity
8.8.2.2 Environmental impact
8.8.2.3 Human health concerns
8.9 Regulatory and safety measures
References
9 Foliar and soil application dynamics: investigating the transport and mechanism of biogenic nanoparticles in the plant tissues
9.1 Introduction
9.1.1 Rudiments of biogenic nanoparticles
9.2 Biological entry points for nanoparticles: uptake mechanics
9.2.1 Leaves: pathways and factors affecting NP absorption
9.2.2 Roots: uptake and factors affecting NP absorption
9.3 Biological migration of nanoparticles: transport mechanics.