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Food, Medical, and Environmental Applications of Nanomaterials [Pehme köide]

Edited by , Edited by (Assistant Professor & Canada Research Chair in Food Proteins and Bioproducts), Edited by , Edited by , Edited by (Professor of Environmental Engineering and Director of Water, Effect Technologies and Tools (WETT) Research Centre at RMIT University, Melbourne, Australia)
  • Formaat: Paperback / softback, 570 pages, kõrgus x laius: 235x191 mm, kaal: 1180 g, 150 illustrations (150 in full color); Illustrations
  • Sari: Micro & Nano Technologies
  • Ilmumisaeg: 28-Mar-2022
  • Kirjastus: Elsevier Science Publishing Co Inc
  • ISBN-10: 012822858X
  • ISBN-13: 9780128228586
Teised raamatud teemal:
Food, Medical, and Environmental Applications of NanomaterialsSuurem pilt
  • Formaat: Paperback / softback, 570 pages, kõrgus x laius: 235x191 mm, kaal: 1180 g, 150 illustrations (150 in full color); Illustrations
  • Sari: Micro & Nano Technologies
  • Ilmumisaeg: 28-Mar-2022
  • Kirjastus: Elsevier Science Publishing Co Inc
  • ISBN-10: 012822858X
  • ISBN-13: 9780128228586
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780128228586.html
Märksõnad:
Food, Medical, and Environmental Applications of Nanomaterials is designed to cover different types of nanomaterials that have applications related to the environment, food and medicine. It is an important resource for materials scientists and bioengineers looking to learn more about the applications of nanomaterials for sustainable development applications. Nanoscale materials possess excellent properties that have been explored in the areas of biomedicals, food, agriculture, the environment, catalysis, sensing and energy storage. Examples of these new applications include smart and active food packaging, nanobiosensors, bioremediation, wastewater treatment, implant coatings, tissue engineering, delivery systems for food and pharmaceutical applications, and food safety.
  • Helps readers make decisions on the suitability and appropriateness of a synthetic route and characterization technique for a particular nanosystem
  • Enables readers to analyze and compare experimental data and extract in-depth information about the physical properties of the polymeric gels using mathematical models
  • Teaches users about the applications of nanomaterials for sustainable development applications
Contributors ix
1 Fabrication of nanomaterials
1(40)
Vaidhegi Kuyarajah
Hushnaara Hadem
Anil Kumar Ojha
Shivcndu Ranjan
Nandita Dasgupta
Bhaitendu Narh Mishra
Sangeetha Dharmalingam
1 Introduction
2(3)
2 Fabrication of nanomaterials
5(2)
3 Top-down fabrication methods
7(10)
4 Bottom-up fabrication methods
17(9)
5 Other common methods available for nanomaterials production
26(6)
6 Nanocomposites
32(1)
7 Future trends
33(8)
References
33(8)
2 Nanoparticles and nanofluids: Characteristics and behavior aspects
41(32)
Vaidhegi Kuyarajah
Atul Kumar Ojha
Hushnaara Hadem
Nandita Dasgupta
Bhartendu Nath Mishra
Shivcndu Ranjan
Ami Sanycctha Dharmaltngam
1 Introduction
42(3)
2 Nanoparticle aggregation and dispersion behavior
45(3)
3 Physicoch Jical characteristics of nanoparticles
48(3)
4 Interactions between nanoparticles
51(2)
5 Properties of nanofluid
53(9)
6 Mass transfer in nanofluids
62(2)
7 Future trends
64(9)
References
64(9)
3 Robust organometallic gold nanoparticles in nanomedicine engineering of proteins
73(22)
Mahrcen Arooj
Mchavcsh Hamccd
Sccma Panickcr
Ihsan Shchadi
Ahmed A. Mohamcd
1 Introduction
74(1)
2 BSA conjugated gold-carbon nanoparticles with outstanding robustness and hemocompatibility
74(2)
3 Green and cytocompatible carboxyl-modified gold-lysozyme antibacterial
76(1)
4 Inhibition of amyloid fibrillation at carboxyl-tailored gold-aryl nanoparticles
76(4)
5 Protein-coated gold nanoparticles: Green and chemical synthesis routes and their cellular uptake
80(4)
6 Computational methods
84(6)
7 Conclusion
90(5)
References
90(5)
4 Polysaccharide-based nanomaterials
95(18)
Lily Jaiswal
Alya Limaycm
Shiv Shankar
1 Introduction
95(2)
2 Agar nanoparticles
97(1)
3 Agarose nanoparticle
98(1)
4 Alginate nanoparticles
99(1)
5 Carrageenan nanoparticles
100(1)
6 Chitin nanoparticles
101(2)
7 Chitooligosaccharide nanoparticles
103(1)
8 Chitosan nanoparticles
104(1)
9 Cellulose nanoparticles
105(1)
10 Conclusion
106(7)
References
106(7)
5 Lipid-based nanostructures in food applications
113(16)
Anujit Ghosal
Nandika Bandara
1 Introduction: Potential of lipid-based nanostructure
113(2)
2 Type of lipid nanostructures used in food industries
115(5)
3 Different synthesis methodologies
120(2)
4 Application of lipid nanostructure in food industries
122(1)
5 Future of lipid-based nanostructures
123(6)
References
124(5)
6 Bio-based multifunctional nanomaterials: Synthesis and applications
129(38)
Tarangini Korumilli
K. Jagajjanani Rao
Sai Satccsh Sagiri
1 Introduction
130(2)
2 Biomolecules in nanomaterial synthesis
132(1)
3 Microbial molecules in nanomaterial synthesis
132(8)
4 Plant resources in nanoparticle synthesis
140(4)
5 Template-based synthesis
144(2)
6 NP shape control with biomolecular systems
146(6)
7 Extensive use of nanoparticles
152(2)
8 Scope and applications of as-synthesized NPs
154(4)
9 Summary and future outlook
158(9)
Acknowledgement
159(1)
References
159(8)
7 Nanocomposites in food packaging
167(38)
Debarshi Nath
Rahul Chetri
R. Santhosh
Preetam Sarkar
1 Introduction
167(2)
2 Fabrication methods of nanocomposites
169(3)
3 Types of nanoparticles
172(3)
4 Essential oils
175(1)
5 Effect of the incorporation of nanoparticles and EOs on the properties of the nanocomposite packaging films
176(17)
6 Regulatory issues
193(3)
7 Concluding remarks
196(9)
References
196(9)
8 Nano delivery systems for food bioactives
205(26)
L. Mahalakshmi
K.S. Yoha
J.A. Moses
C. Anandharamakrishnan
1 Introduction
205(2)
2 Requirement of nano delivery system
207(1)
3 Properties of the delivery system
208(1)
4 Nano delivery system
209(16)
5 Conclusion and future perspective
225(6)
References
226(5)
9 Nanostructures for improving food structure and functionality
231(22)
Sophia Devi Nongmaithem
Nishant Rachayya Swami Hullc
1 Introduction
231(1)
2 Overview of methods for nanostructure formations
232(7)
3 Sources of biopolymers for nanostructure development
239(4)
4 Application on nanostructures in food systems
243(4)
5 Conclusion
247(6)
References
247(6)
10 Nanotechnology in microbial food safety
253(52)
Ahhinandan Pal
Kanishka Bhunia
1 Introduction
254(2)
2 Interaction between nanoparticles and microbes
256(10)
3 Antimicrobial nanocoating
266(2)
4 Anti-fouling surface
268(2)
5 Antimicrobial nanomaterials for biofilm
270(2)
6 Nanoencapsulation
272(2)
7 Nanophotosensitizer
274(3)
8 Application of nanotechnology in microbial food safety
277(11)
9 Risk assessment
288(1)
10 Regulatory and legislative aspects
289(1)
11 Final rematks
290(15)
References
291(14)
11 Electroconductive nanofibrillar biocomposite platforms for cardiac tissue engineering
305(26)
Tarun Agarwal
Shcri-Ann Tan
Lei Nie
Ensieh Zahmatkesh
Aafrcen Ansari
Niloofar Khoshdcl Rad
Ibrahim Zarkesh
Tapas Kumar Maiti
Massoud Vosough
1 Introduction
307(1)
2 Nanotopologies and electrical stimulation-- Intrinsic biophysical determinant of CMs
308(1)
3 Strategies for fabricating electroactive nanofibrous platforms
309(1)
4 Recent developments in electroconductive nanofibrillar platforms for CTE
310(15)
5 Conclusion and outlook
325(6)
Acknowledgment
325(1)
Conflict of interest
325(1)
References
325(6)
12 Impacts of nanotechnology in tissue engineering
331(24)
Mh Busra Fauzi
Jia Xian Law
Min Hwci Ng
Yogeswaran Lokanarhan Nadiah Sulatman
Ariqah Safleh
1 Nanomaterials for skin repair and regeneration
332(3)
2 Nanomaterial technology for eye regeneration
335(2)
3 Nanostructured biomaterial used in bone regeneration
337(3)
4 Nanomaterials in management of chronic respiratory diseases and mucosal injury
340(3)
5 Biomaterials in cardiovascular tissue engineering and regenerative medicine
343(12)
References
346(9)
13 Piezoelectric nanomaterials for biomedical applications
355(24)
Akash Roy
Dipanjan Dwarf
Mukcsh Kumar Ram
Pallah Dana
1 Introduction and origin of piezoelectricity
356(2)
2 Preparation of piezoelectric materials
358(4)
3 Biomedical applications of piezoelectric nanomaterials
362(11)
4 Conclusions
373(6)
References
374(5)
14 Nanotechnology-based interventions for interactions with the immune system
379(34)
Sayandccp Saha
Shalini Dasgupta
Ananya Barui
1 Introduction
380(1)
2 Emerging clinical needs of human immune physiology
380(7)
3 Nanotechnology and nanoparticles for vaccination
387(8)
4 Treatment of immunosuppressive diseases with nanoparticles
395(2)
5 Cancer treatment with nanotechnology by immune modulation
397(10)
6 Conclusion
407(6)
Acknowledgment
407(1)
References
408(5)
15 Polycaprolactone-based shape memory polymeric nanocomposites for biomedical applications
413(22)
Vaishnavi Hada
S.A.R. Hashmi
Mcdha Mili
Nikhil Gorhc
Sai Sateesh Sagiri
Kunal Pal
Rashmi Chawdhary
Manal Khan
Ajay Naik
N. Prashant
A.K. Srivastava
Sarika Vcrma
1 Introduction
414(1)
2 An insight of shape-memory polymers and shape memory effect
415(2)
3 Significance of SMPs in biomedical applications
417(2)
4 Synthesis and properties of PCL
419(3)
5 PCL-based shape memory polymeric nanocomposites
422(4)
6 Scope and future perspective
426(2)
7 Conclusion
428(7)
Acknowledgment
428(1)
Conflicts of interest
429(1)
References
429(6)
16 Nanoemulsions for antitumor activity
435(20)
Soma Mukherjec
Darryl L. Holliday
Naharaj Banjara
Navam Hcttiarachchy
1 Introduction
435(5)
2 Nanoemulsion and MDR
440(1)
3 Application and different types of cancer therapy
441(8)
4 Theragonostic application of nanoemulsion
449(1)
5 Future prospects
449(1)
6 Conclusion
450(5)
References
450(5)
17 Nanomaterials for aging and cosmeceutical applications
455(18)
Mh Busra Fauzi
Ali Smandri
Ibrahim N. Amirrab
Nurkhuzaiah Kamaruzaman
Ariqah Sallch
Zawani Mazlan
Nusaibah Sallchuddin
Izzat Zulkiflee
Law Xia Jian
Fatimah Mobd Nor
1 Introduction
456(1)
2 Classifications of nanocosmeceuticals
457(5)
3 Nanocosmeceuticals mechanisms of action
462(3)
4 Toxicity of nanoparticles for cosmeceuticals
465(2)
5 Safety assessment of nanomaterials in cosmetic industry
467(1)
6 Future perspective and recommendations
468(5)
References
470(3)
18 Nano-formulations in drug delivery
473(20)
Melissa Garcia-Carrasco
Iczel F. Parra-Aguilar
Erick P. Gutierrez-Grijalva
Angel Licea-Claveric
J. Basilin Heredia
1 Nanotechnology in nano-formulations in drug delivery
474(2)
2 Morphologies and their properties in drug delivery
476(3)
3 Preparation of nano-formulations
479(5)
4 Different applications of nano-formulations
484(1)
5 Biocompatibility and mechanism of some system drug delivery
484(2)
6 Perspectives
486(7)
References
487(6)
19 Nano-materials as biosensor for heavy metal detection
493(34)
Samprit Bose
Sourav Maity
Angana Sarkar
1 Introduction
493(2)
2 Biosensor
495(21)
3 Advancement on nanomaterial-based biosensor
516(4)
4 Pros and cons
520(1)
5 Future prospects
520(7)
References
521(6)
20 Smart nano-biosensors in sustainable agriculture and environmental applications
527(16)
Rani Puthukulangara Ramachandran
Chclladurai Vcllaichamy
Chyngyz Erkinbacv
1 Introduction
528(1)
2 Principle of nano-biosensors
528(1)
3 Types of nano-bio sensors
529(3)
4 Nanostructures used in sensors
532(1)
5 Nano-biosensors for environmental and agricultural application
533(5)
6 Conclusion
538(5)
References
538(5)
Index 543
Veeriah Jegatheesan is Professor of Environmental Engineering and Director of Water:, Effect Technologies and Tools (WETT) Research Centre at RMIT University, Melbourne, Australia. His research focuses on the application of membrane bioreactors, sugar cane juiceclarification, sea water desalination and the treatment of mine tailing ponds. Assistant Professor & Canada Research Chair in Food Proteins and Bioproducts at the University of Manitoba, Canada. His research focuses on Integrating material science and nanotechnology for improving bioavailability and therapeutic efficacy. of bioactives and drugs using protein & lipid-based delivery systems. Dr. Preetam Sarkar is an Assistant Professor of Food Sciences at the Department of Food Process Engineering, National Institute of Technology Rourkela, Odisha, India. He completed his Ph.D. in Food Sciences from Purdue University, USA. The research at Dr. Sarkars lab at NIT Rourkela focuses on the development of delivery vehicles such as emulsions, films and coatings, for the protection of bioactive compounds such as antimicrobial agents for food safety applications. He has published 30 articles in SCI journals, 10 book chapters, and co-edited 3 books. Prof. Angana Sarkar pursued her graduation in Agricultural Engineering from Bidhan Chandra Krishi Viswasvidyalaya, West Bengal, India, followed by post-graduation in Biotechnology & Biochemical Engineering from Indian Institute of Technology, Kharagpur, India 2008. Later, she completed her Ph.D. in Environmental Biotechnlogy from Indian Institute of Technology, Kharagpur, India. Subsequently she joined National Institute of Technology, Rourkela, India in the year 2015 as an Assistant Professor in the Department of Biotechnology & Medical Engineering. Her research area is mainly focused on (i) Pollutant detection using biosensors, (ii) Groundwater bioremediation, (iii) Waste water (domestic and industrial) treatment (iv) Solid waste management by bio-refinery approach to produce environmental waste to value like bioethanol, pigment, biofertilizars etc. and (iv) Hydrocarbon and other organic pollutants degradation. Dr. Kunal Pal is a Professor in the Department of Biotechnology and Medical Engineering, National Institute of Technology Rourkela, India. His major research interests revolve around biomedical signal processing, biomedical equipment design, soft materials, and controlled drug delivery. He has published more than 100 publications in SCI-cited journals of high repute.