Bioremediation of Emerging Contaminants
Omics and Phytotech Approaches
- 1 Edición - 1 de julio de 2026
- Última edición
- Editores: Majeti Narasimha Vara Prasad, Larry Erickson, Abin Sebastian, Sailaja Elchuri
- Idioma: Inglés
Bioremediation of Emerging Contaminants: Omics and Phytotech Approaches explores transgenic plant technologies and their important role in addressing environmental pollut… Leer más
Descripción
Descripción
Bioremediation of Emerging Contaminants: Omics and Phytotech Approaches explores transgenic plant technologies and their important role in addressing environmental pollution. The book provides practical applications for improving environmental management strategies by examining established protocols and innovative techniques that enhance phytoremediation efficacy. By addressing current environmental challenges, this book not only advances academic understanding but also develops practical solutions for pollution control. It is a critical resource that assimilates the latest methodologies on genetic engineering and omics approaches for an extensive range of contaminants, from pharmaceuticals to heavy metals.
Puntos claves
Puntos claves
- Addresses various classes of emerging contaminants and topics related to transgenic plant technologies and their applications in bioremediation
- Highlights genetic engineering, omics approaches, and microbial genetic engineering technologies
- Provides solutions to address current environmental issues and the persistent presence of pollutants
De interès para
De interès para
Academics, researchers, professionals and students interested in environmental science, environmental management, biotechnology, microbiology and environmental pollution
Índice
Índice
Section 1: Bioremediation of emerging contaminants
1. Bioremediation of emerging contaminants and pollutants: Anthropocene and One Health Perspective
2. Contaminants of Emerging Concern and applicable remediation technologies – bibliometric resume of salient research findings
3. Phytotechnologies for emerging contaminants and micropollutants - a scoping review
4. Bioremediation of Strontium and manganese
5. Bioremediation of total petroleum hydrocarbons in contaminated environments
Section 2: Omics, phytotech insights, microbial genetic engineering for remediation of emerging contaminants radionuclides and pesticides
6. Omics technologies for phytoremediation of contaminants of emerging concern
7. Biological remediation of emerging contaminants and pollutants: role of genetically modified organisms (bacteria, fungi and plants) and omic approaches
8. Omics and Phyto Insights in Environmental Bioremediation of Antibiotics: Eco-friendly and sustainable approach to remove antibiotics from the environment
9. Microbial Genetic Engineering Technologies for Remediation of Pesticides
10. Transgenic Approaches for Heavy Metal Detoxification in Plants
11. Use of transgenic plants and genetically modified bacteria for remediation of pharmaceutical contaminants in water
12. Remediation of Radionuclides
13. Remediation of Pesticides
14. Personal care products contamination, remediation: Focus on antibiotic resistance using machine learning and Omic approaches
Section 3: Remediation of Indoor air pollutants, nanoparticles, use of Poaceae and transgenic crops for cleanup of emerging contaminants
15. Indoor air pollutants of emerging concern: options for monitoring and remediation
16. Approaches to Bioremediate Nanoparticles: An Emerging Contaminant of Concern
17. Environmental remediation of emerging contaminants using Poacease: Focus on Millets and Miscanthus
18. Transgenic tree crops - Poplars, Willows and Eucalyptus - for remediation of emerging contaminants
19. Impact Assessment of Mulberry (Morus spp.) Cultivation on Soils Contaminated with Emerging Pollutants for Sustainable Sericulture
20. Miscanthus for cleanup of emerging contaminants
Section 4: Biodiversity for remediation of Emerging contaminants
21. Phytoremediation of cyanotoxins
22. Phycoremediation for detoxification of Herbicides
23. Energy crops for remediation of emerging contaminants, a synoptic resume
24. A Case Study on Transgenics and the Spread of Antibiotic Resistance in Bacterial Populations Across the Fresh Water Ecosystem of Uzh River in Transcarpathia, Ukraine
Section 5: Genetic engineering and microbial applications for degradation/detoxification of Emerging contaminants
25. Bioinspired methods in enzymatic degradation of textile dyes
26. Applications and challenges of transgenic plants in the bioremediation of emerging contaminants
27. Microbial bio-desulfurization of crude oil
Section 6: Physiological, biochemical, molecular and nanotechnological approaches for bioremediation of emerging contaminants
28. Recombinant microorganisms role in biodegradation of emerging contaminants
29. Aptamers applications with focus on detection and remediation of contaminants of emerging concern
30. Use of phytotechnology for remediation of pollutants in pharmaceutical and personal care products
31. Physiological, biochemical and molecular aspects of remediation of emerging contaminants
32. Bioremediation of Endocrine Disrupters in the Environment
33. Plant Growth Regulators role in remediations of emerging contaminants
Section 7: Novel approaches for remediation of Emerging contaminants
34. Artificial Intelligence in the Phytoremediation of Emerging Contaminants
35. Fungal Catechol 2, 3 Dioxygeanse as a Tool for the the Degradation of Petroleum Hydrocarbons.
36. Emerging contaminants in wildlife habitats: Ecological risks and phytoremediation
37. Genetic engineering approach for remediation of emerging contaminants in Industrial wastewater
38. Strategies for the Removal of Emerging Nanoparticles from Contaminated Environments
39. Molecular and nanotechnology approaches for bioremediation of emerging contaminants
Section 8: Bioaccumulative and biotoxic Per- and polyfluorinated chemicals as Environmental nightmares
40. Phytoremediation of PFAS: Progress and Challenges
41. Per- and Polyfluoroalkyl Substances in Environmental Matrices: Distribution Patterns and Treatment Technologies
Section 9: Management of Emerging Contaminants including Methods and technologies
42. Modular solutions for managing drinking water emerging contaminants
43. Integrating Phytoremediation and Regenerative Agriculture for the Management of Emerging Contaminants in Soils
44. Methods and technologies applied for removal and remediation of emerging contaminants and pollutants - A synoptic review of bibliography
45. Current status of policies and laws for regulation of emerging contaminants
1. Bioremediation of emerging contaminants and pollutants: Anthropocene and One Health Perspective
2. Contaminants of Emerging Concern and applicable remediation technologies – bibliometric resume of salient research findings
3. Phytotechnologies for emerging contaminants and micropollutants - a scoping review
4. Bioremediation of Strontium and manganese
5. Bioremediation of total petroleum hydrocarbons in contaminated environments
Section 2: Omics, phytotech insights, microbial genetic engineering for remediation of emerging contaminants radionuclides and pesticides
6. Omics technologies for phytoremediation of contaminants of emerging concern
7. Biological remediation of emerging contaminants and pollutants: role of genetically modified organisms (bacteria, fungi and plants) and omic approaches
8. Omics and Phyto Insights in Environmental Bioremediation of Antibiotics: Eco-friendly and sustainable approach to remove antibiotics from the environment
9. Microbial Genetic Engineering Technologies for Remediation of Pesticides
10. Transgenic Approaches for Heavy Metal Detoxification in Plants
11. Use of transgenic plants and genetically modified bacteria for remediation of pharmaceutical contaminants in water
12. Remediation of Radionuclides
13. Remediation of Pesticides
14. Personal care products contamination, remediation: Focus on antibiotic resistance using machine learning and Omic approaches
Section 3: Remediation of Indoor air pollutants, nanoparticles, use of Poaceae and transgenic crops for cleanup of emerging contaminants
15. Indoor air pollutants of emerging concern: options for monitoring and remediation
16. Approaches to Bioremediate Nanoparticles: An Emerging Contaminant of Concern
17. Environmental remediation of emerging contaminants using Poacease: Focus on Millets and Miscanthus
18. Transgenic tree crops - Poplars, Willows and Eucalyptus - for remediation of emerging contaminants
19. Impact Assessment of Mulberry (Morus spp.) Cultivation on Soils Contaminated with Emerging Pollutants for Sustainable Sericulture
20. Miscanthus for cleanup of emerging contaminants
Section 4: Biodiversity for remediation of Emerging contaminants
21. Phytoremediation of cyanotoxins
22. Phycoremediation for detoxification of Herbicides
23. Energy crops for remediation of emerging contaminants, a synoptic resume
24. A Case Study on Transgenics and the Spread of Antibiotic Resistance in Bacterial Populations Across the Fresh Water Ecosystem of Uzh River in Transcarpathia, Ukraine
Section 5: Genetic engineering and microbial applications for degradation/detoxification of Emerging contaminants
25. Bioinspired methods in enzymatic degradation of textile dyes
26. Applications and challenges of transgenic plants in the bioremediation of emerging contaminants
27. Microbial bio-desulfurization of crude oil
Section 6: Physiological, biochemical, molecular and nanotechnological approaches for bioremediation of emerging contaminants
28. Recombinant microorganisms role in biodegradation of emerging contaminants
29. Aptamers applications with focus on detection and remediation of contaminants of emerging concern
30. Use of phytotechnology for remediation of pollutants in pharmaceutical and personal care products
31. Physiological, biochemical and molecular aspects of remediation of emerging contaminants
32. Bioremediation of Endocrine Disrupters in the Environment
33. Plant Growth Regulators role in remediations of emerging contaminants
Section 7: Novel approaches for remediation of Emerging contaminants
34. Artificial Intelligence in the Phytoremediation of Emerging Contaminants
35. Fungal Catechol 2, 3 Dioxygeanse as a Tool for the the Degradation of Petroleum Hydrocarbons.
36. Emerging contaminants in wildlife habitats: Ecological risks and phytoremediation
37. Genetic engineering approach for remediation of emerging contaminants in Industrial wastewater
38. Strategies for the Removal of Emerging Nanoparticles from Contaminated Environments
39. Molecular and nanotechnology approaches for bioremediation of emerging contaminants
Section 8: Bioaccumulative and biotoxic Per- and polyfluorinated chemicals as Environmental nightmares
40. Phytoremediation of PFAS: Progress and Challenges
41. Per- and Polyfluoroalkyl Substances in Environmental Matrices: Distribution Patterns and Treatment Technologies
Section 9: Management of Emerging Contaminants including Methods and technologies
42. Modular solutions for managing drinking water emerging contaminants
43. Integrating Phytoremediation and Regenerative Agriculture for the Management of Emerging Contaminants in Soils
44. Methods and technologies applied for removal and remediation of emerging contaminants and pollutants - A synoptic review of bibliography
45. Current status of policies and laws for regulation of emerging contaminants
Detalles del producto
Detalles del producto
- Edición: 1
- Última edición
- Publicado: 1 de julio de 2026
- Idioma: Inglés
Sobre los editores
Sobre los editores
MV
Majeti Narasimha Vara Prasad
Majeti Narasimha Vara Prasad is currently Emeritus Professor, School of Life Sciences, University of Hyderabad, Hyderabad, India. He has made outstanding contributions to the fields of bioremediation, bioresources, biomass energy sources, bioeconomy and to the broad field of environmental biotechnology, all of which are his main areas of expertise. Dr. Prasad has served the Ministry of Environment, Forests and Climate Change, Government of India in various advisory committees on biodiversity conservation, ecosystem services, pollution control and abatement, environmental information systems and bioremediation of contaminated sites. He is an active visiting scientist in several international universities.
Afiliaciones y experiencia
Professor, School of Life Sciences, University of Hyderabad, Hyderabad, IndiaLE
Larry Erickson
Larry E. Erickson received doctorate in 1964 in chemical engineering from Kansas State University. He has been a member of the chemical engineering faculty at K-State since 1964. In 1967-68 he conducted research in biochemical engineering at the University of Pennsylvania, and introduced courses in biochemical engineering and bioseparations at K-State. From 1985-2018, he has provided leadership for hazardous substance research at K-State. From 1989-2003, he was director of the Great Plains/Rocky Mountain Hazardous Substance Research Center, a consortium of universities with headquarters at K-State. In order to advance pollution prevention and improve environmental management, he introduced seminars in hazardous waste engineering, air quality, and sustainability. He has worked with more than 70 graduate students, coauthored more than 450 papers, traveled professionally to more than 25 countries, and participated in more than $50 million of funded research projects. In January 2015, he transitioned to emeritus professor of chemical engineering. He has been employed by Mobil Oil Company, ESSO Research and Engineering Co., Humble Oil and Refining Company. He has been a visiting faculty member at MIT, University of California, Berkeley, Institute of Biochemistry and Physiology of Microorganisms, Pushchino, Russia, and Institute of Microbiology, Prague, Czech Republic.
Afiliaciones y experiencia
Professor, Chemical Engineering, Kansas State University, USAAS
Abin Sebastian
Dr. Abin Sebastian is working as assistant professor in the Department of Botany, St. Georges College, Aruvithura affiliated to Mahathma Gandhi University, Kottayam, India. He is expertise in ecophysiology of plants and environmental biotechnology. His studies pointed out the role of iron and iron transporters involved in detoxification of cadmium in rice plants. He synthesized magnetic iron nanoparticles that efficiently remove heavy metals from aqueous media, and ameliorate heavy metal stress in plants. He was awarded with outstanding student scholar award during IBC 2017, China, and received fellowship from DAAD, Germany and UGC, India for conducting doctoral and post-doctoral research.
Afiliaciones y experiencia
Assistant Professor, Department of Botany, St. Georges College, AruvithuraSE
Sailaja Elchuri
Dr Sailaja Elchuri completed her Doctoral studies in molecular regulation of light stress in C4 plants under eminent plant physiologist Prof V.S. Ramadas. Significant contribution included paper submission to volume dedicated to Prof Daniel Arnon. Completed post-Doctoral studies at Arizona State University examining UV light effects on canopy photosynthesis. Later studies included animal models of disease and nanotechnology at Stanford University. Recent focus has been to use one health approaches for Human, animal, and plant triad. She used Omic approaches and green Nanotechnology to study human disease progression and therapy for safer environment. She is reviewer for several journals in Omic studies and Nanotechnology. Published 55 papers in peer reviewed journals and 5 book chapters.
Afiliaciones y experiencia
Vision Research Foundation. No 18 College Road, Nugambakkam, Sankara Nethralaya, Chennai, Tamil Nadu