Bioremediation for Sustainable Environmental Cleanup (Anju Malik, Vinod Kumar Garg)

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Bioremediation for Sustainable Environmental Cleanup

Gong R., Y. Ding, H. Liu, Q. Chen and Z. Liu. 2005. Lead biosorption and desorption by intact and pretreated

Spirulina maxima biomass. Chemosphere. 58: 125–130.

Hall, J. Á. 2002. Cellular mechanisms for heavy metal detoxification and tolerance. J. Exp. Bot. 53: 1–11.

Hamdy, A. A. 2000. Biosorption of heavy metals by marine algae. Current Microbiol. 41: 232–238.

Hasan, H. A., S. N. Hatika, A. Bakar and M. S. Takriff. 2021. Microalgae biofilms for the treatment of

wastewater. Microalgae. Academic Press, 2021. 381–407.

Igiri, B. E., S. I. Okoduwa, G. O. Idoko, E. P. Akabuogu, A. O. Adeyi and I. K. Ejiogu. 2018. Toxicity and bioremediation

of heavy metals contaminated ecosystem from tannery wastewater: a review. Journal of Toxicology.

Jankowska, E., K. S. Ashish and O. P. Piotr. 2017. Biogas from microalgae: review on microalgae’s cultivation,

harvesting and pretreatment for anaerobic digestion. Renew. Sustain. Energy Rev. 75: 692–709.

Kalra, R., S. Gaur and M. Goel. 2020. Microalgae bioremediation: a perspective towards wastewater treatment along

with industrial carotenoids production. J. Water Process Eng. 101794.

Kamra, A., A. Kaushik, K. Bala and N. Rani. 2007. Biosorption of Cr(VI) by immobilized biomass of two indigenous

strains of cyanobacteria isolated from metal contaminated soil. J. Hazard. Mater. 148: 383–386.

Kaplan, D. 2013. Absorption and adsorption of heavy metals by microalgae. Handbook of microalgal culture: applied

Phycology and Biotechnology. 2: 602–611.

Kaushik, A., S. Jain, J. Dawra and M. S. Bishnoi. 2000. Heavy metal pollution of river Ghaggar in Haryana. Indian

J. Environ. Toxicol. 10: 63–66.

Kaushik, A., S. Jain, J. Dawra and C. P. Kaushik. 2001. Heavy metal pollution of river Yamuna in the industrially

developing state of Haryana. J. Environ. Biol. 43: 164–168.

Kaushik, A., S. Mona and C. P. Kaushik. 2011. Integrating photobiological hydrogen production with dye-metal

bioremoval from simulated textile wastewater. Bioresour. Technol. 102: 9957–9964.

Kiran, B., A. Kaushik and C. P. Kaushik. 2007a. Biosorption of Cr (VI) by native isolate of L. putealis (HH-15) in the

presence of salts. J. Hazard. Mater. 141: 662–667.

Kiran, B., A. Kaushik and C. P. Kaushik. 2007b. Response surface methodological approach for optimizing removal

of Cr (VI) from aq. sol. using immobilized cyanobacterium. Chem. Eng. J. 126: 147–153.

Kiran, B. and A. Kaushik. 2008. Cyanobacterial biosorption of Cr (VI): application of two parameter and Bohart

Adams models for batch and column studies. Chem. Eng. J. 144: 391–399.

Kiran, B., A. Kaushik and C. P. Kaushik. 2008. Metal–salt co-tolerance and metal removal by indigenous cyanobacterial

strains. Process Biochemistry. 43.6: 598–604.

Kiran, B. and A. Kaushik. 2012. Equilibrium sorption study of Cr (VI) from multi-metal systems in aq. sol. by

Lyngbya putealis. Ecol. Eng. 38: 93–96.

Kiran, B., N. Rani and A. Kaushik. 2016. FTIR spectroscopy and scanning electron microscopic analysis of pretreated

biosorbent to observe the effect on Cr (VI) remediation. Int. J. Phytoremediat. 18: 1067–1074.

Kosek, K., Z. Polkowska, B. Żyszka and J. Lipok. 2016. Phytoplankton communities of polar regions diversity

depending on enviro. conditions and chemical anthropopressure. J. Environ. Manag. 171: 243–259.

Kratochvil, D. and B. Volesky. 1998. Biosorption of Cu from Ferruginous Wastewater by Algal Bio-mass. Water Res.

32: 2760–2768.

Kumar, D., L. K. Pandey and J. P. Gaur. 2016. Metal sorption by algal biomass: from batch to continuous system.

Algal Res. 18: 95–109.

Kumar, K. S., H. U. Dahms, E. J. Won, J. S. Lee and K. H. Shin. 2015. Microalgae–a promising tool for heavy metal

remediation. Ecotoxicol. Enviro Saf. 113: 329–352.

Kumar, V., A. Sharma and A. Cerda. 2020. Heavy Metals in the Environment: Impact, Assessment, and Remediation

Elsevier.

Lau, P. S., H. Y. Lee, C. C. K. Tsang, N. F. Y. Tam and Y. S. Wong. 1999. Effect of metal interference, pH and

temperature on Cu and Ni biosorption by C. Vulgaris and C. Miniata. Environ. Technol. 20: 953–96.

Li, Y., Y. Chen and J. Wu. 2019. Enhancement of methane production in anaerobic digestion process: A review.

Applied Energy 240: 120–137.

Markou, G. and E. Nerantzis. 2013. Microalgae for high-value compounds and biofuels production: a review with

focus on cultivation under stress conditions. Biotechnol. Adv. 31: 1532–1542.

Michalak, I., K. Chojnacka and A. Witek-Krowiak. 2013. State of the art for the biosorption process—a review. Appl.

Biochem. Biotechnol. 170: 1389–1416.

Mona, S., A. Kaushik and C. P. Kaushik. 2011a. Biosorption of Chromium (VI) by spent cyanobacterial biomass from

a hydrogen fermentor using box-behnken model. Int. Biodeterior. Biodegrad. 65: 656–663.

Mona, S., A. Kaushik and C. P. Kaushik. 2011b. Sequestration of Co (II) from aqueous solution using immobilized

biomass of Nostoc linckia waste from a hydrogen bioreactor. Desalin. 276: 408–415.

Mona, S., A. Kaushik and C. P. Kaushik. 2011c. Hydrogen production and metal-dye bioremoval by a N. linckia strain

isolated from textile mill oxidation pond. Bioresour. Technol. 102: 3200–3205.