Emerging Trends in Chemical Engineering

Chrome tanning is the most and widely used types of tanning process and the wastewater generated by these industries is a major source of chromium pollution in the form of Cr (III) & Cr(VI) and become a cause for many human health problems. Several researchers have published papers to find the solution for removal of Cr (VI) but at its low concentration and this research work investigates at high concentration of Cr (VI). Cell suspension of S.Cerevisiae at its exponential growth phase was inoculated at different initial Cr (VI) concentration and pH value for different contact time.  Bio removal of Cr(VI) from tannery wastewater using S.Cerevisiae shows good result after Cr (VI)-contaminated wastewater has been treated at different values of  treatment variables  and bioremoval efficiency of S.Cerevisiae increases at low values of pH, Cr (VI) and incubation time and decreases at high values of these variables and the optimum conditions obtained by using the full factorial experimental design are pH value of 5, Cr(VI)concentration of 5mg/ml and incubation time of 5 days resulting 88.5 %  Cr(VI) removal efficiency . The change of wavenumber of biocomponents of Cr (VI) loaded cell confirms the removal of Cr⁺⁶ by the yeast cell, S.Cerevisiae, from the wastewater.

Dargo, H. and Ayalew, A. (2014) ‘tannery waste water treatment: A Review’, IJETST, 1(November), pp. 1488–1494.

Bahafid et al., (2013) ‘Mechanism of hexavalent chromium detoxification using Cyberlindnera fabianii yeast isolated from contaminated site in Fez (Morocco)’, J. Mater. Environ. Sci, 4(June), pp. 840–847

Verma et al., (2015) ‘Biogenic sulfides for sequestration of Cr (VI), COD and sulfate from synthetic wastewater’, Water Science. National Water Research Center, 29(March), pp. 19–25.

Hlihor et al., (2013) ‘Bioaccumulation of Cr (VI) Polluted Wastewaters by Sorption on Heat Inactivated Saccharomyces cerevisiae Biomass’, Int. J. Environ. Res, 7(March), pp. 581–594.

Bhateria, R. and Dhaka, R. (2017) ‘Biological strategies for detoxification of hexavalent chromium’, Int. J. Pharm Bio Sci, 8(January), pp. 35–48.

Saha, B. and Orvig, C. (2010) ‘Biosorbents for hexavalent chromium elimination from industrial and municipal effluents’, Coordination Chemistry Reviews. Elsevier B.V., 254(june), pp. 2959–2972.

Islam et al., (2015) ‘Evaluation and Characterization of Tannery Wastewater’, Journal of Forest products and Industries, 3(May), pp. 141–150.

Saurav Kumar and Krishnan, K. (2011) ‘“Biosorption of Cr (III) and Cr (VI) by Streptomyces VITSVK9 spp Biosorption of Cr (III) and Cr (VI) by Streptomyces”’, Ann Microbiol, 132(january), pp. 214–257.

Gadd, G. M. (2009) ‘Biosorption : critical review of scientific rationale, environmental importance and significance for pollution treatment’, 35(April), pp. 13–28.

S. Papirio et al., (2017) ‘Heavy Metal Removal from Wastewaters by Biosorption : Mechanisms and Modeling’, Sustainable Heavy Metal Remediation 8(June).pp.445-512.

Tessafa Abrham, Yeamlak Degnetu, Zelalem Gezahegn, Miebele Fisseha,Maiegie Adugna, Anuradha Jabasingh S (2017).” production of citric acid from the Ethiopian sugar cane molasses using isolated, 16SRDNA sequenced Aspergillus niger’’: International Journal of Pharmacy and Pharmaceutical Studies, Oct-Dec

Galichet et al., (2001) ‘FTIR spectroscopic analysis of Saccharomyces cerevisiae cell walls : study of an anomalous strain exhibiting a pink-colored cell phenotype’, FEMS Microbiology Letters, 197(May), pp. 179–186.

Montgomery DC, Runger GC. Applied Statistics and Probability for Engineers, Third Edition, Wiley Publishers,United States, 2002.

D. Park et al., (2005) ‘Studies on hexavalent chromium biosorption by chemically-treated biomass of Eckloniasp’; chemosphere, 60(April), pp.1356–1364.

Czako et al., (2018) ‘Hexavalent chromium uptake by sensitive and tolerant mutants of Schizosaccharomyces pombe’, FEMS Microbiology letters, 178(March), pp.109–115.

Benazir et al. (2010) ‘Bioaccumulation of chromium in tannery effluent by microbial consortia’, African Journal of Biotechnology, 9(May), pp. 3140–3143.

Amirnia, S. (2015) Biosorption Processes for Removal of Toxic Metals from Wastewaters. University of Western Ontario

Farhan, S. N. and Khadom, A. A. (2015) ‘Biosorption of heavy metals from aqueous solutions by Saccharomyces Cerevisiae’, Int. J. Ind. Chem. Springer Berlin Heidelberg, 6(April), pp. 119–

D.Sujitha and P. Saranraj (2014) ‘Microbial Bioaccumulation of Chromium in Tannery Effluent : A Review’, Int. J. Microbiology Res., 4(December), pp. 305–320.

Ahluwalia, S. S. (2014) ‘Microbial removal of hexavalent chromium and scale up potential: review’, int. J. Curr. Microbiology. App. Sci, 3(November), pp. 383–398.

Mohammed et al., (2015) ‘Use of Saccharomyces cerevisiae in Bioaccumulation of Some Heavy Metals’, Research Gates, 24(July), pp. 145–162.

Wyk, V. (2011) ‘Removal of heavy metals from metal-containing effluent by yeast biomass’, African Journal of Biotechnology, 10(May), pp. 11557–11561.

WHO (2004) ‘Guidelines for drinking water quality’. WHO, Geneva

APHA (1999) Standard Methods for the Examination of Water and Wastewater Part 1000 Standard

Method 34 (1991) ‘Determination of hexavalent and total chromium in effluent