TY - JOUR
T1 - Effects of heavy metals on Antarctic bacterial cell growth kinetics and degradation of waste canola oil y
AU - Zahri, K. N.M.
AU - Zulkharnain, A.
AU - Gomez-Fuentes, C.
AU - Sabri, S.
AU - Ahmad, S. A.
N1 - Funding Information:
This work was supported by Universiti Putra Malaysia (Matching Grant PUTRA (9300436) and PUTRA Berimpak (9678900), Yayasan Penyelidikan Antartika Sultan Mizan (YPASM-Smart Partnership Initiative) and Centro de Investigacion y Monitoreo Ambiental Antártico (CIMAA). The authors would like to thanks Chilean scientist Nancy Calisto-Ulloa from Universidad de Magallanes, Chile and Nicolás Ramírez-Moreno from Pontificia Universidad Católica de Valparaíso, Chile for their previously help.The authors also would like to thanks Chilean Army and the Antarctic General Bernardo O'Higgins Station staff especially the Comandante de la Base O ᤀHiggins; Teniente CoronelJose Ignacio Alvarado Camps, the Comandante de la sección de exploracion y rescate O'higgins; Capitan René Salgado Rebolledo and the staff; especially the Chef; Suboficial Juan David Sandoval Navarrete and Sargento Juan Eduardo Cortínez Padovani; Sargento Segundo Augusto Antonio Barra Morale, Sargento Segundo Flavio Marcelo Nahuelcoy Perez, and Sargento Segundo Claudio Durand Ibacache.
Publisher Copyright:
© Triveni Enterprises, Lucknow (India)
PY - 2020/11
Y1 - 2020/11
N2 - Aim: The aim of the present study was to study the effect of heavy metals on growth kinetics of Antarctic bacterial in degradation of waste canola oil. Methodology: The BS14 Antarctic bacterial community was introduced in the minimal salt media containing 1 ppm of heavy metals (Cd, Cr, Al, Zn, Ni, As and Co) with 1% waste canola oil, and the effects of heavy metals on biodegradation of waste canola oil was analysed by gravimetric analysis. The turbidity of bacteria was obtained through UV-visible spectroscopy at 600 nm of wavelength for every 24 hr within seven days of incubation period, and the data were regressed with linear and non-linear kinetic equations. n Results: The results demonstrated that Co was the most active metal that led to 4.217% increase in waste canola oil and the least active metal in biodegradation of oil was zinc, as it degraded the waste canola oil only to 29.26%. Overall, the bacterial growth was inhibited in increasing order of Al > Cd> As> Zn> Ni> Cr> Co whereas the waste canola oil biodegradation was inhibited in the order of Zn> Cr> Ni> Al> Cd> As> Co. The best fitted-regression model was determined by comparing the kinetic parameters estimated between linear and non-linear model equations, where the R2 value for non-linear regression was highest at 0.8421, and low sy.x at 0.324 for Ni with a maximum growth rate (0.01131 hr-1) of the Antarctic bacterial in degrading waste canola oil, meantime best-fitted in the linear regression model was Zn with high R2 and growth constant values (0.9082 and 0.2075 hr-1, respectively) as well as low value of statistical error, which was 0.2075. Onl Interpretation: The presence of heavy metals in Antarctic bacterial community could suppress the ability of bacteria to degrade waste canola oil, and this can slower the rate of bacterial growth in the kinetics studies. Hence, this work would be helpful in actual bioremediation operations by understanding and manipulating the process of the kinetics parameters.
AB - Aim: The aim of the present study was to study the effect of heavy metals on growth kinetics of Antarctic bacterial in degradation of waste canola oil. Methodology: The BS14 Antarctic bacterial community was introduced in the minimal salt media containing 1 ppm of heavy metals (Cd, Cr, Al, Zn, Ni, As and Co) with 1% waste canola oil, and the effects of heavy metals on biodegradation of waste canola oil was analysed by gravimetric analysis. The turbidity of bacteria was obtained through UV-visible spectroscopy at 600 nm of wavelength for every 24 hr within seven days of incubation period, and the data were regressed with linear and non-linear kinetic equations. n Results: The results demonstrated that Co was the most active metal that led to 4.217% increase in waste canola oil and the least active metal in biodegradation of oil was zinc, as it degraded the waste canola oil only to 29.26%. Overall, the bacterial growth was inhibited in increasing order of Al > Cd> As> Zn> Ni> Cr> Co whereas the waste canola oil biodegradation was inhibited in the order of Zn> Cr> Ni> Al> Cd> As> Co. The best fitted-regression model was determined by comparing the kinetic parameters estimated between linear and non-linear model equations, where the R2 value for non-linear regression was highest at 0.8421, and low sy.x at 0.324 for Ni with a maximum growth rate (0.01131 hr-1) of the Antarctic bacterial in degrading waste canola oil, meantime best-fitted in the linear regression model was Zn with high R2 and growth constant values (0.9082 and 0.2075 hr-1, respectively) as well as low value of statistical error, which was 0.2075. Onl Interpretation: The presence of heavy metals in Antarctic bacterial community could suppress the ability of bacteria to degrade waste canola oil, and this can slower the rate of bacterial growth in the kinetics studies. Hence, this work would be helpful in actual bioremediation operations by understanding and manipulating the process of the kinetics parameters.
KW - Antarctic
KW - Canola oil
KW - Degradation
KW - Heavy metal
KW - Kinetic growth
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U2 - 10.22438/JEB/41/6/MRN-1464
DO - 10.22438/JEB/41/6/MRN-1464
M3 - Article
AN - SCOPUS:85097457193
SN - 0254-8704
VL - 41
SP - 1433
EP - 1441
JO - Journal of Environmental Biology
JF - Journal of Environmental Biology
IS - 6
ER -