Research Article
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Year 2023, , 161 - 168, 30.06.2023
https://doi.org/10.59313/jsr-a.1238220

Abstract

References

  • [1] Stocks-Fischer, S., Galinat, J. K., and Bang, S. S., (1999), Microbial precipitation of CaCO3, Soil Biology and Biochemistry, 31, 1563–1571.
  • [2] Chou, C.-W., Seagren, E. A., Aydilek, A. H., and Lai, M., (2011), Biocalcification of sand through ureolysis, Journal of Geotechnical and Geoenvironmental Engineering, 137, 1179–1189.
  • [3] Eryürük, K., Suzuki, D., Mizuno, S., Akatsuka, T., Tsuchiya, T., Yang, S., Kitano, H., and Katayama, A., (2016), Decrease in Hydraulic Conductivity of a Paddy Field using Biocalcification in situ, Geomicrobiology Journal, 33 (8), 690–698.
  • [4] Arpajirakul, S., Pungrasmi, W., and Likitlersuang, S., (2021), Efficiency of microbially-induced calcite precipitation in natural clays for ground improvement. Construction and Building Materials, 282, 122722.
  • [5] Gao, X., Han, S., Yang, Y., Zhang, W., Zou, T., and Cheng, L., (2022), Mechanical Behavior and Microstructural Study of Biocemented Sand under Various Treatment Methods, Geofluids, 6015335.
  • [6] Chen, B., Sun, W., Sun, X., Cui, C., Lai, J., Wang, Y., and Feng, J., (2021), Crack sealing evaluation of self-healing mortar with Sporosarcina pasteurii: Influence of bacterial concentration and air-entraining agent, Process Biochemistry, 107, 100–111.
  • [7] Eryürük, K., Yang, S., Suzuki, D., Sakaguchi, I., Akatsuka, T., Tsuchiya, T., and Katayama, A., (2015), Reducing hydraulic conductivity of porous media using CaCO3 precipitation induced by Sporosarcina pasteurii, Journal of Bioscience and Bioengineering, 119(3), 331–336.
  • [8] Eryürük, K., Yang, S., Suzuki, D., Sakaguchi, I., and Katayama, A., (2015), Effects of bentonite and yeast extract as nutrient on decrease in hydraulic conductivity of porous media due to CaCO3 precipitation induced by Sporosarcina pasteurii, Journal of Bioscience and Bioengineering, 120(4), 411–418.
  • [9] Al Imran, M., Shinmura, M., Nakashima, K., and Kawasaki, S., (2018), Effects of Various Factors on Carbonate Particle Growth Using Ureolytic Bacteria, Materials Transactions, 59(9), 1520–1527.
  • [10] Seifan, M., and Berenjian, A., (2019), Microbially induced calcium carbonate precipitation: a widespread phenomenon in the biological world, Applied Microbiology and Biotechnology, 103, 4693–4708.
  • [11] Ghosh, T., Bhaduri, S., Montemagno, C., and Kumar, A., (2019), Sporosarcina pasteurii can form nanoscale calcium carbonate crystals on cell surface, PLoS ONE, 14(1): e0210339.
  • [12] Jain, S., and Arnepalli, D. N., (2019), Biochemically Induced Carbonate Precipitation in Aerobic and Anaerobic Environments by Sporosarcina pasteurii, Geomicrobiology Journal, 36(5), 443–451.
  • [13] Wu, J., Wang, X. B., Wang, H. F., Zeng, R. J., (2017) Microbially induced calcium carbonate precipitation driven by ureolysis to enhance oil recovery. RSC Advances, 7(59), 37382–37391.
  • [14] Hammes, F., and Verstraete, W., (2002), Key roles of pH and calcium metabolism in microbial carbonate precipitation, Reviews in Environmental Science and Bio/Technology, 1, 3–7.
  • [15] Hsu, C. M., Yi-Hsun, H., Vanita, R., Wen-Chien, L., How-Ji, C., Yi-Hao, K., Chung-Ho, H., Chien-Cheng, C., and Chien-Yen, C., (2018), Comparative Study on the Sand Bioconsolidation through Calcium Carbonate Precipitation by Sporosarcina pasteurii and Bacillus subtilis, Crystals, 8 (5): 189.
  • [16] Saricicek, Y. E., Gurbanov, R., Pekcan, O., and Gozen, A. G., (2019), Comparison of microbially induced calcium carbonate precipitation eligibility using sporosarcina pasteurii and bacillus licheniformis on two different sands, Geomicrobiology Journal, 36(1), 42–52.
  • [17] Li, M., Wen, K., Li, Y., and Zhu, L., (2018), Impact of Oxygen Availability on Microbially Induced Calcite Precipitation (MICP) Treatment, Geomicrobiology Journal, 35(1), 15–22.
  • [18] Eryürük, K., (2022), Effect of cell density on decrease in hydraulic conductivity by microbial calcite precipitation, AMB Express, 12, 104.

TRANSPORTATION OF SPOROSARCINA PASTEURII IN POROUS MEDIA WITH DIFFERENT PARTICLE SIZES

Year 2023, , 161 - 168, 30.06.2023
https://doi.org/10.59313/jsr-a.1238220

Abstract

The current study aimed to determine the transportation distance of Sporosarcina pasteurii (ATCC 11859) and the number of cells present in porous media. The experiments were carried out in continuous-flow columns, which were plastic columns with an inner diameter of 2.4 cm and a height of 50 cm, and which contained glass beads with average diameters of 0.25 mm, 0.50 mm and 1 mm to mimic porous media. To investigate cell transport through columns, suspension of Sporosarcina pasteurii was introduced into columns at a flow rate of 2 mL/min and the cell densities of OD600 0.15, 0.75, 2.25. To count the bacteria in each section, the column was divided into five equal parts. The results showed that the most cells, which were counted as 1.72*1010 cells, were deposited in the columns packed with 0.25 mm glass beads for the experiments with OD600 2.25, while the deposited cell number decreased at the bottom of the column. The cell deposition was greater at the bottom of the column in the case of columns packed with 1 mm glass beads. According to the findings, while using smaller glass beads resulted in more cell deposition in the porous media, using larger glass beads resulted in more cell transport through the porous media. It can be concluded that larger particle sizes may result in easier transportation conditions for cells transporting deep into porous media.

References

  • [1] Stocks-Fischer, S., Galinat, J. K., and Bang, S. S., (1999), Microbial precipitation of CaCO3, Soil Biology and Biochemistry, 31, 1563–1571.
  • [2] Chou, C.-W., Seagren, E. A., Aydilek, A. H., and Lai, M., (2011), Biocalcification of sand through ureolysis, Journal of Geotechnical and Geoenvironmental Engineering, 137, 1179–1189.
  • [3] Eryürük, K., Suzuki, D., Mizuno, S., Akatsuka, T., Tsuchiya, T., Yang, S., Kitano, H., and Katayama, A., (2016), Decrease in Hydraulic Conductivity of a Paddy Field using Biocalcification in situ, Geomicrobiology Journal, 33 (8), 690–698.
  • [4] Arpajirakul, S., Pungrasmi, W., and Likitlersuang, S., (2021), Efficiency of microbially-induced calcite precipitation in natural clays for ground improvement. Construction and Building Materials, 282, 122722.
  • [5] Gao, X., Han, S., Yang, Y., Zhang, W., Zou, T., and Cheng, L., (2022), Mechanical Behavior and Microstructural Study of Biocemented Sand under Various Treatment Methods, Geofluids, 6015335.
  • [6] Chen, B., Sun, W., Sun, X., Cui, C., Lai, J., Wang, Y., and Feng, J., (2021), Crack sealing evaluation of self-healing mortar with Sporosarcina pasteurii: Influence of bacterial concentration and air-entraining agent, Process Biochemistry, 107, 100–111.
  • [7] Eryürük, K., Yang, S., Suzuki, D., Sakaguchi, I., Akatsuka, T., Tsuchiya, T., and Katayama, A., (2015), Reducing hydraulic conductivity of porous media using CaCO3 precipitation induced by Sporosarcina pasteurii, Journal of Bioscience and Bioengineering, 119(3), 331–336.
  • [8] Eryürük, K., Yang, S., Suzuki, D., Sakaguchi, I., and Katayama, A., (2015), Effects of bentonite and yeast extract as nutrient on decrease in hydraulic conductivity of porous media due to CaCO3 precipitation induced by Sporosarcina pasteurii, Journal of Bioscience and Bioengineering, 120(4), 411–418.
  • [9] Al Imran, M., Shinmura, M., Nakashima, K., and Kawasaki, S., (2018), Effects of Various Factors on Carbonate Particle Growth Using Ureolytic Bacteria, Materials Transactions, 59(9), 1520–1527.
  • [10] Seifan, M., and Berenjian, A., (2019), Microbially induced calcium carbonate precipitation: a widespread phenomenon in the biological world, Applied Microbiology and Biotechnology, 103, 4693–4708.
  • [11] Ghosh, T., Bhaduri, S., Montemagno, C., and Kumar, A., (2019), Sporosarcina pasteurii can form nanoscale calcium carbonate crystals on cell surface, PLoS ONE, 14(1): e0210339.
  • [12] Jain, S., and Arnepalli, D. N., (2019), Biochemically Induced Carbonate Precipitation in Aerobic and Anaerobic Environments by Sporosarcina pasteurii, Geomicrobiology Journal, 36(5), 443–451.
  • [13] Wu, J., Wang, X. B., Wang, H. F., Zeng, R. J., (2017) Microbially induced calcium carbonate precipitation driven by ureolysis to enhance oil recovery. RSC Advances, 7(59), 37382–37391.
  • [14] Hammes, F., and Verstraete, W., (2002), Key roles of pH and calcium metabolism in microbial carbonate precipitation, Reviews in Environmental Science and Bio/Technology, 1, 3–7.
  • [15] Hsu, C. M., Yi-Hsun, H., Vanita, R., Wen-Chien, L., How-Ji, C., Yi-Hao, K., Chung-Ho, H., Chien-Cheng, C., and Chien-Yen, C., (2018), Comparative Study on the Sand Bioconsolidation through Calcium Carbonate Precipitation by Sporosarcina pasteurii and Bacillus subtilis, Crystals, 8 (5): 189.
  • [16] Saricicek, Y. E., Gurbanov, R., Pekcan, O., and Gozen, A. G., (2019), Comparison of microbially induced calcium carbonate precipitation eligibility using sporosarcina pasteurii and bacillus licheniformis on two different sands, Geomicrobiology Journal, 36(1), 42–52.
  • [17] Li, M., Wen, K., Li, Y., and Zhu, L., (2018), Impact of Oxygen Availability on Microbially Induced Calcite Precipitation (MICP) Treatment, Geomicrobiology Journal, 35(1), 15–22.
  • [18] Eryürük, K., (2022), Effect of cell density on decrease in hydraulic conductivity by microbial calcite precipitation, AMB Express, 12, 104.
There are 18 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Articles
Authors

Kağan Eryürük 0000-0003-3993-839X

Publication Date June 30, 2023
Submission Date January 17, 2023
Published in Issue Year 2023

Cite

IEEE K. Eryürük, “TRANSPORTATION OF SPOROSARCINA PASTEURII IN POROUS MEDIA WITH DIFFERENT PARTICLE SIZES”, JSR-A, no. 053, pp. 161–168, June 2023, doi: 10.59313/jsr-a.1238220.