Abstract:

Experiments were performed with the bacterial species, Alcanivorax borkumensis which use lower molecular weight alkanes as the chief carbon source. This dataset includes bacterial growth curves in the presence of halloysite clay nanotubes, measured in different ways. The absorbance was measured in a UV-Vis Spectrometer at 600 nm wavelength giving us a parameter commonly known as optical density. The amount of fluorescence emitted by resorufin, a compound that is the product of enzymatic hydrolysis of resazurin was also measured. This dataset supports the publication: Panchal, A., Swientoniewski, L.T., Omarova, M., Yu, T., Zhang, D., Blake, D.A., John, V., & Lvov, Y.M. (2018). Bacterial proliferation on clay nanotube Pickering emulsions for oil spill bioremediation. Colloids and Surfaces B: Biointerfaces, 164: 27-33. doi: 10.1016/j.colsurfb.2018.01.021.

Suggested Citation:

Lauren Swientoniewski, Marzhana Omarova, Tianyi Yu, Donghui Zhang, Diane A. Blake, Vijay John. 2018. Improved growth and proliferation of hydrocarbonoclastic bacteria on halloysite clay pickering emulsions. Distributed by: Gulf of Mexico Research Initiative Information and Data Cooperative (GRIIDC), Harte Research Institute, Texas A&M University–Corpus Christi. doi:10.7266/N72B8WDN

Publications:

Panchal, A., Swientoniewski, L. T., Omarova, M., Yu, T., Zhang, D., Blake, D. A., … Lvov, Y. M. (2018). Bacterial proliferation on clay nanotube Pickering emulsions for oil spill bioremediation. Colloids and Surfaces B: Biointerfaces, 164, 27–33. doi:10.1016/j.colsurfb.2018.01.021

Purpose:

To examine the development of halloysite nanotubes as non-chemical dispersant for oil spill bioremediation and the proliferation of hydrocarbonoclastic bacteria in presence of emulsions formed by halloysite.

Data Parameters and Units:

Figure 2: Growth of A. borkumensis in marine broth supplemented with 0.5% by vol. of n-hexadecane in presence of pristine halloysite clay nanotubes (HNT) and ODTMS halloysite (octadecyltrimethylsilazane). Control is the bacteria grown in the medium without halloysite. Using data from the exponential phase of those curves, we calculated generation time. The generation time is the time required for cells to double their number. Time (hrs or days); Serial number (Sr. No.); Name; Absorbance at 600 nm (Abs, unitless); Dilution factor; Net absorbance (Abs, cells/mL); Number of bacteria (cells/mL); Generation time; Mean; Standard deviation Figure 3: Kinetic of resorufin production by A. borkumensis in presence of pristine halloysite. Time (hr); mean cell number (slope, Relative Fluoresce Units vs dilution) in 1% hexadecane, standard deviation cell number in 1% hexadecane, mean cell number in 1% hexadecane + halloysite clay nanotubes (HNT), standard deviation cell number in 1% hexadecane + HNT

Methods:

This dataset involves experiments with the bacterial species, Alcanivorax borkumensis which use lower molecular weight alkanes as the chief carbon source. Data are growth curves of the bacteria in presence of halloysite clay nanotubes, measured in different ways. One way is measuring the absorbance in a UV-Vis Spectrometer at 600 nm wavelength giving us a parameter commonly known as optical density. The second way is by measuring the amount of fluorescence emitted by resorufin, a compound that is the product of enzymatic hydrolysis of resazurin.

Instruments:

UV-Vis Spectrometer. Micro plate reader / Fluorospectrophotometer.

Individual Files: