Real-time microscopic study and modeling of the disruption of bacterial swarming motion
Collective motion of living organisms is ubiquitous in nature. In biology, certain bacteria such as the Gram-positive Bacillus subtilis can differentiate into swarming cells and move rapidly across the surface of a semisolid media in multicellular rafts or clusters. Experimental studies on the colle...
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sg-ntu-dr.10356-658682023-03-01T00:01:01Z Real-time microscopic study and modeling of the disruption of bacterial swarming motion Lu, Shengtao Yeow Edwin Kok Lee School of Physical and Mathematical Sciences DRNTU::Science::Chemistry::Biochemistry DRNTU::Science::Biological sciences::Biophysics Collective motion of living organisms is ubiquitous in nature. In biology, certain bacteria such as the Gram-positive Bacillus subtilis can differentiate into swarming cells and move rapidly across the surface of a semisolid media in multicellular rafts or clusters. Experimental studies on the collective motion of bacteria have so far been limited to understanding the swarming dynamics of healthy cells. In this work the motion dynamics of disrupted swarming bacteria is studied and modeled: i) The collective motion of Bacillus subtilis in the presence of a photosensitizer is disrupted by reactive oxygen species when exposed to light of sufficient dosages and is partially recovered when light irradiation is suspended. The transition from a highly collective to a more random motion is modeled using an improved self-propelled model with alignment rule. ii) Monolayer of swarming Bacillus subtilis on semi-solid agar display elevated resistance against antibiotics. The drug resistance is impeded when the collective motion of bacteria is judiciously disrupted using non-toxic polystyrene (PS) colloidal particles immobilized on the agar surface. The colloidal particles block and hinder the motion of the cells, causing cohesive rafts of bacteria to lose their collectivity and speed. The negative correlation between the degree of collectivity and PS particle density is examined using an improved self-propelled model that takes in to account inter-particle alignment and hard-core repulsion. DOCTOR OF PHILOSOPHY (SPMS) 2016-01-05T06:19:28Z 2016-01-05T06:19:28Z 2015 2016 Thesis Lu, S. (2015). Real-time microscopic study and modeling of the disruption of bacterial swarming motion. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/65868 10.32657/10356/65868 redirect\Lu Shengtao\Real-time Microscopic Study and Modeling of the Disruption of Bacterial Swarming Motion en 179 p. application/pdf text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html |
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DRNTU::Science::Chemistry::Biochemistry DRNTU::Science::Biological sciences::Biophysics Lu, Shengtao Real-time microscopic study and modeling of the disruption of bacterial swarming motion |
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Collective motion of living organisms is ubiquitous in nature. In biology, certain bacteria such as the Gram-positive Bacillus subtilis can differentiate into swarming cells and move rapidly across the surface of a semisolid media in multicellular rafts or clusters. Experimental studies on the collective motion of bacteria have so far been limited to understanding the swarming dynamics of healthy cells. In this work the motion dynamics of disrupted swarming bacteria is studied and modeled: i) The collective motion of Bacillus subtilis in the presence of a photosensitizer is disrupted by reactive oxygen species when exposed to light of sufficient dosages and is partially recovered when light irradiation is suspended. The transition from a highly collective to a more random motion is modeled using an improved self-propelled model with alignment rule. ii) Monolayer of swarming Bacillus subtilis on semi-solid agar display elevated resistance against antibiotics. The drug resistance is impeded when the collective motion of bacteria is judiciously disrupted using non-toxic polystyrene (PS) colloidal particles immobilized on the agar surface. The colloidal particles block and hinder the motion of the cells, causing cohesive rafts of bacteria to lose their collectivity and speed. The negative correlation between the degree of collectivity and PS particle density is examined using an improved self-propelled model that takes in to account inter-particle alignment and hard-core repulsion. |
| author2 |
Yeow Edwin Kok Lee |
| author_facet |
Yeow Edwin Kok Lee Lu, Shengtao |
| format |
Theses and Dissertations |
| author |
Lu, Shengtao |
| author_sort |
Lu, Shengtao |
| title |
Real-time microscopic study and modeling of the disruption of bacterial swarming motion |
| title_short |
Real-time microscopic study and modeling of the disruption of bacterial swarming motion |
| title_full |
Real-time microscopic study and modeling of the disruption of bacterial swarming motion |
| title_fullStr |
Real-time microscopic study and modeling of the disruption of bacterial swarming motion |
| title_full_unstemmed |
Real-time microscopic study and modeling of the disruption of bacterial swarming motion |
| title_sort |
real-time microscopic study and modeling of the disruption of bacterial swarming motion |
| publishDate |
2016 |
| url |
https://hdl.handle.net/10356/65868 |
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1759858146325561344 |