Your search keyword '"Yun Wah Lam"' showing total 5 results

1. A Unidirectional Cell Switching Gate by Engineering Grating Length and Bending Angle.

Author

Shu Fan Zhou, Singaram Gopalakrishnan, Yuan Hao Xu, Jie Yang, Yun Wah Lam, and Stella W Pang

Subjects

Medicine, Science

Abstract

On a microgrooved substrate, cells migrate along the pattern, and at random positions, reverse their directions. Here, we demonstrate that these reversals can be controlled by introducing discontinuities to the pattern. On "V-shaped grating patterns", mouse osteogenic progenitor MC3T3-E1 cells reversed predominately at the bends and the ends. The patterns were engineered in a way that the combined effects of angle- and length-dependence could be examined in addition to their individual effects. Results show that when the bend was placed closer to one end, migration behaviour of cells depends on their direction of approach. At an obtuse bend (135°), more cells reversed when approaching from the long segment than from the short segment. But at an acute bend (45°), this relationship was reversed. Based on this anisotropic behaviour, the designed patterns effectively allowed cells to move in one direction but blocked migrations in the opposing direction. This study demonstrates that by the strategic placement of bends and ends on grating patterns, we can engineer effective unidirectional switching gates that can control the movement of adherent cells. The knowledge developed in this study could be utilised in future cell sorting or filtering platforms without the need for chemotaxis or microfluidic control.

Published

2016

2. Dynamic localisation of mature microRNAs in Human nucleoli is influenced by exogenous genetic materials.

Author

Zhou Fang Li, Yi Min Liang, Pui Ngan Lau, Wei Shen, Dai Kui Wang, Wing Tai Cheung, Chun Jason Xue, Lit Man Poon, and Yun Wah Lam

Subjects

Medicine, Science

Abstract

Although microRNAs are commonly known to function as a component of RNA-induced silencing complexes in the cytoplasm, they have been detected in other organelles, notably the nucleus and the nucleolus, of mammalian cells. We have conducted a systematic search for miRNAs in HeLa cell nucleoli, and identified 11 abundant miRNAs with a high level of nucleolar accumulation. Through in situ hybridisation, we have localised these miRNAs, including miR-191 and miR-484, in the nucleolus of a diversity of human and rodent cell lines. The nucleolar association of these miRNAs is resistant to various cellular stresses, but highly sensitive to the presence of exogenous nucleic acids. Introduction of both single- and double-stranded DNA as well as double stranded RNA rapidly induce the redistribution of nucleolar miRNAs to the cytoplasm. A similar change in subcellular distribution is also observed in cells infected with the influenza A virus. The partition of miRNAs between the nucleolus and the cytoplasm is affected by Leptomycin B, suggesting a role of Exportin-1 in the intracellular shuttling of miRNAs. This study reveals a previously unknown aspect of miRNA biology, and suggests a possible link between these small noncoding RNAs and the cellular management of foreign genetic materials.

Published

2013

3. A Unidirectional Cell Switching Gate by Engineering Grating Length and Bending Angle

Author

Yun Wah Lam, Jie Yang, Stella W. Pang, Yuan Hao Xu, Singaram Gopalakrishnan, and Shu Fan Zhou

Subjects

0301 basic medicine, Confocal Microscopy, Microfluidics, Cell Culture Techniques, lcsh:Medicine, Bending, Classification of discontinuities, Long segment, Mice, Mathematical and Statistical Techniques, Cell Signaling, Cell Movement, Membrane Receptor Signaling, lcsh:Science, Anisotropy, Microscopy, Multidisciplinary, Physics, Chemotaxis, Light Microscopy, Classical Mechanics, 3T3 Cells, Cell sorting, Cell Motility, Physical Sciences, Engineering and Technology, Fluidics, Cell relay, Statistics (Mathematics), Research Article, Signal Transduction, Materials science, Adhesion Molecules, Cell Migration, Fluid Mechanics, Grating, Research and Analysis Methods, Continuum Mechanics, 03 medical and health sciences, Optics, Animals, Statistical Methods, Fluid Flow, Cell Shape, Focal Adhesions, Analysis of Variance, business.industry, lcsh:R, Biology and Life Sciences, Fluid Dynamics, Cell Biology, Molecular Development, Culture Media, 030104 developmental biology, lcsh:Q, business, Confocal Laser Microscopy, Mathematics, Developmental Biology

Abstract

On a microgrooved substrate, cells migrate along the pattern, and at random positions, reverse their directions. Here, we demonstrate that these reversals can be controlled by introducing discontinuities to the pattern. On "V-shaped grating patterns", mouse osteogenic progenitor MC3T3-E1 cells reversed predominately at the bends and the ends. The patterns were engineered in a way that the combined effects of angle- and length-dependence could be examined in addition to their individual effects. Results show that when the bend was placed closer to one end, migration behaviour of cells depends on their direction of approach. At an obtuse bend (135°), more cells reversed when approaching from the long segment than from the short segment. But at an acute bend (45°), this relationship was reversed. Based on this anisotropic behaviour, the designed patterns effectively allowed cells to move in one direction but blocked migrations in the opposing direction. This study demonstrates that by the strategic placement of bends and ends on grating patterns, we can engineer effective unidirectional switching gates that can control the movement of adherent cells. The knowledge developed in this study could be utilised in future cell sorting or filtering platforms without the need for chemotaxis or microfluidic control.

Published

2016

4. Differential actions of chlorhexidine on the cell wall of Bacillus subtilis and Escherichia coli

Author

Sung-Kay Chiu, Longman Yimin Liang, Hon-Yeung Cheung, Sau Ha Cheung, Yun Wah Lam, and Matthew Man-Kin Wong

Subjects

Proteome, Applied Microbiology, lcsh:Medicine, Bacillus subtilis, Cell morphology, medicine.disease_cause, Oral Diseases, Cell Wall, Tandem Mass Spectrometry, Microbial Physiology, Gram Negative, Electrophoresis, Gel, Two-Dimensional, Bacterial Physiology, lcsh:Science, Phospholipids, Multidisciplinary, biology, Chlorhexidine, Phosphorus, Bacterial Pathogens, Bacillus Subtilis, Biochemistry, Medical Microbiology, Prokaryotic Models, Medicine, medicine.drug, Research Article, Gram-positive bacteria, Oral Medicine, Microbiology, Phosphorus metabolism, Cell wall, Membrane Lipids, Model Organisms, Bacterial Proteins, Microscopy, Electron, Transmission, Microbial Control, medicine, Escherichia coli, Purine nucleoside interconversion, Biology, Gram Positive, lcsh:R, Bacteriology, biology.organism_classification, Dentistry, Microscopy, Electron, Scanning, lcsh:Q, Disinfectants

Abstract

Chlorhexidine is a chlorinated phenolic disinfectant used commonly in mouthwash for its action against bacteria. However, a comparative study of the action of chlorhexidine on the cell morphology of Gram-positive and Gram-negative bacteria is lacking. In this study, the actions of chlorhexidine on the cell morphology were identified with the aids of electron microscopy. After exposure to chlorhexidine, numerous spots of indentation on the cell wall were found in both Bacillus subtilis and Escherichia coli. The number of indentation spots increased with time of incubation and increasing chlorhexidine concentration. Interestingly, the dented spots found in B. subtilis appeared mainly at the hemispherical caps of the cells, while in E. coli the dented spots were found all over the cells. After being exposed to chlorhexidine for a prolonged period, leakage of cellular contents and subsequent ghost cells were observed, especially from B subtilis. By using 2-D gel/MS-MS analysis, five proteins related to purine nucleoside interconversion and metabolism were preferentially induced in the cell wall of E. coli, while three proteins related to stress response and four others in amino acid biosynthesis were up-regulated in the cell wall materials of B. subtilis. The localized morphological damages together with the biochemical and protein analysis of the chlorhexidine-treated cells suggest that chlorhexidine may act on the differentially distributed lipids in the cell membranes/wall of B. subtilis and E. coli.

Published

2012

5. Differential Actions of Chlorhexidine on the Cell Wall of Bacillus subtilis and Escherichia coli.

Author

Hon-Yeung Cheung, Wong, Matthew Man-Kin, Sau-Ha Cheung, Liang, Longman Yimin, Yun-Wah Lam, and Sung-Kay Chiu

Subjects

CHLORHEXIDINE, BACTERIAL cell walls, BACTERIAL genetics, ESCHERICHIA coli, GRAM-positive bacteria, BACILLUS subtilis, ELECTRON microscopy

Abstract

Chlorhexidine is a chlorinated phenolic disinfectant used commonly in mouthwash for its action against bacteria. However, a comparative study of the action of chlorhexidine on the cell morphology of Gram-positive and Gram-negative bacteria is lacking. In this study, the actions of chlorhexidine on the cell morphology were identified with the aids of electron microscopy. After exposure to chlorhexidine, numerous spots of indentation on the cell wall were found in both Bacillus subtilis and Escherichia coli. The number of indentation spots increased with time of incubation and increasing chlorhexidine concentration. Interestingly, the dented spots found in B. subtilis appeared mainly at the hemispherical caps of the cells, while in E. coli the dented spots were found all over the cells. After being exposed to chlorhexidine for a prolonged period, leakage of cellular contents and subsequent ghost cells were observed, especially from B subtilis. By using 2-D gel/MS-MS analysis, five proteins related to purine nucleoside interconversion and metabolism were preferentially induced in the cell wall of E. coli, while three proteins related to stress response and four others in amino acid biosynthesis were up-regulated in the cell wall materials of B. subtilis. The localized morphological damages together with the biochemical and protein analysis of the chlorhexidine-treated cells suggest that chlorhexidine may act on the differentially distributed lipids in the cell membranes/wall of B. subtilis and E. coli. [ABSTRACT FROM AUTHOR]

Published

2012