Search

Your search keyword '"Tsen, Shaw-Wei D."' showing total 21 results
Start Over Author "Tsen, Shaw-Wei D." Search Limiters Available in Library Collection
21 results on '"Tsen, Shaw-Wei D."'

2. Prospects for a novel ultrashort pulsed laser technology for pathogen inactivation

Author

Tsen Shaw-Wei D, Wu Tzyy, Kiang Juliann G, and Tsen Kong-Thon

Subjects
Medicine
Abstract

Abstract The threat of emerging pathogens and microbial drug resistance has spurred tremendous efforts to develop new and more effective antimicrobial strategies. Recently, a novel ultrashort pulsed (USP) laser technology has been developed that enables efficient and chemical-free inactivation of a wide spectrum of viral and bacterial pathogens. Such a technology circumvents the need to introduce potentially toxic chemicals and could permit safe and environmentally friendly pathogen reduction, with a multitude of possible applications including the sterilization of pharmaceuticals and blood products, and the generation of attenuated or inactivated vaccines.

Published
2012
Full Text
View/download PDF

3. Femtosecond laser treatment enhances DNA transfection efficiency in vivo

Author

Hung Chien-Fu, Pai Sara I, Meneshian Avedis, Wu Chao-Yi, Tsen Shaw-Wei D, and Wu T-C

Subjects
Medicine
Abstract

Abstract Background Gene therapy with plasmid DNA is emerging as a promising strategy for the treatment of many diseases. One of the major obstacles to such therapy is the poor transfection efficiency of DNA in vivo. Methods In this report, we employed a very low power, near-infrared femtosecond laser technique to enhance the transfection efficiency of intradermally and intratumorally administered DNA plasmid. Results We found that femtosecond laser treatment can significantly enhance the delivery of DNA into the skin and into established tumors in mice. In addition, we found that both laser power density as well as duration of laser treatment are critical parameters for augmenting DNA transfection efficiency. The femtosecond laser technique employs a relatively unfocused laser beam that maximizes the transfected area, minimizes damage to tissue and simplifies its implementation. Conclusion This femtosecond new laser technology represents a safe and innovative technology for enhancing DNA gene transfer in vivo.

Published
2009
Full Text
View/download PDF

4. Inactivation of viruses by coherent excitations with a low power visible femtosecond laser

Author

Wu T-C, Hung Chien-Fu, Chang Chih-Long, Tsen Shaw-Wei D, Tsen KT, and Kiang Juliann G

Subjects
Infectious and parasitic diseases, RC109-216
Abstract

Abstract Background Resonant microwave absorption has been proposed in the literature to excite the vibrational states of microorganisms in an attempt to destroy them. But it is extremely difficult to transfer microwave excitation energy to the vibrational energy of microorganisms due to severe absorption of water in this spectral range. We demonstrate for the first time that, by using a visible femtosecond laser, it is effective to inactivate viruses such as bacteriophage M13 through impulsive stimulated Raman scattering. Results and discussion By using a very low power (as low as 0.5 nj/pulse) visible femtosecond laser having a wavelength of 425 nm and a pulse width of 100 fs, we show that M13 phages were inactivated when the laser power density was greater than or equal to 50 MW/cm2. The inactivation of M13 phages was determined by plaque counts and had been found to depend on the pulse width as well as power density of the excitation laser. Conclusion Our experimental findings lay down the foundation for an innovative new strategy of using a very low power visible femtosecond laser to selectively inactivate viruses and other microorganisms while leaving sensitive materials unharmed by manipulating and controlling with the femtosecond laser system.

Published
2007
Full Text
View/download PDF

5. Observation of the low frequency vibrational modes of bacteriophage M13 in water by Raman spectroscopy

Author

Tsen Shaw-Wei D, Lin Nien-Tsung, Sankey Otto F, Dykeman Eric C, Tsen KT, and Kiang Juliann G

Subjects
Infectious and parasitic diseases, RC109-216
Abstract

Abstract Background Recently, a technique which departs radically from conventional approaches has been proposed. This novel technique utilizes biological objects such as viruses as nano-templates for the fabrication of nanostructure elements. For example, rod-shaped viruses such as the M13 phage and tobacco mosaic virus have been successfully used as biological templates for the synthesis of semiconductor and metallic nanowires. Results and discussion Low wave number (≤ 20 cm-1) acoustic vibrations of the M13 phage have been studied using Raman spectroscopy. The experimental results are compared with theoretical calculations based on an elastic continuum model and appropriate Raman selection rules derived from a bond polarizability model. The observed Raman mode has been shown to belong to one of the Raman-active axial torsion modes of the M13 phage protein coat. Conclusion It is expected that the detection and characterization of this low frequency vibrational mode can be used for applications in nanotechnology such as for monitoring the process of virus functionalization and self-assembly. For example, the differences in Raman spectra can be used to monitor the coating of virus with some other materials and nano-assembly process, such as attaching a carbon nanotube or quantum dots.

Published
2006
Full Text
View/download PDF

8. Prospects for a Novel Ultrashort Pulsed Laser Technology for Pathogen Inactivation

Author

UNIFORMED SERVICES UNIV OF THE HEALTH SCIENCES BETHESDA MD DEPT OF MEDICINE, Tsen, Shaw-Wei D, Wu, Tzyy C, Kiang, Juliann G, Tsen, Kong-Thon, UNIFORMED SERVICES UNIV OF THE HEALTH SCIENCES BETHESDA MD DEPT OF MEDICINE, Tsen, Shaw-Wei D, Wu, Tzyy C, Kiang, Juliann G, and Tsen, Kong-Thon

Abstract

The threat of emerging pathogens and microbial drug resistance has spurred tremendous efforts to develop new and more effective antimicrobial strategies. Recently, a novel ultrashort pulsed (USP) laser technology has been developed that enables efficient and chemical-free inactivation of a wide spectrum of viral and bacterial pathogens. Such a technology circumvents the need to introduce potentially toxic chemicals and could permit safe and environmentally friendly pathogen reduction, with a multitude of possible applications including the sterilization of pharmaceuticals, blood products, and the generation of attenuated or inactivated vaccines., Published in Journal of Biomedical Science, v19 n62, 2012. The original document contains color images.

Published
2012

9. Evidence of a Novel Gene from Aeromonas hydrophila Encoding a Putative Siderophore Receptor Involved in Bacterial Growth and Survival

Author

Tsen, Shaw-Wei D. and Tsen, Shaw-Wei D.

Abstract

The pathogenic bacterium Aeromonas hydrophila has been shown to exclusively utilize a ligand exchange mechanism for siderophore-mediated iron uptake, with a single nonspecific siderophore receptor facilitating iron exchange. However, the genes involved in this process, including the gene encoding the nonspecific receptor, are unknown. Here we identify and characterize a novel gene, nsr1, from A. hydrophila that encodes a putative protein with high homology and significant predicted structural similarities to the FhuA protein and other known ferric-siderophore receptors. This protein appears to localize on the cell membrane and is likely to be the receptor involved in the ligand exchange siderophore-mediated iron uptake mechanism of A. hydrophila. It is expected that this information may lead to the development of new antibiotics targeting either nsr1 or its gene product for use in controlling A. hydrophila infection., non disponibile

Published
2008

10. Inactivation of Viruses by Coherent Excitations with a Low Power Visible Femtosecond Laser

Author

ARIZONA STATE UNIV TEMPE DEPT OF PHYSICS, Tsen, K. T., Tsen, Shaw-Wei D., Chang, Chih-Long, Hung, Chien-Fu, Wu, T.-C., Kiang, Juliann G., ARIZONA STATE UNIV TEMPE DEPT OF PHYSICS, Tsen, K. T., Tsen, Shaw-Wei D., Chang, Chih-Long, Hung, Chien-Fu, Wu, T.-C., and Kiang, Juliann G.

Abstract

Background: Resonant microwave absorption has been proposed in the literature to excite the vibrational states of microorganisms in an attempt to destroy them. But it is extremely difficult to transfer microwave excitation energy to the vibrational energy of microorganisms due to severe absorption of water in this spectral range. We demonstrate for the first time that, by using a visible femtosecond laser, it is effective to inactivate viruses such as bacteriophage M13 through impulsive stimulated Raman scattering. Results and discussion: By using a very low power (as low as 0.5 nj/pulse) visible femtosecond laser having a wavelength of 425 nm and a pulse width of 100 fs, we show that M13 phages were inactivated when the laser power density was greater than or equal to 50 MW/sq cm. The inactivation of M13 phages was determined by plaque counts and had been found to depend on the pulse width as well as power density of the excitation laser. Conclusion: Our experimental findings lay down the foundation for an innovative new strategy of using a very low power visible femtosecond laser to selectively inactivate viruses and other microorganisms while leaving sensitive materials unharmed by manipulating and controlling with the femtosecond laser system., Published in Virology Journal, v4 n50, 2007.

Published
2007

14. Photonic approach to the selective inactivation of viruses with a near-infrared subpicosecond fiber laser

Author

Tsen, Kong-Thon, primary, Tsen, Shaw-Wei D., additional, Fu, Q., additional, Lindsay, Stuart M., additional, Kibler, Karen, additional, Jacobs, Bert, additional, Wu, T-C., additional, Karanam, B., additional, Jagu, S., additional, Roden, Richard B. S., additional, Hung, Chien-Fu, additional, Sankey, Otto F., additional, Ramakrishna, B., additional, and Kiang, Juliann G., additional

Published
2009
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results