TY - JOUR
T1 - From an integrated biochip detection system to a defensive weapon against the SARS-CoV virus
T2 - Nanoengineered Assemblies and Advanced Micro/Nanosystems
AU - Lee, Chih Kung
AU - Lin, Chi Wan
AU - Lin, Shiming
AU - Lee, Adam Shih Yuan
AU - Wu, Jiun Yan
AU - Lee, Shu Sheng
AU - Hsiao, Wen Hsin
AU - Chen, Shih Jui
AU - Wang, An Bang
PY - 2004
Y1 - 2004
N2 - In this paper, an integrated multifunctional biochip detection system, which we call "OBMorph", are presented. This unique system integrates several optoelectronic-based biological diagnostic tools such as an ellipsometer, a laser Doppler vibrometer/interferometer, a SPR (surface plasmon resonance) analyzer, an interference microscope, a photon tunneling microscope, an optical coherence tomography unit and a confocal scanning microscope. This OBMorph system, useful as a powerful optical metrology diagnostic tool, can be used at the beginning of sensor chip fabrication, on to signal detecting and monitoring, and to the final biological analysis. The principles and experimental results of this multifunctional biochip detection OBMorph system are presented. In addition, an innovative SARS (Severe Acute Respiratory Syndrome) virus denaturing chemical compound that was derived using the OBMorph system to study biolinker fabrication in biochips, are discussed. Several testing strategies are presented herein which proves the effectiveness of the new chemical compound, biochip technology in denaturing the SARS virus. Analysis under an atomic force microscope confirms the actual breaking down of the virus treated by the chemical compound. The fundamentals of how the chemical compound denatures the virus and renders it toxicity useless, is based on principles of nanotechnology and bio-mechanics. Results from preliminary studies show that this denaturing principle can be also effective against other deadly viruses and even bacteria. Some design strategies and innovative working mechanisms derived from study of this chemical compound which can denature the SARS-CoV, are also discussed.
AB - In this paper, an integrated multifunctional biochip detection system, which we call "OBMorph", are presented. This unique system integrates several optoelectronic-based biological diagnostic tools such as an ellipsometer, a laser Doppler vibrometer/interferometer, a SPR (surface plasmon resonance) analyzer, an interference microscope, a photon tunneling microscope, an optical coherence tomography unit and a confocal scanning microscope. This OBMorph system, useful as a powerful optical metrology diagnostic tool, can be used at the beginning of sensor chip fabrication, on to signal detecting and monitoring, and to the final biological analysis. The principles and experimental results of this multifunctional biochip detection OBMorph system are presented. In addition, an innovative SARS (Severe Acute Respiratory Syndrome) virus denaturing chemical compound that was derived using the OBMorph system to study biolinker fabrication in biochips, are discussed. Several testing strategies are presented herein which proves the effectiveness of the new chemical compound, biochip technology in denaturing the SARS virus. Analysis under an atomic force microscope confirms the actual breaking down of the virus treated by the chemical compound. The fundamentals of how the chemical compound denatures the virus and renders it toxicity useless, is based on principles of nanotechnology and bio-mechanics. Results from preliminary studies show that this denaturing principle can be also effective against other deadly viruses and even bacteria. Some design strategies and innovative working mechanisms derived from study of this chemical compound which can denature the SARS-CoV, are also discussed.
UR - http://www.scopus.com/inward/record.url?scp=14944359032&partnerID=8YFLogxK
U2 - 10.1557/proc-820-o9.8
DO - 10.1557/proc-820-o9.8
M3 - 會議論文
AN - SCOPUS:14944359032
SN - 0272-9172
VL - 820
SP - 249
EP - 260
JO - Materials Research Society Symposium - Proceedings
JF - Materials Research Society Symposium - Proceedings
M1 - O9.8
Y2 - 13 April 2004 through 16 April 2004
ER -