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黃士豪

姓名職稱 黃士豪 教授兼系主任 黃士豪
研究室 機械系館A棟207室
電 話 (02) 2462 2192 ext. 3209
傳 真 (02) 2462-0836
E-mail shihhao@mail.ntou.edu.tw
學 歷 清華大學奈米工程與微系統研究所博士(2002-2006)
經 歷 工業技術研究院醫療器材科技中心工程師(2006.12-)
日本交流協會選送赴日本短期研習,東京大學, (2005/6-2005/9)
工業技術研究院電子所副研究員 (2000.05-2002.07)
工業技術研究院能源與資源研究所副研究員(1998.10-2000.05)
研究領域 生醫光電奈微流體系統、生物奈微米機電系統、微光機電系統
研究主題 https://sites.google.com/view/shih-hao/
教學課程 研究所:微流體力學、生醫奈微流體系統技術與應用
大學部:生醫奈微系統概論、微光機電系統導論、熱力學(一)
著作與專利 研究計畫 │Refereed Papers │ Conference Papers │ Other Publications │ Patents


 研究計畫

  1. "以秀麗隱桿線蟲為模式動物於微流體感測平台下探討受高糖毒性作用下之代謝型態與抗高糖毒性天然藥物評估之研究",科技部106年度計畫。
  2. "利用細胞耗氧磷光相位感測裝置探討藻類萃取物於抗台灣石斑虹彩病毒感染之效能分析",科技部105年度計畫。
  3. "生物能量量測之微孔盤系統平台設計開發",工業技術研究院105年度計畫。
  4. "裝戴於石斑魚魚體之整合遠端無線藥物注射與生理狀態無線感測裝置之開發",科技部104年度計畫。
  5. "免疫檢測裝置設計",工業技術研究院104年度計畫。
  6. "可自體產生電力之植入式石斑魚生理狀態無線感測裝置之開發",科技部103年度計畫。
  7. "可同步偵測三種細胞代謝指標之自動化細胞代謝感測裝置雛形機開發",科技部102年度計畫。
  8. "可量測胚胎耗氧代謝之微流體裝置應用於斑馬魚模式動物對致癌毒物與抗癌藥物之快速篩選",科技部101年度計畫。
  9. "開發抗登革病毒與腸病毒71型的藥物及疫苗之快速篩選--細胞包覆耗氧感測微液珠陣列晶片應用於篩選抗登革病毒與腸病毒71型感染之藥物(子計畫二)(3/3)",科技部100年度計畫。

 Refereed Papers

  1. S. H. Huang, C. H. Yu and Y. L. Chien, "Light-Addressable Measurement of in Vivo Tissue Oxygenation in an Unanesthetized Zebrafish Embryo via Phase-Based Phosphorescence Lifetime Detection", Sensors, 15, 8146-8162, 2015 (SCI)
  2. 1.S. H. Huang, H. T. Chu, Y. M. Liou and K. S. Huang, "Light-addressable electrodeposition of magnetically-guided cells encapsulated in alginate hydrogels for three-dimensional cell patterning", Micromachines, Micromachines, 5, 1173-1187 , 2014 (SCI)
  3. S. H. Huang, and Chia-Kai Lin, "Stop-flow Lithography to Continuously Fabricate Microlens Structures Utilizing an Adjustable Three-Dimensional Mask", Micromachines, 5, 667-680, 2014 (SCI)
  4. S. H. Huang, and L. S. Wei, "Light-Addressed Electrodeposition of Polysaccharide Chitosan Membranes on a Photoconductive Substrate", International Journal of Automation and Smart Technology (AUSMT), Vol. 4 No. 4, 196-201, 2014
  5. S.H. Huang, Y. S. Lin, C.C. Wu, and C. J. Wu, "Assessment of the inhibition of Dengue virus infection by carrageenan via real-time monitoring of cellular oxygen consumption rates within a microfluidic device". BioMicrofluidics, 024110, 2014 (SCI)
  6. S. H. Huang, K.S. Huang, C. H. You, H. Y. Gong, "Metabolic profile analysis of a single developing zebrafish embryo via monitoring of oxygen consumption rates within a microfluidic device". BioMicrofluidics, 7, 064107, 2013 (SCI)
  7. S. H. Huang, L. S. Wei, H. T. Chu, Y. L. Jiang, "Light-Addressed Electrodeposition of Enzyme-Entrapped Chitosan Membranes for Multiplexed Enzyme-Based Bioassays Using a Digital Micromirror Device". Sensors 2013, 13, 10711-10724, 2013 (SCI)
  8. Y. J. Chuang, S. H. Huang, Y. C. Chen, K. Y. Hung, "Application of the Inclined Exposure and Molding Process to Fabricate a Micro Beam-Splitter with Nanometer Roughness", Microsystem Technology, (2013) 19:461–470, 2013 (SCI)
  9. C. W. Wu, S. P. Chang, C. J. Wu and Shih-Hao Huang, S. H. Huang, "Cells adhered and cultured on microcantilevers", Microsystem Technology, (2013) 19:105–112, 2013 (SCI)
  10. S.H. Huang, Y. H. Hsu, C.C. Wu, and C. J. Wu, "Light-addressable measurements of cellular oxygen consumption rates in microwell arrays based on phase-based phosphorescence lifetime detection", BioMicrofluidics, 6, 044118, 2012 (SCI)
  11. S. H. Huang, H. J. Hsueh and Y. L. Jiang, "Light-addressable electrodeposition of cell-encapsulated alginate hydrogels for a cellular microarray using a digital micromirror device", BioMicrofluidics, 5, 034109, 2011 (SCI).
  12. T. H. Hsu, J. L. Xiao, Y. W. Tsao, Y. L. Kao, S. H. Huang, W. Y. Liao and C. H. Lee, “Analysis of the paracrine loop between cancer cells and fibroblasts using a microfluidic chip”, Lab Chip, 11, 1808-1814, 2011 (SCI)
  13. H. S. Khoo, C. Lin, S. H. Huang, and F. G. Tseng, “Self-Assembly in Micro- and Nanofluidic Devices: A Review of Recent Efforts”, Micromachines, 2, 17-48, 2011 (SCI)
  14. S. H. Huang, T. C. Chien, and K. Y. Hung, “Selective deposition of electrospun alginate-based nanofibers onto cell-repelling hydrogel surfaces for cell-based microarrays”, Current Nanoscience, 7(2): 267-274, 2011 (SCI)
  15. S.H. Huang, C. H. Tsai, C.C. Wu, and C. J. Wu, " Light-directed, spatially addressable oxygen detection in a hydrogel microarray based on phase-based lifetime detection using a digital micromirror device", Sensors and Actuators A: Physical, 165: 139–146, 2011 (SCI)
  16. S.H. Huang, Z. Y. Yu, C. K. Lin, and K. Y. Hung, "Dynamically adjustable three-dimensional gray masks operated by electrostatic force modulation for the fabrication of microlens arrays in microchannels", Journal of Micro/Nanolithography, MEMS, and MOEMS (JM3), 9(4), 043002, 2010 (SCI)
  17. K. K. Liu, R. G.Wu, Y. J. Chuang, H. S. Khoo, S. H. Huang, and F. G.Tseng, "Microfluidic Systems (MFS) for Biosensing", Sensors, 10: 6623-6661, 2010 (SCI)
  18. K.Y. Hung, T. H. Liao, Y. J. Chuang, D. C. Shye, S.H. Huang, "Research on electrostatic actuator polymer thin-film for controlling light scattering phenomena ", Microsystem Technology, 16:1649–1655, 2010 (SCI)
  19. K.Y. Hung, Y. K. Chen, S.H. Huang, D. C. Shye, "Molding and hot forming techniques for fabricating plastic aspheric lenses with high blue-light transmittance", Microsystem Technology, 16:1439–1444, 2010 (SCI)
  20. S. H. Huang, H. J. Hsueh, K. Y. Hung, "Configurable AC electroosmotic generated in-plane microvortices and pumping flow in microchannels", Microfluidics and Nanofluidics, 8: 187–195, 2010 (SCI)
  21. S. H. Huang, H. S. Khoo, S. Y. ChangChien and F. G. Tseng, 2008,“ Synthesis of bio-functionalized copolymer particles bearing carboxyl groups via a microfluidic device”, Microfluid and Nanofluid, Vol. 5, pp. 459-468(SCI)
  22. S. H. Huang, S. K. Wang, and F. G. Tseng, “AC Electroosmotic Generated In-Plane Microvortices for Stationary or Continuous Fluid Mixing”, Sensors and Actuators B 125 (2007) 326–336 (SCI)
  23. S. H. Huang, and F. G. Tseng, “Synthesis of Bio-functionalized Copolymer Particles in 3D Microfluidic Device”, ( submit to Microsystem Technologies, March, 2007)
  24. S. H. Huang, W. H. Tan, F. G. Tseng, and S. Takeuchi, “A monolithically three-dimensional flow-focusing device for formation of single/double emulsions in the closed/open microfluidic systems”, Journal of Micromechanics and Microengineering, Vol 16, pp. 2336-2344, 2006 (SCI)
  25. S. H. Huang and F. G. Tseng, “Development of a monolithic total internal reflection-based biochip utilizing a microprism array for fluorescence sensing” Journal of Micromechanics and Microengineering, Vol 15, pp 2235-42, 2005 (SCI)
  26. 黃士豪,黃禹傑,魏培坤,曾繁根,“奈微米DNA快速定序實驗室晶片”,電子月刊第十一期第一卷, pp 144-153, 2005
  27. C. H. Kuo (advisor) and S. H. Huang, “Effect of Surface Mounting of Upper Plate on Oscillating Flow Structure within Cavity”, International Journal of Thermal and Fluid Science, 2003, Vol. 27, pp. 755-768. (SCI)
  28. C. H. Kuo (advisor) and S. H. Huang, “Influence of Flow Path Modification on Oscillation of Cavity Shear Layer”, International Journal of Experiments in Fluids, 2001, Vol. 31, pp. 162-179. (SCI).
  29. C. H. Kuo (advisor) and S. H. Huang, “Self-Sustained Oscillation Induced by Horizontal Cover Plate Above the Cavity”, Journal of Fluids and Structure, 2000, Vol. 14, No. 1, pp. 25-48. (SCI)
  30. C. H. Kuo (advisor) and S. H. Hwang, “Influences of The Horizontal Top Plate on The Cavity Shear Flow”, Journal of CSME, Vol. 19, No. 2, 1998, pp. 135-147. (EI).


 Conference Papers

  1. Shr-Hau Huang and Tsai-Chun Chien., “Electrodynamic Focusing Deposition of Electrospun Nanofibers on Cell-repelling Hydrogel Surfaces for Cell-based Microarray,” International Symposium on Microchemistry and Microsystems (ISMM) 2010 in Hong Kong
  2. K. Y. Hung, Shr-Hau Huang etal., “Fabrication and Test of Plastic Aspheric Lenses with High Blu-Ray Transmittance,” HARMST 2009 in Canada
  3. K. Y. Hung, Shr-Hau Huang etal., “Research of Applying the Polymer Thin-Film Development New Display Technology,” HARMST 2009 in Canada
  4. K. Y. Hung, Shr-Hau Huang etal., “Application of the Surface Free Energy Minimization Principle to Improve Sidewall Indentat
  5. S. H. Huang, Yu Z.Y., and Lin C.K, "ELECTROSTATIC-FORCE-MODULATED 3D GRAY MASKS FOR HIGH-THROUGH PUT FABRICATION OF TUNABLE MICROLENS ARRAYS IN MICROCHANNELS", Korea, Micro-Tas, 2009
  6. S. H. Huang, Yu Z.Y., and Hsueh H.J., "CONFIGURABLE AC ELECTROOSMOTIC GENERATED IN-PLANE MICROVORTICES AND PUMPING FLOW IN MICROCHANNELS",Korea, Micro-Tas, 2009
  7. S. H. Huang, Khoo H.S., and Tseng F. G.,"High efficiency of bioconjugation on carboxylated copolymer particles fabricated via a microfluidic device", USA, Micro-Tas, 2008
  8. S. H. Huang, S. K. Wang, and F. G. Tseng, “AC Electroosmotic Generated In-Plane Microvortices for Stationary or Continuous Fluid Mixing”, IEEE-Transducer, 2007/6
  9. S. H. Huang, W. H. Tan, F. G. Tseng, and S. Takeuchi, “Synthesis of Bio-functionalized Copolymer Particles in 3D Microfluidic Device”, IEEE-MEMS, in Kobe, 2007/1
  10. S. H. Huang, W. H. Tan, F. G. Tseng, and S. Takeuchi, “A monolithically three-dimensional flow-focusing device for formation of single/double emulsions in the closed/open microfluidic systems”, MicroTAS, 2006
  11. S. H. Huang and F. G. Tseng, “Continuous Synthesis of Bio-functionalized Copolymer Particles in Microfluidic-based Device”, 第十屆奈米工程暨微系統技術研討會, 2006
  12. S. H. Huang, Y. J. Huang, and F. G. Tseng, “Generation of Local in-plane Microvortexes Actuated by AC electroosmosis”, MicroTAS, pp.158-161, 2005
  13. 黃士豪、黃禹傑、施緯承、曾繁根,“微流道曲率變化對於DNA拉伸特性之影響”,第八屆奈米工程暨微系統技術研討會,pp.63-67, 2004
  14. S. H. Huang, Y. J. Huang, and F. G. Tseng, “A Monolithic Polymer-Optics Network for TIR-based Fluorescence Sensing”, MicroTAS, pp.458-460, 2004
  15. Shr-Hau Huang, Ruey-Jong Shyu, Pen-Chang Tseng, “The Experimental Analysis for the Application of High-Temperature Latent Heat Exchanger”, Third International Conference on Compact Heat Exchangers and Enhancement Technology for the Process Industries, 2000.
  16. Hsiang-Hui Lin, Shr-Hau Huang, Guey-Tian Lin, Bing-Chwen Yang, “Behavior of Charge and Discharge of Thermal Energy in a Storage Type Heat Exchanger”, Symposium on Energy Engineering in the 21st century,2000.
  17. Hsiang-Hui Lin, Shr-Hau Huang, Bing-Chwen Yang, “Experimental Study of Thermal Energy Storage System”, International Mechanical Engineering Congress and Exposition,2000
  18. C. H. Kuo and S. H. Hwang, “Shear Layer Characteristics of Cavity with Different Bottom Slopes”, The 8th International Symposium on Flow Visualization, 1998, Sorrento, September, paper no. 147.
  19. C. H. Kuo and S. H. Huang, “Influence on Cavity Shear Flows by Horizontal Cover-Plate with Different Leading-edge Profiles”, Proceedings of 7th International Conference on Flow Induced Vibrations, 19-22, June, 2000, Lucerne, Switzerland


 Other Publications

  1. S. H. Huang, Y. J. Huang, and F. G. Tseng, 2005, Generation of Local in-plane Microvortexes Actuated by AC electroosmosis, MicroTAS, pp.158-161
  2. 黃士豪,黃禹傑,魏培坤,曾繁根, 2005, 奈微米DNA快速定序實驗室晶片,電子月刊第十一期第一卷, pp 144-153
  3. S. H. Huang, W. H. Tan, F. G. Tseng, and S. Takeuchi, 2006, A monolithically three-dimensional flow-focusing device for formation of single/double emulsions in the closed/open microfluidic systems, MicroTAS
  4. S. H. Huang, S. K. Wang, and F. G. Tseng, 2007, AC Electroosmotic Generated In-Plane Microvortices for Stationary or Continuous Fluid Mixing, IEEE-Transducer, in Lyon,
  5. S. H. Huang, W. H. Tan, F. G. Tseng, and S. Takeuchi, 2007, Synthesis of Bio-functionalized Copolymer Particles in 3D Microfluidic Device, IEEE-MEMS, in Kobe


 Patents

  1. 具有凹凸結構之微管道的核酸萃取裝置與其方法, 黃士豪等人,R.O.C patent, No. 316543, 2009
  2. 魚卵成熟度與受精魚卵光學檢測與篩選裝置, 黃士豪等人,R.O.C patent, No. 370299, 2009
  3. 微型化濕式近場電紡絲製作奈米纖維裝置, 黃士豪等人,R.O.C patent, No. 353202, 2009
  4. 連續流動式光微影製作可調變微透鏡陣列裝置, 黃士豪等人,R.O.C patent, No. 353201, 2009
  5. 重力補償式流體操控裝置及其方法, 黃士豪等人, R.O.C patent, I262254, 2007
  6. Microfluidic mixer apparatus and microfluidic reactor apparatus for microfluidic? processing, Shih-hao Huang et.al., U.S.A patent, No. US 2005/0118647
  7. 動式微流體驅動裝置及方法,黃士豪等人, R.O.C, 177168, 2003
  8. Pneumatic driving device for micro fluids wherein fluid pumping is governed by the control of the flow and direction of incident plural gas streams, Shih-hao Huang et.al., U.S.A patent, No. 6,682311, 2002
  9. 毛細結構式熱管之溫度調節裝置, 黃士豪等人, R.O.C patent, No.174648,2000
  10. 虹吸式熱管之溫度調節裝置, 黃士豪等人, R.O.C patent, No. 175270, 2000
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