Professor

Dr. wang photo
Dr. Gou-Jen Wang

Fellow, ASME
Dean of College of Engineering, NCHU
Distinguished Professor, Mechanical Engineering, NCHU
Adjunct Professor, Institute of Biomedical Engineering, NCHU


Phone: 04-2284-0725 ext. 320
FAX: 04-2287-7170
E-mail: gjwang@dragon.nchu.edu.tw
Address:
Department of Mechanical Engineeirng,National Chung Hsing University, Taichung 40227, Taiwan

Editorial Board
Austin Journal of Biosensors & Bioelectronics
Austin Journal of Nampmedicine & Nanothechnology
Bioengineering
Inventions
The Journal of the Chinese Society of Mechanical Engineers

Education
B.S., Mechanical Engineering, National Taiwan University, 1981
M. S., Mechanical Engineering, University of California at Los Angeles, CA, USA 1986
Ph.D., Mechanical Engineering, University of California at Los Angeles, CA, USA 1991

Professional Experience
Co-founder, Vidabio Inc., 2014/09- (Nanostructured biosensors design and manufacturing)
Vice Director, Biotechnology Center, National Chung-Hsing University, 2014/02-2015/07
Vice Director, Biotechnology Center, National Chung-Hsing University, 2014/02-2015/07
Chairman, Graduate Institute of Biomedical Engineering, National Chung-Hsing University, (2007/10-2011/07)
Distinguished Professor, Mechanical Engineering, National Chung-Hsing University, Since 2008
Visiting Scholar, Department of Mechanical Engineering, U. of Washington, WA, USA, 2006/8-2006/12
Visiting Scholar, Department of Mechanical Engineering, U. of Washington, WA, USA, 2003/7-2003/9
Professor, Mechanical Engineering, National Chung-Hsing University, Since 1999
Associate Professor, Mechanical Engineering, National Chung-Hsing University, (1992/02-1999/07)
System Engineer, Dowty Aerospace, Los Angeles, USA (1991/06-1992/02)
Mechanical Engineer, 3D System, Los Angeles, USA (1989/02-1990/06)

Professional Service
Conference chair-2020 The ASME 14th International Conference on Micro- and Nanosystems, St. Louis, MO, USA.
Program chair-2019 The ASME 13th International Conference on Micro- and Nanosystems, Anaheim, CA, USA.
Conference chair-2017 Asia Pacific Symposium on Technology of Plasticity
Conference chair-2016 International Conference on Advanced Manufacturing
Conference chair- 2016 Automation Taiwan
Conference chair- 2016 21th Symposium of Association for Chemical Sensors in Taiwan
Conference Chair: 2008 Microfabrication, Integration and Packaging Conference (Nice, France)
Committee member: Micro & Nano System Division, American Society of Mechanical Engineers, Since 2009
Conference symposium organizer: American Society of Mechanical Engineers, International Conference on Micro- and Nanosystems, Since 2008
Committee member: DTIP of MEMS/MOEMS Conference, Since 2005

Awards
Futuretech Award-2020 (Ministry of Science and Technology, Taiwan)
Outstanding Research Award-2019 (Ministry of Science and Technology, Taiwan)
16th Innovators-2018 (Taiwan): One medal
15th Innovators-2018 (Taiwan): One medal
14th Innovators-2017 (Taiwan): One medal
13th Innovators-2016 (Taiwan): Four medals (The first person to get four medals in a year)
ASME 2019, 2017, 2016, 2015, 2014, 2011 International Conference on Micro/Nano System, The Best paper award.
ASME 2015 International Mechanical Engineering Congress and Exposition-MEMS Division, The Best paper award.
IEEE Trans. on Nanotechnology, 10(2), 2011, Cover page.

Research Interest

Research interests in our lab include Biomedical Engineering and Nano/Micro Fabrication:

1. Biomedical Engineering research achievements are in (1) Nanostructured biosensors & (2) Tissue engineering and regenerative medicine.

Nanostructured biosensors
Electrochemical analysis is a promising method for biosensing. In our current work, a highly sensitive nanostructured electrochemical biosensor based on a 3D sensing element featuring uniformly deposited gold nanoparticles has been developed. A modified anodic aluminum oxide (AAO) barrier-layer surface is used as the template for nickel thin film deposition. After etching the AAO template off, a 3D mold of the concave nano structure array is created. The fabricated 3D nickel mold is further used for replica molding of a nano-structure polycarbonate (PC) substrate by hot embossing. An Au thin film is then sputtered on the PC substrate to form the electrode followed by the deposition of an orderly and uniform gold nanoparticles (GNPs) layer on the 3D Au electrode using electrochemical deposition. The detections of the dust mite antigen Der p2, allergy patient’s serum, allergy disease related gene mutations (SNP and Haplotype), dengue virus-receptor binding, hepatitis B virus DNA, Alzheimer's (AD) Aβ protein have been successfully carried out using electrochemical impedance spectroscopy (EIS) analysis.

AAO

Publications
1
Tung, Y. T., Liang, J. J., Feng, H. T., Jhang, R. N., Hsieh, S. L., Lin, Y. L.**, Wang, G. J.*, Investigation of the extremely weak interaction between the Japanese Encephalitis virus and CLEC5A using a multivalent-interaction-enhancement sensing electrode, Biosensors and Bioelectronics: x, 100024. (2019) (IF=10.257, 1/86).
2
Jian, Y. S., Lee, C. H., Jan, F. J**, and Wang, G. J.*, Detection of odontoglossum ringspot virus infected phalaenopsis using a nano-structured biosensor, J. Electrochemical Society, 165 (9) H449-H454. (2018) (IF=2.552, 9/21)
3
Shen, M. C., Lai, J. C., Hong, C. Y., and Wang, G. J.*, Electrochemical aptasensor for detecting Der p2 allergen using polycarbonate-based double-generation gold nanoparticle chip, Sensing and Bio-Sensing Research, 13, 75-80, (2017)
4
Chen, C. C., Lai, Z. L., Wang, G. J.*, and Wu, C. Y.**, Polymerase chain reaction-free detection of hepatitis B virus DNA using a nanostructured impedance biosensor, Biosensors & Bioelectronics, 77, 603-608. (2016) (IF=10.257, 1/86).
5
Tung, Y. T., Chang, C. C.*, Y. L. Lin, Hsieh, S. L., and Wang, G. J.*, Development of double-generation gold nanoparticle chip-based dengue virus detection system combining fluorescence turn-on probes, Biosensors & Bioelectronics, 77-90-98. (2016) (IF=10.257, 1/86).
6
Hsu, C. W., Feng, W. C., Su, F. C., and Wang, G. J.*, A novel electrochemical glucose biosensor with a silicon nanowire array electrode, J. Electrochemical Society, 162(10), B1-B5, (2015). (IF=2.552, 9/21)
7
Tung, Y. T., Wu, M. F., Wang, G. J.*, and Hsieh, S. L**, Nanostructured electrochemical biosensor for the detection of the weak binding between the Dengue Virus and the CLEC5A receptor, Nanomedicine: NBM, 10, 1335-1341 (2014). (IF=5.182, 25/138)
8
Hsu, C. W. and Wang, G. J.*, Highly sensitive glucose biosensor based on Au–Ni coaxial nanorod array having high aspect ratio, Biosensors & Bioelectronics, 56, 204-209, (2014). (IF=10.257, 1/86)
9
Chin, Y. T., Liao, E. C., Wu, C. C., Wang, G. J.*, and Tsai, J. J.*, Detection of the haplotype mutations of the MD-2 gene promoter associated with Der p2-induced allergy using a nanostructured biosensor, Inter. J. Nanomedicine, 9, 403-412, (2014). (IF=5.115, 24/270)
10
Chin, Y. T., Liao, E. C., Wu, C. C., Wang, G. J.*, and Tsai, J. J.*, Label-free detection of single-nucleotide polymorphisms associated with myeloid differentiation-2 using a nanostructured biosensor, Biosensors & Bioelectronics, 49, 506-511, (2013). (IF=10.257, 1/86)
11
Liu, H. C., Tsai, C. C. and Wang, G. J.*, Glucose biosensors based on a gold nanodendrite modified screen-printed electrode, Nanotechnology, 24, 215101, (2013) (IF=3.551, 40/154).
12
Tsai, J. J., Liu, Y. F., Liao, E. C., Chen, J. L, and Wang, G. J.*, Reduction of incubation time and enhancement of analyte adhesion uniformity of impedance biosensors using microvibration method, Sensors & Actuators B: Chemical, 178, 404-411, (2013). (IF=7.1, 2/64)
13
Tsai, C. C. and Wang, G. J.*, A glucose biosensor based on a 3D nanostructured gold electrode, J. Electrochemical Society, 160(1), B1-B5, (2013). (IF=2.552, 9/21)
14
Liu, Y. F., Tsai, J. J., Chin, Y. T., Liao, E. C., Wu, C. C., Wang, G. J.*, Detection of allergies using a silver nanoparticle modified nanostructured biosensor, Sensors & Actuators B: Chemical, 171-172, 1095-1100, (2012) (IF=7.1, 2/64).
15
Chen, Y. S., Wu, C. C., Tsai, J. J., and Wang, G. J.*, An electrochemical impedimetric biosensor based on a nanostructured polycarbonate (PC) substrate, Inter. J. Nanomedicine, 7, 133-140, (2012) (IF=5.115, 24/270)
16
Tsai, J. J., Bau, I. J., Chen, H. T., Lin, Y. T., and Wang, G. J.*, A novel nanostructured biosensor for the detection of the dust mite antigen Der p2, Inter. J. Nanomedicine, 6, 1201-1208, (2011) (IF=5.115, 24/270)

In addition to the above nanostructured electrochemical biosensor, we team-up with the Phoenix Silicon International Corporation in semiconductor industry to develop a cost effective and high sensitive non-enzymatic glucose biosensor. The sequential fabrication procedures for the proposed simple non-enzymatic glucose biosensor, including silicon wafer cleaning and photoresist coating, exposure and development, thermal melting, and gold thin film sputtering and deposition of GNPs. Measurements showed a 10.2-fold enhancement of the sensing area in comparison with a plain gold electrode. Actual detection of glucose demonstrated that the proposed non-enzymatic glucose biosensor can operate in a linear range of 55.6 M-13.89 mM. It had a sensitivity of 749.2 μA·mM−1·cm−2 and a detection limit of 9 M. When the glucose concentration is less than 100 mg/Dl, the accuracy of the developed glucose biosensor reaches ±0.18 mg/Dl, which is much better than the FDS and ISO 15197 standard of ±20 mg/Dl and ±15 mg/Dl, respectively. The novel glucose biosensor proposed here has several advantages such as being enzyme free, simple to fabricate, low cost, and easy to preserve on a long-term basis. Thus, it can feasibly be used for future clinical applications.

AU-nano
 

Publications
1
Chu, T. F., Rajendran, R., Kuznetsova, I., and Wang, G. J.*, High-power, non-enzymatic glucose biofuel cell based on a nano/micro hybrid-structured Au anode, Journal of Power Sources, 453, 227844, (2020) (IF=8.247, 10/112)
2
Wang, W. J., Lee, C. H., Li, C. W., Liao, S., Jan, F. J.**, and Wang, G. J.*, Orchid virus detection from orchid leaves using micro/nano hybrid-structured immuno-electrochemical biosensor, J. Electrochemical Society, 167, 027530, (2020) (IF=2.552, 9/21)
3
Lin, Y. T., Kuznetsova, I., and Wang, G. J.*, Genetically modified soybean detection using a biosensor electrode with self-assembled gold nanoparticles on a micro hemisphere array, The ASME 13th International Conference on Micro- and Nanosystems, Anaheim, California, USA. (2019)
4
Lin, Y. C., Liao, S., Huang, T., and Wang, G. J.*, A novel biosensor electrode with self-assembled monolayer of gold nanoparticle on a micro hemisphere array, J. Electrochemical Society, 166 (6) B349-B354. (2019) (IF=2.552, 9/21)
5
Lin, Y, C. and Wang, G. J.*, A novel non-enzymatic glucose biosensor with a monolayer of self-assembled gold nanoparticles on a micro hemisphere array, 28th Anniversary World Congress on Biosensors, Miami, FL, USA (2018).
6
Hsu, C. W., Su, F. C., Peng, P. Y., Young, H. T., Liao, S., and Wang, G. J.*, Highly sensitive non-enzymatic electrochemical glucose biosensor using a photolithography fabricated micro/nano hybrid structured electrode, Sensors and Actuators B, 230, 559-565. (2016) (IF=7.1, 2/64)
7
Hsu, C. W., Feng, W. C., Su, F. C., and Wang, G. J.*, A novel electrochemical glucose biosensor with a silicon nanowire array electrode, J. Electrochemical Society, 162(10), B1-B5. (2015) (IF=2.552, 9/21)
8
Hsu,C. W., Su,F. C., Peng,P. Y., Young,H. T., Yang,M.,and Wang, G. J.*, A novel non-enzymatic electrochemical glucose biosensor based on a simple lithographic process, The ASME 9th International Conference on Micro- and Nanosystems, Boston, MA, USA. (2015). The Best Paper Award.

We have integrated Taiwan’s superior industries such as semiconductor micro-electromechanical manufacturing processes, precision micro-molding, hot embossing, and chip packaging to develop Pt/Au nano-alloy electrodes with applications in neutral non-enzymatic glucose biosensors and neutral non-enzymatic glucose biofuel cell. This novel Pt/Au nano-alloy electrode possesses advantages of technology foresight, good detection performance, and high feasibility of mass production. We have cooperated with the Plastics Industry Development Center to link up-stream and downstream manufacturers in Taiwan for trial production of electrodes and sensors. In the future, we will further develop an autogenous power supply implantable continuous glucose sensor by integrating the glucose detection sensor and the glucose biofuel cell.

AU-nano
 

 

Tissue Engineering and Regenerative Medicine
Our lab has been working on the fabrication of microvessel networks for more than ten years. Currently ongoing studies include the fabrication of a reticular structure scaffold of cylindrical PLGA for the in vitro development of microvascular networks, nerve guidance conduit with a hybrid structure of microfibrous bundle wrapped in a micro/nanostructured membrane, and investigation of the influences of micro/nanopatterning on gel surface on cancer cell interactions.

3
 

The mitochondrion is a very unique organelle found in most eukaryotic cells. In addition to serving as cellular power plants by producing adenosine triphosphate (ATP) through respiration, mitochondria contribute to other physiological functions, including signalling, cellular differentiation, cell death and regulation of cellular metabolism. Reactive oxygen species, which can result from leakage of the high-energy electrons during the cellular respiration process, can cause oxidative stress in the mitochondria and thereby induce mutations of the mitochondrial DNA (mtDNA). These mutations lead to diseases such as tumours, diabetes, cardiovascular disease and age-related neuropathies. Our lab collaborates with Dr. Chin-San Liu (Vice Superintendent, Changhua Christian Hospital, Taiwan) to work on the the issues of mitochondria therapy. We have developed a novel centrifugal device for massive extraction of high-quality and healthy mitochondria. Experimental results confirmed that the proposed microfluidic device could obtain healthy mitochondria, with no structural damage and altered activities in 30 min.

centrifuge

Publications
1
Liu, Z. J., Lin, S. C., Lee, P. Y., Lin, Y. T., Lai, Z. L., Chang, C. C.**, and Wang, G. J.*, Dual-acting antibacterial porous chitosan film embedded with a photosensitizer, Science and Technology of Advanced Materials, accepted, (2020). (IF=5.799)
2
Alvarez-Elizondo, M. B., Li, C. W., Marom, A., Tung, Y. T., Drillich, G., Horesh, Y., Lin, S. C., Wang, G. J.**, Weihs, D.*, Micropatterned topographies reveal measurable differences between cancer and benign cells, Medical Engineering & Physics, 75, 5-12, 2020. (2020) (IF=1.737)
3
Lin, Y. T., Chen, S. T., Chang, J. C., Teoh, R. J., Liu, C. S., and Wang, G. J.*, Green extraction of healthy and chemical free mitochondria with a conventional centrifuge, Lab on Chip, 19, 3862-3869. (2019) (IF= 6.774)
4
Su, C. H., Chen, J. W., Chen, L. D., Chang, J. C., Liu, C. S., Chang, C. C.*, and Wang, G. J.*, Organic Small Molecule for Detection and Photodegradation of Mitochondrial DNA Mutations, Journal of Materials Chemistry B, 39 (7), 5947-5955. (2019) (IF= 5.344)
5
Cai, S. J., Li, C. W., Weihs, D., and Wang, G. J.*, Control of cell proliferation by a porous chitosan scaffold with multiple releasing capabilities, Science and Technology of Advanced Materials, 18(1), 987-996, (2017). (IF=5.799)
6
Li, C. W. and Wang, G. J.*, Double-layer nerve guide conduit with palisade poly(lactic-co-glycolic acid) tube wrapped by microporous chitosan–collagen composite, The ASME 11th International Conference on Micro- and Nanosystems, Cleveland, OH, USA. (2017). The Best Paper Award.
7
Tung, Y. T., Chang, C. C., Ju, J. C.*, and Wang, G. J.*, Fabrication of a reticular poly(lactide-co-glycolide) cylindrical scaffold for the in vitro development of microvascular networks, Science and Technology of Advanced Materials, 18(1), 163-171, (2017) (IF= 5.799).
8
Peng, S. W., Li, C. W., Chiu, I. M., and Wang, G. J.*, Nerve guidance conduit with a hybrid structure of a PLGA microfibrous bundle wrapped in a micro/nanostructured membrane, Inter. J. Nanomedicine, 12, 421-432. (2017) (IF=5.115).
9
Tung, Y. T. and and Wang, G. J.*, In vitro development of microvessels using a scaffold of cylindrical PLGA, The ASME 10th International Conference on Micro- and Nanosystems, Charlotte, NC, USA. (2016). The Best Paper Award-3rd place.
10
Li, C. W., Pan, W. T., Ju, J. C., Wang, G. J.*, An endothelial cell conditioned medium embedded in porous PLGA scaffold for the enhancement of mouse embryonic stem cell differentiation, Biomedical Materials, 11, 025015 (12 pages) (2016) (IF=3.174)
11
Ciudad, P , Dower, R , Nicoli, F , Orfaniotis, G, Maruccia, M , Constantinescu, T , Lin, S. P., Wang, G. J.*, Chen, H. C., Pelvic-perineal reconstruction with the combined transverse upper gracilis and profunda artery perforator (TUG-PAP) flap, Journal of Plastic Reconstructive and Aesthetic Surgery, 69(4), 573-575. (2016) (IF=2.39)
12
Wu, J. Y., Li,C. W., Tsai, C. H., Chou, C. W., Chen, D. R., and Wang, G. J.*, Synthesis of antibacterial TiO2/PLGA composite biofilms, Nanomedicine: NBM, 10, 1097-1107, (2014) (IF=5.182).
13
Li, C. W. and Wang, G. J.*, A material-independent cell–environment niche based on micro-reciprocating motion for cell growth enhancement, Biofabrication, 5, 045001, (2013) (IF=8,213).
14
Chung, I. C., Li, C. W., and Wang, G. J.*, The influence of different nanostructured scaffolds on fibroblast growth, Science and Technology of Advanced Materials, 14, 044401, (2013) (IF=5.799).
15
Wang, H. W., Cheng, C. W., Li, C. W., Chang, H. W., Wu, P. H., Wang, G. J.*, Fabrication of pillared PLGA microvessel scaffold using femtosecond laser ablation, Inter. J. Nanomedicine, 7, 1865-1873, (2012) (IF=5.115)
 

Nano/Micro Fabrication

(1)Anodic Aluminum Oxide (AAO) Fabrication and Application
Anodic aluminum oxide (AAO) membrane, having nano-size porous array of regular hexagonal-shaped cells with straight columnar channels, has been widely used as the template in fabricating one-dimensional nano materials which have controllable orientation. Our group focuses on the fabrications and applications of AAO. Ongoing researches include gold/nickel coaxial nanorods array, nanobiosensor, nano hemispheric nickel array mold, nanostructure biomaterials.

nano-imprinting
Nano-imprinting of flexible photonic crystal

Publications
1
Peng, C. Y., Hsu, C. W., Li, C. W., Wang, P. L., Jeng, C. C., Chang, C. C.**, Wang, G. J.*, A flexible photonic crystal material for multiple anti-counterfeiting applications, ACS Applied Materials & Interfaces, 10 (11), 9858–9864, (2018). (IF=8.758).
2
Peng, C. Y., Hsu, C. W., Li, C. W., Wang, G. J.*, Using anodic aluminum oxide film and nanoimprint to produce polymer anti-counterfeit labels, Smart Science, 5(3), 117-122, (2017)
3
Lee, B. Y., Li, C. W. and Wang, G. J.*, Nanoporous anodic aluminum oxide tube encapsulating a microporous chitosan/collagen composite for long-acting drug release, Biomedical Physics & Engineering Express, 1, 045004 (2015)
4
Lee, B. Y., Li, C. W., and Wang, G. J.*, A microporous chitosan/collagen composite encapsulated small tube of nanoporous anodic aluminum oxide for long-acting drug release, 2015 ASME International Mechanical Engineering Congress and Exposition, Houston, TX, USA. (2015). The Best Paper Award-MEMS Division.
5
Hsu, C. W., Li, C. W. and Wang, G. J.*, Fabrication of biocompatible high aspect ratio Au–Ni coaxial nanorod arrays using the electroless Galvanic displacement reaction method, RSC advances, 4, 12127-12132. (2014) (IF =3.049)
 

Recent Research Project (3 years)
Project title
Execution
duration
Sponsors
Total amount US $
Development of a non-enzymatic glucose, hematocrit, and glycated hemoglobin integrated detection platform
2020. 08-2022. 07
Ministry of Science and Technology (MOST), Taiwan
70,000
The influence of mitochondria transplantation on cell proliferation, differentiation as well as its application in facilitating wound healing
2019.08-2020.07
Ministry of Science and Technology (MOST), Taiwan
30,000
Detection of potassium, sodium and chloride ions using a bosensor with micro/nano hybrid structured electrode
2019.01-2019.12
ProtectLife
60,000
Development and detection applications of surface-enhanced Raman hand-held spectroscopy
2018.11-2020.10
Ministry of Science and Technology (MOST), Taiwan
100,000
Smart innovation, high value medical materials, research and production chain personal training program
2018.3-2019.1
Ministry of Education (MOE), Taiwan
71,000
Design, fabrication and study of the new hybrid integrated sensors based on nanoelectronic, acoustoelectronic, and electrochemical technologies for biological applications- Russia-Taiwan SCIENTIFIC RESEARCH COOPERATION
2018.1-2020.12
Ministry of Science and Technology (MOST), Taiwan
234,000
Personal Training Center of Smart Machinery
2017.9-2019.1
Ministry of Education (MOE), Taiwan
580,000
Green extraction and long-term storage of healthy mitochondria
2016.8-2019.7
Ministry of Science and Technology (MOST), Taiwan
98,000
Investigation of the influences of micro/ nanopatterning on gel surface on cancer cell interactions- Israel-Taiwan SCIENTIFIC RESEARCH COOPERATION
2015.9-2017.8
Ministry of Science and Technology (MOST), Taiwan
70,000
Development of photonic crystal structural color based anti-counterfeiting label fabrication techniques
2015.8-2018.7
Ministry of Science and Technology (MOST), Taiwan
88,000
Study of glycan-lectin interaction by developing a highly sensitive nanostructured biosensor
2014.10-2017.9
Ministry of Science and Technology (MOST), Taiwan
80,000
Development of microvessel network organ-on-chip
2014.8-2016.7
Ministry of Science and Technology (MOST), Taiwan
60,400
 
Publication Lists
(A) Journal papers

2020

  1. Liu, Z. J., Lin, S. C., Lee, P. Y., Lin, Y. T., Lai, Z. L., Chang, C. C.**, and Wang, G. J.*, Dual-acting antibacterial porous chitosan film embedded with a photosensitizer, Science and Technology of Advanced Materials, 21(1), 562-572, 2020. (IF=5.799)
  2. Chu, T. F., Rajendran, R., Kuznetsova, I., and Wang, G. J.*, High-power, non-enzymatic glucose biofuel cell based on a nano/micro hybrid-structured Au anode, Journal of Power Sources, 453, 227844, 2020. (IF=8.247)
  3. Alvarez-Elizondo, M. B., Li, C. W., Marom, A., Tung, Y. T., Drillich, G., Horesh, Y., Lin, S. C., Wang, G. J.*, Weihs, D.*, Micropatterned topographies reveal measurable differences between cancer and benign cells, Medical Engineering & Physics, 75, 5-12, 2020. (IF=1.37)
  4. Wang, W. J., Lee, C. H., Li, C. W., Liao, S., Jan, F. J.**, and Wang, G. J.*, Orchid virus detection from orchid leaves using micro/nano hybrid-structured immuno-electrochemical biosensor, J. Electrochemical Society, 167, 027530, 2020, (IF=2.552)

2019

  1. Lin, Y. T., Chen, S. T., Chang, J. C., Toeh, R. J., Liu, C. S.**, Wang, G. J.*, Green extraction of healthy and chemical free mitochondria with a conventional centrifuge, Lab on a Chip, 19, 3862-3869, 2019. (IF=6.774)
  2. Su, C. H., Chen, J. W., Chen, L. D., Chang, J. C., Liu, C. S., Chang, C. C.*, and Wang, G. J.*, Organic Small Molecule for Detection and Photodegradation of Mitochondrial DNA Mutations, Journal of Materials Chemistry B, 39 (7), 5947-5955, 2019. (IF=5.344)
  3. Tung, Y. T., Liang, J. J., Feng, H. T., Jhang, R. N., Hsieh, S. L., Lin, Y. L.*, Wang, G. J.*, Investigation of the extremely weak interaction between the Japanese Encephalitis virus and CLEC5A using a multivalent-interaction-enhancement sensing electrode, Biosensors and Bioelectronics: x, 100024, 2019. (IF=10.257)
  4. Plekhanova, V., Tikhonenko, S. A., Dubrovsky, A., Kim, A., Musin, E., Wang, G. J.*, Kuznetsova, I., Kolesov, V., Reshetilov, A., Comparative study of the electrochemical sensors based on enzyme immobilized into polyelectrolyte microcapsules and into chitozan gel, Analytical Science, 35 (9), 1037-1043, 2019. (IF=2.049)
  5. Lin, Y. C., Liao, S., Huang, T., and Wang, G. J.*, A novel biosensor electrode with self-assembled monolayer of gold nanoparticle on a micro hemisphere array, J. Electrochemical Society, 166 (6) B349-B354, 2019, (IF=2.552)
  6. Reshetilov, A., Plekhanova, Y., Tarasov, S., Tikhonenko, S., Dubrovsky, A., Kim, A., Kashin, V., Machulin, A., Wang, G. J.*, Kolesov, V., Kuznetsova, I., Bioelectrochemical properties of enzyme-containing multilayered polyelectrolyte microcapsules modified with multiwalled carbon nanotubes, Membranes, 9 (4), 53, 2019. (SCIE)

2018

  1. Hsiao, Y. H., Li, C. H., Chang, J. C, Liu, C. S.*, Wang, G. J.*, Chemical-free extraction of functional mitochondria using a microfluidic device, Inventions, 3, 68 (11 pages), 2018.
  2. Jian, Y. S., Lee, C. H., Jan, F. J**, and Wang, G. J.*, Detection of odontoglossum ringspot virus infected phalaenopsis using a nano-structured biosensor, J. Electrochemical Society, 165 (9) H449-H454, 2018, (IF=2.552)
  3. Wu, C. T. and Wang, G. J.*, Design and manufacture of high-filling-efficiency microfluidic devices, International Journal of Advanced Manufacturing Technology, 97, 5–8, pp 1711–1717, 2018. (IF=2.633)
  4. Peng, C. Y., Hsu, C. W., Li, C. W., Wang, P. L., Jeng, C. C., Chang, C. C.**, Wang, G. J.*, A flexible photonic crystal material for multiple anti-counterfeiting applications, ACS Applied Materials & Interfaces, 10 (11), 9858–9864, 2018. (IF=8.758)
  5. Tseng, Y. T., Li, C. W., and Wang, G. J.*, Template-assisted fabrication of tunable aspect ratio, biocompatible iron oxide pillar arrays, Advanced Materials Letter, 9(4), 249-257, 2018.

2017

  1. Cai, S. J., Li, C. W., Weihs, D., and Wang, G. J.*, Control of cell proliferation by a porous chitosan scaffold with multiple releasing capabilities, Science and Technology of Advanced Materials, 18(1), 987-996, 2017. (IF=5.799)
  2. eh, B. Y., Jian, B. S., Wang, G. J.*, and Tseng, W. J., CuO/V2O5 hybrid nanowires for highly sensitive and selective H2S gas sensor, RSC Adv., 7, 49605, 2017. (IF=3.049)
  3. Peng, C. Y., Hsu, C. W., Li, C. W., Wang, G. J.*, Using anodic aluminum oxide film and nanoimprint to produce polymer anti-counterfeit labels, Smart Science, 5(3), 117-122, 2017.
  4. Shen, M. C., Lai, J. C., Hong, C. Y., and Wang, G. J.*, Electrochemical aptasensor for detecting Der p2 allergen using polycarbonate-based double-generation gold nanoparticle chip, Sensing and Bio-Sensing Research, 13, 75-80, 2017.
  5. Tung, Y. T., Chang, C. C., Ju, J. C.*, and Wang, G. J.*, Fabrication of a reticular poly(lactide-co-glycolide) cylindrical scaffold for the in vitro development of microvascular networks, Science and Technology of Advanced Materials, 18(1), 163-171, 2017. (IF=3.585)
  6. Peng, S. W., Li, C. W., Chiu, I. M., and Wang, G. J.*, Nerve guidance conduit with a hybrid structure of a PLGA microfibrous bundle wrapped in a micro/nanostructured membrane, Inter. J. Nanomedicine, 12, 421-432, 2017. (IF=4.471)

2016

  1. Li, C. W., Pan, W. T., Ju, J. C., Wang, G. J.*, An endothelial cell conditioned medium embedded in porous PLGA scaffold for the enhancement of mouse embryonic stem cell differentiation, Biomedical Materials, 11, 025015, 2016. (IF=3.174)
  2. Ciudad, P, Dower, R , Nicoli, F , Orfaniotis, G, Maruccia, M , Constantinescu, T , Lin, S. P., Wang, G. J.*, Chen, H. C., Pelvic-perineal reconstruction with the combined transverse upper gracilis and profunda artery perforator (TUG-PAP) flap, Journal of Plastic Reconstructive and Aesthetic Surgery, 69(4), 573-575, 2016. (IF=2.39)
  3. Hsu, C. W., Su, F. C., Peng, P. Y., Young, H. T., Liao, S., and Wang, G. J.*, Highly sensitive non-enzymatic electrochemical glucose biosensor using a photolithography fabricated micro/nano hybrid structured electrode, Sensors and Actuators B, 230, 559-565, 2016. (IF=7.1)
  4. Lin, Y. T., Li, C. W., and Wang, G. J.*, The nano/micro hybrid structures enhancing B35 cell guidance on chitosan, ASME Journal of Nanotechnology in Engineering and Medicine, 6, 030702, 2016.
  5. Chang, C. Y., Sasaki, M., Kumagai, S., and Wang, G. J.*, Design of microplasma electrodes for plasma-on-chip devices, Journal of Physics D, Applied Physics, 49, 155203, 2016. (IF=2.829)
  6. Chen, C. C., Lai, Z. L., Wang, G. J.*, and Wu, C. Y.**, Polymerase chain reaction-free detection of hepatitis B virus DNA using a nanostructured impedance biosensor, Biosensors & Bioelectronics, 77, 603-608, 2016. (IF=10.257)
  7. Tung, Y. T., Chang, C. C.*, Y. L. Lin, Hsieh, S. L., and Wang, G. J.*, Development of double-generation gold nanoparticle chip-based dengue virus detection system combining fluorescence turn-on probes, Biosensors & Bioelectronics, 77, 90-98, 2016. (IF=10.257)

Before 2016

  1. Lee, B. Y., Li, C. W. and Wang, G. J.*, Nanoporous anodic aluminum oxide tube encapsulating a microporous chitosan/collagen composite for long-acting drug release, Biomedical Physics & Engineering Express, 1, 045004, 2015.
  2. Hsu, C. W., Feng, W. C., Su, F. C., and Wang, G. J.*, A novel electrochemical glucose biosensor with a silicon nanowire array electrode, J. Electrochemical Society, 162(10), B1-B5, 2015. (IF=3.12)
  3. Hsieh, Y. D., Lee, M. Y., and Wang, G. J.*, Sb2S3 quantum-dot sensitized solar cells with silicon nanowire photoelectrode, Inter. J. of Photoenergy, Vol. 2015, Article ID 213858, 2015. (IF=2.026)
  4. Liao, E. C, Chang, C. Y., Wu, C. C., Wang, G. J.*, Tsai, J. W., Association of single nucleotide polymorphisms in the MD-2 gene promoter region with Der p 2 allergy, Allergy Asthma Immunol Res. 7(3), 249-255, 2015. (IF=5.026)
  5. Liu, H. C. and Wang, G. J.*, Superior antireflection coating for a silicon cell with a micro-nano hybrid structure, Inter. J. of Photoenergy, Vol. 2014, 807812, 2014. (IF=2.026)
  6. Tung, Y. T., Wu, M. F., Wang, G. J.*, and Hsieh, S. L**, Nanostructured electrochemical biosensor for the detection of the weak binding between the Dengue Virus and the CLEC5A receptor, Nanomedicine: NBM, 10, 1335-1341, 2014. (IF=5.57)
  7. Hsu, C. W., Li, C. W. and Wang, G. J.*, Fabrication of biocompatible high aspect ratio Au–Ni coaxial nanorod arrays using the electroless Galvanic displacement reaction method, RSC advances, 4, 12127-12132, 2014. (IF=3.049)
  8. Hsu, C. W. and Wang, G. J.*, Highly sensitive glucose biosensor based on Au–Ni coaxial nanorod array having high aspect ratio, Biosensors & Bioelectronics, 56, 204-209, 2014. (IF=9.518)
  9. Wu, J. Y., Li,C. W., Tsai, C. H., Chou, C. W., Chen, D. R., and Wang, G. J.*, Synthesis of antibacterial TiO2/PLGA composite biofilms, Nanomedicine: NBM, 10, 1097-1107, 2014. (IF=5.57)
  10. Chin, Y. T., Liao, E. C., Wu, C. C., Wang, G. J.*, and Tsai, J. J.*, Detection of the haplotype mutations of the MD-2 gene promoter associated with Der p2-induced allergy using a nanostructured biosensor, Inter. J. Nanomedicine, 9, 403-412, 2014. (IF=4.471)
  11. 3Wu, C. C.*, Ku, B. C., Ko, C. H., Chiu, C. C., Wang, G. J.*, Yang, Y. H., Wu, S. J., Electrochemical impedance spectroscopy analysis of A-beta (1-42) peptide using a nanostructured biochip, Electrochimica Acta, 134, 249-257, 2014. (IF=5.383)
  12. Liu, H. C. and Wang, G. J.*, Fabrication of high anti-reflection nanowires on silicon using two-stage metal-assisted etching, Journal of Renewable and Sustainable Energy, 5, 053115. (2013)
  13. Li, C. W. and Wang, G. J.*, A material-independent cell–environment niche based on micro-reciprocating motion for cell growth enhancement, Biofabrication, 5, 045001. (2013).
  14. Chung, I. C., Li, C. W., and Wang, G. J.*, The influence of different nanostructured scaffolds on fibroblast growth, Science and Technology of Advanced Materials, 14, 044401. (2013).
  15. Chin, Y. T., Liao, E. C., Wu, C. C., Wang, G. J.*, and Tsai, J. J.*, Label-free detection of single-nucleotide polymorphisms associated with myeloid differentiation-2 using a nanostructured biosensor, Biosensors & Bioelectronics, 49, 506-511. (2013).
  16. Wang, H. W., Cheng, C. W., Li, C. W., Wu, P. H., and Wang, G. J.*, Hollow three-dimensional endothelialized microvessel networks based on femtosecond laser ablation, Biomedical Microdevices, 15, 879-885. (2013).
  17. Liu, H. C., Tsai, C. C. and Wang, G. J.*, Glucose biosensors based on a gold nanodendrite modified screen-printed electrode, Nanotechnology, 24, 215101. (2013).
  18. Tsai, J. J., Liu, Y. F., Liao, E. C., Chen, J. L, and Wang, G. J.*, Reduction of incubation time and enhancement of analyte adhesion uniformity of impedance biosensors using microvibration method, Sensors & Actuators B: Chemical, 178, 404-411. (2013)
  19. Chou, C. W.*, Hsieh, H. H., Chen, K. S., Hong-Ru Lin, H. R., Wang, G. J., Chang, H. C., Pan, Y. L., Wei, Y. S., Chang, K. S., and Harn, Y. W., Biopolymer coated gold nanocrystals prepared using the green chemistry approach and their shape-dependent catalytic and surface-enhanced Raman scattering properties, Physical Chemistry Chemical Physics, 15, 11275-11286. (2013).
  20. Lin, Y. W. and Wang, G. J.*, Dielectrophoresis measurement of bovine endothelial cells adhesion on different materials, Microsystem Technologies, 19, 945-955. (2013)
  21. Tsai, Y. T., Chang, K. J., and Wang, G. J.*, Measurement and control of the ion diffusion coefficient in a nanochannel, Microsystem Technologies, 19, 937-944. (2013)
  22. Tsai, C. C. and Wang, G. J.*, A glucose biosensor based on a 3D nanostructured gold electrode, J. Electrochemical Society, 160(1), B1-B5. (2013)
  23. Liu, Y. F., Tsai, J. J., Chin, Y. T., Liao, E. C., Wu, C. C., Wang, G. J.*, Detection of allergies using a silver nanoparticle modified nanostructured biosensor, Sensors & Actuators B: Chemical, 171-172, 1095-1100. (2012)
  24. Wang, H. W., Cheng, C. W., Li, C. W., Chang, H. W., Wu, P. H., Wang, G. J.*, Fabrication of pillared PLGA microvessel scaffold using femtosecond laser ablation, Inter. J. Nanomedicine, 7, 1865-1873. (2012)
  25. Chen, Y. S., Wu, C. C., Tsai, J. J., and Wang, G. J.*, An electrochemical impedimetric biosensor based on a nanostructured polycarbonate (PC) substrate, Inter. J. Nanomedicine, 7, 133-140 (2012)
  26. Ho, J. Y. and Wang, G. J.*, Fabrication of high aspect ratio nanoporous array on silicon, Microsystem Technologies, 18, 1849-1856. (2012)
  27. Tsai, J. J., Bau, I. J., Chen, H. T., Lin, Y. T., and Wang, G. J.*, A novel nanostructured biosensor for the detection of the dust mite antigen Der p2, Inter. J. Nanomedicine, 6, 1201-1208. (2011)
  28. Chang, C. Y. and Wang, G. J.*, Anodic Aluminum Oxide Diodes, Japanese Journal of Applied Physics, 50(7), 075201 (4 pages) (2011) (SCI, Impact Factor=1.122)
  29. Tubtimtae, A., Lee, M. W.*, and Wang, G. J., Ag2Se quantum-dot sensitized solar cells for full solar spectrum light harvesting, Journal of Power Sources, 196, 6603-6608. (2011)
  30. Lin, Y. H., Chang, K. J., and Wang, G. J.*, A Novel Chip-on-Glass method for Slim LCD Packaging, Microsystem Technologies, 17, 685-691. (2011)
  31. Wang, G. J.*, Lee, M. W., Chen, W. Z., Chen, Y. H., Chien, M. C., Yu, M. C., A Metal-Solution Field-Effect-Transistor Enhanced Proton-Motive-Force Driving Photovoltaic, IEEE Trans. on Nanotechnology, 10, 191-196. Cover page (2011)
  32. Wang, C. G. and Wang, G. J.*, A MOSFET-like infrared sensor for the enhancement of photoconductivity and photoresponsivity, Current Nanoscience, 6(6), 648-653. (2010)
  33. Wang, G. J.*, Lin, Y. C., and Hsu, S. h., The Fabrication of PLGA Microvessel Scaffolds with Nano-Patterned Inner Walls, Biomedical Microdevices, 12, 841-848. (2010). Wang, G. J.* and Chou, S. W., Electrophoretic deposition of uniformly distributed TiO2 nanoparticles using an anodic aluminum oxide template for efficient photolysis, Nanotechnology, 21, 115206, (2010)
  34. Hsu, C. W., Chou, Z. D., and Wang, G. J.*, Fabrication of High Aspect Ratio Alumina-Nickel Coaxial Nanorod Array by Electrodeposition, ASME/IEEE J. of Microelectromechnaical System, 19(4), 849-853 (2010)..
  35. Chen, Y. C., Chen, G. Y., Lin, Y. C., and Wang, G. J.*, A Lab-on-a-Chip Capillary Network for Red Blood Cell Hydrodynamics, Microfluidics and Nnaofluidics, 9, 585-591. (2010).
  36. Chen, G. Y., Lee, M. W., and Wang, G. J.*, Fabrication of Dye- Sensitized Solar Cells with A 3D Nanostructured Electrode, Inter. J. of Photoenergy, 2010, Article ID 585621, 7 pages, DOI:10.1155/2010/585621, (2010)
  37. Lai, M. H., Tubtimtae, A., Lee, M. W.*, Wang, G. J., ZnO-Nanorod Dye-Sensitized Solar Cells: New Structure without a Transparent Conducting Oxide Layer, Inter. J. of Photoenergy, 2010, Article ID 497095, 5 pages, , (2010)
  38. Tubtimtae, A., Wu, K. L., Tung, H. Y., Lee, M. W.*, Wang, G. J., Ag2S quantum dot-sensitized solar cells, Electrochemistry Communications, 12, 1158-1160 (2010)
  39. Wang, G. J.*, Lin, Y. C., Lee, J. W,, Hsueh, C. C., Hsu, S. h, Hung, H. S., Fabrication of Orderly Nanostructured PLGA Scaffolds Using Anodic Aluminum Oxide Templates, Biomedical Microdevices, 11, 843-850. (2009)
  40. Chen, H. T. and Wang, G. J.*, Fabrication of 3D Nano-structured ITO Films by RF Magnetron Sputtering, Current Nanoscience, 5(3), 297-301. (2009)
  41. Wang, G. J.*, Lee, M. W., Chen, Y. H., A TiO2/CNT coaxial structure and standing CNT array laminated photocatalyst to enhance the photolysis efficiency of TiO2, Photochemistry and Photobiology, 84, 1493-1499. (2008)
  42. Chien, M. C., Wang, G. J.*, Yu. M. C., Nanopore Size Estimation Using Electrochemical ImpedanceSpectroscopy Analysis, Japanese Journal of Applied Physics, 47(9), 7459-7463. (2008)
  43. Wang, G. J.*, Chen, H. T., Yang, H., Fabrication of crystalline indium tin oxide nanobaskets electrode using AAO template, Japanese Journal of Applied Physics, 47(7), 5727-5729. (2008)
  44. Wang, G. J.*, Ho, K. H., Hsueh, C. C., Biodegradable polylactic acid (PLA) microstructures for scaffold applications, Microsystem Technologies, 14, 989-993. (2008)
  45. Wang, G. J.*, Chen, W. Z., Chang, K., A two-step etching method to fabricate nanopores in silicon, Microsystem Technologies, 14, 925-927. (2008)
  46. Wang, G. J.*, Hsueh, C. C., Hsu, S. H., Hung, H. S., “Fabrication of PLGA Microvessel Scaffolds with Circular Microchannels Using Soft Lithography,” Journal of Micromechanics and Microengineering, Vol. 17, pp. 2000-2005. (2007)
  47. Chien, M. C., Wang, G. J.*, Yu. W. C., “Modeling Ion Diffusion Current in a Nanochannel Using Infinitesimal Distribution RC Circuits,” Japanese Journal of Applied Physics, Vol. 46, No. 11, pp. 7436-7440. (2007)
  48. Wang, G. J.*, Ho, K. H., Hsu, S. H., Wang, K. P., “Microvessel Scaffold with Circular Microchannels by Photoresist Melting,” Biomedical Microdevices, Vol. 9, pp. 657-663. (2007)
  49. Wang, G. J.*, Lin, Y. C., Lin, G. S., “Ultra Fine Pitch Flat Panel Display Packaging Using 3mm Conductive Particles,” Microsystem Technologies, Vol. 13, No. 11-12. pp. 1471-1476. (2007)
  50. Fan, J. Y., Chien, M. C, Wang, G. J.*, “Experimental Investigation on the Bi-directional Growing Mechanism of the Foils Laminate Approach in AAO Fabrication,” Nanoscale Research Letters, Vol. 2, No. 1, pp. 49-53. (2007)
  51. Wang, G. J.*, Lin, Y. C., Lin, G. S., “A Novel Contact Resistance Model of Anisotropic Conductive Film for FPD Packaging,” Microsystem Technologies, Vol. 13, No. 11-12. pp. 1477-1482. (2007)
  52. Wang, G. J.*, Lin, B. S. and Chang, K., “In-Situ Neural Network Process Controller for Copper Chemical Mechanical Polishing,” International Journal of Advanced Manufacturing Technology, Vol. 32, pp. 42-54. (2007)
  53. Wang, G. J.*, Chang, J. H., and Yang H., “Triplex-Pumping CD-Like Microfluidic Platform with Parabolic Microchannels,” Microsystem Technologies, Vol. 12, No. 10-11. pp. 899-905. (2006)
  54. Yu, W. C. and Wang, G. J.*, “Discrete Sliding Mode Controller Design Based on the LQR Suboptimal Approach with Application on AC Servo Motor,” Journal of Chinese Institute of Engineers, Vol. 29, No 5, pp. 873-882. (2006)
  55. Wang, G. J.* and Hsu, W. H., “PET Laminated Thin-Film Capillary Electrophoresis Chips by Sandwiching Method,” International Journal of Advanced Manufacturing Technology, Vol. 30, No 1-2, pp. 87-91. (2006)
  56. Chen, S. N., Wang, G. J.* and M. C. Chien, “Analytical modeling of piezoelectric vibration-induced micro power generator, “Mechatronics, Vol. 16, pp 379-387. (2006)
  57. Wang, G. J.*, Yu, W. C., Lin, Y. H., Yang, H., “Modeling and Fabrication of a Piezoelectric Vibration-Induced Micro Power Generator,” Journal of Chinese Institute of Engineers, Vol. 29, No. 4. pp. 697-706. (2006)
  58. Wang, G. J.* and Liu, H. R., “Piezoelectric Actuated Multiple Channels Optical Switch,” Analog integrated circuits and signal processing, Vol. 48, No. 1, pp15-20. (2006)
  59. Wang, G. J.* and Peng, C. S., “Control Porous Pattern of Anodic Aluminum Oxide by Foils Laminate Approach,” Journal of Nanoscience and Nanotechnology, Vol. 6, No. 4, pp 1004-1008. (2006)
  60. Wang, G. J.* and Yu, C. H., “Developing a Neural Network Based Run-To-Run Process Controller For Chemical Mechanical Planarization,” International Journal of Advanced Manufacturing Technology, Vol. 28, No. 9, pp 899-908. (2006)
  61. Wang, G. J.* and Hsu, Y. F., “Structure Optimization of Microvascular Scaffolds” Biomedical Microdevices, Vol. 8, No. 1, pp 51-58. (2006)
  62. Wang, G. J.*, Hsu, Y. F., Hsu, S. H., Horng, R. H. “JSR Photolithography Based Microvascular Fabrication and Cell Seeding” Biomedical Microdevices, Vol. 8, No. 1, pp 17-23. (2006)
  63. Chang, Y. Z., Yang, M. W., Wang, G. J.*, “A New Mass Spectrometry Electro-Spray Tip Based on Precise Mechanical Micro Machining,” Analytical and Bioanalytical Chemistry, Vol. 383, No. 1, pp. 76-82. (2005)
  64. Wang, G. J.*, Chen, C. L., Hsu, S. H., and Chiang, Y. L., “Bio-MEMS Fabricated Artificial Vascular Network for Tissue Engineering,” Microsystem Technologies, Vol. 12, No. 1-2, pp. 120-127. (2005)
  65. Wang, G. J.* and Chou, M. H., “A Neural-Taguchi Based Quasi Time-Optimal Control Strategy For Chemical Mechanical Polishing Processes,” International Journal of Advanced Manufacturing Technology, Vol. 26, No. 7-8, pp. 759-765. (2005)
  66. Wang, G. J.*, Lee, C. K., Hsu, C. C.,” Toward a Comprehensively Interdisciplinary Nanoscience and Nanotechnology Personnel Training Program In Taiwan,” INNOVATIONS 2005-World Innovations in Engineering Education and Research, Chapter IV. (2005)
  67. Wang, G. J.*, Cheng, Y. D, Chang, K.,” A New Neural Fuzzy Control System with Heuristic Learning,” International Journal of Fuzzy Systems, Vol. 7, No. 4, pp. 158-168. (2005)
  68. Wang, G. J.*, Yang, M. W., Chang, Y. Z. “Dead Volume Free Micro-machined Electro-spray Chip for Mass Spectrometry,” Biomedical Microdevices, Vol. 6, No. 2. pp. 159-164 (2004)
  69. Yu, W. C. and Wang, G. J.*, “Discrete Sliding Mode Control with Forgetting Dynamic Sliding Surface,“ Mechatronics, Vol. 14, pp. 737-755. (2004)
  70. Wang, G. J.*, Hsu, W. H., Chang, Y. Z., Yang, H. H. “Centrifugal and Electric Field Forces Dual-Pumping CD-Like Microfluidic Platform for Biomedical Separation,” Biomedical Microdevices, Vol. 6, No. 1, pp. 47-53. (2004)
  71. Wang, G. J.*, and Song, S. W., Yu, W. C., “A New Discrete Dynamic Sliding Mode Controller for Singular Perturbed Servo Systems,” Journal of Chinese Society of Mechanical Engineers, Vol. 25, No. 1, pp 41-50. (2004)
  72. Wang, G. J.* and Chou, M. H., Chang K., “New Orthogonalization And Conjugate Descendent Based Parameter Setting-Free Methods For The Backpropagation Algorithm,” Journal of Chinese Society of Mechanical Engineers, Vol. 24, No 5, pp. 499-505. (2003)
  73. Wang, G. J.*, Wang, S. Y., and Chin, C. H., “Fabrication and Modeling of the Gray-scale Mask Based Aspheric Refraction Microlens Array,” JSME International Journal, Series C, Vol. 46, No. 4, pp. 1958-1603 (2003)
  74. Yu, W. C. and Wang, G. J.*, “Discrete-Type Heuristic Self-Tuning PID Controller,“ Journal of Chinese Society of Mechanical Engineers, Vol. 24, No 2, pp. 181-186. (2003)
  75. Wang, G. J.*, Wu, J. G., Chang K., “A New Neural Network Based Parameter Optimization Method,” Journal of Chinese Society of Mechanical Engineers, Vol. 24, No 2, pp. 99-109. (2003)
  76. Wang, G. J.*, Fong, T. T., and K. J. Chang, “Neural Network-Based Self-Tuning PI Controller for Precise Motion Control of PMAC Motors,” IEEE Transaction on Industrial Electronics, Vol. 48, No. 2, pp 408-416. (2001)
  77. Wang, G. J.*, Chen, J. L., and Hwang, J. Y., “New Optimization Strategy for Chemical Mechanical Polishing Process,” JSME International Journal, Series C, Vol. 44, No. 2, pp. 534-543. (2001)
  78. Wang, G. J.*, and Chen, J. J., “Cascade Steepest Descendant Learning Algorithm for Multilayer Feedforward Neural Network,” JSME International Journal, Series C, Vol.43, No. 2, pp 350-358. (2000)
  79. Wang, G. J.*, and Cheng, T. C., “A Robust Self-Tuning Learning Algorithm for Multilayer Feedforward Neural Network,” Neurocomputing, Vol. 25, pp167-189.  (1999)
  80. Wang, G. J.*, and Wang, C. C., "Reverse Engineering of Sculptured Surface by Four-Axis Non-Contacting Scanning," International Journal of Advanced Manufacturing Technology, Vol. 15, No. 5. (1999)
  81. Wang, G. J.*, Luh, C. F., and Wang, C. C., "Intelligent 3D CAD Data Extracting System," JSME International Journal, Series C, Vol.41, No. 4, pp. 912-921. (1998)
  82. Wang, G. J.*, and Yang, Y. Z., Chang, K., "A MDRS Network Based Intelligent Vision System," the International Journal of Knowledge-Based Intelligent Engineering Systems, Vol. 2, NO 1, pp. 17-31. (1998)
  83. Wang, G. J.*, Tsai, J. C., Tzeng, P. C., and Cheng, T. C., "Neural-Taguchi Method for Robust Design Analysis," Journal of the Chinese Society of Mechanical Engineers Vol. 19, NO 2. pp. 223-230. (1998)
  84. Wang, G. J.*, and Cheng, C. C., "A Fast Multilayer Neural Network Training Algorithm Based on the Layer-By-Layer Optimizing Procedures," IEEE Tran. on Neural Network, Vol. 7, No. 3, pp. 768-775  (1996)

(B)   Book Chapter

(C) Conference proceedings