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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 陳林祈 | |
dc.contributor.author | Chien-Wen Yao | en |
dc.contributor.author | 姚傑文 | zh_TW |
dc.date.accessioned | 2021-06-07T23:49:53Z | - |
dc.date.copyright | 2014-02-26 | |
dc.date.issued | 2014 | |
dc.date.submitted | 2014-02-10 | |
dc.identifier.citation | Andreescu, S., V. Magearu, et al. (2001). 'Immobilization of enzymes on screen-printed sensors via an histidine tail. Application to the detection of pesticides using modified cholinesterase.' Analytical Letters 34(4): 529-540.
Bakker, E., P. Buhlmann, et al. (1997). 'Carrier-Based Ion-Selective Electrodes and Bulk Optodes. 1. General Characteristics.' Chemical reviews 97(8): 3083. Bakker, E., M. Nagele, et al. (1995). 'Applicability of the phase boundary potential model to the mechanistic understanding of solvent polymeric membrane‐based ion‐selective electrodes.' Electroanalysis 7(9): 817-822. Bobacka, J. (1999). 'Potential stability of all-solid-state ion-selective electrodes using conducting polymers as ion-to-electron transducers.' Analytical chemistry 71(21): 4932-4937. Bobacka, J. (2006). 'Conducting Polymer‐Based Solid‐State Ion‐Selective Electrodes.' Electroanalysis 18(1): 7-18. Bobacka, J., A. Ivaska, et al. (1999). 'Plasticizer-free all-solid-state potassium-selective electrode based on poly (3-octylthiophene) and valinomycin.' Analytica chimica acta 385(1): 195-202. Bobacka, J., A. Ivaska, et al. (2008). 'Potentiometric ion sensors.' Chemical reviews 108(2): 329. Bobacka, J., A. Lewenstam, et al. (2000). 'Electrochemical impedance spectroscopy of oxidized poly (3, 4-ethylenedioxythiophene) film electrodes in aqueous solutions.' Journal of Electroanalytical Chemistry 489(1): 17-27. Brun, R., B. Paris, et al. (1993). 'Fertigation management of rose plants grown in greenhouse on rockwool.' Advances in Horticultural Science: 145-145. Buhlmann, P., E. Pretsch, et al. (1998). 'Carrier-based ion-selective electrodes and bulk optodes. 2. Ionophores for potentiometric and optical sensors.' Chemical Reviews 98(4): 1593-1687. Cadogan, A., Z. Gao, et al. (1992). 'All-solid-state sodium-selective electrode based on a calixarene ionophore in a poly (vinyl chloride) membrane with a polypyrrole solid contact.' Analytical Chemistry 64(21): 2496-2501. Chou, N. H., J. C. Chou, et al. (2008). 'Differential type solid-state urea biosensors based on ion-selective electrodes.' Sensors and Actuators B-Chemical 130(1): 359-366. Crespo, G. A., S. Macho, et al. (2008). 'Ion-selective electrodes using carbon nanotubes as ion-to-electron transducers.' Analytical chemistry 80(4): 1316-1322. Davies, O. G., G. Moody, et al. (1988). 'Optimisation of poly (vinyl chloride) matrix membrane ion-selective electrodes for ammonium ions.' Analyst 113(3): 497-500. Dimeski, G., T. Badrick, et al. (2010). 'Ion Selective Electrodes (ISEs) and interferences--a review.' Clin Chim Acta 411(5-6): 309-317. Dondoi, M. P., B. Bucur, et al. (2006). 'Organophosphorus insecticides extraction and heterogeneous oxidation on column for analysis with an acetylcholinesterase (AChE) biosensor.' Analytica chimica acta 578(2): 162-169. Fahnrich, K., M. Pravda, et al. (2003). 'Disposable amperometric immunosensor for the detection of polycyclic aromatic hydrocarbons (PAHs) using screen-printed electrodes.' Biosensors and Bioelectronics 18(1): 73-82. Fibbioli, M., W. E. Morf, et al. (2000). 'Potential Drifts of Solid‐Contacted Ion‐Selective Electrodes Due to Zero‐Current Ion Fluxes Through the Sensor Membrane.' Electroanalysis 12(16): 1286-1292. Gieling, T. H., G. Van Straten, et al. (2005). 'ISE and Chemfet sensors in greenhouse cultivation.' Sensors and Actuators B: Chemical 105(1): 74-80. Gilmartin, M. A. and J. P. Hart (1995). 'Sensing with chemically and biologically modified carbon electrodes. A review.' Analyst 120(4): 1029-1045. Gilmartin, M. A. T., J. P. Hart, et al. (1994). 'Development of Amperometric Sensors for Uric-Acid Based on Chemically-Modified Graphite-Epoxy Resin and Screen-Printed Electrodes Containing Cobalt Phthalocyanine.' Analyst 119(2): 243-252. Gupta, V. K., S. Chandra, et al. (2002). 'Magnesium-selective electrodes.' Sensors and Actuators B-Chemical 86(2-3): 235-241. Gupta, V. K., S. Chandra, et al. (2002). 'Magnesium-selective electrodes.' Sensors and Actuators B: Chemical 86(2): 235-241. Gutierrez, M., S. Alegret, et al. (2007). 'Application of a potentiometric electronic tongue to fertigation strategy in greenhouse cultivation.' Computers and Electronics in Agriculture 57(1): 12-22. Gutierrez, M., S. Alegret, et al. (2008). 'Nutrient solution monitoring in greenhouse cultivation employing a potentiometric electronic tongue.' Journal of agricultural and food chemistry 56(6): 1810-1817. Hart, J., R. Pemberton, et al. (1997). 'Studies towards a disposable screen-printed amperometric biosensor for progesterone.' Biosensors and Bioelectronics 12(11): 1113-1121. Hart, J. P. and I. C. Hartley (1994). 'Voltammetric and Amperometric Studies of Thiocholine at a Screen-Printed Carbon Electrode Chemically-Modified with Cobalt Phthalocyanine - Studies Towards a Pesticide Sensor.' Analyst 119(2): 259-263. Hauser, P. C., D. W. Chiang, et al. (1995). 'A potassium-ion selective electrode with valinomycin based poly (vinyl chloride) membrane and a poly (vinyl ferrocene) solid contact.' Analytica chimica acta 302(2): 241-248. Heim, S., I. Schnieder, et al. (1999). 'Development of an automated microbial sensor system.' Biosensors & Bioelectronics 14(2): 187-193. Henderson, L. J. (1921). 'Blood as a physicochemical system.' Journal of Biological Chemistry 46(2): 411-419. Hiraoka, M. (1992). Crown ethers and analogous compounds. Amsterdam ; New York, Elsevier. Honeychurch, K. C., J. P. Hart, et al. (2003). 'Development of an electrochemical assay for 2,6-dinitrotoluene, based on a screen-printed carbon electrode, and its potential application in bioanalysis, occupational and public health.' Biosens Bioelectron 19(4): 305-312. James, H. J., G. Carmack, et al. (1972). 'Coated wire ion-selective electrodes.' Anal Chem 44(4): 856-857. Joshi, K. A., M. Prouza, et al. (2006). 'V-type nerve agent detection using a carbon nanotube-based amperometric enzyme electrode.' Analytical chemistry 78(1): 331-336. Kotte, H., B. Gruendig, et al. (1995). 'Methylphenazonium-modified enzyme sensor based on polymer thick films for subnanomolar detection of phenols.' Analytical chemistry 67(1): 65-70. Kreuzer, M. P., M. Pravda, et al. (2002). 'Novel electrochemical immunosensors for seafood toxin analysis.' Toxicon 40(9): 1267-1274. Lanyon, Y. H., I. E. Tothill, et al. (2006). 'An amperometric bacterial biosensor based on gold screen-printed electrodes for the detection of benzene.' Analytical Letters 39(8): 1669-1681. Lanyon, Y. H., I. E. Tothill, et al. (2006). 'An Amperometric Bacterial Biosensor Based on Gold Screen‐Printed Electrodes for the Detection of Benzene.' Analytical Letters 39(8): 1669-1681. Levin, O., V. Kondratieva, et al. (2005). 'Charge transfer processes at poly-o-phenylenediamine and poly-o-aminophenol films.' Electrochimica Acta 50(7-8): 1573-1585. Lindner, E. and R. E. Gyurcsanyi (2009). 'Quality control criteria for solid-contact, solvent polymeric membrane ion-selective electrodes.' Journal of Solid State Electrochemistry 13(1): 51-68. Marrazza, G., I. Chianella, et al. (1999). 'Disposable DNA electrochemical biosensors for environmental monitoring.' Analytica Chimica Acta 387(3): 297-307. Marrazza, G., I. Chianella, et al. (1999). 'Disposable DNA electrochemical sensor for hybridization detection.' Biosens Bioelectron 14(1): 43-51. Mathison, S. and E. Bakker (1998). 'Effect of transmembrane electrolyte diffusion on the detection limit of carrier-based potentiometric ion sensors.' Analytical Chemistry 70(2): 303-309. Matthews, D. R., R. R. Holman, et al. (1987). 'Pen-sized digital 30-second blood glucose meter.' Lancet 1(8536): 778-779. Micheli, L., A. Radoi, et al. (2004). 'Disposable immunosensor for the determination of domoic acid in shellfish.' Biosens Bioelectron 20(2): 190-196. Moody, G. J., B. Saad, et al. (1987). 'Glass-Transition Temperatures of Polyvinyl-Chloride) and Polyacrylate Materials and Calcium Ion-Selective Electrode Properties.' Analyst 112(8): 1143-1147. Mousavi, Z., J. Bobacka, et al. (2009). 'Poly (3, 4-ethylenedioxythiophene)(PEDOT) doped with carbon nanotubes as ion-to-electron transducer in polymer membrane-based potassium ion-selective electrodes.' Journal of Electroanalytical Chemistry 633(1): 246-252. Nivens, D. E., T. E. McKnight, et al. (2004). 'Bioluminescent bioreporter integrated circuits: potentially small, rugged and inexpensive whole-cell biosensors for remote environmental monitoring.' Journal of Applied Microbiology 96(1): 33-46. Paczosa-Bator, B. (2012). 'All-solid-state selective electrodes using carbon black.' Talanta 93: 424-427. Pawłowski, P., A. Kisiel, et al. (2011). 'Potentiometric responses of ion-selective electrodes after galvanostatically controlled incorporation of primary ions.' Talanta 84(3): 814-819. Pemberton, R., J. Hart, et al. (1999). 'A comparison of 1-naphthyl phosphate and 4 aminophenyl phosphate as enzyme substrates for use with a screen-printed amperometric immunosensor for progesterone in cows’ milk.' Biosensors and Bioelectronics 14(5): 495-503. Peng, B., J. W. Zhu, et al. (2008). 'Potentiometric response of ion-selective membranes with ionic liquids as ion-exchanger and plasticizer.' Sensors and Actuators B-Chemical 133(1): 308-314. Perez-Olmos, R., A. Rios, et al. (2001). 'Construction and evaluation of ion selective electrodes for nitrate with a summing operational amplifier. Application to tobacco analysis.' Talanta 53(4): 741-748. Perez-Olmos, R., A. Rios, et al. (2001). 'Construction and evaluation of ion selective electrodes for nitrate with a summing operational amplifier. Application to tobacco analysis.' Talanta 53(4): 741-748. Pungor, E. (1992). 'Working mechanism of ion-selective electrodes.' Pure & Appl. Chem 64(4): 503-507. Rakhman’ko, E., V. Yegorov, et al. (1991). 'Sel.' Electrode Rev 13: 5. Rantala, T. S., L. Pirttiaho, et al. (1993). 'Simulation Studies of Nonohmic Conductance Behavior in Sno2 Thick-Film Gas Sensors.' Sensors and Actuators B-Chemical 16(1-3): 323-327. Rogers, K. R. (2006). 'Recent advances in biosensor techniques for environmental monitoring.' Analytica Chimica Acta 568(1-2): 222-231. Rzewuska, A., M. Wojciechowski, et al. (2008). 'Composite polyacrylate-poly (3, 4-ethylenedioxythiophene) membranes for improved all-solid-state ion-selective sensors.' Analytical chemistry 80(1): 321-327. Sapelnikova, S., E. Dock, et al. (2003). 'Screen-printed multienzyme arrays for use in amperometric batch and flow systems.' Analytical and Bioanalytical Chemistry 376(7): 1098-1103. Savvas, D. (2002). 'SW—Soil and Water: Automated Replenishment of Recycled Greenhouse Effluents with Individual Nutrients in Hydroponics by Means of Two Alternative Models.' Biosystems engineering 83(2): 225-236. Schuhmann, W., C. Lehn, et al. (1992). 'Comparison of Native and Chemically Stabilized Enzymes in Amperometric Enzyme Electrodes.' Sensors and Actuators B-Chemical 7(1-3): 393-398. Schwake, A., K. Cammann, et al. (1999). 'The influence of an anionic additive on the properties of cation-exchanger based calcium-selective electrodes.' Fresenius' journal of analytical chemistry 363(4): 369-375. Sigel, H., A. D. Zuberbuhler, et al. (1991). 'Comments on potentiometric pH titrations and the relationship between pH-meter reading and hydrogen ion concentration.' Analytica chimica acta 255(1): 63-72. Skladal, P., N. O. Morozova, et al. (2002). 'Amperometric biosensors for detection of phenol using chemically modified electrodes containing immobilized bacteria.' Biosensors & Bioelectronics 17(10): 867-873. Skladal, P., N. O. Morozova, et al. (2002). 'Amperometric biosensors for detection of phenol using chemically modified electrodes containing immobilized bacteria.' Biosensors and Bioelectronics 17(10): 867-873. Sutter, J. and E. Pretsch (2006). 'Response Behavior of Poly (vinyl chloride)‐and Polyurethane‐Based Ca2+‐Selective Membrane Electrodes with Polypyrrole‐and Poly (3‐octylthiophene)‐Mediated Internal Solid Contact.' Electroanalysis 18(1): 19-25. Sutter, J., A. Radu, et al. (2004). 'Solid-contact polymeric membrane electrodes with detection limits in the subnanomolar range.' Analytica chimica acta 523(1): 53-59. Theorell, T. (1935). 'An Attempt to Formulate a Quantitative Theory of Membrane Permeability Proc.' Soc. Exp. Biol. Med 33: 282-285. Tudorache, M. and C. Bala (2007). 'Biosensors based on screen-printing technology, and their applications in environmental and food analysis.' Analytical and Bioanalytical Chemistry 388(3): 565-578. Umadevi, P., C. L. Nagendra, et al. (1993). 'Structural, Electrical and Infrared Optical-Properties of Vanadium Pentoxide (V2o5) Thick-Film Thermistors.' Sensors and Actuators a-Physical 39(1): 59-69. Vazquez, M., J. Bobacka, et al. (2002). 'Influence of oxygen and carbon dioxide on the electrochemical stability of poly(3,4-ethylenedioxythiophene) used as ion-to-electron transducer in all-solid-state ion-selective electrodes.' Sensors and Actuators B-Chemical 82(1): 7-13. Vidal, J. C., E. Garcia-Ruiz, et al. (2003). 'Recent advances in electropolymerized conducting polymers in amperometric biosensors.' Microchimica Acta 143(2-3): 93-111. Wang, J., X. Cai, et al. (1996). 'DNA electrochemical biosensor for the detection of short DNA sequences related to the human immunodeficiency virus.' Anal Chem 68(15): 2629-2634. Wang, L. H., L. Zhang, et al. (2006). 'Enzymatic biosensors for detection of organophosphorus pesticides.' Progress in Chemistry 18(4): 440-452. Yamasaki, K., Y. Suzuki, et al. (1976). 'Studies on water culture of several vegetables with special reference to the control of nutrient solution and ratio of nutrients absorption per water consumption (= n/w).' Memoirs of the Faculty of Agriculture Tokyo University of Education. YOSHIO UMEZAWA, K. U. and H. SAT03 (1995). 'SELECTIVITY COEFFICIENTS FOR METHODS FOR REPORTING Krb VALUES.' Zhang, Y. and A. Heller (2005). 'Reduction of the nonspecific binding of a target antibody and of its enzyme-labeled detection probe enabling electrochemical immunoassay of an antibody through the 7 pg/mL-100 ng/mL (40 fM-400 pM) range.' Analytical chemistry 77(23): 7758-7762. Zhu, J., X. Li, et al. (2010). 'Single-piece solid-contact ion-selective electrodes with polymer–carbon nanotube composites.' Sensors and Actuators B: Chemical 148(1): 166-172. Zhu, J. W., X. Li, et al. (2010). 'Single-piece solid-contact ion-selective electrodes with polymer-carbon nanotube composites.' Sensors and Actuators B-Chemical 148(1): 166-172. MITSUBISHI CHEMICAL HONG KONG,2012, Plant factory, Available at: http://www.m-kagaku.com.hk/productlist.aspx?clid=204&lan=2 農業易遊網, 2013, Available at: http://ezgo.coa.gov.tw/index.php ECHO, 2012 Identifying Nutrient Deficiencies in the Garden, Available at: http://echonet.org/blog/Postmarked/NutrientDeficiencies Growing Tomatoes Hydroponically, 2012, Plant Nutrition, Available at: http://ag.arizona.edu/hydroponictomatoes/nutritio.htm | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/16922 | - |
dc.description.abstract | 植物工廠中植物的栽培主要是以水耕為主,因為其具有能使作物生長離開土壤,避免地力損失、連作障礙等弊病,利於生長過程的自動化,同時營養液可以循環使用的優勢。然而水耕作物的營養大多來自於水耕養液中的各成份離子濃度,在生長過程中各離子的成份消長不易監控,且傳統的固態離子選擇電極又有離子與電子訊號轉換上的限制,故在本論文中製造平面式的固態離子選擇電極輔以一接觸層的結構用以解決訊號傳遞問題並將其應用在植物工廠的水耕養液分析上。此外固態離子選擇電極的水層效應亦是需要克服的問題,因此本論文使用五種不同的導電材料做為選擇膜以及導電基材之間的接觸層,其中包括氨基修飾的多層奈米碳管、酯類修飾的多層奈米碳管、聚吡咯、聚噻吩以及聚鄰氨基酚。由循環伏安法(電容提升約4.5倍,相較於無接觸層)、電化學阻抗分析法(電容提升約7倍,電阻減少四分之一,相較於無接觸層)以及計時電位法(電容提升約4.33倍,電阻減少77%,相較於無接觸層)的結果以及再現性的評估,發現到聚鄰氨基酚具有極佳的高電容以及低電阻的特性,有助於感測時離子與電子間的訊號傳遞,此外其疏水的結構(接觸角增加11.2度)亦可避免水層所帶來的電壓不穩定性。
而在電極製作部分,本論文使用開路電位法量測鉀離子、鈣離子、銨根、硝酸根、鎂離子這五種離子感測電極的靈敏度,分別是55.0mV/decade、26.7 mV/decade、55.8 mV/decade、55.3 mV/decade、26.1 mV/decade。同時,這些電極的偵測極限也分別在7.2 | zh_TW |
dc.description.abstract | The main cultivation in a plant factory is hydroponics owing to its advantages of no soil needed, avoiding the loss of soil fertility and continuous cropping obstacle. Also, the productions of the plant growth are automatic and the nutrient can be recycled. However, the ion concentrations are difficult to monitor during the plant cultivation. Besides, the traditional solid-state ion selective electrodes are limited by the ion-to-electron transduction. Hence, we would manufacture the planar solid-state ion selective electrodes with a contact layer in order to overcome the signal issue and ap-ply it to monitor the nutrient. In this thesis, we utilized five conducting materials in-cluding multi walled carbon nanotubes modified NH2, multi walled carbon nanotubes modified ester, polypyrrole, polythiophene and poly-o-aminophenol as a contact layer between ion selective membrane and conducting substrate. By cyclic voltammetry(the capacitance enhanced 4.5 times comparing to the electrode without the contact layer), electrochemical impedance spectroscopy(the capacitance increased 7 times and the resistance decreased around one forth than the electrode without the contact layer), chronopotentiometry (the capacitance increased 4.33 times and the resistance de-creased around 77% than the electrode without the contact layer) and reproductively, poly-o-aminophenol have the best performance to enlarge the capacitance and reduce the resistance of the ion sensor. Moreover, its hydrophobic structure (contact angle increased 11.2 degrees) avoids the potential instability resulting from water layer. In the ion selective electrode part, the sensitivities of potassium, calcium, ammonium, nitrate and magnesium ISEs are 55.0mV/decade、26.7 mV/decade、55.8 mV/decade、55.3 mV/decade、26.1 mV/decade, respectively by measuring their open circuit po-tentials. Furthermore, the detection limits of those electrodes are7.2 | en |
dc.description.provenance | Made available in DSpace on 2021-06-07T23:49:53Z (GMT). No. of bitstreams: 1 ntu-103-R00631044-1.pdf: 3538041 bytes, checksum: c586020b6eec853208d429cee2caa239 (MD5) Previous issue date: 2014 | en |
dc.description.tableofcontents | 口試委員審定書 i
致謝 ii 中文摘要 iii Abstract v Contents vii LIST OF FIGURES xi LIST OF TABLES xiv Chapter 1 Introduction 1 1.1 Research background 1 1.2 Research motivation 4 1.3 Research objectives 5 1.4 Research framework 6 Chapter 2 Literature Reviews 7 2.1 Nutrient solutions for water cultivation 7 2.1.1 Hydroponics and the plant factory 7 2.1.2 The nutrient solutions for different crops 10 2.1.3 The monitor units of the nutrient solution 11 2.1.4 Symptoms of Nutrient Deficiencies and Toxicities 13 2.2 Ion selective electrodes 17 2.2.1 The history of ion selective electrode 17 2.2.2 The characteristics of ionophore 19 2.2.3 The ion sensing principle 26 2.2.4 Assessment of ion selectivity 29 2.3 The screen-printed sensor 31 2.3.1 Screen-printed technology for sensor 31 2.3.2 Biorecognition elements of the screen-printed biosensor 32 2.3.3 Application of environmental and food 37 Chapter 3 Materials and Methods 38 3.1 Materials and Instrumentation 38 3.1.1 Materials 38 3.1.2 Instrumentation 41 3.2 Screen-printing of ion selective electrodes 42 3.2.1 The manufacture and the design of screen printing electrodes 42 3.2.2 Formation of contact layer 45 3.3.2 Preparation of ion selective membranes 47 3.4 Electrochemical Characterization of the ISEs 50 3.4.1 Open circuit potential measurement 50 3.4.2 Cyclic voltammetry 50 3.4.3 Electrochemical impedance spectroscopy 51 3.4.4 Chronopotentiometry 52 Chapter 4 Result and Discussion 53 4.1 The obstacles of the solid state ion sensor 53 4.1.1 The ion-to-electron transduction issue 53 4.1.2 Water effect of ion selective electrodes 56 4.2 The ion-to-electron transduction of the contact layer – capacitance 58 4.2.1 Chronopotentiometry 58 4.2.2 The impedance spectra of the contact layer 61 4.2.1 Cyclic voltammetry 65 4.3 The ion-to-electron transduction of the contact layer –resistance 68 4.3.1 The Nyquist plot of ISEs with different contact layers 68 4.4Contact angle and water layer test 70 4.5 Conclusions of the contact layer 74 4.6 The performance of ion selective electrodes 76 4.6.1 Sensitivity and limit of detection 76 4.6.2 Response time 79 4.6.3 Selectivity coefficient 81 4.7 The monitor of nutrient 84 4.7.1 The real samples test 84 4.7.2 Life time measurement 88 Chapter 5 Conclusions and Suggestions 91 5.1 Conclusions 91 5.2 Suggestions and perspectives 94 References 96 | |
dc.language.iso | en | |
dc.title | 平面式離子選擇電極研究與水耕養液巨量元素感測應用 | zh_TW |
dc.title | Study of planar ion selective electrodes and macro-element sensing for hydroponics | en |
dc.type | Thesis | |
dc.date.schoolyear | 102-1 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 方煒,鄭宗記,楊雯如 | |
dc.subject.keyword | 離子選擇電極,接觸層,導電高分子,奈米碳管,水耕栽培, | zh_TW |
dc.subject.keyword | ion selective electrode,contact layer,conducting polymer,carbon nanotubes,water cultivate, | en |
dc.relation.page | 105 | |
dc.rights.note | 未授權 | |
dc.date.accepted | 2014-02-11 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 生物產業機電工程學研究所 | zh_TW |
顯示於系所單位: | 生物機電工程學系 |
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