個人簡介
汪高博,男����,漢族���,1995年生����,中共黨員,工學(xué)博士�����,碩士研究生導(dǎo)師�。主要研究方向?yàn)槲⒘骺厣飩鞲衅鳌⒔?jīng)皮藥物遞送系統(tǒng)及植入式診療器件的開發(fā)���。近年來,在Advanced Science, Science Advances, Advanced Healthcare Materials, Analytical Chemistry等國際期刊共發(fā)表SCI論文14篇�����。擔(dān)任Biomedical Engineering Communications, VIEW等期刊青年編委。
聯(lián)系方式
地址:新鄉(xiāng)醫(yī)學(xué)院北區(qū)科技樓生物醫(yī)學(xué)工程系辦公室717
電話:13683934173
E-mail: wanggaobo@xxmu.edu.cn
研究方向
微流控檢測芯片����;微針經(jīng)皮給藥�����;植入式診療器件
招生方向
學(xué)術(shù)型碩士:生物醫(yī)學(xué)工程
教育背景
2018/12-2022/12, 香港城市大學(xué), 生物醫(yī)學(xué)工程�,博士
2016/09-2018/08, 韓國高麗大學(xué), 生物融合工程,碩士
2012/09-2016/06, 河南科技學(xué)院, 化學(xué)工程與工藝����,學(xué)士
工作經(jīng)歷
2024/09-至今, 新鄉(xiāng)醫(yī)學(xué)院�,醫(yī)學(xué)工程學(xué)院�����,講師
2023/03-2024/08, 日本東北大學(xué), 精密機(jī)械系, 博士后
承擔(dān)項(xiàng)目
1. 新鄉(xiāng)醫(yī)學(xué)院科研啟動項(xiàng)目�����,便攜式微納生物傳感器,2024.10-2027.12����,主持;
2. 日本學(xué)術(shù)振興會(科學(xué)研究費(fèi)助成金S)��,基于離子傳輸?shù)碾娮悠つw,22H04956�����,960萬�,2022.04-2027.03��,參與;
3. 深圳市科技創(chuàng)新局�,基于微流控磁粒子的前列腺癌視覺量化檢測微芯片的研究��,JCYJ20210324134006017,40萬��,2021.10 – 2024.10�����,參與;
近五年代表性論文(#:共同作者/equal contribution; *:通訊作者/corresponding author)
1. G. Wang#, Y. Zhang#, H. Kwong#, M. Zheng, J. Wu, C. Cui, K. Chan, C. Xu*, and T-H Chen*. On-site melanoma diagnosis utilizing a swellable microneedle-assisted skin interstitial fluid sampling and a microfluidic particle dam for visual quantification of S100A1. Adv. Sci. 2306188, 2024 (IF=14.3, 中科院一區(qū)Top)
2. G. Wang#, J. Li#, S. Wu, T. Jiang, and T-H Chen*. A fully integrated, ready-to-use distance-based chemosensor for visual quantification of multiple heavy metal ions. Anal. Chem. 94, 46, 15925–15929, 2022 (IF=6.8, 中科院一區(qū)Top)
3. G. Wang, M. Wu, L. Chu, T-H Chen*. Portable microfluidic device with thermometer-like display for real-time visual quantitation of Cadmium(ii) contamination in drinking water. Anal. Chim. Acta 1160, 338444. 2022 (IF=5.7, 中科院一區(qū)Top)
4. G. Wang#, L. Chu#, H. Hartanto, W. B. Utomo, R. A. Pravasta, and T-H Chen*. Microfluidic particle dam for visual and quantitative detection of lead ions. ACS Sens. 5, 19–23, 2020 (IF=8.3, 中科院一區(qū)Top)
5. G. Wang, K. Kato, S. Ichinose, D. Inoue, A. Kobayashi, H. Terui, S. Tottori, M. Kanzaki, M. Nishizawa*. Bilaterally aligned electroosmotic flow generated by porous microneedle device for dual-mode delivery. Adv. Healthc. Mater. 2401181, 2024 (IF=10.0, 中科院二區(qū)Top)
6. G. Wang, K. Kato, I. Aoki, S. Ichinose, D. Inoue, S. Tottori and M. Nishizawa*. Transdermal drug delivery using a porous microneedle device driven by a hydrogel electroosmotic pump. J. Mater. Chem. B 12, 1490-1494, 2024 (IF=6.1, 中科院三區(qū))
7. M. Wu#, G. Wang#, L. Chu, H. Huang, T-H Chen*. Cascade-amplified microfluidic particle accumulation enabling quantification of lead ions through visual inspection. Sens. Actuators B: Chem. 324, 128727, 2020 (IF=8.0, 中科院一區(qū)Top)
8. H. Shirinkami#, G. Wang#, J. Park, J. Ahn, Y. Choi*, H. Chun*. Red blood cell and white blood cell separation using a lateral-dimension scalable microchip based on hydraulic jump and sedimentation. Sens. Actuators B: Chem. 307, 127412, 2020 (IF=8.0, 中科院一區(qū)Top)
