[1] Heng SUN, Ning HU, Jianhua WANG. Application of microfluidic technology in antibody screening. Biotechnology Journal, 17, 2100623(2022).
[2] Yuetong WANG, Zhouyue CHEN, Feika BIAN et al. Advances of droplet-based microfluidics in drug discovery. Expert Opinion on Drug Discovery, 15, 969-979(2020).
[3] T S SANTISTEBAN, O RABAJANIA, I KALININA et al. Rapid spheroid clearing on a microfluidic chip. Lab on a Chip, 18, 153-161(2018).
[4] O FREY, P M MISUN, D A FLURI et al. Reconfigurable microfluidic hanging drop network for multi-tissue interaction and analysis. Nature Communications, 5, 4250(2014).
[5] U HASSAN, N N WATKINS, C EDWARDS et al. Flow metering characterization within an electrical cell counting microfluidic device. Lab on a Chip, 14, 1469-1476(2014).
[6] N BOURGUIGNON, P KARP, C ATTALLAH et al. Large area microfluidic bioreactor for production of recombinant protein. Biosensors, 12, 526(2022).
[7] Yuan GONG, Qunfeng LIU, chenlin ZHANG et al. Microfluidic flow rate detection with a large dynamic range by optical manipulation. IEEE Photonics Technology Letters, 27, 2508-2511(2015).
[8] A GLANINGER, A JACHIMOWICZ, F KOHL et al. Wide range semiconductor flow sensors. Sensors and Actuators A: Physical, 85, 139-146(2000).
[9] Jack CHEN, Zhifang FAN, Jun ZOU et al. Two-dimensional micromachined flow sensor array for fluid mechanics studies. Journal of Aerospace Engineering, 16, 85-97(2003).
[10] J COLLINS, A P LEE. Microfluidic flow transducer based on the measurement of electrical admittance. Lab on a Chip, 4, 7-10(2004).
[11] G J M KRIJNEN, M DIJKSTRA, J J VAN BAAR et al. MEMS based hair flow-sensors as model systems for acoustic perception studies. Nanotechnology, 17, S84(2006).
[12] Ran GAO, Danfeng LU, Jin CHENG et al. Simultaneous measurement of refractive index and flow rate using graphene-coated optofluidic anti-resonant reflecting guidance. Optics Express, 25, 28731-28742(2017).
[13] Da LIU, Ran GAO, Zhipei LI et al. Simultaneous measurement of refractive index and flow rate using a Co2+-doped microfiber. Applied Sciences, 11, 10525(2021).
[14] J SADEGHI, A H B GHASEMI, H LATIFI. A label-free infrared opto-fluidic method for real-time determination of flow rate and concentration with temperature cross-sensitivity compensation. Lab on a Chip, 16, 3957-3968(2016).
[15] Xuefeng JIANG, A J QAVI, S H HUANG et al. Whispering-gallery sensors. Matter, 3, 371-392(2020).
[16] Yanyan ZHI, Xiaochong YU, Qihuang GONG et al. Single nanoparticle detection using optical microcavities. Advanced Materials, 29, 1604920(2017).
[17] N TOROPOV, G CABELLO, M P SERRANO et al. Review of biosensing with whispering-gallery mode lasers. Light: Science & Applications, 10, 42(2021).
[18] J SU, A F G GOLDBERG, B M STOLTZ. Label-free detection of single nanoparticles and biological molecules using microtoroid optical resonators. Light: Science & Applications, 5, e16001(2016).
[19] Xin TU, Yuxiang WANG, Zhihe GUO et al. Underwater acoustic wave detection based on packaged optical microbubble resonator. Journal of Lightwave Technology, 40, 6272-6279(2022).
[20] Jinshun PAN, Bin ZHANG, Zhengyong LIU et al. Microbubble resonators combined with a digital optical frequency comb for high-precision air-coupled ultrasound detectors. Photonics Research, 8, 303-310(2020).
[21] Yong YANG, S SAURABH, J M WARD et al. High-Q, ultrathin-walled microbubble resonator for aerostatic pressure sensing. Optics Express, 24, 294-299(2016).
[22] Bing DUAN, Hanying ZOU, Jinhui CHEN et al. High-precision whispering gallery microsensors with ergodic spectra empowered by machine learning. Photonics Research, 10, 2343-2348(2022).
[23] Hanyang LI, Bo SUN, Yonggui YUAN et al. Guanidine derivative polymer coated microbubble resonator for high sensitivity detection of CO2 gas concentration. Optics Express, 27, 1991-2000(2019).
[24] Zhongdi PENG, Changqiu YU, Hongliang REN et al. Gas identification in high-Q microbubble resonators. Optics Letters, 45, 4440-4443(2020).
[25] Daquan YANG, Jinhui CHEN, Qitao CAO et al. Operando monitoring transition dynamics of responsive polymer using optofluidic microcavities. Light: Science & Applications, 10, 128(2021).
[26] Daquan YANG, Bing DUAN, Aiqiang WANG et al. Packaged microbubble resonator for versatile optical sensing. Journal of Lightwave Technology, 38, 4555-4559(2020).
[27] Zihao LI, Chenggang ZHU, Zhihe GUO et al. Highly sensitive label-free detection of small molecules with an optofluidic microbubble resonator. Micromachines, 9, 274(2018).
[28] Zhihe GUO, Qijing LU, Chenggang ZHU et al. Ultra-sensitive biomolecular detection by external referencing optofluidic microbubble resonators. Optics Express, 27, 12424-12435(2019).
[29] Xuyang ZHAO, Zhihe GUO, Yi ZHOU et al. Optical whispering-gallery-mode microbubble sensors. Micromachines, 13, 592(2022).
[30] J M WARD, Yong YANG, SNIC CHORMAIC. Glass-on-glass fabrication of bottle-shaped tunable microlasers and their applications. Scientific Reports, 6, 1-10(2016).
[31] Yuan GONG, Minglei ZHANG, Chaoyang GONG et al. Sensitive optofluidic flow rate sensor based on laser heating and microring resonator. Microfluidics and Nanofluidics, 19, 1497-1505(2015).
[32] Zhenmin CHEN, Zhihe GUO, Xin MU et al. Packaged microbubble resonator optofluidic flow rate sensor based on Bernoulli Effect. Optics Express, 27, 36932-36940(2019).
[33] Zijie WANG, Xiaobei ZHANG, Shuaichang ZHAO et al. High-sensitivity flow rate sensor enabled by higher order modes of packaged microbottle resonator. IEEE Photonics Technology Letters, 33, 599-602(2021).
[34] M E SALETA, D TOBIA, S GIL. Experimental study of Bernoulli's equation with losses. American Journal of Physics, 73, 598-602(2005).
[35] J ARMENGOL, J CALBÓ, T PUJOL et al. Bernoulli correction to viscous losses: Radial flow between two parallel discs. American Journal of Physics, 76, 730-737(2008).
[36] REA U , T MCKRELL, Linwen HU et al. Laminar convective heat transfer and viscous pressure loss of alumina–water and zirconia-water nanofluids. International Journal of Heat and Mass Transfer, 52, 2042-2048(2009).
[37] J P BRODY, P YAGER, R E GOLDSTEIN et al. Biotechnology at low Reynolds numbers. Biophysical Journal, 71, 3430-3441(1996).
[38] E F MEGYESY. Pressure vessel handbook(1973).
[39] A BARUCCI, S BERNESCHI, A GIANNETTI et al. Optical microbubble resonators with high refractive index inner coating for bio-sensing applications: an analytical approach. Sensors, 16, 1992(2016).
