Droplet manipulation enabled by bio-inspired high-aspect-ratio micropumps via mold-assisted microfabrication

Zebing Mao; Chao Luo; Yanhong Peng; Yang Li; Yile Chen; Sirui Pan; Junji Ohgi; Weidi Huang; Jianhua Zhang; Bing Xu

doi:10.1002/dro2.70049

Droplet ›› 2026, Vol. 5 ›› Issue (1) :e70049 DOI: 10.1002/dro2.70049

RESEARCH ARTICLE

Droplet manipulation enabled by bio-inspired high-aspect-ratio micropumps via mold-assisted microfabrication

Author information +

History +

PDF

Abstract

Miniaturized functional fluidic pumps have found broad applications across various fields; however, the fabrication and dimensional limitations of their electrodes remain a significant challenge. Conventional manufacturing techniques often fail to achieve high aspect ratio structures exceeding 2 and electrode heights greater than 1 mm. In this work, we propose a novel extreme microfabrication strategy that integrates flexible molding techniques with advanced microfabrication processes to develop high-precision pump electrodes. These electrodes are successfully implemented in droplet manipulation applications. First, we selected suitable microfabrication-compatible materials and developed a conductive, flexible liquid elastomer, along with a tailored fabrication process. Next, a functional working fluid compatible with the electrodes was synthesized and characterized in terms of its viscosity, electrical conductivity, dielectric constant, and interfacial behavior with aqueous phases. A corresponding microfluidic chip was also fabricated to assess its droplet generation performance. Both duty cycle-based and frequency-based droplet manipulation strategies were investigated using this chip. Finally, a machine learning approach was employed to model the droplet generation process and evaluate the influence of four key parameters on device performance. This study establishes a foundational platform and design pathway for future development of integrated on-chip pumping systems in microfluidic applications.

Cite this article

Download citation ▾

Zebing Mao, Chao Luo, Yanhong Peng, Yang Li, Yile Chen, Sirui Pan, Junji Ohgi, Weidi Huang, Jianhua Zhang, Bing Xu. Droplet manipulation enabled by bio-inspired high-aspect-ratio micropumps via mold-assisted microfabrication. Droplet, 2026, 5(1): e70049 DOI:10.1002/dro2.70049

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Xu J, Xiu S, Lian Z, Yu H, Cao J. Bioinspired materials for droplet manipulation: principles, methods and applications. Droplet. 2022; 1: 11-37.

[2]	Sun J, Zhang L, Zhou Y, et al. Highly efficient liquid droplet manipulation via human-motion-induced direct charge injection. Mater Today. 2022; 58: 41-47.

[3]	Fang D, Zhou W, Jin Y, et al. Programmable droplet manipulation enabled by charged-surface pattern reconfiguration. Droplet. 2023; 2:e74.

[4]	Jiang S, Wu D, Li J, Chu J, Hu Y. Magnetically responsive manipulation of droplets and bubbles. Droplet. 2024; 3:e117.

[5]	Wang J, Zhu Z, Liu P, et al. Magneto-responsive shutter for on-demand droplet manipulation. Adv Sci. 2021; 8:2103182.

[6]	Hartmann J, Schür MT, Hardt S. Manipulation and control of droplets on surfaces in a homogeneous electric field. Nat Commun. 2022; 13: 289.

[7]	Yuan Z, Lu C, Liu C, et al. Ultrasonic tweezer for multifunctional droplet manipulation. Sci Adv. 2023; 9:eadg2352.

[8]	Cheng G, Kuan CY, Lou KW, Ho YP. Light-responsive materials in droplet manipulation for biochemical applications. Adv Mater. 2025; 37:2313935.

[9]	Nan L, Zhang H, Weitz DA, Shum HC. Development and future of droplet microfluidics. Lab Chip. 2024; 24: 1135-1153.

[10]	Moragues T, Arguijo D, Beneyton T, et al. Droplet-based microfluidics. Nat Rev Methods Primer. 2023; 3: 32.

[11]	Wehner M, Truby RL, Fitzgerald DJ, et al. An integrated design and fabrication strategy for entirely soft, autonomous robots. Nature. 2016; 536: 451-455.

[12]	Hao B, Wang X, Dong Y, et al. Focused ultrasound enables selective actuation and Newton-level force output of untethered soft robots. Nat Commun. 2024; 15: 5197.

[13]	Rothemund P, Kellaris N, Mitchell SK, Acome E, Keplinger C. HASEL artificial muscles for a new generation of lifelike robots—recent progress and future opportunities. Adv Mater. 2021; 33:2003375.

[14]	Del Campo Fonseca A, Glück C, Droux J, et al. Ultrasound trapping and navigation of microrobots in the mouse brain vasculature. Nat Commun. 2023; 14: 5889.

[15]	Smith M, Cacucciolo V, Shea H. Fiber pumps for wearable fluidic systems. Science. 2023; 379: 1327-1332.

[16]	Cacucciolo V, Shintake J, Kuwajima Y, Maeda S, Floreano D, Shea H. Stretchable pumps for soft machines. Nature. 2019; 572: 516-519.

[17]	Xin Y, Zhou X, Tan MRJ, et al. 3D-printed electrohydrodynamic pump and development of anti-swelling organohydrogel for soft robotics. Adv Mater. 2025; 37:2415210.

[18]	Kuwajima Y, Marzuq A, Segawa S, et al. Resilient and flexible electrohydrodynamics pumps for human-machine interfaces. Adv Sci. 2025; 12:2416502.

[19]	Li F, Sun S, Wan X, Sun M, Zhang SL, Xu M. A self-powered soft triboelectric-electrohydrodynamic pump. Nat Commun. 2025; 16: 1315.

[20]	Mao Z, Hosoya N, Maeda S. Flexible electrohydrodynamic fluid-driven valveless water pump via immiscible interface. Cyborg Bionic Syst. 2024; 5: 0091.

[21]	Kuwajima Y, Yamaguchi Y, Yamada Y, et al. Pocketable and smart electrohydrodynamic pump for clothes. ACS Appl Mater Interfaces. 2023; 16: 1883-1891.

[22]	Tang W, Zhang C, Zhong Y, et al. Customizing a self-healing soft pump for robot. Nat Commun. 2021; 12: 2247.

[23]	Tang W, Zhong Y, Xu H, et al. Self-protection soft fluidic robots with rapid large-area self-healing capabilities. Nat Commun. 2023; 14: 6430.

[24]	Shigemune H, Pradidarcheep K, Kuwajima Y, Seki Y, Maeda S, Cacucciolo V. Wireless electrohydrodynamic actuators for propulsion and positioning of miniaturized floating robots. Adv Intell Syst. 2021; 3:2100004.

[25]	Suntornnond R, Ng WL, Shkolnikov V, Yeong WY. A facile method to fabricate cell-laden hydrogel microparticles of tunable sizes using thermal inkjet bioprinting. Droplet. 2024; 3:e144.

[26]	Ma Y, Liang Z, Chen Y, Wang J. Advances in precise cell manipulation. Droplet. 2025; 4:e149.

[27]	Abe H, Imai Y, Tokunaga N, Yamashita Y, Sasaki Y. Highly efficient electrohydrodynamic pumping: molecular isomer effect of dielectric liquids, and surface states of electrodes. ACS Appl Mater Interfaces. 2015; 7: 24492-24500.

[28]	Seo WS, Yoshida K, Yokota S, Edamura K. A high performance planar pump using electro-conjugate fluid with improved electrode patterns. Sens Actuators Phys. 2007; 134: 606-614.

[29]	Mao Z, Yoshida K, Kim JW. Developing O/O (oil-in-oil) droplet generators on a chip by using ECF (electro-conjugate fluid) micropumps. Sens Actuators B Chem. 2019; 296:126669.

[30]	Bott H, Leonhardt R, Laermer F, Hoffmann J. Employing fluorescence analysis for real-time determination of the volume displacement of a pneumatically driven diaphragm micropump. J Micromech Microeng. 2021; 31:075003.

[31]	Nicola BA, Popescu MN, Gáspár S. Substrate-controlled bidirectional pumping by a bienzymatic micropump. ACS Appl Mater Interfaces. 2024; 16: 59556-59566.

[32]	Mujtaba J, Kuzin A, Chen G, et al. Synergistic integration of hydrogen peroxide powered valveless micropumps and membraneless fuel cells: a comprehensive review. Adv Mater Technol. 2024; 9:2302052.

[33]	Vakili S, Banejad A, Ramezani-Fard E, Passandideh-Fard M, Shaegh SAM. Characterization of a peristaltic micropump using experiments and simulations. Multiscale Sci Eng. 2024; 6: 237-248.

[34]	Shan J, Guo L, Ran P, et al. Implantable double-layer pump chamber piezoelectric valveless micropump with adjustable flow rate function. J Micromechanics Microengineering. 2022; 32:105002.

[35]	Bohm S, Phi HB, Dittrich L, Runge E. Chip-integrated non-mechanical microfluidic pump driven by electrowetting on dielectrics. Lab Chip. 2024; 24: 2893-2905.

[36]	Sedky M, Ali A, Abdel-Mottaleb M, Serry M. A new rapid-release SMA-activated micropump with incorporated microneedle arrays and polymeric nanoparticles for optimized transdermal drug delivery. Sens Actuators B Chem. 2024; 408:135549.

[37]	Hamid N, Majlis BY, Yunas J, Ibrahim M. Thermo-pneumatic micropump for drug delivery applications. Asian J Med Technol. 2022; 2: 19-34.

[38]	Matia Y, An HS, Shepherd RF, Lazarus N. Magnetohydrodynamic levitation for high-performance flexible pumps. Proc Natl Acad Sci USA. 2022; 119:e2203116119.

[39]	Diteesawat RS, Helps T, Taghavi M, Rossiter J. Electro-pneumatic pumps for soft robotics. Sci Robot. 2021; 6:eabc3721.

[40]	ESX-04. Gotec. https://www.gotec.ch/En/Product/Esx-04/

[41]	Di Giovine G, Mariani L, Di Battista D, Cipollone R, Fremondi F. Modeling and experimental validation of a triple-screw pump for internal combustion engine cooling. Appl Therm Eng. 2021; 199:117550.

[42]	Micro-gear Pumps (MG Series). Micropumps. https://micropumps.co.uk/Micro-Gear-Pumps-Mg-Series/

[43]	Zhao H, Mills W, Glidle A, et al. On-demand droplet formation at a T-junction: modelling and validation. Microsyst Nanoeng. 2025; 11: 94.

[44]	Zeng W, Tong Z, Shan X, Fu H, Yang T. Monodisperse droplet formation for both low and high capillary numbers in a T-junction microdroplet generator. Chem Eng Sci. 2021; 243:116799.

[45]	Jena SK, Bahga SS, Kondaraju S. Prediction of droplet sizes in a T-junction microchannel: effect of dispersed phase inertial forces. Phys Fluids. 2021; 33:032120.

[46]	Bacha TW, Manuguerra DC, Marano RA, Stanzione JF. Hydrophilic modification of SLA 3D printed droplet generators by photochemical grafting. RSC Adv. 2021; 11: 21745-21753.

[47]	Liu Y, Zhu C, Fu T, Gao X, Ma Y. Breakup dynamics of water-in-water droplet generation in a flow-focusing microchannel. Chem Eng Sci. 2024; 283:119384.

[48]	Yao J, He C, Wang J, et al. A novel integrated microfluidic chip for on-demand electrostatic droplet charging and sorting. Bio-Des Manuf. 2024; 7: 31-42.

[49]	Zhao B, Cui X, Ren W, Xu F, Liu M, Ye ZG. A controllable and integrated pump-enabled microfluidic chip and its application in droplets generating. Sci Rep. 2017; 7:11319.

[50]	Ma T, Wang Y, Sun S, Pan T, Li B, Chu J. Size-tunable droplet microfluidic system using an on-chip microfluidic peristaltic pump. Sens Actuators Phys. 2022; 334:113332.

[51]	Wang M, Fu Q, Liu R, et al. A microfluidic manipulation platform based on droplet mixing technology. Chem Eng Sci. 2024; 298:120422.

[52]	Fajrial AK, Vega A, Shakya G, Ding X. A frugal microfluidic pump. Lab Chip. 2021; 21: 4772-4778.

[53]	Chen I-J, Wu T, Hu S. A hand-held, power-free microfluidic device for monodisperse droplet generation. MethodsX. 2018; 5: 984-990.

[54]	Biswas GC, Suzuki H. Simple manual roller pump-driven valve-free microfluidic solution exchange system for urgent bioassay. RSC Adv. 2022; 12: 2938-2946.

[55]	Jeon JW, Choi JW, Shin Y, Kang T, Chung BG. Machine learning-integrated droplet microfluidic system for accurate quantification and classification of microplastics. Water Res. 2025; 274:123161.

[56]	Lashkaripour A, Rodriguez C, Mehdipour N, et al. Machine learning enables design automation of microfluidic flow-focusing droplet generation. Nat Commun. 2021; 12: 25.

[57]	Lashkaripour A, McIntyre DP, Calhoun SG, Krauth K, Densmore DM, Fordyce PM. Design automation of microfluidic single and double emulsion droplets with machine learning. Nat Commun. 2024; 15: 83.