posted on 2021-03-16, 13:34authored byJiahao Fang, Yabin Zhang, Lin Xiao, Yan Jiao, Xiaoxuan Tang, Hui Cheng, Zehang Cui, Xiaohong Li, Guoqiang Li, Moyuan Cao, Liang Zhong
Droplet
manipulation is of paramount significance for microfluidics-based
biochips, especially for bioanalytical chips. Despite great progresses
made on droplet manipulation, the existing bioanalytical methods face
challenges in terms of capturing minute doses toward hard-to-obtain
samples and analyzing biological samples at low temperatures immediately.
To circumvent these limitations, a self-propelled and electric stimuli
synergetic droplet manipulator (SES-SDM) was developed by a femtosecond
laser microfabrication strategy followed by post-treatment. Combining
the inspiration from cactus and Nepenthes pitcher
plants, the wedge structure with the microbowl array and silicone
oil infusion was endowed cooperatively with the SES-SDM. With the
synergy of the ultralow voltage (4.0 V) stimuli, these bioinspired
features enable the SES-SDM to transport the droplet spontaneously
and controllably, showing the maximum fast motion (15.7 mm/s) and
long distance (96.2 mm). Remarkably, the SES-SDM can function at −5
°C without the freezing of the droplets, where the self-propelled
motion and electric-responsive pinning can realize the accurate capture
and real-time analysis of the microdroplets of the tested samples.
More importantly, the SES-SDM can realize real-time diagnosis of excessive
heavy metal in water by the cooperation of self-propulsion and electro-brake.
This work opens an avenue to design a microsampling (5–20 μL)
manipulator toward producing the minute samples for efficient bioanalysis
and offers a strategy for microanalysis using the synergistic droplet
manipulation.