材料科学
生物污染
生物电子学
超声
阳离子聚合
化学工程
电化学
壳聚糖
结垢
生物传感器
粘附
涂层
图层(电子)
电极
纳米技术
纳米颗粒
聚合
吸附
多糖
表面改性
生物界面
逐层
自愈水凝胶
检出限
蛋白质吸附
表面电荷
作者
Peng Sun,Jie Jin,Meiling Wang,Jiao Ma,Hua Wang
标识
DOI:10.1021/acsami.5c11449
摘要
The serious fouling layer from the nonspecific adsorption in complex media would greatly impair the analytical performance and even lead to the complete failure of the electrochemical sensor. Zwitterionic hydrogel has been demonstrated to possess excellent antifouling capability, while it suffers from a weak interface and spontaneous detachment from the electrode surface due to the double-edged hydrophilicity. Here, we found that the anionic polysaccharide coating on the liquid metal (LM) nanoparticle surface, in combination with the cationic chitosan penetrated in the hydrogel network, could synergistically enhance the interface adhesion while retaining antifouling ability, providing an ingenious solution to this issue. Additionally, only ultrasonic treatment was involved for the preparation of this LM-based zwitterionic hydrogel because ultrasonication could easily induce the formation of LM nanoparticles, the self-assembly of anionic polysaccharide on its surface, and simultaneous free radical polymerization of zwitterionic monomer. Finally, an electrochemical immunosensor was successfully fabricated based on this polysaccharide cross-linked LM-based zwitterionic hydrogel, and an ultralow detection limit of 7.17 pg·mL–1, while a wide linear range from 10 pg·mL–1 to 10 μg·mL–1 was obtained in 100% human serum with negligible difference from that in PBS solution. We believe the polysaccharide-stabilized antifouling hydrogel interface presented in this work could inspire more innovative research for biosensing and bioelectronics in the future.
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