Surface-functionalized PAN fiber membranes for the sensitive detection of airborne specific markers.
IF 2.4 3区 生物学Q2 MULTIDISCIPLINARY SCIENCESPeerJPub Date : 2024-10-23eCollection Date: 2024-01-01DOI:10.7717/peerj.18077
Leontyna Varvarovska, Bruno Sopko, Dana Gaskova, Tomas Bartl, Evzen Amler, Tatana Jarosikova
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引用次数: 0
Abstract
PAN fibers are characterized by having a large surface-to-volume ratio and small pores, which are beneficial for applications in filtration and specific molecular detection systems. Naturally, larger items are filtered, and a lower ratio between specific and nonspecific binding is expected since small pores do not allow larger elements to penetrate through membranes; thus, nonspecific binding is enhanced. We prepared and tested fiber membranes (diameter cca 700 nm) functionalized with a specific antibody to prove that even microscopic systems such as bacteria could be specifically identified. In addition, we established a methodology that enabled the effective binding of bacteria in not only an aqueous environment but also air. Our data clearly prove that even large systems such as bacteria could be specifically identified by fiber membranes surface-functionalized with a specific antibody. This research opens the door to the construction of biosensors for the fast, inexpensive, and sensitive identification of airborne bacterial contaminants and other airborne pollutants.
PAN 纤维的特点是表面体积比大、孔隙小,有利于应用于过滤和特异性分子检测系统。由于小孔不允许较大的元素穿透膜,因此非特异性结合会增强。我们制备并测试了具有特异性抗体功能的纤维膜(直径约 700 纳米),证明即使是细菌等微观系统也能被特异性识别。此外,我们还建立了一种方法,不仅能在水环境中有效结合细菌,还能在空气中有效结合细菌。我们的数据清楚地证明,即使是细菌这样的大型系统,也可以通过表面功能化了特异性抗体的纤维膜进行特异性识别。这项研究为构建快速、廉价、灵敏地识别空气中细菌污染物和其他空气污染物的生物传感器打开了大门。
期刊介绍:
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