In-situ and label-free measurement of cytochrome C concentration with a Ti2C-MXene sensitized fiber-optic MZI sensor

• Published in: Analytica chimica acta Vol. 1309; p. 342665
• Main Authors: Jin, Po, Zhang, Ya-nan, Li, Zhong, Zheng, Wanlu, Cheng, Liangliang, Li, Like, Li, Xuegang, Zhao, Yong
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 22.06.2024
• Subjects: Cytochrome C; Fiber-optic sensor; In-situ measurement; Microbial corrosion; Ti2C-MXene; Cytochrome C; Microbial corrosion; Fiber-optic sensor; In-situ measurement; Ti2C-MXene
• ISSN: 0003-2670; 1873-4324
• DOI: 10.1016/j.aca.2024.342665

The concentration of cytochrome C is demonstrated to be an effective indicator of the microbial corrosion strength of metals. Traditional cytochrome C sensor can detect cytochrome C with a low detection limit, but their use is limited by their high cost, cumbersome operation, and susceptibility to malignant environments. In addition, studies on the monitoring of cytochrome C in the field of microbial corrosion has still not been carried out. Therefore, there is a need for a highly sensitive, selective, low-cost, anti-interference, and stable cytochrome C sensor with online monitoring and remote sensing capabilities for in-situ measurement of microbial corrosion strength. This paper proposed a highly sensitive label-free fiber-optic sensor based on Mach-Zehnder interferometer (MZI) for in-situ measurement of the microbial corrosion marker cytochrome C. Two-dimensional Ti2C-MXene material is uniformly immobilized onto the surface of the sensing area to improve the sensitivity, hydrophilicity, and specific surface area of the sensing area, as well as to facilitate the immobilization of specific sensitive materials. The cytochrome C antibody is modified on the surface of Ti2C-MXene to specifically recognize cytochrome C, whose concentration variation can be measured by monitoring the spectral shift of MZI sensor. Results demonstrate a measurement sensitivity of 1.428 nm/μM for cytochrome C concentrations ranging from 0 to 7.04 μM. The detection limit of the sensor is calculated to be 0.392 μM with remarkable performance, including selectivity, stability, and reliability. Besides, the measurement result of the proposed sensor in real microbial corrosive environment is consistent with that of the ideal environment. This is the first instance of achieving in-situ and label-free measurement of cytochrome C by using a fiber-optic MZI sensor, which undoubtedly provides a feasible solution for the effective monitoring of microbial metal corrosion in the environment. [Display omitted] •A transverse mismatched MZI with a strong evanescent field is proposed.•Ti2C-MXene is used as a sensitizing material to increase the penetration depth of evanescent wave.•In situ and label-free measurements of cytochrome C were achieved.•The strength of microbial corrosion in complex environments can be monitored in real-time.