基于多波长透射光谱的水体细菌微生物活性快速检测方法

doi:10.3964/j.issn.1000-0593(2025)07-1857-09

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摘要：研究水体中细菌微生物活性，快速评估细菌在水体环境中的生长态势与繁殖能力，对于水资源科学管理以及公共卫生安全保障具有重要意义。传统细菌活性检测技术，如菌落计数法、染色观察法和分子生物学方法等，虽然有效，但操作流程繁琐，耗费时间与人力，难以满足实时在线检测的需要。针对传统细菌活性检测技术的弊端，提出了一种基于多波长透射光谱的细菌活性快速检测新方法。以水体常见大肠埃希氏菌（大肠杆菌）为研究对象，采用紫外-可见分光光度计测量其在190～800 nm波段范围内的透射光谱，并深入研究不同活菌比例下大肠杆菌透射光谱的特征及规律；通过系统分析不同波长下大肠杆菌透射光谱随活性变化的相关性和灵敏性，构建出双波长光密度比值与细菌活性之间关系模型，基于该模型计算出细菌活性，并对比分析了不同双波长比值法下细菌活性计算结果的准确性和稳定性。结果表明：（1）由于不同活性的细菌体内所含生物分子的含量存在差异，在 230～300 nm波段范围内，活菌比例较高的细菌菌液具有更高的光密度；（2）通过分析230～300 nm波段范围内大肠杆菌透射光谱随活性变化的灵敏性和相关性，发现大肠杆菌活性和光密度值之间相关系数范围值为0.959 2～0.993 3，初步确定为细菌活性定量的最优波段；（3）选取230 nm作为测定波长，670 nm作为参比波长，构建了两波长光密度比值与细菌活性拟合曲线，其相关系数达到0.946 2，活细菌比例检测范围为0%~100%；（4）基于该拟合曲线对3份具有不同活性的大肠杆菌菌液活性进行测定，与平板菌落计数法相比，最大相对误差为3.70%，平均相对误差为 1.43%，准确性最优。本方法仅需测量230和670 nm处的光密度，检测时间在1秒钟以内，就能完成对细菌活性的快速准确检测。该研究成果为水体细菌微生物活性的快速检测与预警提供了新的技术思路，具有潜在的应用价值。

关键词：光谱学；多波长透射光谱；细菌活性；双波长；Mie散射

Abstract：Studying the microbial activity of bacteria in water and rapidly assessing the growth status and reproductive capacity of bacteria in water environments are of great significance for the scientific management of water resources and the guarantee of public health security. Although traditional bacterial activity detection techniques, such as the colony counting method, staining observation method and molecular biology methods, are effective, they have cumbersome operation procedures, consume a lot of time and workforce, and are difficult to meet the needs of real-time online detection. In response to the drawbacks of traditional bacterial activity detection techniques, a novel rapid detection method for bacterial activity based on multi-wavelength transmittance spectra is proposed. Taking the common Escherichia coli (E. coli) in water as the research object, the transmittance spectra of E. coli within the wavelength range of 190～800 nm were measured using an ultraviolet-visible spectrophotometer. The characteristics and regularities of the transmittance spectra of E. coli under different proportions of viable bacteria were thoroughly studied. A relationship model between the ratio of double-wavelength optical density and bacterial activity was constructed through the systematic analysis of the correlation and sensitivity of the transmittance spectra of E. coli with changes in activity at different wavelengths. Based on this model, the bacterial activity was calculated, and the accuracy and stability of the calculation results of bacterial activity under different double-wavelength ratio methods were compared and analyzed. The results show that: (1) Due to the differences in the contents of biomolecules in bacteria with different activities, within the wavelength range of 230～300 nm, the bacterial solutions containing higher proportions of viable bacteria have higher optical densities. (2) By analyzing the sensitivity and correlation of the transmittance spectra of E. coli in the wavelength range of 230～300 nm with the activity changes, it was found that the correlation coefficient ranges between the activity of E. coli and the optical densities is 0.959 2～0.993 3, which preliminarily determines the optimal wavelength band for quantitative determination of bacterial activity. (3) Selecting 230 nm as the measurement wavelength and 670 nm as the reference wavelength, a fitting curve of the ratio of optical densities at the two wavelengths to bacterial activity was constructed. The correlation coefficient reached 0.946 2, and the detection range of the viable bacteria proportion was 0%～100%. (4) This fitting curve determined the activities of three E. coli bacterial solutions with different activities. Compared with the plate colony counting method, the maximum relative error was 3.70%, the average relative error was 1.43%, and the accuracy was optimal. This method only requires the optical densities at 230 and 670 nm, and the detection time is within 1 second, which can complete the rapid and accurate detection of bacterial activity. This research achievement provides a new technical idea for the rapid detection and early warning of bacterial activity in water and has potential application value.

Key words：Spectroscopy; Multi-wavelength transmittance spectra; Bacteria Viability; Dual-wavelength; Mie scattering

收稿日期: 2024-10-15 修订日期: 2025-02-22

中图分类号:

O433.4

基金资助: 国家自然科学基金项目（62105002, 61875254, 52370021），国家重点实验室开放课题（6142804230105），安徽省高校省级自然科学研究重点项目（2024AH050854），安徽建筑大学引进人才及博士启动基金项目（JZ202346），安徽建筑大学大学生创业创新项目（S202410878112）资助

通讯作者: 赵南京 E-mail: njzhao@aiofm.ac.cn

作者简介: 胡玉霞，女，1983年生，安徽建筑大学电子与信息工程学院博士研究生 e-mail: yxhuhf@163.com

引用本文:

胡玉霞，吴頠森，张瑞祥，薛芙蓉，黄书龙，孙龙，李卫华，甘婷婷，赵南京. 基于多波长透射光谱的水体细菌微生物活性快速检测方法[J]. 光谱学与光谱分析, 2025, 45(07): 1857-1865.
HU Yu-xia, WU Wei-sen, ZHANG Rui-xiang, XUE Fu-rong, HUANG Shu-long, SUN Long, LI Wei-hua, GAN Ting-ting, ZHAO Nan-jing. Rapid Detection Method of Bacteria Viability in Water Based on Multi-Wavelength Transmittance Spectra. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(07): 1857-1865.

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