Baek Beomyeol, Park Yoon Ho, Jeon Ju-Mi, Shim Hee-Young, Lee Eun-Kyoung, Hong Mi-Jeong, Bae Young-Woo, An Joong-Heok, Shin In-Cheol, Jung Hyun Suk
Department of Biochemistry, College of Natural Sciences, Kangwon National University, Chuncheon 24341, Republic of Korea.
Infectious Disease Research Division, Gangwon-do Institute of Health and Environment, 386-1, Sinbuk-ro, Sinbuk-eup, Chuncheon-si 24203, Republic of Korea.
Int J Mol Sci. 2025 May 4;26(9):4355. doi: 10.3390/ijms26094355.
is a significant foodborne pathogen that presents a critical challenge in food safety due to its ability to form resistant spores and produce various toxins. The potential for severe food poisoning makes rapid and accurate identification of this pathogen essential. Conventional microbiological methods for identification rely on morphological characteristics and biochemical tests, requiring extensive time and labor. However, even automated biochemical systems like VITEK2, while providing reliable results, still require up to 16 h for analysis and complex sample preparation procedures. MALDI-TOF (matrix-assisted laser desorption/ionization time-of-flight) mass spectrometry utilizes laser-induced ionization of bacterial proteins and subsequent time-of-flight analysis to generate unique mass spectral patterns. This established analytical technique for bacterial identification offers exceptional speed and simplicity through direct protein profiling. In this study, we optimized MALDI-TOF analysis conditions for identification by examining various cultivation times. Our results demonstrated complete species-level identification accuracy with MALDI-TOF scores ≥ 2.0 with 12-h cultures, matching the reliability of VITEK2 while significantly reducing processing time. The identification rates decreased significantly from 100% at 12 h to 73.3% at 24 h and 50% at 48 h of incubation, correlating directly with increased spore formation. Detailed analysis at 4-h intervals revealed that high identification rates (93.3%) were maintained during 16 h of cultivation before declining significantly. This study establishes MALDI-TOF as a reliable and efficient tool for rapid identification, representing a significant advancement in food safety diagnostics with potential time savings of more than 50% compared to conventional methods.
是一种重要的食源性病原体,由于其能够形成抗性孢子并产生多种毒素,在食品安全方面构成了严峻挑战。严重食物中毒的可能性使得快速准确地鉴定这种病原体至关重要。传统的微生物鉴定方法依赖于形态特征和生化试验,需要大量的时间和人力。然而,即使是像VITEK2这样的自动化生化系统,虽然能提供可靠的结果,但仍需要长达16小时的分析时间和复杂的样品制备程序。基质辅助激光解吸/电离飞行时间(MALDI-TOF)质谱法利用激光诱导细菌蛋白质电离并随后进行飞行时间分析,以生成独特的质谱图。这种成熟的细菌鉴定分析技术通过直接蛋白质谱分析提供了卓越的速度和简便性。在本研究中,我们通过检查不同的培养时间,优化了用于鉴定的MALDI-TOF分析条件。我们的结果表明,对于培养12小时的样品,MALDI-TOF得分≥2.0时,物种水平的鉴定准确率达到100%,与VITEK2的可靠性相当,同时显著缩短了处理时间。随着培养时间从12小时延长至24小时,鉴定率从100%显著下降至73.3%,在48小时时降至50%,这与孢子形成增加直接相关。每隔4小时进行的详细分析表明,在培养16小时内保持了较高的鉴定率(93.3%),之后才显著下降。本研究确立了MALDI-TOF作为快速鉴定的可靠且高效工具的地位,与传统方法相比,在食品安全诊断方面取得了重大进展,可能节省超过50%的时间。
