荧光法生物气溶胶监测仪性能验证及应用

doi:10.3969/j.issn.1000-1158.2023.03.06

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摘要利用荧光法生物气溶胶监测仪设备分别进行总粒子计数效率、荧光粒子计数效率评价,并在实验室和实际应用场景利用多种微生物气溶胶进行验证。通过菌落计数法和显微镜观察2种传统的离线检测方法与实时在线生物气溶胶监测仪的数值比对,发现实时生物气溶胶监测技术与传统方法检测结果具有较好的一致性。同时应用生物气溶胶监测仪对不同应用场景中的生物粒子进行监测,验证了检测结果的的可靠性。

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	田莹
	张国城
	潘一廷
	吴丹
	刘佳琪
	沈上圯
	李晶晶

关键词 ：计量学, 生物气溶胶监测仪, 荧光法, 菌落计数, 显微计数, 应用场景

Abstract：The total particle counting efficiency and fluorescence particle counting efficiency were evaluated by the fluorescence bioaerosol monitor, and verified by a variety of microbial aerosols in laboratory and practical application scenarios. By comparing the values of two traditional off-line detection methods, colony counting method and microscope observation method, it was found that the real-time bioaerosol monitoring technology has a good agreement with the traditional detection methods. At the same time, the bioaerosol monitor was used to monitor biological particles in different application scenarios, and the reliability of the detection results was verified.

Key words： metrology bioaerosol detector fluorescence method colony counting method microscopic count application scenarios

收稿日期: 2022-07-21 发布日期: 2023-03-08

PACS:

TB99

基金资助:国家市场监督管理总局科技计划(2021MK003);北京市2022年度博士后科研活动经费;朝阳区2021年度博士后科研活动经费

通讯作者: 张国城(1980-),男,福建永春人,北京市计量检测科学研究院教授级高工,主要从事化学分析与环境监测仪器的计量检测研究。Email:zhanggc@bjjl.cn E-mail: tiany@bjjl.cn

作者简介: 田莹(1990-),女,河南焦作人,北京市计量检测科学研究院工程师,主要从事颗粒物相关环境监测仪器。Email: tiany@bjjl.cn

引用本文:

田莹,张国城,潘一廷,吴丹,刘佳琪,沈上圯,李晶晶. 荧光法生物气溶胶监测仪性能验证及应用[J]. 计量学报, 2023, 44(3): 356-360.
TIAN Ying,ZHANG Guo-cheng,PAN Yi-ting,WU Dan,LIU Jia-qi,SHEN Shang-yi,LI Jing-jing. Performance Verification and Application of Bioaerosol Monitor by Fluorescence Method. Acta Metrologica Sinica, 2023, 44(3): 356-360.

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http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2023.03.06 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2023/V44/I3/356

［12］	刘佳琪,张国城,吴丹,等. 气旋式生物气溶胶采样器采集物理效率评价方法研究［J］. 计量学报, 2022, 43(10):1378-1381.
［19］	耿洲,魏淑波,汪林,等.基于激光诱导荧光技术原理的微生物实时监测技术在USP<1223>标准下的替代验证及其在PIVAS洁净室的应用研究［J］.中国现代应用药学,2021,38(23):2992-3001.
［8］	Felini M, Johnson E, Preacely N, et al. A pilot case-cohort study of liver and pancreatic cancers in poultry workers［J］. Ann. Epidemiol. 2011, 21(10):755-766.
［13］	潘一廷,张国城,刘佳琪,等.荧光法生物气溶胶监测仪标准物质研制及校准方法研究［J］.中国环境监测,2021,37(4):192-198.
［4］	Georgakopoulos D G, Despres V, Frohlich-Nowoisky J, et al. Microbiology and atmospheric processes: biological, physical and chemical characterization of aerosol particles［J］. Biogeosciences. 2009, 6:721-737.
［7］	Maheswaran D, Zeng Y, Chan-Yeung M, et al. Exposure to beta-(1,3)-D-glucan in house dust at age 7-10 is associated with airway hyperresponsiveness and atopic asthma by age 11-14［J］. Plos One. 2014, 9(6):1-11.
	Liu J Q, Zhang G C, Wu D, et al. Study on Evaluation Method of Physical Efficiency of Cyclone Microbiological Sampler［J］. Acta Metrologia Sinica, 2022, 43(10):1378-1381.
	Geng Z, Wei S B, Wang L, et al. Verification of Real-time Microbial Monitoring Technology Based on the Principle of Laser-induced Fluorescence Under USP<1223> Standard and Application in Hospital PIVAS Clean Room［J］. Chinese Journal of Modern Applied Pharmacy, 2021,38(23):2992-3001.
［6］	郑云昊,李菁,陈灏轩, 等. 生物气溶胶的昨天、今天和明天［J］.科学通报, 2018, 63(10):878-894.
	Tian Y, Zhang G C, Wu D, et al. Device Construction and Method Research of Biological Counting Evalutation of Bioaerosol Detectors, Acta Metrologica Sinica, 2021,42(12):1687-1692.
［18］	张霞.微生物显微镜直接计数法的点滴改进［J］.生物学通报,1998(1):27.
［1］	Kim K H, Kabir E, Jahan S A. Airborne bioaerosols and their impact on human health［J］. Journal of Environmental Sciences (China), 2018, 67: 23-35.
［11］	潘一廷, 张国城, 杨振琪, 等. 生物气溶胶监测仪校准方法的研究［J］. 中国测试, 2020, 46(10):18-22.
［11］	田莹,张国城,吴丹,等.生物气溶胶监测仪生物计数评价装置的搭建和方法研究［J］.计量学报,2021,42(12):1687-1692.
［14］	陈福民,付建涛,张文阁.JJG846—2015《粉尘浓度测量仪检定规程》解读［J］.中国计量,2016(4):125-126.
［2］	Després V, Huffman J, Burrows S, et al. Primary biological aerosol particles in the atmosphere: a review［J］. Tellus B: Chemical and Physical Meteorology, 2012, 64(1):1-58
［3］	Douglas P, Robertson S, Gay R, et al. A systematic review of the public health risks of bioaerosols from intensive farming［J］. International Journal of Hygiene and Environmental Health, 2018, 221(2): 134-173.
［5］	Xu Z Q, Wu Y, Shen F X, et al. Bioaerosol Science, Technology, and Engineering: Past, Present, and Future［J］. Aerosol Science and Technology, 2011, 45(11):1337-1349.
［9］	Brosseau L, Vesley D, Rice N, et al. Differences in Detected Fluorescence Among Several Bacterial Species Measured with a Direct-Reading Particle Sizer and Fluorescence Detector［J］. Aerosol Science and Technology, 2000, 32(6):545-558.
［10］	Phlker C, Huffman J A, Pschl U. Autofluorescence of atmospheric bioaerosols-fluorescent biomolecules and potential interferences［J］. Atmospheric Measurement Techniques, 2012, 5(29): 37-71.
	Pan Y T, Zhang G C, Liu J Q, et al. Development and Application of Fluorescent Microsphere Reference Material for Calibration of Bioaerosol Monitor Instrument［J］. Environmental Monitoring in China, 2021,37(4):192-198.
［15］	Kanaani H, Hargreaves M, Smith J, et al. Performance of UVAPS with respect to detection of airborne fungi［J］. Journal of Aerosol Science, 2007, 39(2):175-189
［17］	李洪臣,杨秀艳.使用血细胞计数板测定微生物数量实验的改进［J］.生物学通报,2007(7):22.
	Zheng Y H, Li J, Chen H X, et al. Bioaerosol research: Yesterday, today and tomorrow［J］. Chinese Science Bulletin, 2018, 63(10):878-894.
	Pan Y T, Zhang G C, Yang Z Q, et al. Research on calibration method of bioaerosol monitor instrument［J］. China Measurement and Test, 2020, 46(10):18-22.
［16］	Kanaani H, Hargreaves M, Ristovski Z, et al. Performance assessment of UVAPS: Influence of fungal spore age and air exposure［J］. Journal of Aerosol Science, 2006, 38(1):83-96