Acta Optica Sinica, Volume. 42, Issue 21, 2130001(2022)
FeNO Detection Method Based on Highly Sensitive Mid-Infrared Absorption Spectroscopy
References(38)
[1] Francesco F D, Fuoco R, Trivella M G et al. Breath analysis: trends in techniques and clinical applications[J]. Microchemical Journal, 79, 405-410(2005).
[2] Lourenço C, Turner C. Breath analysis in disease diagnosis: methodological considerations and applications[J]. Metabolites, 4, 465-498(2014).
[3] de Lacy C B, Amann A, Al-Kateb H et al. A review of the volatiles from the healthy human body[J]. Journal of Breath Research, 8, 014001(2014).
[4] Henderson B, Khodabakhsh A, Metsälä M et al. Laser spectroscopy for breath analysis: towards clinical implementation[J]. Applied Physics B, 124, 161(2018).
[5] Amann A, Costello B, Miekisch W et al. The human volatilome: volatile organic compounds (VOCs) in exhaled breath, skin emanations, urine, feces and saliva[J]. Journal of Breath Research, 8, 034001(2014).
[6] Oertel P, Küntzel A, Reinhold P et al. Continuous real-time breath analysis in ruminants: effect of eructation on exhaled VOC profiles[J]. Journal of Breath Research, 12, 036014(2018).
[7] Risby T H, Tittel F K. Current status of midinfrared quantum and interband cascade lasers for clinical breath analysis[J]. Optical Engineering, 49, 111123(2010).
[8] Carpagnano G E, Turchiarelli V, Spanevello A et al. Aging and airway inflammation[J]. Aging Clinical and Experimental Research, 25, 239-245(2013).
[9] Roller C, Namjou K, Jeffers J et al. Simultaneous NO and CO2 measurement in human breath with a single IV-VI mid-infrared laser[J]. Optics Letters, 27, 107-109(2002).
[10] Gao J, Chen Z C, Jie X et al. Both fractional exhaled nitric oxide and sputum eosinophil were associated with uncontrolled asthma[J]. Journal of Asthma and Allergy, 11, 73-79(2018).
[11] Dweik R A, Boggs P B, Erzurum S C et al. An official ATS clinical practice guideline: interpretation of exhaled nitric oxide levels (FENO) for clinical applications[J]. American Journal of Respiratory and Critical Care Medicine, 184, 602-615(2011).
[12] Ahovuo-Saloranta A, Csonka P, Lehtimäki L. Basic characteristics and clinical value of FeNO in smoking asthmatics: a systematic review[J]. Journal of Breath Research, 13, 034003(2019).
[13] Mandon J, Högman M, Merkus P J F M et al. Exhaled nitric oxide monitoring by quantum cascade laser: comparison with chemiluminescent and electrochemical sensors[J]. Journal of Biomedical Optics, 17, 017003(2012).
[14] Dunlea E J, Herndon S C, Nelson D D et al. Evaluation of nitrogen dioxide chemiluminescence monitors in a polluted urban environment[J]. Atmospheric Chemistry and Physics Discussions, 7, 2691-2704(2007).
[15] Brooks C R, Brogan S B M, van Dalen C J et al. Measurement of exhaled nitric oxide in a general population sample: a comparison of the Medisoft HypAir FENO and Aerocrine NIOX analyzers[J]. Journal of Asthma, 48, 324-328(2011).
[16] Mandon J, Högman M, Merkus P J F M et al. Quantum cascade laser for breath analysis: application to nitric oxide monitoring[C], LM3B.6(2012).
[17] Sun L Q, Zou M L, Wang X. Application of tunable diode laser absorption spectroscopy in breath diagnosis[J]. Chinese Journal of Lasers, 48, 1511001(2021).
[18] Roller C, Namjou K, Jeffers J D et al. Nitric oxide breath testing by tunable-diode laser absorption spectroscopy: application in monitoring respiratory inflammation[J]. Applied Optics, 41, 6018-6029(2002).
[19] McManus J B, Shorter J H, Nelson D D et al. Pulsed quantum cascade laser instrument with compact design for rapid, high sensitivity measurements of trace gases in air[J]. Applied Physics B, 92, 387-392(2008).
[20] Shorter J H, Nelson D D, McManus J B et al. Multicomponent breath analysis with infrared absorption using room-temperature quantum cascade lasers[J]. IEEE Sensors Journal, 10, 76-84(2009).
[21] Ai Y K, Li J, Li Q Y et al. Cavity ringdown spectroscopy of nitric oxide in the ultraviolet region for human breath test[J]. Journal of Breath Research, 14, 037101(2020).
[22] Ventrillard I, Gorrotxategi-Carbajo P, Romanini D. Part per trillion nitric oxide measurement by optical feedback cavity-enhanced absorption spectroscopy in the mid-infrared[J]. Applied Physics B, 123, 180(2017).
[23] Huang Y Y, Li A, Qin M et al. Nitrogen oxides spatial distribution and emissions with mobile multi-axis differential optical absorption spectroscopy in Wuhan city[J]. Acta Optica Sinica, 41, 1030002(2021).
[24] Chen D Y, Zhou L, Yang F M et al. Application progress of cavity-enhanced absorption spectroscopy (CEAS) in atmospheric environment research[J]. Spectroscopy and Spectral Analysis, 41, 2688-2695(2021).
[25] Li M Y, Wang F, Zhang Y Q. Measurement of nitric oxide with low concentration based on mid-infrared laser absorption spectroscopy[J]. Laser & Optoelectronics Progress, 55, 053002(2018).
[26] Zha L F, Pan H M, Fei X P et al. Diagnostic value of exhaled nitric oxide in bronchial asthma[J]. Contemporary Medicine, 26, 146-147(2020).
[27] Wang T Y, Shang Y X, Zhang H. Diagnostic values of fractional exhaled nitric oxide for typical bronchial asthma and cough variant asthma in children[J]. Chinese Journal of Contemporary Pediatrics, 17, 800-805(2015).
[28] Zhang S R, An Z B, Zhang Y et al. Determination of fractional exhaled nitric oxide in elderly patients with asthma-COPD overlap syndrome[J]. Journal of Clinical Pulmonary Medicine, 21, 217-219(2016).
[29] Zhang H Q, Zhang J J, Liu Y D et al. Application of pulmonary function and fractional exhaled nitric oxide tests in the standardized management of bronchial asthma in children[J]. Chinese Journal of Contemporary Pediatrics, 19, 419-424(2017).
[30] Zhou S, Han Y L, Li B C. Pressure optimization of an EC-QCL based cavity ring-down spectroscopy instrument for exhaled NO detection[J]. Applied Physics B, 124, 27(2018).
[31] Rieker G B, Jeffries J B, Hanson R K. Calibration-free wavelength-modulation spectroscopy for measurements of gas temperature and concentration in harsh environments[J]. Applied Optics, 48, 5546-5560(2009).
[32] Li H J, Rieker G B, Liu X et al. Extension of wavelength-modulation spectroscopy to large modulation depth for diode laser absorption measurements in high-pressure gases[J]. Applied Optics, 45, 1052-1061(2006).
[33] McCurdy M R, Bakhirkin Y A, Wysocki G et al. Performance of an exhaled nitric oxide and carbon dioxide sensor using quantum cascade laser-based integrated cavity output spectroscopy[J]. Journal of Biomedical Optics, 12, 034034(2007).
[34] Kosterev A A, Malinovsky A L, Tittel F K et al. Cavity ringdown spectroscopic detection of nitric oxide with a continuous-wave quantum-cascade laser[J]. Applied Optics, 40, 5522-5529(2001).
[35] Petralia L S, Bahl A, Peverall R et al. Accurate real-time FENO expirograms using complementary optical sensors[J]. Journal of Breath Research, 14, 047102(2020).
[36] Sun J, Ding J Y, Liu N W et al. Detection of multiple chemicals based on external cavity quantum cascade laser spectroscopy[J]. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 191, 532-538(2018).
[37] Liu N W, Zhou S, Zhang L et al. Standoff detection of VOCs using external cavity quantum cascade laser spectroscopy[J]. Laser Physics Letters, 15, 085701(2018).
[38] Sun J. Laser spectroscopy based on an external cavity quantum cascade laser[D](2018).
Tools
Get Citation
Copy Citation Text
Zhihao Zhao, Bing Chen, Hao Deng, Guosheng Ma, An Huang, Ying Liu, Ruifeng Kan, Zhenyu Yuan. FeNO Detection Method Based on Highly Sensitive Mid-Infrared Absorption Spectroscopy[J]. Acta Optica Sinica, 2022, 42(21): 2130001
Paper Information
Category: Spectroscopy
Received: Feb. 24, 2022
Accepted: May. 11, 2022
Published Online: Nov. 4, 2022
The Author Email: Kan Ruifeng (yuanzhenyu@ise.neu.edu.cn), Yuan Zhenyu (kanruifeng@aiofm.ac.cn)
© Copyright 2018-2021 | Chinese Laser Press.
All Rights Reserved 沪ICP备15018463号-20