Chemical Analysis of Deep-Lung Fluid Derived from Exhaled Breath Particles

Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for...

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Published in	Analytical chemistry (Washington) Vol. 97; no. 7; pp. 4128 - 4136
Main Authors	Kakeshpour, Tayeb, Louis, John M., Walter, Peter J., Bax, Ad
Format	Journal Article
Language	English
Published	United States American Chemical Society 25.02.2025
Subjects	Aerosols Aerosols - analysis Air sampling Analytical chemistry Biomarkers Biomarkers - analysis Blood plasma Breath Tests - methods Bronchoalveolar Lavage Fluid - chemistry Bronchus Chemical analysis Collection condensates Contamination Decoupling Dehydration derivatization Dilution Exhalation Fluid filters Humans Lavage Lipids Lung - chemistry Lung - metabolism Lungs Magnetic Resonance Spectroscopy Mass spectrometry Mass spectroscopy Microreactors NMR Nuclear magnetic resonance Particle Size Phosphocholine phosphorylcholine Reagents Respiration Samplers Sampling Urea
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ISSN	0003-2700 1520-6882 1520-6882
DOI	10.1021/acs.analchem.4c06422

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Abstract	Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using 23Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ∼ 5.5 based on known Na levels in lung fluid. 1H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying subnanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values.
AbstractList	Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ∼ 5.5 based on known Na levels in lung fluid. H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying subnanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values. Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using 23Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ∼ 5.5 based on known Na levels in lung fluid. 1H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying subnanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values. Breath particles generated deep within the lung provide non-invasive access to sampling non-volatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using 23 Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ~5.5 based on known Na levels in lung fluid. 1 H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying sub-nanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values. Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using 23Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ∼ 5.5 based on known Na levels in lung fluid. 1H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying subnanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values.Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using 23Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ∼ 5.5 based on known Na levels in lung fluid. 1H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying subnanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values. Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background contamination, their variable production among subjects, together with a huge unknown dilution when using the common breath condensate method for collection has limited their use for quantitative biomarker analysis. Instead, we first capture and dry the particles in a flexible chamber followed by accurate optical particle characterization during their collection for chemical analysis. By decoupling breathing and aerosol sampling airflows, this sequential approach not only accommodates all types of breathing routines but also enables the use of a variety of aerosol samplers for downstream biomarker analysis. Using ²³Na NMR, we measured 0.66 M Na in dry particles collected on a filter, which suggests that dehydration reduces their volume by a factor of ∼ 5.5 based on known Na levels in lung fluid. ¹H NMR revealed 0.36 and 0.68 M phosphocholine lipids in dried particles collected from two volunteers, presumably enriched to these levels relative to literature values derived from bronchoalveolar lavage fluid due to the film-bursting mechanism that underlies breath particle generation. Decoupling of breath collection and aerosol capture enabled the design of an impactor sampler with 72% efficiency. This impactor minimizes reagent and handling-related contamination associated with traditional filters by collecting dry particles directly in a microreactor for subsequent derivatization and quantification by mass spectrometry. The method is demonstrated by quantifying subnanogram amounts of urea from breath particles, corresponding to lung fluid urea concentrations consistent with literature blood plasma values.
Author	Kakeshpour, Tayeb Bax, Ad Louis, John M. Walter, Peter J.
AuthorAffiliation	Laboratory of Chemical Physics National Institute of Diabetes and Digestive and Kidney Diseases, Clinical Mass Spectrometry Core National Institutes of Health
AuthorAffiliation_xml	– name: National Institute of Diabetes and Digestive and Kidney Diseases, Clinical Mass Spectrometry Core – name: National Institutes of Health – name: Laboratory of Chemical Physics – name: 1 Laboratory of Chemical Physics, National Institute of Diabetes and Digestive and Kidney Diseases, National Institutes of Health, Bethesda, MD, USA – name: 2 National Institute of Diabetes and Digestive and Kidney Diseases, Clinical Mass Spectrometry Core, National Institutes of Health, Bethesda, MD, USA
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Snippet	Breath particles generated deep within the lung provide noninvasive access to sampling nonvolatiles in peripheral airway lining fluid. However, background... Breath particles generated deep within the lung provide non-invasive access to sampling non-volatiles in peripheral airway lining fluid. However, background...
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SubjectTerms	Aerosols Aerosols - analysis Air sampling Analytical chemistry Biomarkers Biomarkers - analysis Blood plasma Breath Tests - methods Bronchoalveolar Lavage Fluid - chemistry Bronchus Chemical analysis Collection condensates Contamination Decoupling Dehydration derivatization Dilution Exhalation Fluid filters Humans Lavage Lipids Lung - chemistry Lung - metabolism Lungs Magnetic Resonance Spectroscopy Mass spectrometry Mass spectroscopy Microreactors NMR Nuclear magnetic resonance Particle Size Phosphocholine phosphorylcholine Reagents Respiration Samplers Sampling Urea
Title	Chemical Analysis of Deep-Lung Fluid Derived from Exhaled Breath Particles
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