The effect of exhalation flow on endogenous particle emission and phospholipid composition

[Display omitted] •Exhaled particles have potential as a tool for monitoring respiratory disease.•This potential would increase if particle formation was better understood.•Maximal forced exhalation generate particles mainly in central or upper airways.•Deep exhalations and inhalations generate part...

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Published inRespiratory physiology & neurobiology Vol. 243; pp. 39 - 46
Main Authors Larsson, Per, Bake, Björn, Wallin, Anita, Hammar, Oscar, Almstrand, Ann-Charlotte, Lärstad, Mona, Ljungström, Evert, Mirgorodskaya, Ekaterina, Olin, Anna-Carin
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 01.09.2017
Subjects
1994
Adult
Aged
Airway re-opening
asthma
Breath Tests
clearance
cough
Cough - metabolism
Cough - physiopathology
european respiratory journal
Exhalation - physiology
Exhaled particles
Female
Forced expiration
Functional Residual Capacity
Health Sciences
Healthy Volunteers
Humans
Hälsovetenskap
Inhalation
limitation
lung
Lung Volume Measurements
Male
Mass Spectrometry
mass-spectrometric analysis
Medical Education
metabolism
Middle Aged
Non-invasive technique
p1616
PEx
phosphatidylcholine
Phospholipids - analysis
Physiology
Pulmonary surfactant
Pulmonary Surfactants - analysis
Pulmonary/Respiratory
Respiration
Respiratory System
Respiratory System - metabolism
sanctis gt
surfactant protein-a
Non-invasive technique
PEx
Exhaled particles
Forced expiration
Pulmonary surfactant
Airway re-opening
Online AccessGet full text
ISSN1569-9048
1878-1519
1878-1519
DOI10.1016/j.resp.2017.05.003

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Abstract [Display omitted] •Exhaled particles have potential as a tool for monitoring respiratory disease.•This potential would increase if particle formation was better understood.•Maximal forced exhalation generate particles mainly in central or upper airways.•Deep exhalations and inhalations generate particles mainly in small airways.•Particles from small airways contain a higher concentration of alveolar surfactant. Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the airway re-opening mechanism. Forced exhalations are assumed to generate particles in central airways by mechanisms associated with high air velocities. To increase knowledge on how and where particles are formed, different breathing manoeuvres were compared in 11 healthy volunteers. Particles in the 0.41–4.55μm diameter range were characterised and sampled. The surfactant lipid dipalmitoylphosphatidylcholine (DPPC) was quantified by mass spectrometry. The mass of exhaled particles increased by 150% (95% CI 10–470) for the forced exhalation and by 470% (95% CI 150–1190) for the airway re-opening manoeuvre, compared to slow exhalations. DPPC weight percent concentration (wt%) in particles was 2.8wt% (95%CI 1.4–4.2) and 9.4wt% (95%CI 8.0–10.8) for the forced and the airway re-opening manoeuvres, respectively. In conclusion, forced exhalation and airway re-opening manoeuvres generate particles from different airway regions having different DPPC concentration.
AbstractList [Display omitted] •Exhaled particles have potential as a tool for monitoring respiratory disease.•This potential would increase if particle formation was better understood.•Maximal forced exhalation generate particles mainly in central or upper airways.•Deep exhalations and inhalations generate particles mainly in small airways.•Particles from small airways contain a higher concentration of alveolar surfactant. Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the airway re-opening mechanism. Forced exhalations are assumed to generate particles in central airways by mechanisms associated with high air velocities. To increase knowledge on how and where particles are formed, different breathing manoeuvres were compared in 11 healthy volunteers. Particles in the 0.41–4.55μm diameter range were characterised and sampled. The surfactant lipid dipalmitoylphosphatidylcholine (DPPC) was quantified by mass spectrometry. The mass of exhaled particles increased by 150% (95% CI 10–470) for the forced exhalation and by 470% (95% CI 150–1190) for the airway re-opening manoeuvre, compared to slow exhalations. DPPC weight percent concentration (wt%) in particles was 2.8wt% (95%CI 1.4–4.2) and 9.4wt% (95%CI 8.0–10.8) for the forced and the airway re-opening manoeuvres, respectively. In conclusion, forced exhalation and airway re-opening manoeuvres generate particles from different airway regions having different DPPC concentration.
Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the airway re-opening mechanism. Forced exhalations are assumed to generate particles in central airways by mechanisms associated with high air velocities. To increase knowledge on how and where particles are formed, different breathing manoeuvres were compared in 11 healthy volunteers. Particles in the 0.41-4.55μm diameter range were characterised and sampled. The surfactant lipid dipalmitoylphosphatidylcholine (DPPC) was quantified by mass spectrometry. The mass of exhaled particles increased by 150% (95% CI 10-470) for the forced exhalation and by 470% (95% CI 150-1190) for the airway re-opening manoeuvre, compared to slow exhalations. DPPC weight percent concentration (wt%) in particles was 2.8wt% (95%CI 1.4-4.2) and 9.4wt% (95%CI 8.0-10.8) for the forced and the airway re-opening manoeuvres, respectively. In conclusion, forced exhalation and airway re-opening manoeuvres generate particles from different airway regions having different DPPC concentration.
Graphical abstract
Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the airway re-opening mechanism. Forced exhalations are assumed to generate particles in central airways by mechanisms associated with high air velocities. To increase knowledge on how and where particles are formed, different breathing manoeuvres were compared in 11 healthy volunteers. Particles in the 0.41-4.55 mu m diameter range were characterised and sampled. The surfactant lipid dipalmitoylphosphatidylcholine (DPPC) was quantified by mass spectrometry. The mass of exhaled particles increased by 150% (95% CI 10-470) for the forced exhalation and by 470% (95% CI 150-1190) for the airway re-opening manoeuvre, compared to slow exhalations. DPPC weight percent concentration (wt%) in particles was 2.8 wt% (95%CI 1.4-4.2) and 9.4 wt% (95%CI 8.0-10.8) for the forced and the airway re-opening manoeuvres, respectively. In conclusion, forced exhalation and airway re-opening manoeuvres generate particles from different airway regions having different DPPC concentration.
Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the airway re-opening mechanism. Forced exhalations are assumed to generate particles in central airways by mechanisms associated with high air velocities. To increase knowledge on how and where particles are formed, different breathing manoeuvres were compared in 11 healthy volunteers. Particles in the 0.41-4.55μm diameter range were characterised and sampled. The surfactant lipid dipalmitoylphosphatidylcholine (DPPC) was quantified by mass spectrometry. The mass of exhaled particles increased by 150% (95% CI 10-470) for the forced exhalation and by 470% (95% CI 150-1190) for the airway re-opening manoeuvre, compared to slow exhalations. DPPC weight percent concentration (wt%) in particles was 2.8wt% (95%CI 1.4-4.2) and 9.4wt% (95%CI 8.0-10.8) for the forced and the airway re-opening manoeuvres, respectively. In conclusion, forced exhalation and airway re-opening manoeuvres generate particles from different airway regions having different DPPC concentration.Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the airway re-opening mechanism. Forced exhalations are assumed to generate particles in central airways by mechanisms associated with high air velocities. To increase knowledge on how and where particles are formed, different breathing manoeuvres were compared in 11 healthy volunteers. Particles in the 0.41-4.55μm diameter range were characterised and sampled. The surfactant lipid dipalmitoylphosphatidylcholine (DPPC) was quantified by mass spectrometry. The mass of exhaled particles increased by 150% (95% CI 10-470) for the forced exhalation and by 470% (95% CI 150-1190) for the airway re-opening manoeuvre, compared to slow exhalations. DPPC weight percent concentration (wt%) in particles was 2.8wt% (95%CI 1.4-4.2) and 9.4wt% (95%CI 8.0-10.8) for the forced and the airway re-opening manoeuvres, respectively. In conclusion, forced exhalation and airway re-opening manoeuvres generate particles from different airway regions having different DPPC concentration.
Author Bake, Björn
Wallin, Anita
Almstrand, Ann-Charlotte
Lärstad, Mona
Mirgorodskaya, Ekaterina
Olin, Anna-Carin
Hammar, Oscar
Larsson, Per
Ljungström, Evert
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  surname: Larsson
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  organization: Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Institute of Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
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  organization: Unit of Respiratory Medicine and Allergy, Department of Internal Medicine, Institute of medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
– sequence: 3
  givenname: Anita
  surname: Wallin
  fullname: Wallin, Anita
  organization: Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Institute of Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
– sequence: 4
  givenname: Oscar
  surname: Hammar
  fullname: Hammar, Oscar
  organization: AstraZeneca, R&D, Pepparedsleden 1, 431 50 Mölndal, Sweden
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  givenname: Ann-Charlotte
  surname: Almstrand
  fullname: Almstrand, Ann-Charlotte
  organization: Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Institute of Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
– sequence: 6
  givenname: Mona
  surname: Lärstad
  fullname: Lärstad, Mona
  organization: Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Institute of Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
– sequence: 7
  givenname: Evert
  surname: Ljungström
  fullname: Ljungström, Evert
  organization: Atmospheric Science, Department of Chemistry and Molecular Biology, University of Gothenburg, Gothenburg, Sweden
– sequence: 8
  givenname: Ekaterina
  surname: Mirgorodskaya
  fullname: Mirgorodskaya, Ekaterina
  organization: Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Institute of Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
– sequence: 9
  givenname: Anna-Carin
  surname: Olin
  fullname: Olin, Anna-Carin
  organization: Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Institute of Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden
BackLink https://www.ncbi.nlm.nih.gov/pubmed/28502893$$D View this record in MEDLINE/PubMed
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Keywords Non-invasive technique
PEx
Exhaled particles
Forced expiration
Pulmonary surfactant
Airway re-opening
Language English
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Copyright © 2017 The Authors. Published by Elsevier B.V. All rights reserved.
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Snippet [Display omitted] •Exhaled particles have potential as a tool for monitoring respiratory disease.•This potential would increase if particle formation was...
Graphical abstract
Exhaled particles constitute a micro-sample of respiratory tract lining fluid. Inhalations from low lung volumes generate particles in small airways by the...
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StartPage 39
SubjectTerms 1994
Adult
Aged
Airway re-opening
asthma
Breath Tests
clearance
cough
Cough - metabolism
Cough - physiopathology
european respiratory journal
Exhalation - physiology
Exhaled particles
Female
Forced expiration
Functional Residual Capacity
Health Sciences
Healthy Volunteers
Humans
Hälsovetenskap
Inhalation
limitation
lung
Lung Volume Measurements
Male
Mass Spectrometry
mass-spectrometric analysis
Medical Education
metabolism
Middle Aged
Non-invasive technique
p1616
PEx
phosphatidylcholine
Phospholipids - analysis
Physiology
Pulmonary surfactant
Pulmonary Surfactants - analysis
Pulmonary/Respiratory
Respiration
Respiratory System
Respiratory System - metabolism
sanctis gt
surfactant protein-a
Title The effect of exhalation flow on endogenous particle emission and phospholipid composition
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https://dx.doi.org/10.1016/j.resp.2017.05.003
https://www.ncbi.nlm.nih.gov/pubmed/28502893
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