Peripheral and proximal lung ventilation in asthma: Short-term variation and response to bronchodilator inhalation

The relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs. Our aims were t...

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Published in	Journal of allergy and clinical immunology Vol. 147; no. 6; pp. 2154 - 2161.e6
Main Authors	Marshall, Helen, Kenworthy, J. Chris, Horn, Felix C., Thomas, Steven, Swift, Andrew J., Siddiqui, Salman, Brightling, Christopher E., Wild, Jim M.
Format	Journal Article
Language	English
Published	United States Elsevier Inc 01.06.2021 Elsevier Limited
Subjects	Administration, Inhalation Airway management Asthma Asthma - diagnosis Asthma - drug therapy Asthma - physiopathology Bias Bronchodilator Agents - administration & dosage Bronchodilator Agents - therapeutic use bronchodilator response Bronchodilators Defects Humans Hyperpolarized gas MRI Inhalation Lungs Magnetic resonance imaging Magnetic Resonance Imaging - methods peripheral proximal Pulmonary Ventilation Reproducibility Reproducibility of Results Respiratory Function Tests Severity of Illness Index Spirometry Spirometry - methods Treatment Outcome Values Ventilation VV peripheral VDP MRI reproducibility ventilation asthma 2D FVC MCID Hyperpolarized gas MRI bronchodilator response proximal PET LOA TLV
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ISSN	0091-6749 1097-6825 1097-6825
DOI	10.1016/j.jaci.2020.11.035

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Abstract	The relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs. Our aims were to (1) quantify the baseline reproducibility of VV%, (2) assess the ventilation distribution between the proximal and peripheral lungs, and (3) investigate regional ventilation response to bronchodilator inhalation in a cohort of patients with asthma. A total of 33 patients with poorly controlled, moderate-to-severe asthma were scanned with hyperpolarized 3He MRI. Two image data sets were acquired at baseline, and 1 image data set was acquired after bronchodilator inhalation. Images were divided into proximal and peripheral regions for analysis. Bland-Altman analysis showed strong reproducibility of VV% (bias = 0.12%; LOA = –1.86% to 2.10%). VV% variation at baseline was greater in the periphery than in the proximal lung. The proximal lung was better ventilated than the peripheral lung. Ventilation increased significantly in response to bronchodilator inhalation, globally and regionally, and the ventilation increase in response to bronchodilator inhalation was greater in the peripheral lung than in the proximal lung. Hyperpolarized gas MRI was more sensitive to changes in response to bronchodilator inhalation (58%) than spirometry (33%). The peripheral lung showed reduced ventilation and a greater response to bronchodilator inhalation than the proximal lung. The high level of baseline reproducibility and sensitivity of hyperpolarized gas MRI to bronchodilator reversibility suggests that it is suitable for low subject number studies of therapy response. [Display omitted]
AbstractList	The relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs. Our aims were to (1) quantify the baseline reproducibility of VV%, (2) assess the ventilation distribution between the proximal and peripheral lungs, and (3) investigate regional ventilation response to bronchodilator inhalation in a cohort of patients with asthma. A total of 33 patients with poorly controlled, moderate-to-severe asthma were scanned with hyperpolarized He MRI. Two image data sets were acquired at baseline, and 1 image data set was acquired after bronchodilator inhalation. Images were divided into proximal and peripheral regions for analysis. Bland-Altman analysis showed strong reproducibility of VV% (bias = 0.12%; LOA = -1.86% to 2.10%). VV% variation at baseline was greater in the periphery than in the proximal lung. The proximal lung was better ventilated than the peripheral lung. Ventilation increased significantly in response to bronchodilator inhalation, globally and regionally, and the ventilation increase in response to bronchodilator inhalation was greater in the peripheral lung than in the proximal lung. Hyperpolarized gas MRI was more sensitive to changes in response to bronchodilator inhalation (58%) than spirometry (33%). The peripheral lung showed reduced ventilation and a greater response to bronchodilator inhalation than the proximal lung. The high level of baseline reproducibility and sensitivity of hyperpolarized gas MRI to bronchodilator reversibility suggests that it is suitable for low subject number studies of therapy response. BackgroundThe relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs.ObjectiveOur aims were to (1) quantify the baseline reproducibility of VV%, (2) assess the ventilation distribution between the proximal and peripheral lungs, and (3) investigate regional ventilation response to bronchodilator inhalation in a cohort of patients with asthma.MethodsA total of 33 patients with poorly controlled, moderate-to-severe asthma were scanned with hyperpolarized 3He MRI. Two image data sets were acquired at baseline, and 1 image data set was acquired after bronchodilator inhalation. Images were divided into proximal and peripheral regions for analysis.ResultsBland-Altman analysis showed strong reproducibility of VV% (bias = 0.12%; LOA = –1.86% to 2.10%). VV% variation at baseline was greater in the periphery than in the proximal lung. The proximal lung was better ventilated than the peripheral lung. Ventilation increased significantly in response to bronchodilator inhalation, globally and regionally, and the ventilation increase in response to bronchodilator inhalation was greater in the peripheral lung than in the proximal lung. Hyperpolarized gas MRI was more sensitive to changes in response to bronchodilator inhalation (58%) than spirometry (33%).ConclusionThe peripheral lung showed reduced ventilation and a greater response to bronchodilator inhalation than the proximal lung. The high level of baseline reproducibility and sensitivity of hyperpolarized gas MRI to bronchodilator reversibility suggests that it is suitable for low subject number studies of therapy response. The relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs.BACKGROUNDThe relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs.Our aims were to (1) quantify the baseline reproducibility of VV%, (2) assess the ventilation distribution between the proximal and peripheral lungs, and (3) investigate regional ventilation response to bronchodilator inhalation in a cohort of patients with asthma.OBJECTIVEOur aims were to (1) quantify the baseline reproducibility of VV%, (2) assess the ventilation distribution between the proximal and peripheral lungs, and (3) investigate regional ventilation response to bronchodilator inhalation in a cohort of patients with asthma.A total of 33 patients with poorly controlled, moderate-to-severe asthma were scanned with hyperpolarized 3He MRI. Two image data sets were acquired at baseline, and 1 image data set was acquired after bronchodilator inhalation. Images were divided into proximal and peripheral regions for analysis.METHODSA total of 33 patients with poorly controlled, moderate-to-severe asthma were scanned with hyperpolarized 3He MRI. Two image data sets were acquired at baseline, and 1 image data set was acquired after bronchodilator inhalation. Images were divided into proximal and peripheral regions for analysis.Bland-Altman analysis showed strong reproducibility of VV% (bias = 0.12%; LOA = -1.86% to 2.10%). VV% variation at baseline was greater in the periphery than in the proximal lung. The proximal lung was better ventilated than the peripheral lung. Ventilation increased significantly in response to bronchodilator inhalation, globally and regionally, and the ventilation increase in response to bronchodilator inhalation was greater in the peripheral lung than in the proximal lung. Hyperpolarized gas MRI was more sensitive to changes in response to bronchodilator inhalation (58%) than spirometry (33%).RESULTSBland-Altman analysis showed strong reproducibility of VV% (bias = 0.12%; LOA = -1.86% to 2.10%). VV% variation at baseline was greater in the periphery than in the proximal lung. The proximal lung was better ventilated than the peripheral lung. Ventilation increased significantly in response to bronchodilator inhalation, globally and regionally, and the ventilation increase in response to bronchodilator inhalation was greater in the peripheral lung than in the proximal lung. Hyperpolarized gas MRI was more sensitive to changes in response to bronchodilator inhalation (58%) than spirometry (33%).The peripheral lung showed reduced ventilation and a greater response to bronchodilator inhalation than the proximal lung. The high level of baseline reproducibility and sensitivity of hyperpolarized gas MRI to bronchodilator reversibility suggests that it is suitable for low subject number studies of therapy response.CONCLUSIONThe peripheral lung showed reduced ventilation and a greater response to bronchodilator inhalation than the proximal lung. The high level of baseline reproducibility and sensitivity of hyperpolarized gas MRI to bronchodilator reversibility suggests that it is suitable for low subject number studies of therapy response. The relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution 3-dimensional images of ventilation distribution that can be quantified by the ventilated volume percentage (VV%) of the lungs. Our aims were to (1) quantify the baseline reproducibility of VV%, (2) assess the ventilation distribution between the proximal and peripheral lungs, and (3) investigate regional ventilation response to bronchodilator inhalation in a cohort of patients with asthma. A total of 33 patients with poorly controlled, moderate-to-severe asthma were scanned with hyperpolarized 3He MRI. Two image data sets were acquired at baseline, and 1 image data set was acquired after bronchodilator inhalation. Images were divided into proximal and peripheral regions for analysis. Bland-Altman analysis showed strong reproducibility of VV% (bias = 0.12%; LOA = –1.86% to 2.10%). VV% variation at baseline was greater in the periphery than in the proximal lung. The proximal lung was better ventilated than the peripheral lung. Ventilation increased significantly in response to bronchodilator inhalation, globally and regionally, and the ventilation increase in response to bronchodilator inhalation was greater in the peripheral lung than in the proximal lung. Hyperpolarized gas MRI was more sensitive to changes in response to bronchodilator inhalation (58%) than spirometry (33%). The peripheral lung showed reduced ventilation and a greater response to bronchodilator inhalation than the proximal lung. The high level of baseline reproducibility and sensitivity of hyperpolarized gas MRI to bronchodilator reversibility suggests that it is suitable for low subject number studies of therapy response. [Display omitted]
Author	Swift, Andrew J. Siddiqui, Salman Kenworthy, J. Chris Horn, Felix C. Marshall, Helen Thomas, Steven Brightling, Christopher E. Wild, Jim M.
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CitedBy_id	crossref_primary_10_1016_j_jaip_2021_03_015 crossref_primary_10_1183_13993003_02130_2021 crossref_primary_10_1016_j_pccm_2023_07_002 crossref_primary_10_3389_fmed_2023_1160292 crossref_primary_10_1186_s12890_024_03451_6 crossref_primary_10_1080_17476348_2023_2237872 crossref_primary_10_1002_jmri_29746 crossref_primary_10_1016_j_jaci_2024_12_1067
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Keywords	VV peripheral VDP MRI reproducibility ventilation asthma 2D FVC MCID Hyperpolarized gas MRI bronchodilator response proximal PET LOA TLV
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Snippet	The relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides high-resolution... BackgroundThe relative involvement of the large and small airways in asthma is not clear. Hyperpolarized gas magnetic resonance imaging (MRI) provides...
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SubjectTerms	Administration, Inhalation Airway management Asthma Asthma - diagnosis Asthma - drug therapy Asthma - physiopathology Bias Bronchodilator Agents - administration & dosage Bronchodilator Agents - therapeutic use bronchodilator response Bronchodilators Defects Humans Hyperpolarized gas MRI Inhalation Lungs Magnetic resonance imaging Magnetic Resonance Imaging - methods peripheral proximal Pulmonary Ventilation Reproducibility Reproducibility of Results Respiratory Function Tests Severity of Illness Index Spirometry Spirometry - methods Treatment Outcome Values Ventilation
Title	Peripheral and proximal lung ventilation in asthma: Short-term variation and response to bronchodilator inhalation
URI	https://www.clinicalkey.com/#!/content/1-s2.0-S0091674920317115 https://dx.doi.org/10.1016/j.jaci.2020.11.035 https://www.ncbi.nlm.nih.gov/pubmed/33309743 https://www.proquest.com/docview/2536433033 https://www.proquest.com/docview/2470025559
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