Abstract
Preserved ratio impaired spirometry (PRISm) is defined by reduced FEV1 with a preserved FEV1/FVC ratio; some individuals with PRISm can also have restrictive ventilatory abnormality. The aim of this study was to clarify clinical features of restrictive and non-restrictive PRISm. In total, 11,246 participants (mean, 49.1 years; range, 35–65 years) from five healthcare centres were included in this study. We evaluated baseline characteristics of participants with restrictive PRISm (FEV1/FVC ≥ 0.7, FEV1 < 80% and FVC < 80%) and non-restrictive PRISm (FEV1/FVC ≥ 0.7, FEV1 < 80% and FVC ≥ 80%), and airflow obstruction (FEV1/FVC < 0.7). We examined the longitudinal risk of developing airflow obstruction by comparing spirometry results at baseline and 5 years post-baseline among 2141 participants. Multivariate analysis demonstrated that a history of asthma or smoking could constitute an independent risk factor for non-restrictive PRISm, and that non-restrictive PRISm was independently associated with the risk of developing airflow obstruction. In contrast, female sex, advanced age, and high BMI, but not history of asthma or smoking, were risk factors for restrictive PRISm. Restrictive PRISm was not associated with the development of airflow obstruction. In conclusion, our results indicate that PRISm can be categorized according to the presence or absence of restrictive abnormality. Non-restrictive PRISm, which does not meet the conventional criteria of obstructive and restrictive ventilatory abnormalities, may be a precursor of chronic obstructive pulmonary disease and merits increased monitoring.
Similar content being viewed by others
Introduction
Preserved ratio impaired spirometry (PRISm) is defined by reduced FEV1 (< 80% of predicted value) with a preserved FEV1/FVC ratio (≥ 0.7), and its prevalence is between 3 and 20%1,2,3,4. PRISm is reported to be a risk factor in the development of COPD and increased respiratory symptoms and mortality; it is also associated with the risk of cardiovascular disease1,2,3,4,5,6. Additionally, previous reports show that PRISm is associated with various characteristics including sex, smoking, age, metabolic syndrome, systemic inflammation, exposure to dust, history of tuberculosis, and asthma1,2,7,8,9. These observations suggest that PRISm might include heterogenous groups of people with increased risk of respiratory disease and systemic comorbidities.
Restrictive ventilatory abnormality, together with obstructive abnormality, is a widely used spirometric criteria10. Restrictive abnormality is associated with increased respiratory symptoms11,12,13 and increased risk of various comorbidities, such as cardiovascular disease, metabolic syndrome, hypertension, stroke, and diabetes14,15,16,17,18,19. PRISm can be divided into two groups according to the presence or absence of a restrictive abnormality (FEV1/FVC ≥ 0.7 and FVC < 80% predicted)15. There may be differences in clinical features between PRISm with or without restrictive abnormality, but there has been no study to investigate them separately.
The aim of this study was to clarify the differences in clinical features between restrictive and non-restrictive PRISm. In this study, we divided individuals with PRISm into two subgroups according to the presence or absence of a restrictive abnormality and examined potential risk factors and longitudinal risk of developing airflow obstruction.
Materials and methods
Study design and study population
This was a survey study of participants who visited one of five healthcare centers in Hiroshima, Japan, between 2007 and 2015 for their annual health check-ups, including spirometry. In total, 12,162 participants aged 35–65 years were enrolled. Participants with histories of lung cancer, lung surgery, pulmonary tuberculosis, tuberculous pleurisy, interstitial pneumonia and participants who submitted incomplete questionnaires were excluded from the analysis (n = 916). The remaining 11,246 study participants were eligible for the cross-sectional analysis (Fig. 1). Of the 11,246 participants, 2141 participants were followed-up with five years post-baseline; these were included in the longitudinal analysis. All participants were informed of the aims of this study and that their participation was entirely voluntary and anonymized. This study was conducted in accordance with the ethical standards established in the Helsinki Declaration of 1975. The Medical Ethics Committee of Hiroshima University approved this study and waived the requirement for obtaining the participants’ signed informed consent (E-M699-1).
Spirometry and classifications
Pre-bronchodilator pulmonary function was measured using portable spirometers (Chest-AC33, Chest HI-801; Chest Co., Tokyo, Japan; FUDAC-77, SP-350; Fukuda Denshi Co., Tokyo, Japan). The Japanese reference values for pulmonary function were used20.
The participants were categorized as follows based on their baseline lung function measurements: no PRISm/airflow obstruction (FEV1/FVC ≥ 0.7 and FEV1 ≥ 80%; n = 10,070), airflow obstruction (FEV1/FVC < 0.7 independent of FVC values; n = 338) and PRISm (FEV1/FVC ≥ 0.7 and FEV1 < 80%; n = 838). Individuals with PRISm were classified according to the presence or absence of restrictive abnormality; these groups were non-restrictive PRISm (FEV1/FVC ≥ 0.7, FEV1 < 80% and FVC ≥ 80%; n = 214) and restrictive PRISm (FEV1/FVC ≥ 0.7, FEV1 < 80% and FVC < 80%; n = 624) (Fig. 2).
Questionnaire
The details of the self-administered questionnaires have been described previously21,22. Smoking habits, underlying respiratory or cardiac disease, exposure to dust or asbestos, and respiratory symptoms were investigated.
Statistical analyses
Comparisons among groups were performed by using the chi-square test for categorical variables and the Kruskal–Wallis test followed by the Bonferroni correction for continuous variables. Univariate and multivariate logistic regression analyses were performed to investigate the clinical predictors of non-restrictive PRISm, restrictive PRISm and airflow obstruction in the cross-sectional analysis. Sex, age, body mass index (BMI), smoking status, and history of asthma were used as independent variables in the multivariate analyses. In the longitudinal analysis, univariate and multivariate logistic regression analyses were performed to examine whether non-restrictive PRISm or restrictive PRISm was a risk factor for development of airflow obstruction. Risk ratio was adjusted for age, sex, BMI, and pack-year. All data analyses were performed using JMP statistical software version 15.1.0 (SAS Institute Inc., Cary, NC, USA).
Results
Baseline characteristics and clinical predictors of the participants in the restrictive and non-restrictive PRISm
The participants with restrictive PRISm were more likely to be older, female, and obese when compared with the participants without PRISm/airflow obstruction (Table 1). The proportion of ever smokers with ≥10 pack-years was significantly higher in the non-restrictive PRISm group than in the restrictive PRISm and no PRISm/airflow obstruction groups. The proportion with a history of asthma was significantly higher in the non-restrictive PRISm than in the no PRISm/airflow obstruction group, but not in the restrictive PRISm group. In the participants with restrictive PRISm, the incidence of cough was significantly higher when compared with the participants without PRISm/airflow obstruction, and there was also a trend toward a higher incidence of breathlessness (p < 0.10). In the participants with non-restrictive PRISm, there was a trend toward a higher incidence of cough, phlegm and breathlessness when compared with the participants without PRISm/airflow obstruction. The mean values of %FEV1 and %FVC were significantly higher, but FEV1/FVC were significantly lower, in the non-restrictive PRISm group than in the restrictive PRISm group (Table 1).
Multivariate logistic analysis showed that history of asthma and smoking were independently associated with non-restrictive PRISm, whereas being of the female sex, having a more advanced age and having a higher BMI were independent risk factors for restrictive PRISm (Table 2).
Transitions of lung function categories and risk factors for the development of airflow obstruction (longitudinal analysis)
The characteristics of the participants in the longitudinal analysis were similar to those of participants in the cross-sectional analysis (Supplementary Table S1). Figure 3 shows the transitions of lung function categories among participants between their first visits, and their visits five years later. A higher proportion of the participants with non-restrictive PRISm transitioned to airflow obstruction compared with the participants without PRISm/airflow obstruction (12.0% and 2.5%, p < 0.017). No significant differences were observed in the proportion of transition to airflow obstruction between the restrictive PRISm and no PRISm/airflow obstruction groups. In participants with restrictive and non-restrictive PRISm, about half transitioned to the no PRISm/airflow obstruction category. Supplementary Figure S1 visually shows the transitions of lung function categories among participants with restrictive and non-restrictive PRISm using the conventional criteria of obstructive and restrictive ventilatory abnormalities. A quarter of participants with non-restrictive PRISm and half of those with restrictive PRISm transitioned to other categories. Univariate and multivariate logistic analysis showed that non-restrictive PRISm, but not restrictive PRISm, was independently associated with the development of airflow obstruction (Table 3; adjusted risk ratio, 4.47; 95% CI, 1.66–12.01; p = 0.003).
Discussion
In the present study, we investigated the clinical features and longitudinal trajectory of lung function for individuals with restrictive and non-restrictive PRISm. Multivariate analysis of background demographics demonstrated that history of asthma and smoking were independently associated with non-restrictive PRISm, while female sex, advanced age, and high BMI were associated with restrictive PRISm. Longitudinal analysis of lung function showed that non-restrictive PRISm, but not restrictive PRISm, was independently associated with development of airflow obstruction. These results indicate that PRISm can be divided into two subgroups according to the presence or absence of restrictive spirometric abnormalities, and non-restrictive PRISm may be associated with increased risk of developing COPD.
The present study demonstrated that non-restrictive PRISm was independently associated with the development of airflow obstruction. Several longitudinal studies have shown that PRISm is associated with the development of airflow obstruction2,3,4,6,23. In the COPDGene study, approximately 25% of the current or ex-smokers with a spirometric finding of PRISm developed airflow obstruction five years later2. In a population-based cohort study at Rotterdam, 33% of individuals with PRISm developed airflow obstruction4. Marott et al. reported that individuals with PRISm between 20 and 40 years old experienced an increased risk of hospital admission for COPD in a 15-years long study6. The present study showed that non-restrictive PRISm, but not restrictive PRISm, is associated with an increased risk of developing airflow obstruction in 5 years. While restrictive PRISm can be classified into restrictive spirometric pattern, non-restrictive PRISm may be classified into normal spirometric pattern by the conventional criteria of obstructive and restrictive ventilatory abnormalities. Non-restrictive PRISm, which is more likely to be underestimated than restrictive PRISm in clinical practice, may be a precursor of COPD and may merit increased monitoring.
The present study also showed that there is a difference in the risk factors for restrictive PRISm and those for non-restrictive PRISm. A history of asthma and smoking were independent risk factors for non-restrictive PRISm, and female sex, advanced age, and high BMI were independent risk factors for restrictive PRISm. Previous population studies have shown that history of asthma and smoking are associated with obstructive ventilatory abnormality, and obesity is associated with restrictive abnormality14,15,21,24,25,26,27,28. Two large population-based European cohorts: ECRHS and SAPALDIA, reported that the incidence of history of asthma and heavy smoker was lower and the incidence of obesity was higher in individuals with restrictive ventilatory abnormality than in those with obstructive abnormality15. The TESAOD study showed that individuals with restrictive ventilatory abnormality were more likely to be female, to be non-smokers, and to not have had asthma, and to have lower IgE levels than those with obstructive abnormality14. The results of the present study indicate that non-restrictive PRISm had similar features to obstructive abnormality, while restrictive PRISm had similar features to restrictive abnormality.
Previous studies have reported that there are several subtypes of PRISm1,4. Wan et al. reported that PRISm was divisible into three subgroups through cluster analysis in observational cross-sectional study: “COPD-subtype,” “Restrictive-subtype,” and “Metabolic-subtype”1. The Rotterdam study reported that PRISm encompassed at least three distinct clinical groups: one with progression to COPD, a second with high cardiovascular burden and early death, and a third with persistent PRISm and normal age-related lung function decline4. These previous reports indicated that individuals with PRISm may be clinically heterogeneous, but the criteria for classifying subtypes in PRISm remained unclear. In this study, we showed that PRISm can be split into two subgroups according to the presence or absence of a restrictive spirometric pattern by assessing their risk factors, baseline lung function, and longitudinal trajectory; one is the restrictive subtype and the other is the obstructive subtype. The pathophysiology of the two types of PRISm remains unclear because detailed examinations, such as computed tomography, post-bronchodilator spirometry, and measurement of total lung capacity, were not performed in this study. However, since non-restrictive PRISm was independently associated with asthma and smoking history, its pathophysiology may encompass intrapulmonary factors, such as airway inflammation, bronchial hyperresponsiveness, and emphysema. In contrast, restrictive PRISm was associated with a high BMI, and thus its pathophysiology may be explained by extrapulmonary factors, such as obesity. The varied pathophysiology may underlie the differences in risk of transition to airflow limitation between the two types of PRISm. Further investigation is warranted to clarify the pathophysiology, incidence of cardiovascular events, and mortality among the two types of PRISm.
In the present study, approximately half of the participants with restrictive and non-restrictive PRISm transitioned to the no PRISm/airflow obstruction category after five years. Previous studies have shown that PRISm is a fluctuating state6,29,30. The Copenhagen City Heart Study showed that more than half of the individuals with PRISm transitioned to normal spirometry after 15 years6. In the cohort study of Japanese patients, one-third of the individuals with PRISm transitioned to normal spirometry after 3 years29. Similar to the previous findings, our results also suggest that PRISm may be a fluctuating state, even if it is classified into two subgroups according to the presence or absence of a restrictive spirometric pattern.
The strengths of our study are the large sample size and the use of multivariate regression to adjust for confounders. However, several limitations should be considered. First, we did not perform post-bronchodilator spirometry because the study population underwent only a general check-up. For the same reason, we did not measure total lung capacity. In the absence of a direct measurement of total lung capacity, it is difficult to evaluate whether the restrictive spirometric pattern actually identifies a true pulmonary restriction31,32,33. A decreased FVC may show a true restrictive spirometric pattern or may reflect airflow obstruction due to air trapping. About 80% of the study participants were male, therefore, gender bias was a limitation of this study. Additionally, we excluded participants who could not be followed-up with 5 years post-initial visit in the longitudinal analysis. This may have led to selection bias. Finally, despite the large sample size of the overall population, there were few individuals who transitioned to airflow obstruction from PRISm.
In conclusion, PRISm can be divided into two subgroups according to the presence or absence of a restrictive spirometric abnormality. One is the restrictive subtype and the other is PRISm without restrictive abnormality; the latter can be classified as normal in the conventional spirometric criteria but is associated with an increased risk of developing airflow obstruction. These findings suggest the need for the stratified management of individuals with PRISm.
Data availability
The datasets used and/or analyzed during the current study are available from the corresponding author upon reasonable request.
References
Wan, E. S. et al. Epidemiology, genetics, and subtyping of preserved ratio impaired spirometry (PRISm) in COPDGene. Respir. Res. 15, 89 (2014).
Wan, E. S. et al. Longitudinal phenotypes and mortality in preserved ratio impaired spirometry in the COPDGene study. Am. J. Respir. Crit. Care Med. 198(11), 1397–1405 (2018).
Park, H. J. et al. Significant predictors of medically diagnosed chronic obstructive pulmonary disease in patients with preserved ratio impaired spirometry: A 3-year cohort study. Respir. Res. 19(1), 185 (2018).
Wijnant, S. R. A. et al. Trajectory and mortality of preserved ratio impaired spirometry: The Rotterdam study. Eur. Respir. J. 55(1), 1901217 (2020).
Adibi, A. & Sadatsafavi, M. Looking at the COPD spectrum through “PRISm”. Eur. Respir. J. 55(1), 1902217 (2020).
Marott, J. L., Ingebrigtsen, T. S., Colak, Y., Vestbo, J. & Lange, P. Trajectory of preserved ratio impaired spirometry: Natural history and long-term prognosis. Am. J. Respir. Crit. Care Med. 204(8), 910–920 (2021).
Kaise, T. et al. Prevalence and characteristics of individuals with preserved ratio impaired spirometry (PRISm) and/or impaired lung function in Japan: The OCEAN study. Int. J. Chron. Obstruct. Pulmon. Dis. 16, 2665–2675 (2021).
Amaral, A. F. et al. Tuberculosis associates with both airflow obstruction and low lung function: BOLD results. Eur. Respir. J. 46(4), 1104–1112 (2015).
van den Borst, B., Gosker, H. R., Zeegers, M. P. & Schols, A. M. Pulmonary function in diabetes: A meta-analysis. Chest 138(2), 393–406 (2010).
Gibson, G. J. Spirometry: Then and now. Breathe 1(3), 206–216 (2005).
Mannino, D. M., Ford, E. S. & Redd, S. C. Obstructive and restrictive lung disease and functional limitation: Data from the 3rd national health and nutrition examination. J. Intern. Med. 254(6), 540–547 (2003).
Wheaton, A. G. et al. Pulmonary function, chronic respiratory symptoms, and health-related quality of life among adults in the United States—National health and nutrition examination survey 2007–2010. BMC Pub Health 13, 854 (2013).
Vaz Fragoso, C. A. et al. Phenotype of spirometric impairment in an aging population. Am. J. Respir. Crit. Care Med. 193(7), 727–735 (2016).
Guerra, S. et al. Morbidity and mortality associated with the restrictive spirometric pattern: A longitudinal study. Thorax 65(6), 499–504 (2010).
Guerra, S. et al. Health-related quality of life and risk factors associated with spirometric restriction. Eur. Respir. J. 49(5), 4 (2017).
Honda, Y. et al. Impact of restrictive lung disorder on cardiovascular mortality in a general population: The Yamagata (Takahata) study. Int. J. Cardiol. 241, 395–400 (2017).
Jankowich, M. et al. Restrictive spirometry pattern, cardiac structure and function, and incident heart failure in African Americans. The jackson heart study. Ann. Am. Thorac. Soc. 15(10), 1186–96 (2018).
Leone, N. et al. Lung function impairment and metabolic syndrome: The critical role of abdominal obesity. Am. J. Respir. Crit. Care Med. 179(6), 509–516 (2009).
Ford, E. S., Mannino, D. M. & National, H. Nutrition examination survey epidemiologic follow-up S. Prospective association between lung function and the incidence of diabetes: Findings from the national health and nutrition examination survey epidemiologic follow-up study. Diabetes Care. 27(12), 2966–70 (2004).
Kubota, M. et al. Reference values for spirometry, including vital capacity, in Japanese adults calculated with the LMS method and compared with previous values. Respir. Investig. 52(4), 242–250 (2014).
Omori, K. et al. Clinically remitted childhood asthma is associated with airflow obstruction in middle-aged adults. Respirology 22(1), 86–92 (2017).
Miura, S. et al. Accelerated decline in lung function in adults with a history of remitted childhood asthma. Eur. Respir. J. 59(1), 2100305 (2022).
Iyer, V. N., Schroeder, D. R., Parker, K. O., Hyatt, R. E. & Scanlon, P. D. The nonspecific pulmonary function test: Longitudinal follow-up and outcomes. Chest 139(4), 878–886 (2011).
Silva, G. E., Sherrill, D. L., Guerra, S. & Barbee, R. A. Asthma as a risk factor for COPD in a longitudinal study. Chest 126(1), 59–65 (2004).
Lange, P., Parner, J., Vestbo, J., Schnohr, P. & Jensen, G. A 15-year follow-up study of ventilatory function in adults with asthma. N. Engl. J. Med. 339(17), 1194–1200 (1998).
Bell, M. C. & Busse, W. W. Is it asthma or is it COPD: The overlap syndrome. J. Allergy Clin. Immunol. Pract. 3(4), 641–2 (2015).
Scanlon, P. D. et al. Smoking cessation and lung function in mild-to-moderate chronic obstructive pulmonary disease. The lung health study. Am. J. Respir. Crit. Care Med. 161(2 Pt 1), 381–90 (2000).
Gold, D. R. et al. Effects of cigarette smoking on lung function in adolescent boys and girls. N. Engl. J. Med. 335(13), 931–937 (1996).
Kanetake, R., Takamatsu, K., Park, K. & Yokoyama, A. Prevalence and risk factors for COPD in subjects with preserved ratio impaired spirometry. BMJ Open Respir. Res. 9(1), e001298 (2022).
Wan, E. S. et al. Significant spirometric transitions and preserved ratio impaired spirometry among ever smokers. Chest 161(3), 651–661 (2022).
Venkateshiah, S. B., Ioachimescu, O. C., McCarthy, K. & Stoller, J. K. The utility of spirometry in diagnosing pulmonary restriction. Lung 186(1), 19–25 (2008).
Aaron, S. D., Dales, R. E. & Cardinal, P. How accurate is spirometry at predicting restrictive pulmonary impairment?. Chest 115(3), 869–873 (1999).
Pellegrino, R. et al. Interpretative strategies for lung function tests. Eur. Respir. J. 26(5), 948–968 (2005).
Acknowledgements
The authors are indebted to the Hiroshima COPD Cohort Study investigators for their assistance and to the participating centres for designing and distributing the questionnaires. The participating centres of this study were as follows: Hiroshima Atomic Bomb Casualty Council, Health Management and Promotion Center, Hiroshima, Japan (Hideo Sasaki, MD, Noriko Inoue, MD); Yoshijima Hospital, Hiroshima, Japan (Toshihiko Kuraoka, MD); West Japan Railway Company Health Promotion Center, Hiroshima, Japan (Jitsuro Yanagida, MD, Kazuyo Sakuma, MD, Haruko Miyamoto, MD); Grand Tower Medical Court, Hiroshima, Japan (Chikako Ito, MD, Rumi Fujikawa, MD), and Nippon Telegraph and Telephone West Corporation Chugoku Health Administration Center, Hiroshima, Japan (Hitoshi Hara, MD, Kiminori Yamane, MD). We also thank the Editage English Editing Services for English language editing.
Funding
This study was partly funded by Teijin Pharma Co., Japan. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Author information
Authors and Affiliations
Contributions
Conception and design: S.M., H.I., K.O., and A.Y. Analysis and interpretation: S.M, H.I., Y.H. Drafting the manuscript: S.M and H.I. Reviewing the manuscript for important intellectual content and approval for submission: K.Y., S.S., Y.H., T.M., S.M., T.N., K.F., H.H., and N.H.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Miura, S., Iwamoto, H., Omori, K. et al. Preserved ratio impaired spirometry with or without restrictive spirometric abnormality. Sci Rep 13, 2988 (2023). https://doi.org/10.1038/s41598-023-29922-0
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-023-29922-0
- Springer Nature Limited
This article is cited by
-
The prevalence and mortality risks of PRISm and COPD in the United States from NHANES 2007–2012
Respiratory Research (2024)