Figures
Abstract
Background
The main pulmonary artery diameter (mPA), aortic diameter (Ao), and the mPA/Ao ratio, easily measured using chest computed tomography (CT), provide information that enables the diagnosis and evaluation of cardiopulmonary diseases. Here, we used CT to determine the sex- and age-specific distribution of normal reference values for mPA, Ao, and mPA/Ao ratio in an adult Korean population.
Methods
Data from non-contrast, ECG-gated, coronary-calcium-scoring CT images of 2,547 individuals who visited the Health Screening Center of the Severance Hospital were analyzed. Healthy individuals (n = 813) included those who do not have hypertension, diabetes, asthma, obstructive lung disease, ischemic heart disease, stroke, smoking, obesity, and abnormal CT findings. Both mPA and Ao were measured at the level of bifurcation of the main pulmonary artery.
Results
The mean mPA and Ao were 25.9 mm and 30.0 mm in healthy participants, respectively, while the mean mPA/Ao ratio was 0.87. Medical conditions associated with a larger mPA were male, obesity, smoking history, hypertension, and diabetes. A larger mPA/Ao ratio was associated with female, the obese, non-smoker, normotensive, and normal serum level of lipids, while a smaller mPA/Ao ratio was associated with older age. In healthy individuals, the 90th percentile sex-specific mPA, Ao, and mPA/Ao ratio were, 31.3 mm (95% CI 29.9–32.2), 36.8 mm (95% CI 35.7–37.5), and 1.05 (95% CI 0.99–1.07) in males, and 29.6 mm (95% CI 29.1–30.2), 34.5 mm (95% CI 34.1–34.9), and 1.03 (95% CI 1.02–1.06) in females, respectively.
Citation: Lee SH, Kim YJ, Lee HJ, Kim HY, Kang YA, Park MS, et al. (2015) Comparison of CT-Determined Pulmonary Artery Diameter, Aortic Diameter, and Their Ratio in Healthy and Diverse Clinical Conditions. PLoS ONE 10(5): e0126646. https://doi.org/10.1371/journal.pone.0126646
Academic Editor: Xian Wu Cheng, Nagoya University, JAPAN
Received: December 9, 2014; Accepted: April 4, 2015; Published: May 8, 2015
Copyright: © 2015 Lee et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: The authors have no support or funding to report.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Chest computed tomography (CT) is widely performed in patients with respiratory symptoms because of its simplicity and accessibility, although radiation exposure is a concern. Among the various types of clinical findings provided by chest CT, the main pulmonary artery diameter (mPA) and aortic diameter (Ao) are readily measurable.
The mPA, as determined by chest CT, is a reliable predictor of pulmonary hypertension [1,2], which is defined as a resting mean pulmonary artery pressure ≥ 25 mmHg, measured by right cardiac catheterization. Enlargement of the pulmonary artery is associated with the severe exacerbations of chronic obstructive pulmonary disease (COPD) [3,4]. Recently, Nakanishi et al. [5] reported that an elevated (> 0.9) pulmonary trunk diameter to ascending aorta diameter ratio was significantly associated with an increased risk of all-cause death, regardless of the presence or absence of coronary artery disease. Therefore, mPA and the ratio of mPA to aortic diameter (mPA/Ao ratio) can inform clinicians on the risk and current status of a diverse range of underlying illnesses, as well as provide patient prognostic information.
However, to determine the clinical significance of mPA and mPA/Ao ratio in cardiopulmonary disease, normal reference values for mPA, Ao, and mPA/Ao ratio must be defined, and the different clinical characteristics associated with an elevated versus normal mPA/Ao ratio should be determined.
Although mPA has been previously measured using chest radiography or chest CT [5–7], the sample sizes of those studies were insufficient to determine normal reference values, especially in Asian countries such as Japan and Turkey [5,7]. Moreover, in Korea, large population studies to establish the normal reference ranges of mPA and investigate the relationship between mPA, mPA/Ao ratio, and clinical parameters are lacking [6–8]. Thus, in this study, we aimed to examine the sex- and age- specific distribution of mPA, Ao, and mPA/Ao ratio using ECG-gated coronary-calcium-scoring CT to establish normal reference values in a Korean population. We also investigated the relationship between these values and various clinical conditions.
Methods
Study participants
In this retrospective single-center study, we examined 2,547 individuals (1,023 females, 1,524 males) who visited the Severance Hospital Health Screening Center, Seoul, Korea, between January 2011 and December 2012. Demographic, underlying diseases, lung function, transthoracic echocardiography (TTE), and CT imaging data were obtained from electronic medical records. Individuals who were < 20 years of age, pregnant, or had a history of congenital heart disease, valvular heart disease, thoracic surgery, or radiotherapy, were excluded. Normal reference values were obtained from a group of healthy individuals (n = 813), defined as those who do not have hypertension, diabetes mellitus (DM), asthma, obstructive lung disease (OLD), ischemic heart disease (IHD), stroke, smoking history, obesity, or abnormal pulmonary CT findings. This study was reviewed and approved by the Yonsei University Health Service, Severance Hospital Institutional Review Board (Ref. 4-2013-0839). A written informed consent was not necessary because of the retrospective cohort nature of the study.
Definitions
Obesity and OLD were defined as a body mass index (BMI) > 30 kg/m2, and as a ratio of forced expiratory volume in 1 second to forced vital capacity (FEV1/FVC) < 70%, according to a pulmonary function test, respectively. Abnormal pulmonary CT findings included bronchiectasis, interstitial lung disease, emphysema, bronchial thickening, any mass, or fibrosis.
CT image acquisition
Non-contrast, ECG-gated, coronary-calcium-scoring CT was performed using a 64-slice multi-detector CT (LightSpeed Volume CT, GE Healthcare, Waukesha, Wisconsin). Prospective ECG-triggered acquisitions were obtained in mid-diastole at 120–140 kVp and 150–220 mA, depending on the patient’s size. Other parameters were a 350 ms gantry rotation time and a 64 × 1.25 mm slice collimation. The CT was reconstructed at 70% of the R-R interval using a slice thickness of 2.5 mm and an increment of 2.5 mm.
Measurement of the pulmonary artery and aortic diameters
The pulmonary artery and ascending aorta were assessed on a transverse image at the level of the pulmonary artery bifurcation. Vessel diameters were obtained by measuring the widest diameter vertical to the long axis of the main pulmonary artery, using a computer caliper (Fig 1). A chest radiologist blinded to the study design and clinical data reviewed all the CT images, and measured the mPA and Ao at a workstation. Interobserver agreement was determined by comparing the mPA and Ao measurements with those obtained from a second blinded pulmonologist at a different workstation. The κ value of the intraclass correlation coefficient was 0.95 (95% confidence interval (CI), 0.94–0.95) for mPA, and 0.97 (95% CI, 0.96–0.97) for Ao.
Pulmonary artery and ascending aorta diameters were assessed on a transverse CT image at the level of the pulmonary artery bifurcation. Vessel diameters were obtained by measuring the widest diameter vertical to the long axis of the main pulmonary artery, using a computer caliper. mPA, main pulmonary artery; Ao, aorta
Transthoracic echocardiography
TTE data were available from 289 individuals, of whom, 69 were healthy. TTE was performed using a Vivid 7 apparatus (GE Medical Systems, Milwaukee, WI, USA) and data collected included left ventricular end diastolic diameter (LVEDD), left ventricular end systolic diameter (LVESD), left ventricular ejection fraction (LVEF), left atrial volume index (LAVI), and right ventricular systolic pressure (RVSP).
Statistical analysis
Continuous variables were analyzed using Student’s t-test or Mann-Whitney U test. Categorical variables were analyzed using Pearson χ-square test or Fisher’s exact test. mPA, Ao, and mPA/Ao ratio values at the 10th, 25th, 50th, 75th, and 90th percentiles were derived from the healthy reference group (n = 813). Pearson’s correlation analyses were performed to examine relationships between age, BSA, FEV1, echocardiography data; and mPA, Ao, and mPA/Ao ratio in all participants. Multiple linear regression analysis was conducted to determine the effect of demographic factors, underlying diseases, and lung function on mPA, Ao, and mPA/Ao ratio. All statistical analyses including 95% CI for the 90th percentile values were conducted using the SPSS version 20.0 software (SPSS, Chicago, IL, USA). A two-sided P-value < 0.05 was considered statistically significant for all analyses.
Results
Baseline characteristics
Table 1 shows the baseline clinical characteristics of all participants (n = 2,547) and healthy individuals (n = 813, 187 males and 626 females), and their distribution according to age and BMI (S1 Fig) (Details are shown in S1 Table). The mean age of the entire group was 53.1 years, and that of the healthy group was 51.2 years. The body surface area (BSA) was 1.74 and 1.63, respectively. Of all participants, 3.9% were obese and 50.2% had a history of smoking. Underlying diseases included hypertension (23.7%), DM (8.5%), dyslipidemia (4.9%), asthma (0.4%), IHD (0.6%), stroke (0.5%), and OLD (2.6%). The overall mean mPA, Ao, and mPA/Ao ratio in all participants were 26.6 mm, 32.0 mm, and 0.84, respectively, while in the healthy reference group, the corresponding values were 25.9 mm, 30.0 mm, and 0.87, respectively. Fig 2 shows the mPA, Ao, and mPA/Ao ratio distributions in all participants and healthy participants, with mean values of RVSP of 24.1 mmHg, and 24.9 mmHg, respectively.
Histograms show the distributions of mPA, Ao and mPA/Ao ratio values in all (n = 2,547) (A, C, E) and healthy participants (n = 813) (B, D, F), respectively (dark gray: male, gray: female). mPA, main pulmonary artery; Ao, aorta.
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mPA, Ao, and mPA/Ao ratio in diverse clinical conditions
Table 2 shows the relationship between mPA, Ao, and mPA/Ao ratio according to sex, obesity, smoking status, hypertension, DM, dyslipidemia, asthma, IHD, stroke, OLD, and abnormal pulmonary findings on chest CT. The mPA was significantly larger in males (27.0 mm vs. 26.0 mm, P < 0.001), the obese (29.3 mm vs. 26.5 mm, P < 0.001), and in those with a history of smoking (26.9 mm vs. 26.4 mm, P < 0.001), hypertension (27.6 mm vs. 26.3 mm, P < 0.001), or DM (28.2 mm vs. 26.5 mm, P < 0.001). While a similar trend was observed for Ao, this diameter was also significantly larger in individuals with dyslipidemia, stroke, OLD, or abnormal pulmonary findings on chest CT. The mPA/Ao ratio was significantly larger in females (0.86 vs. 0.83, P < 0.001), the obese (0.89 vs. 0.84, P < 0.001), or in those with abnormal findings on chest CT (0.85 vs. 0.81, P = 0.002), but significantly smaller in those with hypertension (0.80 vs. 0.86, P < 0.001), a history of smoking (0.84 vs. 0.85, P = 0.002), or dyslipidemia (0.79 vs. 0.85, P < 0.001).
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Correlations between mPA, Ao, and mPA/Ao ratio with age, BSA, and FEV1 (%) are shown in S2 Fig. Age was significantly correlated with mPA, Ao, and mPA/Ao ratio. BSA was correlated with mPA and Ao, and FEV1 (%) with mPA and mPA/Ao ratio. Correlations between mPA, Ao, and mPA/Ao ratio with LAVI and RVSP are shown in S3 Fig. LAVI was significantly correlated with mPA and Ao, but RVSP showed no correlation with any of the three parameters.
mPA, Ao, and mPA/Ao ratio in the healthy reference group
The distributions of mean mPA, Ao, and mPA/Ao ratio for the healthy participants are shown in Table 3 according to age. Mean mPA values in males and females ranged from 26.0–27.0 mm, and 24.4–27.0 mm, respectively. A larger age-related difference in mPA was observed in females than in males (2.6 mm vs. 1.0 mm). Although the mPA was larger in males than in females for all percentiles and for ages < 45 and 45–54 years, the opposite was true for females age ≥ 55 years. The 90th percentile value of mPA was 31.3 mm (95% CI 29.9–32.2) in males and 29.6 mm (95% CI 29.1–30.2) in females. Mean Ao was 29.4–33.8 mm in males and 26.4–31.8 mm in females. The difference in mean Ao was greater in females than in males (5.4 mm vs. 4.4 mm). Aortic enlargement was observed with aging. The mean mPA/Ao ratio was larger in females than in males for all age groups, but tended to decrease with increasing age in both sexes. The 90th percentile value of mPA/Ao ratio was 1.05 (95% CI 0.99–1.07) in males and 1.03 (95% CI 1.02–1.06) in females.
Clinical characteristics of the groups with mPA/Ao ratio < 1.04 and mPA/Ao ratio ≥ 1.04
Clinical characteristics were compared based on the 90th percentile mPA/Ao ratio value of 1.04 as shown in Table 4. Individuals with mPA/Ao ratio ≥ 1.04 were significantly younger, predominantly female, and less likely to have hypertension. They also had a smaller FVC (%) and FEV1 (%), and a larger FEV1/FVC. LAVI was significantly larger in participants with mPA/Ao ratio < 1.04, while RVSP did not differ between the groups.
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Multivariate linear analysis of the effects of clinical characteristics on mPA, Ao, and mPA/Ao ratio
The association between mPA, Ao, and mPA/Ao ratio with various demographic factors, underlying diseases, and physiologic parameters was analyzed using a multiple linear regression model (Table 5). The mPA/Ao ratio was positively associated with BSA, obesity, and DM, but negatively associated with age, male (vs. female) sex, current smoking, hypertension, dyslipidemia, and FEV1 (%).
Discussion
We used non-contrast, ECG-gated coronary-calcium-scoring CT scans to obtain reference values for mPA and Ao in the Korean population, and then determined the relationship between these values and various clinical conditions. Both mPA and Ao were larger in males, the obese, and those with hypertension, DM, or dyslipidemia. Larger mPA/Ao ratio was found in females, the obese, non-smokers, normotensive and in individuals with normal serum level of lipids. In the healthy reference group, mean mPA, Ao, and mPA/Ao ratio were 26.5 mm, 31.6 mm, and 0.85 in males, and 25.8 mm, 29.6 mm, and 0.88 in females, respectively. The 90th percentile sex-specific values for mPA, Ao, and mPA/Ao ratio were 31.3 mm, 36.8 mm, and 1.05 in males, and 29.6 mm, 34.5 mm, and 1.03 in females, respectively. Factors influencing mPA diameter were age, sex, BSA, obesity, hypertension, DM, and FEV1 (%), whereas those influencing Ao were age, BSA, hypertension, and dyslipidemia. The mPA/Ao ratio was affected by age, sex, BSA, obesity, current smoking, hypertension, DM, dyslipidemia, and FEV1 (%).
All three parameters (i.e., mPA, Ao, and mPA/Ao ratio) are easily obtained through chest or heart CT images, and were previously shown to clinically correlate with underlying cardiopulmonary diseases [3,4,6,9,10]. In addition, Matsushita et al. [11] reported a significant difference in mPA between patients with stable interstitial pneumonia and those with acute disease exacerbation. Similarly, we found significant differences in mPA, Ao, and mPA/Ao ratio according to sex, obesity, smoking status, hypertension, DM, dyslipidemia, stroke, OLD, and abnormal CT findings. Male sex and any of these clinical conditions are risk factors for cardiopulmonary disease, which explains their positive relationship with mPA and Ao. By contrast, in the healthy reference group, aging was associated with a lower mPA/Ao ratio due to aortic enlargement. In this study, age was positively associated with mPA and Ao, but the effect of age was larger on Ao than on mPA.
In previous studies in which chest CT was used to investigate mPA in a reference group, the mean mPA ranged from 24.2 mm to 27.2 mm [6–8], and the mean mPA of 25.9 mm was found in our group of healthy individuals. The mean Ao in our reference group was 31.6 mm in males and 29.6 mm in females (i.e., slightly lower than the values reported by Rogers et al. [12] [34.1 and 31.9, respectively]). This difference can be explained by differences in the study populations who showed relatively higher BMI or BSA, and more medical problems in the study of Rogers et al. [12] Mao et al. [13] reported a mean Ao of 33.6 mm in males and 31.1 mm in females. Their study population also had a relatively higher mean BSA than that in our study. These factors, in addition to ethnic and lifestyle differences, may account for the differences in Ao values.
The 90th percentile sex-specific mPA, Ao, and mPA/Ao ratio values determined in our healthy reference group were, 31.3 mm, 36.8 mm, and 1.05 in males, and 29.6 mm, 34.5 mm, and 1.03 in females, respectively. In several studies, mPA cutoff values ranging from 28.6 mm to 33.2 mm have been reported for the prediction of pulmonary hypertension [6,8,10]. However, in our study, the 90th percentile mPA/Ao ratio value of 1.04, was greater than the previously reported ratios of 0.9–1.0 [3,5,14,15]. This difference may reflect the exclusion from the healthy reference group of individuals with abnormal CT findings, which are associated with a significantly lower mPA/Ao ratio (Table 2). The group with mPA/Ao ratio < 1.04 was older, had aortic enlargement, and a higher prevalence of hypertension. These comorbidities are among the cardiovascular diseases primarily affecting Ao rather than mPA. In a linear regression analysis, hypertension, and dyslipidemia were positively correlated with Ao, and the effect of hypertension was greater on Ao than on mPA (Table 5).
Blum et al. [16] reported that, compared to a healthy control group, COPD patients had a more dilated brachial artery and a smaller change in post-hyperemia arterial diameter. Iyer et al. [17] reported that mPA/Ao ratio > 1.0, as determined on CT scan, was better than echocardiography for predicting pulmonary hypertension in patients with severe COPD. These results suggest an association between impaired lung function and arterial diameter, especially with respect to the pulmonary artery rather than the aorta. Consistent with previous studies, in our study, RVSP determined by echocardiography did not show any significant results, while FEV1 (%) negatively correlated with mPA. However, further large-scale studies are needed to demonstrate the relationship between lung function and mPA and mPA/Ao ratio.
This study had several limitations. First, participants were from a single center and mostly middle aged; thus, the results may not accurately represent the Korean population. However, the Severance Hospital Health Screening Center is affiliated with the Severance Hospital, a tertiary hospital that admits patients from all over South Korea. Second, the healthy reference group made up less than half of the total participants, and was predominantly female. However, the number of participants included was not less than in previous studies, and ours is the first such study from Korea [6,7,18]. Third, cardiac or pulmonary symptoms that may be related to mPA and Ao were not assessed. Nonetheless, specific cardiopulmonary symptoms were unlikely in our study group, because most were healthy check-up subjects. However, the subjects might have specific reasons such as other comorbidities or risk factors for undertaking chest CT scan. Therefore, we defined the healthy reference group as those who were free of cardiopulmonary diseases and their risk factors, without abnormal pulmonary CT findings. Lastly, because we based our findings on non-contrast CT images, the measured values would show minor differences compared with those determined on contrast CT. However, ECG-gated, coronary-calcium-scoring CT provides consistent results, and thus allows the accurate measurement of arterial diameter.
Conclusions
In this study, age- and sex-specific reference values were obtained for mPA and Ao in a population of healthy Koreans. These two, readily available measurements were associated with age, sex, BSA, pulmonary function, and comorbidities such as obesity, hypertension, DM, and dyslipidemia. Currently, regular check-ups that include low-dose lung CT are more frequently performed, especially in individuals at high risk for pulmonary disease. Our reference values provide physicians with clinical clues and information on the current cardiopulmonary status of patients in whom these two parameters are determined on chest CT.
Supporting Information
S1 Fig. Distribution of age and BMI.
Histograms show age and BMI distributions in all (n = 2,547) (A, C) and healthy participants (n = 813) (B, D), respectively (dark gray: male, gray: female). BMI, body mass index.
https://doi.org/10.1371/journal.pone.0126646.s002
(TIF)
S2 Fig. Correlations of mPA, Ao, and mPA/Ao ratio with age, BSA, and FEV1 (%). Plots show correlations of mPA, Ao, and mPA/Ao ratio with age, BSA, and FEV1 (%).
Significant correlations were observed between age with mPA (r = 0.183, P < 0.001), Ao (r = 0.527, P < 0.001), and mPA/Ao ratio (r = -0.334, P < 0.001). BSA was correlated with mPA (r = 0.300, P < 0.001) and Ao (r = 0.227, P < 0.001). FEV1 (%) was correlated with mPA (r = -0.065, P = 0.001) and mPA/Ao ratio (r = -0.080, P < 0.001). mPA, main pulmonary artery; Ao, aorta; FEV1, forced expiratory volume in 1 second.
https://doi.org/10.1371/journal.pone.0126646.s003
(TIF)
S3 Fig. Correlations of mPA, Ao, and mPA/Ao ratio with LAVI and RVSP.
Plots show correlations of mPA, Ao, and mPA/Ao ratio values with LAVI and RVSP. Significant correlations were observed between LAVI with mPA (r = 0.196, P = 0.001) and Ao (r = 0.253, P < 0.001). No correlations were observed between RVSP and the three parameters. mPA, main pulmonary artery; Ao, aorta; LAVI, left atrial volume index; RVSP, right ventricular systolic pressure.
https://doi.org/10.1371/journal.pone.0126646.s004
(TIF)
Author Contributions
Conceived and designed the experiments: YAK MSP JYJ. Performed the experiments: SHL YJK HJL HYK. Analyzed the data: SHL YJK YSK SKK JC JYJ. Contributed reagents/materials/analysis tools: SHL YJK HJL HYK. Wrote the paper: SHL YJK JYJ.
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