Association Between Inappropriateness of Left Ventricular Mass and Left Ventricular Diastolic Dysfunction: A Study Using the Tissue Doppler Parameter, E/E'

Young Hyo Lim; Jae Ung Lee; Kyung Soo Kim; Soon Gil Kim; Jeong Hyun Kim; Heon Kil Lim; Bang Hun Lee; Jinho Shin

doi:10.4070/kcj.2009.39.4.138

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Lim, Lee, Kim, Kim, Kim, Lim, Lee, and Shin: Association Between Inappropriateness of Left Ventricular Mass and Left Ventricular Diastolic Dysfunction: A Study Using the Tissue Doppler Parameter, E/E'

Original Article

Korean Circulation Journal

Korean Circulation Journal 2009; 39(4): 138-144.

Published online: 28 April 2009

DOI: https://doi.org/10.4070/kcj.2009.39.4.138

Association Between Inappropriateness of Left Ventricular Mass and Left Ventricular Diastolic Dysfunction: A Study Using the Tissue Doppler Parameter, E/E'

Young Hyo Lim, MD, Jae Ung Lee, MD, Kyung Soo Kim, MD, Soon Gil Kim, MD, Jeong Hyun Kim, MD, Heon Kil Lim, MD, Bang Hun Lee, MD, Jinho Shin, MD

Cardiology Division, Department of Internal Medicine, Hanyang University College of Medicine, Seoul, Korea.

Correspondence: Jinho Shin, MD, Cardiology Division, Department of Internal Medicine, Hanyang University College of Medicine, 17 Haengdang-dong, Seongdong-gu, Seoul 133-792, Korea. Tel: 82-2-2290-8308, Fax: 82-2-2298-9183, jhs2003@hanyang.ac.kr

Received 17 July 2008 Revised 3 December 2008 Accepted 10 January 2009

(open-access):

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background and Objectives

The structural significance of the inappropriateness of left ventricular mass (iLVM) is known to be an important prognostic factor for cardiovascular events; however, the functional changes associated with iLVM have not been established. This study was performed to determine if diastolic dysfunction is associated with iLVM using a tissue Doppler technique.

Subjects and Methods

Three hundred sixty consecutive subjects, including 221 hypertension patients from the echocardiography database, were analyzed. Regarding the appropriateness of left ventricular (LV) mass, an observed/predicted ratio of LV mass (OPR) >130% was defined as inappropriate. Echocardiographic parameters, including early diastolic peak velocity (E)/late diastolic peak velocity (A), deceleration time (DT), isovolumetric relaxation time (IVRT), and E/early mitral annulus velocity (E'), were compared between the appropriate LV mass (aLVM) group and the iLVM group.

Results

Among transmitral flow parameters, only the E velocity was negatively correlated with the OPR when adjusted for age (adjusted r=-0.107, p=0.04). Based on multiple regression analysis, the OPR (β=0.163, p=0.003), as well as age (β=0.286, p=0.0001), systolic blood pressure (β=0.120, p=0.019), fasting blood glucose (β=0.098, p=0.042), and male gender (β=0.157, p=0.002) were independent factors determining E/E'. The cholesterol level was not an independent factor (β=-0.059, p=0.355). In the iLVM group (n=105), the adjusted E/E' was higher than in the aLVM group (n=255; 11.7±3.4 vs. 10.8±3.1, p=0.02), while the peak E flow velocity was significantly lower than in the aLVM group (70.9±15.1 vs. 75.5±17.6, p=0.03).

Conclusion

Inappropriateness of LV mass is independently associated with increased E/E'. Thus, E/E' may be a useful parameter for the evaluation of diastolic dysfunction.

Keywords: Hypertrophy, Left ventricle, Echocardiography

Introduction

Left ventricular hypertrophy (LVH) is a well-known prognostic factor for cardiovascular events.1) Left ventricular (LV) mass is influenced by hemodynamic factors, such as high blood pressure and stroke work, as well as constitutional factors, such as body size and gender.2) Inappropriateness of LV mass (iLVM) is defined in cases in which the degree of LVH is excessive considering hemodynamic and constitutional factors, and it may be represented by the percent ratio of the observed LV mass to the predicted LV mass by height, gender, and stroke work. Blood pressure, which is important in the development of LVH, is included in the equation for stroke work calculation.

Inappropriateness of LV mass has been reported to be an independent prognostic factor, regardless of the presence of LVH or not.3) Inappropriately or excessively increased LV mass is associated with metabolic abnormality, systolic dysfunction, and concentric geometry of LV, which is independent of the presence of hypertension.4-6) iLVM has also been reported to be associated with diastolic dysfunction, which can be demonstrated using various transmitral blood flow parameters.7) While the functional implication of iLVM is an important issue, there may be an argument for this association because of the intrinsic limitations of the transmitral flow parameters. The objective of this study was to clarify the relationship between iLVM and diastolic dysfunction using a tissue Doppler technique which is more reliable than transmitral blood flow parameters.

Subjects and Methods

In a cross-sectional design, data from 360 consecutive patients, including 221 hypertensive patients with or without hypercholesterolemia, were analyzed. The dataset was acquired by applying exclusion criteria to a consecutive patient echocardiography database, including 2,515 patients from 1 December 2004 to 31 August 2005 at Hanyang University Hospital in Seoul, Korea. Exclusion criteria included poor acoustic image quality, M-mode interrogation angle >10°, any regional wall motion abnormalities, grade II or greater valvular regurgitation, any valvular stenosis, ejection fraction <50%, pericardial disease, cardiomyopathy based on the echocardiographic findings, atrial fibrillation, creatinine level >1.5 mg/dL for males and 1.4 mg/dL for females, hemoglobin <13 mg/dL in males and <12 mg/dL in females, clinical history of angina, congestive heart failure, known coronary artery disease, and incomplete clinical data.

During the study period, height, weight, abdominal circumference, blood pressure, and heart rate were measured before echocardiography was performed. Blood pressure was measured 2 times with 1 minute interval using an A&D UA-767 (AND, Japan) and the averaged value was used for analysis. Abdominal circumference was measured at the mid-level of the abdomen between the iliac crest and the lower costal margin with a spring-loaded measuring tape in the sitting or standing position, according to the World Health Organization guidelines.8) Duplicate measurements were made in all cases and the average was used for analysis unless there was <3% difference between the measurements, in which case the measurement was not used for analysis. The levels of total cholesterol, triglycerides, high density lipoprotein (HDL), fasting blood glucose (FBG), and serum creatinine were obtained from the medical records. The study protocol was approved by the Institutional Review Board of Hanyang University Medical Center. Informed consent was obtained from each patient regarding the process of the examination and use of the data.

Abdominal obesity was defined by abdominal circumference ≥80 cm in females and ≥90 cm in males with the Asia-Pacific perspective.9) Metabolic syndrome was defined by the Adult Treatment Panel III guidelines.10)

Echocardiography

Two-dimensional and guided M-mode echocardiograms were performed on each subject by a single sonographer with a commercially available machine (IE-33; Philips) with a 1-5 MHz transducer. Measurements for M-mode-guided calculations of LV mass were taken at or just below the tip of the mitral valve with a paper speed of 50 mm/sec. The LV internal end-diastolic dimension (EDD), the end systolic dimension (ESD), and the septal and posterior wall thicknesses (PWT) were measured on the leading edge-to-the leading edge, according to the guidelines of the American Society of Echocardiography. LV mass was calculated by the following equation: 1.04×(IVSd+LVDd+PWTd)³-LVDd³)×0.8+0.6.11)

Doppler echocardiographic recordings were performed by pulsed-wave Doppler with the sample volume at the tips of the mitral valve in the apical four-chamber view and recorded at a paper speed of 100 mm/sec. Early (E) and late (A) diastolic peak velocities, deceleration time (DT), and early-to-late diastolic peak velocity ratio (E/A) were determined, as previously reported.12) For patients <55 years of age, impaired relaxation was diagnosed if the E/A ratio <1 or the DT ≥240 ms. For older patients, both an E/A ratio <0.8 and a DT ≥240 ms were required to diagnose impaired relaxation.13) Early mitral annulus velocity (E') was measured at the septal portion of the mitral annulus in an apical four chamber view using a tissue Doppler technique with a Nyquist limit of 15 cm/s.

Appropriateness of left ventricular mass

Appropriateness of LV mass (aLVM) was expressed as the observed/predicted ratio (OPR) of the LV mass.3) The predicted LV mass was calculated as previously described.14) Briefly, the LV mass was predicted by the following equation: 54.9+7.62×height (m^2.7)+0.67×stroke work (g-m/beat)-13.2×gender (male=1, female=2) (constant=54.9±14.7 g, adjusted R²=0.576, SEE=21.67, p=0.001).

We adopted the LV mass index by the height to highlight the effect of weight and set the cut-off value (mean+2 SD) for LVH as 54 g/m^2.7 for both genders. The cut-off value between the iLVM and aLVM groups was 130% or higher for both genders.

Statistical analysis

Data were expressed as the mean±SD. For the simple analysis of general characteristics and the gender difference, chi-square and independent t-tests were performed. Comparing the means among groups, age, gender, body mass index (BMI), systolic blood pressure (SBP), heart rate, fasting blood glucose (FBG) and the type of antihypertensive therapy {using indicator variables for angiotensin-converting enzyme (ACE) inhibitors or angiotensin II receptor antagonists, other anti-hypertensive drugs, and no drug therapy} were adjusted using the least square means or a univariate general linear model for each dependent variable. Least squares multiple linear regression analysis (stepwise procedure) was used to evaluate the relationships, with assessment of in-model tolerance to evaluate multiple-collinearity. The minimal accepted tolerance was 0.70. A two-tailed p<0.05 was considered to be statistically significant. Data were analyzed using Statistical Package for Social Science (SPSS) 12.0 software (SPSS Inc., Chicago, IL, USA).

Results

General characteristics of the subjects

The average age of the subjects was 58.1±13.9 years (range, 19-87 years). Two hundred of the subjects (55.5%) were females. Two hundred twenty-one of the subjects (61.3%) had hypertension, 71 (19.7%) had diabetes mellitus, 72 (20%) had hypercholesterolemia, and 106 (29.4%) had no risk factors. Thirty-nine patients (10.8%) had both hypertension and diabetes. Thirty-one patients (8.9%) had both hypertension and hypercholesterolemia. Four patients (1.1%) had both diabetes and hypercholesterolemia. Nineteen patients (5.2%) had hypertension, diabetes, and hypercholesterolemia. One hundred seventy patients (47.2%) had metabolic syndrome. Abdominal obesity was noted in 249 (69.1%) patients.

Among 221 hypertensive patients, 144 (65.1%) were on medical treatment; specifically, 68 patients (30.7%) were taking a prescription, including an angiotensin converting enzyme inhibitor or an angiotensin receptor antagonist, and 76 patients (34.4%) were taking other types of antihypertensive drugs.

In a comparison of general characteristics between the male and female patients, the average age of the female patients was older (61.3±13.7 vs. 54.4±13.9 years, p=0.0001). The age-adjusted systolic and diastolic blood pressures were higher in male patients. The frequencies of increased BMI, diabetes mellitus, and hypercholesterolemia were similar in males and females. In female patients, the degree of abdominal obesity was much higher compared with male patients (83.8% vs. 50.6%) (Table 1).

Clinical characteristics between the appropriateness and inappropriateness of left ventricular mass groups

In 217 subjects (60.3%), the LVs were normal with respect to both the LV mass index and the appropriateness. Forty-six patients (12.8%) had inappropriate LV mass with a normal LV mass index. Thirty-eight patients (10.5%) had appropriate LV mass with an abnormal LV mass index and 59 patients (16.4%) had inappropriate LV mass and abnormal LV mass index. Among all the patients, 105 patients (29.1%) had inappropriate LV mass and 255 patients (70.9%) had appropriate LV mass (Table 2).

Patients with iLVM were older (63.0±11.8 vs. 56.1±14.2 years, p=0.0001) and more likely to be female (73.3% vs. 48.0%, p=0.0001). In the iLVM group, BMI (26.0±3.2 vs. 24.3±3.6, p=0.0001) and total cholesterol (201.6±36.2 vs. 185.1±36.5 mg/dL, p=0.001) was higher. The frequencies of abdominal obesity (74.0% vs. 68.4%), diabetes mellitus (23.4% vs. 18.5%) and hypertension (58.2% vs. 62.4%) were not different when adjusted for age and gender (Table 3).

Observed/predicted ratio versus transmitral flow pattern

Among transmitral blood flow parameters, only isovolumetric relaxation time (IVRT) showed a correlation with OPR in males. In female patients, E, A, E/A, and IVRT showed an association with OPR (Table 4). For both genders, however, only the inverse relationship between E velocity and OPR, when adjusted by age, was significant among the transmitral flow parameters (Table 5).

Observed/predicted ratio versus early diastolic peak velocity/early mitral annulus velocity

The age, BMI, FBG level, and OPR were significantly correlated with E/E' in male patients. The age, SBP, and OPR were significantly correlated with E/E' in female patients (Table 4). In multiple regression analysis, age (β=0.286, p=0.0001), SBP (β=0.120, p=0.019), FBG (β=0.098, p=0.042), male gender (β=0.157, p=0.002), and OPR (β=0.163, p=0.003) were independent factors for E/E'. The cholesterol level was not an independent factor (β=-0.059, p=0.355).

Comparison between groups

When adjusted by age, gender, BMI, SBP, cholesterol level, FBG, and types of antihypertensive medications, both the diastolic LV dimension (5.06±0.46 vs. 4.91±0.44, p=0.007) and the relative wall thickness (0.38±0.04 vs. 0.33±0.04, p<0.0001) were higher in the iLVM group. In the iLVM group, peak E flow velocity was significantly lower than in the aLVM group (70.9±15.1 vs. 75.5±17.6, p=0.03), as well as E' velocity (6.59±2.04 vs. 7.34±1.50 cm/sec, p=0.001). E/E' was higher in iLVM group (11.7±3.4 vs. 10.8±3.1, p=0.02) (Table 6) (Fig. 1). The E/E' was 10.7±0.2 in normal LV mass, 10.9±0.5 in patients with iLVM without LVH, 11.2±0.5 in appropriate LVH patients, and 12.1±0.4 in inappropriate LVH patients {analysis of variance (ANOVA), p=0.02}.

Discussion

This study was designed to clarify the functional significance of the inappropriately increased LV mass using a tissue Doppler technique, in addition to the traditional transmitral flow parameters. The results showed that the appropriateness of LV mass is an independent factor determining E/E', along with age, SBP, gender, and FBG level. The adverse influence of inappropriate LV mass was evidenced by the finding that the adjusted E/E' value was higher in the iLVM group. In the iLVM group, the E velocity was lower, and the E' velocity was even lower. Accordingly, the resultant E/E' was lower in the iLVM group than the aLVM group.

In contrast, with respect to the transmitral flow parameters, only the inverse correlation between the OPR and the transmitral E velocity was significant when adjusted for age. The borderline statistical significance for IVRT may be attributable to the smaller sample size compared to a previous study.7) Transmitral flow parameters are widely used for practicality reasons; however, the non-linearity associated with LV function deterioration make it difficult to interpret the functional relevance of the structural changes of the LV. E/E' is advantageous because of its linear relationship with the left atrial pressure or brain natriuretic peptide (BNP).

Some authors have pointed out that the indexation methods of LV mass (e.g., indexation by body surface area or height^2.7) have a different clinical significance.20) Of note, the functional aspect of these different indexations has not been clarified. Our study showed that age-adjusted partial correlation coefficients between E/E' and LV mass, regardless of using different indexations, were consistently significant, as well as the OPR of the LV mass (Table 5).

Age, gender and the LV mass are well-known contributors for E' velocity or E/E'.21)22) There may be an argument against the suggestion that the OPR of the LV mass have additional value to the traditionally defined LV hypertrophy regarding the influence on diastolic dysfunction. In our study, the correlation coefficients of the OPR versus LVM, LVMI indexed by body surface area, and LVMI indexed by height^2.7 were similar (0.502, 0.590, and 0.647, respectively); however, the correlation coefficient between LVMI indexed by body surface area and LVMI indexed by height^2.7 (0.928) was in contrast with the OPR and LVMI indexed by height (0.68)^2.7.

With the limitation that the number of patients in the study did not allow multiple comparisons among groups, only in the inappropriate LVH group, the E/E' value was higher than the group of normal LV mass. The E/E' in iLVM without LVH or aLVH was not statistically different from that of the normal LV mass group. These findings suggest that inappropriateness of LV mass is functionally more important in LVH patients. There might be an additive or synergistic interaction between LVH and the appropriateness of LV mass. For sufficient statistical analysis of the interaction between appropriate LVH and inappropriate LVM, a study with a larger sample size is needed.

LV dysfunction was demonstrated in patients with prehypertension, and even in normotensive patients23) and the additive effect of diabetes on myocardial dysfunction in hypertension was also reported.24) These findings suggest that there may be other factors affecting LV dysfunction than blood pressure itself. In our study, another consistent finding with the previously reported data is that BMI was much higher in the iLVM group.4) The prevalence of abdominal obesity was not different between the groups. This may be attributable to the Asian Pacific criteria for abdominal obesity.9) Using these criteria, the prevalence in the population was relatively high25) and there is a suggestion for a new cutoff value for abdominal obesity for the Korean population.26) Another possible explanation may be that abdominal obesity may be an early sign of obesity and the difference between abdominal obesity is evident only before overt obesity develops.14) Even though our data derived from the database of the echocardiography laboratory and hospital records included quite heterogeneous subjects, other parameters associated with iLVM, such as anemia, renal insufficiency, and thyroid dysfunction were excluded very cautiously. Thus, regarding LV diastolic function, the inappropriateness of LV mass might be another factor to be considered in addition to the presence or absence of LVH in patients with a wide spectrum of cardiovascular risk factors.

In conclusion, inappropriateness of LV mass is functionally associated with LV dysfunction and high left atrial pressure.

Figures and Tables

Fig. 1

Adjusted E/E' by age, gender, BMI, systolic blood pressure, cholesterol level, fasting blood glucose level, and types of antihypertensive medication is significantly higher in the inappropriate LV mass group than the appropriate LV mass group. E: early diastolic peak velocity, E': early mitral annulus velocity, BMI: body mass index, LV: left ventricular.

Table 1

General characteristics of subjects

Continuous values are the mean±SD. ^*p<0.05 adjusted for age. HDL: high density lipoprotein, LV: left ventricular, OPR: observed/predicted ratio of LV mass, BMI: body mass index

Table 2

Clinical characteristics of subjects

LV: left ventricular, OPR: observed/predicted ratio of left ventricular mass, aLVM: appropriate LV mass, iLVM: inappropriate LV mass

Table 3

Comparison between groups of appropriate LV mass (aLVM) versus inappropriate LV mass (iLVM)

Continuous values are the mean±SD adjusted by age, gender, body mass index, systolic blood pressure, heart rate, fasting blood glucose level, and the type of antihypertensive therapy. HDL: high density lipoprotein, LV: left ventricle, DT: deceleration time, IVRT: isovolumetric relaxation time

Table 4

Pearson correlation coefficients between age, SBP, BMI, OPR, FBG, and echocardiographic parameters

^*p=0.001, ^†p<0.001, ^‡p<0.01, ^§p<0.05. SBP: systolic blood pressure, BMI: body mass index, OPR: observed/predicted ratio of left ventricular mass, FBG: fasting blood glucose, E: early diastolic peak velocity, A: late diastolic peak velocity, E': early mitral annulus velocity, DT: deceleration time, IVRT: isovolumetric relaxation time

Table 5

Age-adjusted correlation coefficients between LV structure and diastolic function

^*p<0.05, ^†p=0.001, ^‡p<0.001. LV: left ventricular, LVM: left ventricular mass, LVMI: left ventricular mass index, OPR: observed/predicted ratio of left ventricular mass, E: early diastolic peak velocity, A: late diastolic peak velocity, DT: deceleration time, IVRT: isovolumic relaxation time, E': early mitral annulus velocity

Table 6

Left ventricular dimensions and diastolic properties

Continuous values are the mean±SD adjusted by age, gender, BMI, systolic blood pressure, heart rate, fasting blood glucose level, and the type of antihypertensive therapy. LA: left atrium, LV: left ventricular, OPR: observed/predicted ratio of LV mass, E: early diastolic peak velocity, A: late diastolic peak velocity, E': early mitral annulus velocity, BMI: body mass index

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