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Abstract
Background—Hypertensive left ventricular hypertrophy (HTN-LVH) is a leading cause of heart failure. Conventional patterns of cardiac geometry do not adequately risk-stratify patients with HTN-LVH. Using cardiovascular magnetic resonance, we developed a novel Remodeling Index (RI) that was designed to detect an exaggerated hypertrophic response to hypertension and tested its potential to risk-stratify hypertensive patients.
Methods and Results—The RI was derived using LaPlace’s Law (
), and normal RI ranges were established in 180 healthy volunteers. The utility of the RI was examined in 256 asymptomatic hypertensive patients and 10 patients with heart failure with preserved ejection fraction. Hypertensive patients underwent multimodal cardiac assessment: contrast-enhanced cardiovascular magnetic resonance, echocardiograms, 24-hour blood pressure monitoring, and cardiac biomarkers (high-sensitivity cardiac troponins, NT-proBNP [N-terminal pro-B-type natriuretic peptide], and galectin-3). Blood pressure accounted for only 20% of the variance observed in LV mass. Although there was no association between blood pressure and myocardial fibrosis, LV mass was independently associated with fibrosis. Compared with hypertensive patients without LVH (n=191; 74.6%) and those with HTN-LVH and normal RI (n=50; 19.5%), patients with HTN-LVH and low RI (HTN-LVH/low RI; n=15, 5.9%) had an amplified myocardial response: elevated indexed LV masses (83±24 g/m2), more fibrosis (73%), and higher biomarkers of myocardial injury and dysfunction (P<0.05 for all). RI was similar in HTN-LVH/low RI and heart failure with preserved ejection fraction (4.1 [3.4–4.5] versus 3.7 [3.4–4.0], respectively; P=0.15).
Conclusions—We suggest that RI provides an approach for stratifying hypertensive patients and is suitable for testing in other disease cohorts to assess its clinical utility.
Clinical Trial Registration—URL: https://clinicaltrials.gov. Unique identifier: NCT02670031.
- blood pressure
- heart diseases
- hypertrophy, left ventricular
- magnetic resonance imaging
- natriuretic peptide, brain
Introduction
Hypertensive heart disease is a syndrome characterized by left ventricular hypertrophy (LVH), systolic and diastolic dysfunction alongside the clinical manifestations of heart failure.1 In susceptible patients, the myocardium progressively thickens in response to elevated arterial pressure to minimize myocardial wall stress (σ) according to the LaPlace’s Law: σ=[P×r]/2h, where P is the left ventricular (LV) pressure, r is the LV radius, and h is the myocardial wall thickness. These changes are initially adaptive to maintain cardiac output and function. Over time, the LV can decompensate and fail.1–3 Two major processes drive the transition from ventricular adaptation to decompensation: cardiac myocyte dysfunction/death and myocardial fibrosis.4 Myocyte dysfunction/death occurs in response to chronic exposure to neurohormonal factors and progressive myocardial ischemia associated with elevated wall stress.5,6 Myocardial fibrosis, a common final pathology in all heart failure causes, is characterized by an increase in collagen volume fraction of myocardial tissue that can be assessed noninvasively using contrast-enhanced cardiovascular magnetic resonance (CMR) techniques.7
See Editorial by Aurigemma and Salerno
Hypertensive LVH is associated with adverse prognosis, above and beyond the effects of blood pressure (BP).8–14 Four LV geometric patterns have conventionally been described: normal, concentric remodeling, concentric hypertrophy, and eccentric hypertrophy,15 but the 3-dimensional (3D) phenotype of LVH shows the true situation to be far more nuanced.16 Both concentric and eccentric LVH patterns are associated with increased cardiovascular events. LV geometry has limited incremental prognostic value when LV mass and other cardiovascular risk factors are considered.10,17–22 Therefore, a better marker of adverse remodeling is needed to identify high-risk hypertensive LVH phenotypes.
Ventricular dilatation and myocardial thickening are 2 important determinants of increased LV mass and myocardial wall stress. We hypothesize that an index of LV end-diastolic volume (EDV) and wall thickness (Remodeling Index [RI]) may provide a more clinically relevant readout of adverse ventricular remodeling by combining the effects of LV volumes and wall thickness in a single metric. Using multi-imaging techniques (CMR and echocardiography), ECG, comprehensive BP assessment (office and 24-hour ambulatory), and cardiac biomarkers (high-sensitive cardiac troponin I/T [hsTnI/T], NT-proBNP [N-terminal pro-B-type natriuretic peptide], and galectin-3), we aim to examine the myocardial response and the potential role of RI in hypertensive patients.
Methods
Derivation of the Novel RI
The Law of LaPlace states the factors that determine LV generated wall stress, σ, as:
(1)where P is intra-LV pressure generated during passive filling (at end of diastole), R is LV radius, and t is LV wall thickness.23,24 Assuming LV to be spherical, LV volume is related to radius (R):
(2)
(3)Substituting Equation 3 into Equation 1, we have
(4)We define 
as theRI, which describes the geometric relationship between LVEDV and wall thickness and it is proportionate to the LV generated wall stress (
). LVEDV and maximum wall thickness (across the 16 segments) were used in the calculation of RI.
Patient Population
The REMODEL study (Response of the Myocardium to Hypertrophic Conditions in the Adult Population) consists of adults with essential hypertension. We excluded individuals with known secondary causes of hypertension; those with previously diagnosed significant coronary artery disease (previous myocardial infarction, ≥70% luminal stenosis on invasive angiography, or positive cardiac stress tests), cerebrovascular events, heart failure, atrial fibrillation; and those with contraindications to gadolinium contrast and CMR (implantable devices, cerebral aneurysmal clips, cochlear implants, estimated glomerular filtration rate <30 mL/min per 1.73m2, severe claustrophobia, and women who are pregnant or breastfeeding).
Healthy volunteers between 20 and 69 years old (n=180) without cardiac symptoms, coronary artery risk factors, and clinical and family history of cardiovascular disease were prospectively recruited from the community. The inclusion and exclusion criteria of this cohort have been described in detail previously.25
Patients in the REMODEL cohort did not have heart failure. We examined the role of RI in patients with hypertension and heart failure with preserved ejection fraction (HFpEF) who had been referred for CMR evaluation. These patients did not have other diagnoses that could account for heart failure, such as ischemic heart disease, valvular heart disease, or infiltrative cardiomyopathies.
The study was conducted in accordance with the Declaration of Helsinki and approved by the local research ethics committee. Written informed consent was obtained from all participants.
Cardiovascular Procedures and Biochemical Markers
All participants in REMODEL underwent comprehensive cardiovascular assessment including 24-hour ambulatory BP, ECG, echocardiography, CMR, and cardiac biochemical markers.
Electrocardiography
A standard 12-lead ECG was obtained in all participants. ECGs were scored according to the Romhilt–Estes score that includes voltage criteria, ST-T abnormalities, QRS duration and other variables to diagnose LVH on ECG.26
Echocardiography
Echocardiography was performed in all hypertensive patients (ProSound F75; Hitachi Aloka Medical Ltd., Tokyo, Japan). Cardiac dimensions, function, and severity of valvular heart disease (if present) were assessed according to the European Association of Echocardiography/American Society of Echocardiography guidelines.15,27,28 Diastolic function was assessed using pulse-wave and tissue Doppler imaging. Trans-mitral early (E), late diastolic velocities, and deceleration time of early filling velocity were measured at the tips of the mitral valve leaflets in the apical 4-chamber view. Early diastolic velocities (e') of the medial and lateral mitral annulus were measured using tissue Doppler imaging. Diastolic function was assessed using the E/e' ratio.
Cardiovascular Magnetic Resonance
CMR was performed in all participants (Siemens Ingenia 1.5T; Siemens AG, Healthcare Sector, Erlangen, Germany). Balanced steady-state free precision cine images of the vertical and horizontal long-axis planes and the sagittal LV outflow tract view were acquired (acquired voxel size 1.6×1.3×8.0 mm; 30 phases per cardiac cycle). Short-axis cines were obtained from the mitral valve annulus to the apex (acquired voxel size 1.6×1.3×8.0 mm; 30 phases per cardiac cycle). Image analysis was performed in our dedicated research laboratory using standardized protocols for measuring cardiac volumes, function and LV mass (CMR42; Circle Cardiovascular Imaging, Calgary, Canada).25 End-diastolic myocardial wall thickness was measured semiautomatically in the short-axis views (50 chords per myocardial slice), according to the standard 16-segment model (Data Supplement). Short-axis slices that did not have complete ring of myocardium were excluded in the wall thickness analysis.
Myocardial fibrosis was assessed using 2 approaches: late gadolinium–enhanced imaging (focal replacement fibrosis) and myocardial T1 mapping (diffuse myocardial fibrosis). Late gadolinium–enhanced imaging started 8 minutes after 0.1 mmol/kg of gadobutrol (Gadovist; Bayer Pharma AG, Germany). An inversion-recovery fast gradient echo sequence was used. The inversion time was optimized to achieve appropriate nulling of the myocardium. Myocardial T1 mapping was performed using the Modified Look-Locker inversion-recovery sequence (flip angle 35°; minimum TI 100 ms; TI increment of 80 ms). Native and postcontrast myocardial T1 (15 minutes after contrast administration) were acquired using a heartbeat acquisition scheme of 5(3)3 and 4(1)3(1)2, respectively. Extracellular volume fraction was quantified using an approach as described previously.29 Recently, we have demonstrated an excellent correlation between interstitial volume on CMR and the amount of histological fibrosis that had an adverse prognostic impact on patients with aortic stenosis.30 Interstitial volume was defined as extracellular volume fraction × myocardial volume, where myocardial volume (mL)=myocardial mass (g)/1.05 g/mL.
Cardiac Biochemical Markers
All biochemical analyses were performed in a single freeze–thaw cycle >3 assay runs using the same lot of reagents in an accredited laboratory (Changi General Hospital, Singapore). Serum NT-proBNP (proBNP II STAT; Roche Diagnostics, Pensberg, Germany) and hsTnT (STAT; Roche Diagnostics, Pensberg, Germany) were assayed using electrochemiluminescence immunoassay on the Cobas E602 analyzer (Roche Diagnostics Asia-Pacific, Singapore). Serum hsTnI (ARCHITECT STAT High-Sensitive Troponin-I; Abbott Diagnostics, Abbott Park, IL) and galectin-3 (ARCHITECT Galectin-3; Abbott Diagnostics) were determined using chemiluminescent microparticle immunoassay on the ARCHITECT i2000SR analyzer (Abbott Laboratories [Diagnostics], Singapore). Blood samples were collected on the day of CMR.
The manufacturer-reported lower limit of detection (LOD) and the 99th percentile upper reference limit for NT-proBNP were 5 and 135 pg/mL, respectively.31 The LOD and 99th percentile upper reference limit for hsTnT were 5 and 14 pg/mL, respectively.32 The LOD for hsTnI was 1.1 ng/L. We have determined previously that the 99th percentile upper reference limit for hsTnI was 26 ng/L.33 Serum galectin-3 had a manufacturer-reported LOD of 1.0 ng/mL.34 All biochemical concentrations lower than the detection levels were assigned a value equivalent to half the LOD.
Statistical Analysis
Continuous variables were assessed for normal distribution using the Shapiro–Wilk test. Data were presented in either mean±SD or median (interquartile range), as appropriate. Depending on the normality of the data, parametric Student t test and 1-way ANOVA or the nonparametric Mann–Whitney U test and Kruskal–Wallis test were used to compare groups of continuous data. Categorical data were compared using the χ2 tests. We used multivariable linear and logistic regression models to assess association between variables, adjusting for potential confounders (age, sex, systolic BP [SBP], treatment duration, and where appropriate, LV mass, and LV concentricity). Log-transformed NT-proBNP, hsTnT/I, and galectin-3 concentrations were used in correlations and regression analyses because of non-normal distribution.
Normal RI ranges were established in healthy volunteers using the 95% prediction interval: mean ± t0.975, n-1 (√(n+1)/n)·(SD). To account for the effects of sample size on the reference range, 95% confidence intervals of the upper and lower reference limits were estimated.35 Values within these confidence limits were considered indeterminate/borderline.25
Analyses were performed using GraphPad Prism 6 (GraphPad Software, Inc., San Diego) and STATA/MP version 13.0 (StataCorp, TX). Statistical significance was taken as a 2-sided P<0.05.
Results
Baseline Characteristics
Patients in REMODEL (n=256; men=66%) were older and had higher body mass index compared with healthy volunteers (n=180; men=51%). Hypertensive patients in REMODEL had close to normal BPs as they were receiving antihypertensive treatment (Table 1). Twelve patients had moderate valvular heart disease diagnosed on echocardiography and corroborated on CMR (aortic regurgitation, n=5; tricuspid regurgitation, n=5; mitral regurgitation, n=2). No patients had aortic stenosis.
Baseline Characteristics of Healthy Volunteers and Patients with Hypertension
Hypertensive LVH and Myocardial Fibrosis
The thickest LV segments were predominantly localized in the basal septum in the majority (74.2%) of patients with hypertension (Figure 1A), with an asymmetrical ratio of 1.36 (1.27–1.48). Conversely, only 4 patients (1.6%) had maximal wall thickening in the apical segments. Regardless of the methods of assessment, SBP accounted for only 5% to 20% of the variance in LV mass (24-hour SBP: r=0.44, P<0.001; office SBP: r=0.22, P<0.01) and maximal wall thickness.
Maximal wall thickening were predominantly localized in the basal anterior segments and septum (A). Midwall myocardial fibrosis was predominantly present in the basal and midventricular septum (B). Maximal wall thickness (mm) and proportion of segments (%) with midwall fibrosis are presented in A and B, respectively.
Thirty-eight patients had midwall fibrosis and 2 had incidental myocardial infarction. Midwall fibrosis was predominantly present in the basal and midventricular septum and can involve the RV insertion points (Figure 1B). Positive correlations were observed between SBP and interstitial volume (24-hour SBP: r=0.36, P<0.001; office SBP: r=0.21, P<0.01), and there were small differences in BPs between those without and with myocardial midwall fibrosis (24-hour SBP: 129±13 versus 134±16 mm Hg, respectively; P=0.04). Conversely, LV mass correlated strongly with myocardial interstitial volume (r=0.91; P<0.001) and was higher in those with midwall fibrosis (65±25 versus 51±11 g/m2; P<0.001; Figure 2). Indeed, LV mass was an independent determinant of myocardial fibrosis (using either CMR approaches) after adjusting for age, sex, SBP, and treatment duration (Data Supplement).
Indexed left ventricular (LV) mass correlated positively with interstitial volume assessed on cardiovascular magnetic resonance (A). Compared with those without midwall myocardial fibrosis, hypertensive patients with midwall fibrosis had increased left ventricular mass index (B) and high-sensitive cardiac troponin I concentrations, a marker of myocardial injury (C). Results in B and C presented in box-and-whiskers plot (Tukey method).
Indexed LV mass and myocardial fibrosis were independently associated with serum cardiac troponin T and I (Figure 2; Data Supplement). As a marker of cardiac wall stress, NT-proBNP was associated with increased indexed LA and LV volumes, LV mass, and myocardial fibrosis (but not RV volumes) independent of age, sex, SBP, and creatinine levels (Data Supplement). Conversely, no correlations were observed between galectin-3 and LV mass (r=−0.07; P=0.35), myocardial interstitial volume (r=−0.03; P=0.71) and LV volumes.
RI as a Marker of Advanced Hypertrophy
We established age- and sex-specific RI reference ranges in healthy volunteers (Figure 3). Women had increased RI when compared with men (7.3±1.3 versus 6.3±1.0; P<0.001) and RI correlated inversely with age (r=−0.43; P<0.001).
Sex- and age-specific reference ranges of Remodeling Index (RI) in a healthy population.
Based on these normal values, 15 patients in the REMODEL cohort had RI values below the normal range. All 15 patients had LVH as defined by age- and sex-specific CMR criteria.25 Compared with patients with hypertension without LVH (n=191; RI=6.1±1.0) and those with hypertensive LVH and normal RI (n=50; RI=5.7±0.8), patients with hypertensive LVH and low RI (n=15; RI=4.0±0.7) were the youngest (45±16 years old; P<0.001) and had a relatively short duration of hypertensive treatment (2.0 years [0.3–3.8 years]; Table 2).
Characteristics of Patients With Hypertension Stratified by the Presence of Left Ventricular Hypertrophy and Remodeling Index
Hypertensive patients with low RI values represented a group with advanced LVH: highest Romhilt–Estes ECG scores, increased LV mass index, most myocardial fibrosis (assessed by interstitial volumes and proportion of patients with replacement fibrosis), impaired diastolic function, and elevated cardiac biochemical markers of cardiac injury and decompensation (Table 2; Figure 4). We further demonstrated the incremental value of RI and the novel classification (normal, hypertensive LVH with normal RI, and hypertensive LVH with low RI) compared with conventional geometric classification (Data Supplement).
The Remodeling Index (RI) identifies a subgroup of hypertensive (HTN) patients with advanced left ventricular hypertrophy (LVH; A). These patients had the highest blood pressures (B), left ventricular mass (C), more myocardial fibrosis (D), and elevated markers of myocardial injury and cardiac decompensation (E and F). Results presented in box-and-whiskers plot (Tukey method).
One patient with hypertension had a higher than normal RI (man=73 years; RI=9.1). Indexed LVEDV was increased for age, whereas LV mass, stroke volume, and systolic function were normal. He had no valvular heart or history of coronary artery disease.
Discussion
To date, this is the largest prospective study to systematically examine the effects of BP on ventricular remodeling using multi-imaging and biochemical approaches. BP correlated only modestly with LV mass (accounting for <20% of the variance observed), and it was not associated with myocardial fibrosis. Instead, LV mass was positively and independently associated with myocardial fibrosis, and both LV mass and myocardial fibrosis were independently associated with circulating markers of myocardial injury and cardiac dysfunction. The novel RI, derived from the biophysical model of myocardial wall stress, risk stratified patients with hypertensive LVH. A lower than normal RI was associated with LVH on CMR, increased myocardial fibrosis and injury and heart failure.
Currently, the diagnosis and management of hypertension relies primarily on brachial BP. However, the difficulties associated with all noninvasive techniques of measuring BP are well recognized.36,37 Contemporary management places great emphasis on achieving BP targets, but the specific targets (particularly in older patients) remain controversial. Compared with previous recommendations, less stringent but different BP targets were recently proposed by all major organizations.38–40 Adding to this complexity, a more recent trial demonstrated a significant reduction in mortality in patients (including >75 years) intensely treated to achieve SBP <120 mm Hg,41 challenging the new targets and increasing uncertainty among physicians. These limitations signal a critical need of a more reliable marker to monitor the progression of hypertensive heart disease.
The myocardium thickens to minimize myocardial wall stress in the presence of elevated BP.2 However, excessive LVH carries an increased risk of adverse cardiac events, independent of BP.8–11 Myocardial fibrosis is an important mediator in the transition between adaptive hypertrophy and cardiac decompensation,4 and it is a common histological hallmark of cardiac decompensation.7,42 Indeed, LV mass and myocardial fibrosis demonstrated significant and independent associations with circulating biomarkers of myocardial injury and cardiac decompensation, over and above the effects of increased BPs. This relationship between the myocardium and adverse outcomes justifies the complementary role of assessing the myocardium in the management of hypertensive LVH.
This study examined a novel myocardial marker, the RI that incorporates LVEDV and myocardial wall thickness. Both are important determinants of myocardial mass and wall stress. In the absence of invasive pressure measurements, myocardial wall stress is estimated based on a spherical biophysical model. The advantage of using a spherical model is the ease of application and its ability to reflect the effects of cardiac geometry on function.45 Exaggerated wall thickening from pressure-overloaded conditions such as hypertension would result in a low RI. In this cohort, ≈6% of all hypertensive patients (23% of those with hypertensive LVH) had low RI according to the normal age- and sex-specific ranges established in 180 healthy volunteers. Hypertensive patients with low RI have LVH, myocardial fibrosis, and elevated biochemical markers of cardiac injury and dysfunction. All patients with ECG strain pattern had low RI. This ECG pattern is highly specific for myocardial fibrosis and has been shown to be associated with worse outcomes in aortic stenosis and hypertension.46–48 The RI provided incremental value to hypertensive LVH in the association with markers of cardiac decompensation.
When LV dilatation exceeds the relative effects of wall thickening to maintain wall stress, RI increases. In this study, only 1 hypertensive patient had a higher than normal RI. Of note, in patients with dilated cardiomyopathy and systolic dysfunction, a higher than normal RI was associated with increased cardiovascular events (Data Supplement).
Clinical Implications
We examined the role of RI in 10 patients with hypertensive HFpEF (7 men; median, 57 years [range, 37–75 years]). All patients with hypertensive HFpEF had LVH and low RI values. The RI values were not significantly different between asymptomatic patients with hypertensive LVH and low RI in REMODEL and those with hypertensive HFpEF (4.1 [3.4–4.5] versus 3.7 [3.4–4.0], respectively; P=0.15). Two patients with hypertensive LVH and low RI developed hypertension-related events over 5.2-month [3.0–7.8-month] follow-up: one was in the emergency department for hypertensive emergency and the other had an acute myocardial infarction. No events occurred in the other patients groups.
The RI is an index easily derived on routine CMR. It holds potential as a marker to monitor progression of disease and response to therapies targeted at the myocardium.49 Hypertensive patients with HFpEF had lower than normal RI, highlighting the potential role of differentiating patients with dyspnea and suspected HFpEF.
Study Limitations
A longer follow-up with higher event rates would be necessary to clearly demonstrate the incremental prognostic value of RI over traditional predictors. The RI was derived using a spherical model according to the LaPlace’s Law. In the spherical model, the radius (R in the wall stress formula) is estimated from LVEDV, which can be measured accurately on routine CMR. Conversely, the ellipsoid model requires 2 to 3 linear measurements in 1 to 2 cardiac views to estimate R (depending on the specific model used). This will not only increase the complexity but also introduce more variation and error in the measurements and calculations. Regardless of the model used, each was associated with systematic differences in assessing wall stresses.45 We have excluded hypertensive patients with impaired estimated glomerular filtration rate <30 mL/min per 1.73 m2 because of the risks of nephrogenic systemic fibrosis. In large population-based studies, the prevalence of stages 4 and 5 chronic kidney disease in hypertensive patients was <5%.50,51 Therefore, the impact of excluding these individuals, if any, is likely small.
Conclusions
The RI is a marker of advanced hypertrophy in patients with hypertensive LVH. Its true potential should be examined in larger cohorts with long-term follow-up.
Acknowledgments
We thank the radiographers of the National Heart Center Singapore for conducting the study, and Abbott for providing the high-sensitive cardiac troponin I reagents and controls. Hitachi Healthcare has kindly provided the echo machine used in this study.
Sources of Funding
The study was supported by the National Medical Research Council, Singapore.
Disclosures
None.
Footnotes
The author is presenting this work at the European Society of Cardiology Scientific Congress meeting in Barcelona, Spain on August 28, 2017.
The Data Supplement is available at http://circimaging.ahajournals.org/lookup/suppl/doi:10.1161/CIRCIMAGING.117.006840/-/DC1.
- Received June 22, 2017.
- Accepted July 26, 2017.
- © 2017 The Authors.
Circulation: Cardiovascular Imaging is published on behalf of the American Heart Association, Inc., by Wolters Kluwer Health, Inc. This is an open access article under the terms of the Creative Commons Attribution Non-Commercial-NoDerivs License, which permits use, distribution, and reproduction in any medium, provided that the original work is properly cited, the use is noncommercial, and no modifications or adaptations are made.
References
CLINICAL PERSPECTIVE
Longstanding hypertension ultimately leads to heart failure. In response to the increased afterload, cardiac hypertrophy is initially compensatory to maintain wall stress and cardiac function. Over time, cardiac decompensation occurs. The transition from adaptive hypertrophy to cardiac decompensation is mediated by myocyte death and myocardial fibrosis. We have developed a novel risk marker (
, where EDV is the left ventricular end-diastolic volume and WT is the maximal myocardial wall thickness) based on a spherical model of LaPlace’s wall stress. Normal Remodeling Index values were established 180 healthy volunteers. With advanced hypertrophy from wall thickening, Remodeling Index values will be lower than normal. In 256 patients with hypertension, patients with hypertensive left ventricular hypertrophy and low Remodeling Index (n=15) had more advanced hypertrophy: increased mass, most myocardial fibrosis, impaired diastolic function, and elevated cardiac biochemical markers of myocardial injury and decompensation. This marker holds important potential in identifying patients with hypertensive LVH at risk of cardiac decompensation.
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