Heart Asia. 2019; 11(1): e011108. ,1 Siew Pang Chan,2,3
Chang Fen Xu,4 Jonathan Yap,4
Arthur Mark Richards,1,3,5 Lieng Hsi Ling,1,2
David Sim,4,6 Fazlur Jaufeerally,6,7
Daniel Yeo,8 Seet Yoong Loh,8
Hean Yee Ong,9 Kui Toh Gerard Leong,10
Tze Pin Ng,2 Shwe Zin Nyunt,2
Liang Feng,6 Peter Okin,11
Carolyn SP Lam, AbstractObjectiveECG markers of heart failure (HF) with preserved ejection fraction (HFpEF) are lacking. We hypothesised that the Cornell product (CP) is a risk marker of HFpEF and has prognostic utility in HFpEF. MethodsCP =[(amplitude of R wave in aVL+depth of S wave in V3)×QRS] was measured on baseline 12-lead ECG in a prospective Asian population-based study of 606 healthy controls (aged 55±10 years, 45% men), 221 hypertensive controls (62±9 years, 58% men) and 242 HFpEF (68±12 years, 49% men); all with EF ≥50% and followed for 2 years for all-cause mortality and HF hospitalisations. ResultsCP increased across groups from healthy controls to hypertensive controls to HFpEF, and distinguished between HFpEF and hypertension with an optimal cut-off of ≥1800 mm*ms (sensitivity 40%, specificity 85%). Age, male sex, systolic blood pressure (SBP) and heart rate were independent predictors of CP ≥1800 mm*ms, and CP was associated with echocardiographic E/e′ (r=0.27, p<0.01) and left ventricular mass index (r=0.46, p<0.01). Adjusting for clinical and echocardiographic variables and log N-terminal pro B-type natriuretic peptide (NT-proBNP), CP ≥1800 mm*ms was significantly associated with HFpEF (adjusted OR 2.7, 95% CI 1.0 to 7.0). At 2-year follow-up, there were 29 deaths and 61 HF hospitalisations, all within the HFpEF group. Even after adjusting for log NT-proBNP, clinical and echocardiographic variables, CP ≥1800 mm*ms remained strongly associated with a higher composite endpoint of all-cause mortality and HF hospitalisations (adjusted HR 2.1, 95% CI 1.2 to 3.5). ConclusionThe Cornell product is an easily applicable ECG marker of HFpEF and predicts poor prognosis by reflecting the severity of diastolic dysfunction and LV hypertrophy. Keywords: electrocardiography, heart failure with normal ejection fraction, hypertensive heart disease Key questionsWhat is already known about this subject?
What does this study add?
How might this impact on clinical practice?
IntroductionHeart failure with preserved ejection fraction (HFpEF) has been studied with great interest in recent times. In addition to increased systemic afterload, ventricular stiffness and impaired diastolic function have also been suggested in the pathophysiology of HFpEF.1–3 The assessment of HFpEF involves objective evidence of diastolic dysfunction in the presence of normal systolic function on transthoracic echocardiography. Left ventricular hypertrophy (LVH), determined by left ventricular mass, has been widely used as a surrogate of diastolic function in the diagnosis of HFpEF.4–6 A quick and simple way to screen for LVH without the use of echocardiography would be through the widely available 12-lead ECG. Several ECG voltage criteria have been developed in the assessment of LVH, including the Sokolow-Lyon and Cornell voltage criteria.7 8 The Cornell product (CP),9 an ECG voltage-duration product, was found to have greater sensitivity for LVH9 10 and has been shown to be associated with diastolic dysfunction.11 We hypothesised that CP would be an alternate way of identifying patients at high risk of HFpEF and sought to determine the implications of CP in patients with HFpEF. MethodsStudy populationThe study population included participants from the Singapore Heart Failure Outcomes and Phenotypes (SHOP) Study,12 a prospective study of consecutive in-patients and outpatients identified with heart failure (HF) from six centres in Singapore followed up over 2 years, as well as healthy controls without HF from the community-based Singapore Longitudinal Ageing Study (SLAS).13 Participants in SLAS were adults randomly sampled from the community via door-to-door census of residents in contiguous precincts within five districts in Southeastern Singapore. All participants underwent detailed clinical profiling with prospective 12-lead resting ECG, comprehensive Doppler echocardiography, phlebotomy for biomarker measurements and were followed up for all-cause death and HF hospitalisations. In compliance with the Declaration of Helsinki, informed consent was obtained from all participants. As this was a prospective study, there was no recall bias and only participants with HF were recruited in the HFpEF group, hence avoiding selection bias. There were minimal missing data, and hence imputation was not performed. Loss to follow-up was minimal at <1%. In this study with 2087 subjects (1100 with HF), participants with reduced EF <50% or left bundle branch block were excluded. The remaining 1069 participants were split into three groups (827 participants from SLAS in both groups I and II and 242 participants from SHOP in group III).
Importantly, the diagnosis of HFpEF was based on the validated clinical diagnosis of HF (the presence of typical symptoms and signs, established by cardiologists and validated by investigators) and the presence of LVEF ≥50% (independently verified in an echocardiography core laboratory). As previously published,14 49 out of 50 HFpEF cases in a substudy satisfied the detailed 2007 European diagnostic criteria for HFpEF.4 ElectrocardiographyResting baseline standard 12-lead ECGs were done at recruitment. ECGs were performed in a standardised fashion across all participating centres. To minimise intercentre and interobserver variability, the same ECG machine (Mortara ELI 250, Milwaukee, Wisconsin, USA) was used across all centres and ECGs calibrated at 25 mm/s and 1 mV/cm were read by a single, independent, trained reader. ECG variables of interest including R wave amplitude in aVL (RaVL), S wave depth in V3 (SV3) and QRS duration were recorded. ECG CP was defined as: CP=((RaVL+SV3)*QRS duration).9 EchocardiographyComprehensive two-dimensional echocardiograms, including M-mode, pulse wave Doppler and tissue Doppler imaging, were performed by experienced sonographers. Commercially available ultrasound systems (Vivid seven and E9, General Electric, Milwaukee, Wisconsin, USA) equipped with broadband transducers were used across all centres. Measurements of ejection fraction, mitral inflow E and A velocities, septal and LV lateral annular early diastolic velocities (e′), LV dimensions including interventricular septum thickness, LV internal diameter and inferolateral wall thickness were made by trained echocardiographers blinded to ECG data. As all patients included in this study had preserved LVEF, average E/e′>14 was used as the definitive marker of diastolic dysfunction in our study as per American Society of Echocardiography recommendations.15 LV mass was calculated using the Cube formula16 and LV mass index (LVMI) obtained by indexing LV mass to body surface area. Statistical analysisBaseline characteristics were reported as percentages (%) for categorical variables and mean±SD or median with IQR for continuous variables. Bivariate analyses were carried out with the χ2 (categorical) or Kruskal-Wallis test (continuous). Pairwise correlations were made between CP and echocardiographic markers of LVMI and E/e′ ratio. An optimal CP cut-off to distinguish between HFpEF and hypertension without HF was identified using receiver operating characteristics (ROC) curves. Kaplan-Meier curves were generated to compare time to all-cause mortality, time to first recurrent HF hospitalisation and time to composite event (all-cause mortality and first recurrent HF hospitalisation) according to the optimal CP cut-off. To ascertain the association of CP with clinical covariates and its prognostic significance at the identified cut-off, a generalised structural equation model (gSEM) was constructed.17 The association between CP and clinical and echocardiographic variables (age, gender, ethnicity, blood pressure, heart rate, E/e′ and LVMI) were determined, and time to events (all-cause mortality, first recurrent HF hospitalisation and composite event) was estimated in patients with HFpEF only. Two-sided statistical tests were performed at 5% level of significance. All data analyses were carried out with Stata MP V.14. ResultsBaseline characteristicsBaseline characteristics of the study population by group are shown in table 1. A total of 1069 adults (median CP 1065 mm*ms (IQR 736–1517)) were included in this study, with 606 healthy controls (55±10 years, 45% men), 221 controls with hypertension but without HF (62±9 years, 58% men) and 242 with HFpEF (68±12 years, 49% men). In the HFpEF group, 86% of participants had hypertension. Median CP increased across groups from 924 mm*ms in healthy controls to 1210 mm*ms in hypertension without HF to 1523 mm*ms in HFpEF (p<0.001) (figure 1). Similarly, there was an increasing trend in age, body mass index, QRS duration (ms), R wave amplitude in aVL, depth of S wave in V3, E/e′, LVMI and N-terminal pro B-type natriuretic peptide (NT-proBNP) across all three groups (table 1). Table 1Baseline characteristics of study population (n=1069)
 Distribution of Cornell product across study population. The optimal CP cut-off for predicting HFpEF from hypertension without HF (Group II and III only) was identified to be greater than or equal to 1800mm*ms, with sensitivity and specificity of 40% and 85%, respectively (area under ROC curve 0.62; 95% CI 0.56 to 0.67). Sex-specific cut-offs were also tested but they did not significantly improve diagnostic accuracy. Age, gender, SBP and heart rate were significant independent predictors of a CP ≥1800 mm*ms (table 2). The associations between the optimal CP cut-off and ethnicity were not significant when compared with the reference Chinese group (table 2). Table 2Association of clinical covariates with CP ≥1800 mm*ms
Association of CP with HFpEFCP ≥1800 mm*ms was significantly associated with sixfold increased odds of HFpEF after adjusting for clinical variables of age, sex, ethnicity, SBP and heart rate (table 3) among patients from Groups II and III. When adjusted for clinical variables and echocardiographic variables of LVMI and mitral E/e′, CP ≥1800 mm*ms was associated with twofold increased odds of HFpEF (table 3). CP correlated positively with NT-proBNP, which was also a significant predictor of HFpEF (adjusted OR (AOR) of logNT-proBNP 6.03, 95% CI 3.76 to 9.69) (r=0.27, p<0.001). However, after adjusting for both clinical and echocardiographic variables, as well as logNT-proBNP, CP remained strongly predictive of HFpEF with threefold increased odds (table 3). Even when analysed as a continuous variable, CP remained strongly predictive with 10% increased odds of HFpEF for every 100 mm*ms increase in CP after adjusting for clinical variables. Table 3Association of CP≥1800 mm*ms with HFpEF
CP was also significantly associated with the echocardiographic markers of diastolic dysfunction, E/e′ (r=0.27, p<0.001) and LVMI (r=0.46, p<0.01). Stratifying by gender, CP maintained its correlation with LVMI (r=0.42, p<0.001 in males and r=0.43, p<0.001 in females). Association of CP with outcomesDuring follow-up of 2 years, there were 29 deaths and 61 first HF admissions from enrolment, all of which occurred in the HFpEF group. The relationships of CP ≥1800 mm*ms to time to events are depicted in table 4. In patients with HFpEF (Group III only), those with CP ≥1800 mm*ms were associated with a twofold increased risk of earlier composite outcomes of all-cause death and recurrent HF hospitalisation after adjustment for age, sex, ethnicity, SBP, heart rate, E/e′, LVMI as well as logNT-proBNP (table 4, figure 2). There was no significant interaction between logNT-proBNP and CP 1800 (pinteraction=0.81) on their association with outcomes. The increased association was noted when all-cause death and HF hospitalisation were accessed individually (table 4). Table 4Association of CP ≥1800 mm*ms with time to events in patients with heart failure with preserved ejection fraction
(A) CP ≥1800 mm*ms and all-cause mortality in HFpEF. (B) CP ≥1800 mm*ms and recurrent HF hospitalisation in HFpEF. (C) CP ≥1800 mm*ms and composite of all-cause mortality and recurrent HF hospitalisation. (A–C) Kaplan-Meier curves of the association of CP at the optimal cut-off of 1800 mm*ms with composite of all-cause mortality and first recurrent HF hospitalisation in patients with HFpEF. CP, Cornell product; HF, heart failure; HFpEF, HF with preserved ejection fraction. DiscussionWe demonstrate that the CP is an important risk ECG marker of HFpEF, and at a cut-off greater or equal to 1800 mm*ms, CP is a strong marker of HFpEF and poorer prognosis. Moreover, its prognostic value is independent of NT-proBNP and age. Association of CP and clinical covariatesThe CP was developed as an extension of the ECG Cornell voltage criteria for better sensitivity in detecting LVH.9 10 Casale et al found significant sex differences in SV3, while age did not influence ECG detection of LVH.7 Similarly, we found that females were less likely to have a CP ≥1800 mm*ms than men, which may be accounted for by their lower LV mass. Apart from gender, we observed that age, heart rate and SBP were independently associated with CP. The association of ECG parameters with age, sex and ethnicity has been previously described, with men having wider QRS and deeper SV3, while age was associated with wider QRS and taller RaVL and Malays with wider QRS duration.18 We observed no inter-ethnic differences in CP, likely due to the small number of Malays and Indians as compared with Chinese. The effect of heart rate on CP is more uncertain, although recent studies have shown reductions in QRS duration with increased heart rates.19 20 The effect of heart rate on RaVL and SV3 remains unknown. Association of CP and HFpEFEven though Molloy et al 10 had previously found sex-specific values for ECG Cornell voltage criteria, we did not find significant differences in the association between CP and HFpEF when sex-specific cut-offs were used. Sex-specific cut-offs in the association between CP and HFpEF were therefore not applied, and a cut-off of CP ≥1800 mm*ms was used in both sexes. The CP has higher sensitivity in patients with more severe LVH.10 Okin et al showed that above a median LVMI of 153 g/m2, CP had a sensitivity of 41% compared with 33% in LVMI <153 g/m2.9 Our study reiterates these findings, showing an increase in CP across the three groups from healthy controls to hypertension to HFpEF, corresponding with higher LVMI in the same rank order. The moderate to strong correlation with LVMI indicates a direct influence of LVH on the constituent ECG components of CP, arising from prolonged impulse conduction in hypertrophied myocardium and velocity changes secondary to intramural fibrosis.10 21 Previous studies have found a diagnostic threshold for LVH at CP of 2440 mm*ms9 10 and 2370 mm*ms more recently in a Japanese study.22 Median CP levels in patients with HFpEF from our study were however lower, suggesting a risk of HF at even lower CP levels. Krepp et al demonstrated that CP was a strong predictor of diastolic dysfunction, with fivefold increased odds when CP was ≥1595 mm*ms.11 Although our study was not intended to determine the relationship between CP and diastolic dysfunction, the correlation between CP and E/e′ (r=0.27, p<0.001) and trend towards HF with higher CP values supports such an association. Our patients with HFpEF had a mean E/e′ ratio of 14.5 and a corresponding median CP of 1523 mm*ms, suggesting that even at lower CP values 1595 mm*ms, patients may already have diastolic dysfunction and be at risk of progression to HF. In contrast, hypertensive participants without HF had a mean E/e′ of 9.6 and a corresponding median CP of 1210 mm*ms. Results from the Dallas Heart Study showed that compared with ECG alone, NT-proBNP had higher sensitivity and lower specificity for LVH, but the combination of NT-proBNP and ECG LVH criteria significantly improved the discrimination of LVH.23 The positive correlation of NT-proBNP with CP and their independent associations with HFpEF further demonstrate that both are complementary markers in screening for LVH,23 Even after accounting for NT-proBNP, CP at the cut-off value of greater than or equal to 1800 mm*ms was still predictive of HFpEF from hypertensive heart disease without HF. The association of CP with HFpEF is likely a reflection of the severity of LVH as well as diastolic dysfunction. Although HFpEF remains a clinical diagnosis requiring history, physical examination and echocardiographic findings, ECGs are widely available, affordable and commonly used to screen symptomatic patients. In this context, the recognition of CP as a marker of increased risk of HFpEF may be useful. Prognostic utility of CPData on the prognostic utility of CP in HFpEF are scarce. The associations of CP with death and HF rehospitalisations in chronic HF was demonstrated by Otaki et al,22 and the incremental value of CP in predicting HF when combined with echocardiographic LVH criteria by Gerdts et al.24 However, both studies included patients with reduced LVEF. Other studies have also shown that CP is a useful predictor of adverse cardiac events and stroke25 26 but did not take LVEF into account. However, in our study of only patients with LVEF ≥50%, we showed that in addition to predicting increased HFpEF hospitalisations, CP ≥1800 also predicts for earlier HF hospitalisations. The association of CP with mortality had previously been established by Sundström et al. At the LVH diagnostic threshold of 2440 mm*ms, CP conferred HRs of 3.56 and 3.82 for cardiovascular and total mortality, respectively, after adjusting for cardiovascular risk factors.27 The Losartan Intervention for Endpoint reduction in hypertension study demonstrated a reduction in HF hospitalisations28 and lower risks of cardiovascular mortality, myocardial infarctions and stroke with CP regression during antihypertensive therapy.29 Our study extends these findings to patients with HFpEF, some of whom were not hypertensive. We report the ability of CP ≥1800 mm*ms to predict worse outcomes in these patients, which was independent of multiple factors known to impact outcomes. Thus, patients may already be at higher risk of HF and mortality, even before florid expression of ECG LVH.27 BNPs have been shown to predict worse outcomes in HFpEF and HFrEF—for a given BNP level, the risk of all-cause mortality and HF hospitalisation is similar in both HFpEF and HFrEF.30 In our study, NT-proBNP was similarly a significant predictor of HF readmissions and all-cause mortality. However, despite the presence of NT-proBNP as a strong predictor of poorer outcomes, CP ≥1800 mm*ms remained independently associated with increased composite events. Our study suggests that in addition to BNP or NT-proBNP, CP may be an inexpensive and readily available prognostic marker among patients with HFpEF. LimitationsThe small number of mortality events limited the survival analyses and reflected brief follow-up. We analysed CP at a single time point but acknowledge that time trends of CP and their relationship to outcomes would be of interest. Participants in our study were all Asians, in particular, a predominantly ethnic Chinese population. Given ethnic variations in the prevalence of hypertension and ECG parameters, this may potentially limit the generalisability of our findings, in particular the cut-off point of greater than or equal to 1800 mm*ms across all populations. Differences between body and heart size, as well as ECG differences between Caucasian and Asian populations are well recognised, and comparative future studies are warranted. ConclusionThe ECG CP is an important risk marker of HFpEF and is independently related to poorer outcomes in HFpEF. It is a useful and easily measured alternative to identify patients at high risk of HFpEF. AcknowledgmentsThe authors thank the sonographers, technicians, nurses and staff at the Cardiovascular Research Institute, National University Heart Centre, Singapore, for their technical and clinical support. FootnotesCSL and TWL contributed equally. Contributors: ET and SPC contributed to data analysis and writing of the manuscript. CFX, JY, AMR, LHL, DS, FJ, DY, SYL, HYO, KTGL, TPN, SZN and LF contributed to the conduction of the study. CFX, SZN and LF contributed to the data acquisition. ET, JY, AMR, LHL, DS, FJ, DY, SYL, HYO, KTGL and TPN contributed to the reporting. ET, AMR, PO, CL and TWL contributed to the planning. ET, SPC, AMR, PO, CL and TWl contributed to the interpretation of data. CFX, JY, AMR, LHL, DS, FJ, DY, SYL, HYO, KTGL, TPN, SZN, LF, PO, CL and TWL contributed to the review of the manuscript. Funding: This work (SHOP
study) was supported by the National Medical Research Council, Singapore (grant no. R-172-003-219-511); the A*STAR-NZ HRC (grant no. JGC 10_027); and the Clinician Scientist Award (CL) to CL, and Singapore Longitudinal Aging Study supported by National Medical Research Council, Singapore (NMRC/CIRG/1348/2012) Competing interests: CL reports grants from National Medical Research Council of Singapore, non-financial support from Boston Scientific, non-financial support from Bayer, non-financial support from Thermofisher, non-financial support from Medtronic, non-financial support from Vifor Pharma, other from Bayer, other from Novartis, other from Takeda, other from Merck, other from Astra Zeneca, other from Janssen Research and Development, other from LLC, other from Menarini, other from Boehringer Ingelheim, other from Abbott Diagnostics, other from Corvia, other from Stealth BioTherapeutics, other from Roche, other from Amgen, outside the submitted work. In addition, CL has a patent PCT/SG2016/050217 pending. CL reports grants from National Medical Research Council, Singapore (grant no. R-172-003-219-511), grants from A*STAR-NZ HRC (grant no. JGC 10_027), grants from Clinician Scientist Award (CL) to CL, TPN reports grants from Singapore Longitudinal Aging Study supported by National Medical Research Council, Singapore (NMRC/CIRG/1348/2012). Patient consent for publication: Not required. Ethics approval: Ethics approval was obtained from the National Healthcare Group Domain Specific Review Board (reference number 2010/00114) and Singhealth Centralised Institutional Review Board (reference number 2010/196/C). Informed consent was obtained from all patients prior to participation. Provenance and peer review: Not commissioned; externally peer reviewed. Author note: All the co-authors listed in this manuscript fulfill criteria of authorship. References1. Lam CSP, Roger VL, Rodeheffer RJ, et al.. Cardiac structure and ventricular-vascular function in persons with heart failure and preserved ejection fraction from Olmsted County, Minnesota. Circulation 2007;115:1982–90. 10.1161/CIRCULATIONAHA.106.659763 [PMC free article] [PubMed] [CrossRef] [Google Scholar] 2. Melenovsky V, Borlaug BA, Rosen B, et al.. Cardiovascular features of heart failure with preserved ejection fraction versus nonfailing hypertensive left ventricular hypertrophy in the urban Baltimore community: the role of atrial remodeling/dysfunction. J Am Coll Cardiol 2007;49:198–207. 10.1016/j.jacc.2006.08.050 [PubMed] [CrossRef] [Google Scholar] 3. Paulus WJ, Tschöpe C. A novel paradigm for heart failure with preserved ejection fraction: comorbidities drive myocardial dysfunction and remodeling through coronary microvascular endothelial inflammation. J Am Coll Cardiol 2013;62:263–71. 10.1016/j.jacc.2013.02.092 [PubMed] [CrossRef] [Google Scholar] 4. Paulus WJ, Tschöpe C, Sanderson JE, et al.. How to diagnose diastolic heart failure: a consensus statement on the diagnosis of heart failure with normal left ventricular ejection fraction by the heart failure and echocardiography associations of the European Society of cardiology. Eur Heart J 2007;28:2539–50. 10.1093/eurheartj/ehm037 [PubMed] [CrossRef] [Google Scholar] 5. Vasan RS, Levy D. Defining diastolic heart failure: a call for standardized diagnostic criteria. Circulation 2000;101:2118–21. [PubMed] [Google Scholar] 6. Yturralde RF, Gaasch WH. Diagnostic criteria for diastolic heart failure. Prog Cardiovasc Dis 2005;47:314–9. 10.1016/j.pcad.2005.02.007 [PubMed] [CrossRef] [Google Scholar] 7. Casale PN, Devereux RB, Kligfield P, et al.. Electrocardiographic detection of left ventricular hypertrophy: development and prospective validation of improved criteria. J Am Coll Cardiol 1985;6:572–80. 10.1016/S0735-1097(85)80115-7 [PubMed] [CrossRef] [Google Scholar] 8. Sokolow M, Lyon TP. The ventricular complex in left ventricular hypertrophy as obtained by unipolar precordial and limb leads. Am Heart J 1949;37:161–86. 10.1016/0002-8703(49)90562-1 [PubMed] [CrossRef] [Google Scholar] 9. Okin PM, Roman MJ, Devereux RB, et al.. Electrocardiographic identification of increased left ventricular mass by simple voltage-duration products. J Am Coll Cardiol 1995;25:417–23. 10.1016/0735-1097(94)00371-V [PubMed] [CrossRef] [Google Scholar] 10. Molloy TJ, Okin PM, Devereux RB, et al.. Electrocardiographic detection of left ventricular hypertrophy by the simple QRS voltage-duration product. J Am Coll Cardiol 1992;20:1180–6. 10.1016/0735-1097(92)90376-X [PubMed] [CrossRef] [Google Scholar] 11. Krepp JM, Lin F, Min JK, et al.. Relationship of electrocardiographic left ventricular hypertrophy to the presence of diastolic dysfunction. Ann Noninvasive Electrocardiol 2014;19:552–60. 10.1111/anec.12166 [PMC free article] [PubMed] [CrossRef] [Google Scholar] 12. Santhanakrishnan R, Ng TP, Cameron VA, et al.. The Singapore heart failure outcomes and phenotypes (shop) study and prospective evaluation of outcome in patients with heart failure with preserved left ventricular ejection fraction (people) study: rationale and design. J Card Fail 2013;19:156–62. 10.1016/j.cardfail.2013.01.007 [PubMed] [CrossRef] [Google Scholar] 13. Tan CSH, Chan YH, Wong TY, et al.. Prevalence and risk factors for refractive errors and ocular biometry parameters in an elderly Asian population: the Singapore longitudinal aging study (SLAS). Eye 2011;25:1294–301. 10.1038/eye.2011.144 [PMC free article] [PubMed] [CrossRef] [Google Scholar] 14. Santhanakrishnan R, Chong JPC, Ng TP, et al.. Growth differentiation factor 15, ST2, high-sensitivity troponin T, and N-terminal pro brain natriuretic peptide in heart failure with preserved vs. reduced ejection fraction. Eur J Heart Fail 2012;14:1338–47. 10.1093/eurjhf/hfs130 [PubMed] [CrossRef] [Google Scholar] 15. Nagueh SF, Smiseth OA, Appleton CP, et al.. Recommendations for the evaluation of left ventricular diastolic function by echocardiography: An Update from the American Society of Echocardiography and the European Association of Cardiovascular Imaging. J Am Soc Echocardiogr 2016;29:277–314. 10.1016/j.echo.2016.01.011 [PubMed] [CrossRef] [Google Scholar] 16. Lang RM, Badano LP, Mor-Avi V, et al.. Recommendations for cardiac chamber quantification by echocardiography in adults: an update from the American Society of echocardiography and the European association of cardiovascular imaging. J Am Soc Echocardiogr 2015;28:1–39. 10.1016/j.echo.2014.10.003 [PubMed] [CrossRef] [Google Scholar] 17. Beran TN, Violato C. Structural equation modeling in medical research: a primer. BMC Res Notes 2010;3:261–7. 10.1186/1756-0500-3-267 [PMC free article] [PubMed] [CrossRef] [Google Scholar] 18. Tan ESJ, Yap J, Xu CF, et al.. Association of age, sex, body size and ethnicity with electrocardiographic values in community-based older Asian adults. Heart Lung Circ 2016;25:705–11. 10.1016/j.hlc.2016.01.015 [PubMed] [CrossRef] [Google Scholar] 19. Chiladakis J, Kalogeropoulos A, Zagkli F, et al.. Effect of heart rate on the intrinsic and the ventricular-paced QRS duration. J Electrocardiol 2015;48:689–95. 10.1016/j.jelectrocard.2015.04.009 [PubMed] [CrossRef] [Google Scholar] 20. Mason JW, Badilini F, Vaglio M, et al.. A fundamental relationship between intraventricular conduction and heart rate. J Electrocardiol 2016;49:362–70. 10.1016/j.jelectrocard.2016.03.008 [PubMed] [CrossRef] [Google Scholar] 21. Hancock EW, Deal BJ, Mirvis DM, et al.. AHA/ACCF/HRS recommendations for the standardization and interpretation of the electrocardiogram: Part V: electrocardiogram changes associated with cardiac chamber hypertrophy: a scientific statement from the American Heart Association electrocardiography and arrhythmias Committee, Council on clinical cardiology; the American College of cardiology Foundation; and the heart rhythm Society. endorsed by the International Society for computerized Electrocardiology. J Am Coll Cardiol 2009;53:992–1002. 10.1016/j.jacc.2008.12.015 [PubMed] [CrossRef] [Google Scholar] 22. Otaki Y, Takahashi H, Watanabe T, et al.. Electrocardiographic left ventricular hypertrophy Cornell product is a feasible predictor of cardiac prognosis in patients with chronic heart failure. Clin Res Cardiol 2014;103:275–84. 10.1007/s00392-013-0646-2 [PubMed] [CrossRef] [Google Scholar] 23. Martinez-Rumayor AA, de Lemos JA, Rohatgi AK, et al.. Addition of highly sensitive troponin T and N-terminal pro-B-type natriuretic peptide to electrocardiography for detection of left ventricular hypertrophy: results from the Dallas heart study. Hypertension 2013;61:105–11. 10.1161/HYPERTENSIONAHA.112.195289 [PMC free article] [PubMed] [CrossRef] [Google Scholar] 24. Gerdts E, Okin PM, Boman K, et al.. Association of heart failure hospitalizations with combined electrocardiography and echocardiography criteria for left ventricular hypertrophy. Am J Hypertens 2012;25:678–83. 10.1038/ajh.2012.31 [PubMed] [CrossRef] [Google Scholar] 25. Sosner P, Cabasson S, Hulin-Delmotte C, et al.. Effect of Cornell product and other ECG left ventricular hypertrophy criteria on various cardiovascular endpoints in type 2 diabetic patients. Int J Cardiol 2014;175:193–5. 10.1016/j.ijcard.2014.04.242 [PubMed] [CrossRef] [Google Scholar] 26. Ishikawa J, Ishikawa S, Kabutoya T, et al.. Cornell product left ventricular hypertrophy in electrocardiogram and the risk of stroke in a general population. Hypertension 2009;53:28–34. [PMC free article] [PubMed] [Google Scholar] 27. Sundström J, Lind L, Arnlöv J, et al.. Echocardiographic and electrocardiographic diagnoses of left ventricular hypertrophy predict mortality independently of each other in a population of elderly men. Circulation 2001;103:2346–51. 10.1161/01.CIR.103.19.2346 [PubMed] [CrossRef] [Google Scholar] 28. Okin PM, Devereux RB, Harris KE, et al.. Regression of left ventricular hypertrophy is associated with less hospitalization for heart failure in hypertensive patients. Ann Intern Med 2007;147:311–9. [PubMed] [Google Scholar] 29. Okin PM, Devereux RB, Jern S, et al.. Regression of electrocardiographic left ventricular hypertrophy during antihypertensive treatment and the prediction of major cardiovascular events. JAMA 2004;292:2343–9. 10.1001/jama.292.19.2343 [PubMed] [CrossRef] [Google Scholar] 30. van Veldhuisen DJ, Linssen GCM, Jaarsma T, et al.. B-type natriuretic peptide and prognosis in heart failure patients with preserved and reduced ejection fraction. J Am Coll Cardiol 2013;61:1498–506. 10.1016/j.jacc.2012.12.044 [PubMed] [CrossRef] [Google Scholar] Articles from Heart Asia are provided here courtesy of BMJ Publishing Group What does minimal voltage criteria for LVH?Suggested voltage criteria for LVH include:
The sum of the S wave in v1 or v2, PLUS the R wave in v5 or 6 ≥35 mm.
Can LVH be a normal variant?Left ventricular hypertrophy by voltage criteria alone is a normal variant. Intraventricular conduction delay is when the QRS complex is greater than or equal to 0.12 seconds and does not appear like a right or left bundle branch block.
What does LVH show on ECG?ECG changes seen in left ventricular hypertrophy (LVH) and right ventricular hypertrophy (RVH). The electrical vector of the left ventricle is enhanced in LVH, which results in large R-waves in left-sided leads (V5, V6, aVL and I) and deep S-waves in right-sided chest leads (V1, V2).
Can ECG be wrong about LVH?Conclusion: ECG criteria for the diagnosis of LVH had a relatively low sensitivity, and high specificity. The accuracy was in the range of 0.71-0.80.
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Minimal voltage criteria for lvh may be normal variant
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