Europace Advance Access originally published online on October 12, 2007
Europace 2007 9(11):1031-1037; doi:10.1093/europace/eum133
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
CARDIAC RESYNCHRONISATION THERAPY
Late gadolinium enhancement-cardiovascular magnetic resonance as a predictor of response to cardiac resynchronization therapy in patients with ischaemic cardiomyopathy
1 Department of Cardiology, University of Birmingham, Good Hope Hospital, Rectory Road, Sutton Coldfield, West Midlands B75 7RR, UK; 2 City and Sandwell Hospitals, Birmingham, UK; 3 Department of Cardiology, University of Birmingham, Queen Elizabeth Hospital, Birmingham, UK
Manuscript submitted 25 November 2006. Accepted after revision 8 June 2007.
* Corresponding author. Tel: +44 121 3786604; fax: +44 121 3786188. E-mail address: francisco.leyva{at}goodhope.nhs.uk
 |
Abstract |
|---|
 Top Abstract IntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
Aim: To determine whether myocardial scarring, quantified using late gadolinium enhancement-cardiovascular magnetic resonance (LGE-CMR), predicts response to cardiac resynchronization therapy (CRT).
Methods and results: A total of 45 patients with ischaemic cardiomyopathy [age 67.1 ± 10.4 years (mean ± SD)] underwent assessment of 6 min walking distance (6MWD) and quality of life (QoL) before and after CRT. Scar size (percentage of left ventricular mass), location, and transmurality were assessed prior to CRT using LGE-CMR. Responders (survived for 1year with no heart failure hospitalizations, and improvement by 
1 NYHA classes or 25% 6MWD) had a higher left ventricular ejection fraction (P = 0.048), smaller scars (<33%) (P = 0.009), and fewer scars with 51% transmurality (P = 0.002). Scar size correlated negatively with change in 6MWD (r = –0.54, P < 0.001) and positively with changes in QoL scores (r = 0.35, P = 0.028). Responder rates in patients with <33% scar were higher than in those with 33% scar (82 vs. 35%, P < 0.01). Responder rates in patients with scar transmurality <51% were higher than in those with 51% (89 vs. 46%, P < 0.01). Among the patients with posterolateral scars, a transmurality value of 51% was associated with a particularly poor response rate (23%), compared with scars with <51% transmurality (88%, P < 0.001). In multivariate analyses, both scar size (P = 0.022) and transmurality (P = 0.004) emerged as predictors of response. In patients with posterolateral scars, pacing outside the scar was associated with a better responder rate than pacing over the scar (86 vs. 33%, P = 0.004).
Conclusions: In patients with ischaemic cardiomyopathy, a scar size 33%, a transmurality 51%, and pacing over a posterolateral scar are associated with a suboptimal response to CRT.
Key Words: Cardiac resynchronization therapy, Heart failure, Cardiovascular magnetic resonance, Myocardial viability
|
Introduction |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
The Cardiac Resynchronisation Heart Failure (CARE-HF) study has recently shown that, in patients with heart failure, cardiac resynchronization therapy (CRT) leads to a 36% reduction in all-cause mortality.1
Other benefits include an improvement in symptoms and a reduction in hospitalizations.1–3 It is well recognized, however, that the clinical response to CRT is difficult to predict, with as many as 20–30% of patients failing to respond.4 Because CRT appears to work by reducing mechanical dyssynchrony, increasing attention has been focused on the latter as a possible predictor of clinical response to CRT. QRS duration was considered a surrogate measure of mechanical dyssynchrony, but recent studies refute this assumption.5,6 Numerous methods of assessing mechanical dyssynchrony directly using echocardiography have also emerged.5–9 Using such techniques, some reports have demonstrated that clinical benefit is predicted by the magnitude of mechanical dyssynchrony.4 Importantly, however, not all patients with dyssynchrony improve following CRT.
In the field of revascularization, it is well established that functional myocardial recovery is inversely related to the extent of myocardial scarring.10 In a study using late gadolinium-enhancement-cardiovascular magnetic resonance (LGE-CMR), Bleeker et al.11 have recently shown that in patients with a transmural posterolateral left ventricular (LV) scar, CRT did not lead to a reduction in LV dyssynchrony or to clinical improvement. In this study, we have assessed the impact of scar size as well as location and transmurality on the response to CRT. The effect of lead position in relation to scar tissue and to clinical benefit was also assessed.
|
Methods |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
Patients
The study was carried out at Good Hope Hospital. Subjects were recruited during the period from July 2002 to March 2006, during which 161 patients underwent CRT, 118 of whom had ischaemic cardiomyopathy and 43 of whom had non-ischaemic cardiomyopathy. Patients who underwent successful biventricular pacemaker implantation and LGE-CMR were included in this study. The following inclusion criteria were adopted: (1) heart failure because of coronary heart disease; (2) New York Heart Association (NYHA) class III or IV; (3) attendance to a dedicated heart failure clinic to achieve maximum tolerated treatment with diuretics, angiotensin-converting enzyme inhibitors or angiotensin-II receptor blockers, beta-blockers, spironolactone, and digoxin; (4) a left bundle branch block, with a QRS duration
120ms; and (5) left ventricular ejection fraction (LVEF) 
35%. Exclusion criteria included (1) contraindications to cardiac pacing, (2) myocardial infarction or acute coronary syndrome within the previous 3 months, (3) presence of or indications for an implantable cardioverter-defibrillator, (4) severe structural valvular heart disease, (5) presence of co-morbidities likely to threaten survival for 12months, (6) pulmonary oedema requiring iv diuretics in the previous week, and (7) intermittent or chronic atrial fibrillation or atrial flutter. All participants had undergone coronary angiography. The clinical diagnosis of heart failure (HF) was made on the basis of documented evidence of LV systolic dysfunction on echocardiography. The diagnosis of ischaemic cardiomyopathy was made if LV systolic dysfunction was associated with a history of myocardial infarction12 and if there was angiographically documented coronary heart disease (>50% stenosis in 1 coronary arteries). The findings of LGE-CMR were also used to distinguish between ischaemic from non-ischaemic cardiomyopathy, as suggested by Assomull et al.13 Patients with LV dysfunction in combination with the finding of transmural or subendocardial late gadolinium uptake were classified as having ischaemic cardiomyopathy, whereas patients with LV dysfunction and no gadolinium uptake, patchy uptake, or mid-wall hyperenhancement were classified as having non-ischaemic cardiomyopathy. The latter were excluded from the study. The study conforms with the Declaration of Helsinki. All patients gave written informed consent and the study was approved by the North Birmingham Ethics Committee.
Study design
This is a single-centred, uncontrolled, observational study. Patients referred for CRT underwent pacemaker implantation during an elective admission. Patients underwent a clinical assessment, including a 6 min walk test,14 (the primary endpoint) and a quality of life (QoL) assessment using Minnesota Living with Heart Failure questionnaire15 (the secondary endpoint) (S.C., P.F., and S.A.M.) on the day prior to implantation and at 1.48 years after implantation. Echocardiography and LGE-CMR studies were undertaken within a month prior to implantation. Patients were classified as responders if they satisfied all the following criteria: (1) survival for 1year following implantation; (2) no hospitalizations for HF for 1year following implantation, and (3) improvement by 1 NYHA classes or by 25% in 6 min walking distance (6MWD). In patients who died, the clinical and echocardiographic data at follow-up pertains to the latest available follow-up.
Device therapy
None of the patients had previously been paced. Transvenous biventricular pacemaker implantation was undertaken using standard techniques under local anaesthesia. Patients underwent a pacemaker check and transmitral Doppler-directed optimization of atrioventricular delay16 prior to discharge and at the scheduled visit thereafter. Generators used included the InSync III, model 8042 (Medtronic Inc), Frontier II (St Jude Medical Inc), Stratos LV (Biotronik) and Contak Renewal TR2 (Boston Scientific).
The LV lead was placed in the venous tributary preferred by the implanter, who was blinded to the CMR study. Lead placement following implantation was determined retrospectively using Mortensen's o'clock method,17 which employs bi-plane fluoroscopy. In the left anterior oblique view, the coronary sinus encircles the mitral ring with its tributaries radiating out like the hands of a clock. In the right anterior oblique view, the LV is divided into basal, mid-ventricular, and apical segments. The distance from the mitral ring to the lead tip was also taken, using the lead tip coil as the distance reference in that plane. The exact localization of the lead tip in relation to myocardial scarring was determined using the o'clock position and the mitral ring-to-lead tip distance. The implanter was blinded to the results of the CMR scan.
Echocardiography
Two-dimensional echocardiography was performed using System 5 scanner (Vingmed-General Electric). Standard left parasternal long-axis and short-axis, and apical, four-, five-, and two-chamber views were obtained. Digital images were stored for off-line analysis (EchoPAC, Vingmed-General Electric). Left ventricular volumes were estimated through Simpson's equation by planimetry of apical four-chamber views. The frame at the beginning of the QRS complex was used to estimate end-diastolic volume (LVEDV), whereas the frame with the smallest ventricular area just prior to mitral valve opening was used to estimate end-systolic volume (LVESV). LVEF was derived according to the formula (LVEDV – LVSEV/LVEDV) x 100.
Cardiovascular magnetic resonance
Images were acquired on a 1.5 Tesla scanner (Signa, General Electric Healthcare Worldwide, Slough, UK) using a phased array cardiac coil during repeated 8-second breathholds. A short-axis stack of LV images was acquired using a steady state in free precession sequence (repetition time, 3.0–3.8 ms; excitation time, 1.0 ms; image matrix, 224 x 224; field of view, 36–42 cm; flip angle, 45°) in sequential 8 mm slices (2 mm inter-slice gap) from the atrioventricular ring to apex. Left ventricular volumes, ejection fraction, and mass (myocardial density = 1.05 g/cm3) were quantified using manual planimetry of all short-axis SSFP cine images with MASS analysis software (Medis, Leiden, The Netherlands).
For the LGE-CMR study, gadolinium-diethylenetriamine pentaacetic acid (0.1mmol/kg) was administered intravenously, and images were acquired after 10 min using a segmented inversion-recovery technique in identical short-axis slices. Inversion times were adjusted to null normal myocardium (260–400 ms). Quantification of myocardial scarring was carried out by planimetry of hyperenhanced tissue on LGE-CMR images, assumed to represent scar tissue. Because of heart size and shape, the number of slices per short-axis stack varied from six to eight. Infarct volume was calculated in cubic centimetre by multiplying the planimetred area in each segment by the slice thickness. Scar volume was expressed as percentage of LV myocardial volume in the diastolic phase. Examples of LGE-CMR images are shown in Figure 1. The observer was blinded to clinical data.
|
Transmurality was assessed on LGE images using a 17-segment model.18
A scar was regarded as having 51% transmurality if its transmurality was 51% in any of these 17 segments.
Statistical analysis
Continuous variables are expressed as mean ± SD. Comparisons between normally distributed continuous variables were made using ANOVA. Differences between categorical variables were assessed using the 
2 test test. The ability of percentage of scar volume to predict the changes in 6MWD and QoL was assessed using logistic regression analyses. Receiver-operating characteristic (ROC) curves were used to derive optimal cut-off points for scar size. The value of percentage of scar size with the optimum sensitivity and specificity for the differentiation between responders and non-responders was 33%. Follow-up time failed to emerge as a significant predictor when it entered as a covariate in all analyses. Statistical analyses were performed using Statview (Cary, NC, USA). A two-tailed P-value of <0.05 was considered statistically significant.
|
Results |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
As shown in Table 1, 64% of the study sample responded to CRT. Responders and non-responders were well matched for age, sex, NYHA class, QRS duration (range, 120–233ms), co-morbidities, and medication. With regard to CMR variables, the non-responder group had a lower LVEF (P = 0.048), a higher scar size (P = 0.009), and a greater number of scars with
51% transmurality (P = 0.002). After a mean follow-up of 540 days, there was neither improvement in LVEF, nor evidence of negative LV remodelling in either responders or non-responders (Table 2).
|
|
Effect of scar size
As shown in Figure 2, percentage of scar correlated negatively with change in 6MWD (r = –0.54, P < 0.0001) and positively with changes in QoL scores (r = 0.35, P = 0.028). At a cut-off of <33%, scar size predicted a response to CRT, with a sensitivity of 79% and a specificity of 69% [area under ROC curve (AUC) = 0.74, P = 0.016)] (Figure 3). A scar size cut-off of 15% predicted a response to CRT with a sensitivity of 27% and a specificity of 87%, whereas a cut-off of 40% predicted a response to CRT with a sensitivity of 83%, but a specificity of 50%. As shown in Table 3, the responder rate in patients with <33% scar was 2.3 times greater than that in patients with
33% scar (P < 0.01). Increasing scar size to 33% in scars with 51% transmurality or in scars of any location was associated with a poorer response to CRT.
|
|
|
Effect of scar transmurality
As shown in Table 3, the responder rate in scars with <51% transmurality was 1.9 times the responder rate in the group with
51% transmurality. Increasing transmurality to 51% in scars 33% in size was associated with a poorer response to CRT (P < 0.05). In patients with posterolateral scars, a transmurality of 51% was associated with a poor response to CRT (P < 0.001). A tendency towards a poor response with increasing transmurality was observed in patients with non-posterolateral scars, but this did not reach the statistical significance.
Effect of scar location
As shown in Table 3, the responder rate is higher in patients with posterolateral scars compared with patients with non-posterolateral scars, but this difference did not reach statistical significance. Among scars with 51% transmurality, however, a posterolateral location was associated with a significantly worse responder rate than scars with <51% transmurality (23 vs. 69%, P < 0.05).
Scar size, transmurality, and location combined
The relative contribution of scar size, transmurality, and location to response was explored using logistic regression. As shown in Table 4, both scar size (P = 0.003) and transmurality (P = 0.007) emerged as significant predictors of response. In multivariate analyses, scar size (P = 0.022) and transmurality (P = 0.004) also emerged as predictors of response, whereas scar location failed to reach the statistical significance.
|
Effect of pacing over the scar
Of the 29 patients with a posterolateral scar, 14 underwent CRT with the LV lead deployed outside the scar and 15 with the lead over the scar. In patients with the LV lead deployed outside the scar, 6WMD increased from 300.0 ± 107.2 to 370.4 ± 110.1 m (P = 0.011) and QoL scores improved from 46.2 ± 20.3 to 19.2 ± 15.4 (P < 0.001). In contrast, neither 6MWD or QoL improved in patients receiving CRT with the LV lead deployed over the scar (Figure 4). Pacing outside the scar was associated with a better responder rate than pacing over the scar [12/14 (86%) vs. 5/15 (33%), P = 0.004].
|
|
Discussion |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
In this study, we have explored the clinical response to CRT in relation to the extent of myocardial scarring, assessed using LGE-CMR. We have shown that, in patients with ischaemic cardiomyopathy and conventional indications for CRT, improvements in exercise capacity and QoL following CRT are inversely related to the extent of myocardial scarring. A scar transmurality of
51% and pacing over the scar were also associated with a suboptimal response to CRT.
The clinical response to treatments such as revascularization in patients with LV dysfunction is critically dependent on the presence of viable myocardium.19–22 Similar findings have been shown in relation to beta-blockade in patients with HF.23 Although CRT improves cardiac performance by different mechanisms to revascularization, the relationship between myocardial scarring and subsequent clinical improvement still holds. In revascularization studies, clinical benefit decreases markedly when the area of viable myocardium reaches a critical size.24,25 In the present study, a scar volume of 33% appears to be the best cut-off for the prediction of favourable response to CRT. White et al.26 have identified a lower cut off of 15% for scar size as the best predictor of response. In that study, however, only 12 of 23 patients studied had a history of myocardial infarction and 5 of 23 had no scar at all. The inclusion in our study of patients only with a history of myocardial infarction and with myocardial scar on LGE-CMR is perhaps responsible for the higher threshold for percentage of scar size identified. Notwithstanding, White et al.26 found that septal scars of 40% provided a 100% sensitivity and specificity for a response to CRT. Taken together, both studies support the hypothesis that there is a limit of scar size beyond which resynchronization becomes ineffective.
We have also found an association between increasing transmurality and poor response to CRT. Across the study group, the response to CRT in patients with a transmurality of 51% was half the response observed in patients with a transmurality of <51%. In posterolateral scars, a transmurality of 51% was associated with almost a four-fold reduction in response. These findings are consistent with revascularization studies showing that an increase in the transmurality value is associated with a suboptimal response to revascularization, i.e. with reduced myocardial viability.21
With regard to scar location, a trend towards a lower response in patients with a posterolateral scar. Statistical significance for this difference, however, was only reached after taking into account transmurality. Accordingly, the symptomatic responder rate in patients with a posterolateral scar of transmurality value of 51% was 23%. These findings are consistent with those of Bleeker et al.11, who demonstrated that in patients with a transmural posterolateral scar, CRT does not lead to improvements in 6MWD or QoL. A further finding from this study is that pacing over the scar was associated with a lack of response to CRT, both in terms of 6MWD and QoL. Several factors might contribute to this. First, scar tissue does not contract. Secondly, pacing over a scar is likely to lead to suboptimal resynchronization of the neighbouring myocardium, as electrical conduction is slower over scar tissue.27,28
The observed mortality rate of 33% over 1.48 years is admittedly high, as is the absence of reverse remodelling. This may be because of the inclusion of patients with, exclusively, ischaemic cardiomyopathy. This is in contrast to the CARE-HF study, in which 40% of patients in the paced group had ischaemic cardiomyopathy. Moreover, our study involves a greater proportion of patients in NYHA class IV (22%) than the CRT arms of the Multicenter InSync Randomized Clinical Evaluation (MIRACLE) (9.9%)2 and the Multisite Stimulation in Cardiomyopathies (MUSTIC) (0%)3 studies. Patients in this study also had lower 6MWD (275 m) than in the MIRACLE (307.2 m) and the MUSTIC (399 m) studies.
Limitations of the study
Our measure of myocardial scarring does not take into account the effects of myocardial thinning. If thinning has occurred, the planimetred area of myocardial scar is likely to be an underestimation of the original scar size. Our finding of 33% as a cut-off for clinical response following CRT is the result of a retrospective analysis. Clearly, this threshold would be different if patients were not selected on the basis of QRS duration. These finding therefore requires confirmation in a validation series.
|
Conclusions |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
We conclude that the extent of myocardial scarring, assessed using LGE-CMR, is a strong negative predictor of clinical benefit following CRT in patients with ischemic cardiomyopathy. Scar transmurality and a posterolateral scar location were also found to influence the response to CRT negatively. In patients with posterolateral scars, pacing over the scar was associated with a suboptimal response. These findings illustrate how LGE-CMR undertaken prior to implantation can predict the likely benefit of CRT in individual patients. Moreover, this imaging modality also provides useful information for guiding LV lead deployment.
|
Acknowledgements |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
We are grateful to Lisa Ball, Janet Brashaw-Smith, and Nick Irwin for their invaluable contribution to the follow-up of patients included in this study. We are also grateful to Medtronic Inc. for their continued support.
Conflict of interest: S.C. and S.A.M. held research fellowships sponsored by Medtronic Inc. F.L. has also received sponsorship from St Jude Medical Inc.
|
References |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionConclusionsAcknowledgementsReferences |
|---|
[1] Cleland JGF, Daubert JC, Erdmann E, Freemantle N, Gras D, Kappenberger L, et al. for the Cardiac Resynchronization-Heart Failure (CARE-HF) study investigators. The effect of cardiac resynchronization on morbidity and mortality in heart failure. N Eng J Med (2005) 352:1539–49.
[2] Abraham WT, Fisher WG, Smith AL, Deluergio DB, Leon AR, Kocovic DZ, et al, for the MIRACLE study group. Cardiac resynchronization in chronic heart failure. N Engl J Med (2002) 346:1845–53.
[3] Cazeau S, Leclercq C, Lavergene T, Walker S, Varma C, Linde C, et al, for the Multistimulation in Cardiomyopathies (MUSTIC) Study Investigators. Effects of multisite biventricular pacing in patients with heart failure and interventricular conduction delay. N Engl J Med (2001) 344:873–80.
[4] Kass DA. Ventricular resynchronization: pathophysiology and identification of responders. Rev Cardiovasc Med (2003) 4:S3–13.
[5] Yu CM, Fung WH, Lin H, Zhang Q, Sanderson JE, Lau CP. Predictors of left ventricular reverse remodeling after cardiac resynchronization therapy for heart failure secondary to idiopathic dilated or ischemic cardiomyopathy. Am J Cardiol (2003) 91:684–8.[CrossRef][Web of Science][Medline]
[6] Yu CM, Yang H, Lau CP, Wang Q, Wang S, Lam L, et al. Regional left ventricle mechanical asynchrony in patients with heart disease and normal QRS duration: implication for biventricular pacing therapy. Pacing Clin Electrophysiol (2003) 26:562–570.[CrossRef][Medline]
[7] Nelson GS, Curry CW, Wyman BT, Kramer A, Declerck J, Talbot M, et al. Predictors of systolic augmentation from left ventricular pre excitation in patients with dilated cardiomyopathy and intraventricular conduction delay. Circulation (2000) 101:2703–9.
[8] Søgaard P, Kim WK, Jensen HK, Mortensen P, Pedersen AK, Kristensen BO, et al. Impact of acute biventricular pacing on left ventricular performance and volumes in patients with severe heart failure. A tissue Doppler and three dimensional echocardiographic study. Cardiology (2001) 95:173–82.[CrossRef][Web of Science][Medline]
[9] Søgaard P, Egeblad H, Kim WY, Jensen HK, Pedersen AK, Kristensen BO, et al. Tissue Doppler imaging predicts improved systolic performance and reversed left ventricular remodeling during long-term cardiac resynchronization therapy. J Am Coll Cardiol (2002) 40:723–30.
[10] Depre C, Vanoverschelde JL, Melin JA, Borgers M, Bol A, Ausma J, et al. Structural and metabolic correlates of reversibility of chronic left ventricular ischemic dysfunction in humans. Am J Physiol (1995) 268:H1265–75.[Web of Science][Medline]
[11] Bleeker GB, Kaandorp TAM, Lamb HJ, Boersma E, Steendijk P, de Roos A, et al. Effect of posterolateral scar tissue on clinical and echocardiographic improvement after cardiac resynchronization therapy. Circulation (2006) 113:969–76.
[12] Alpert JS, Thygesen K, Antman E, Bassand JP. Myocardial infarction redefined—a consensus document of The Joint European Society of Cardiology/American College of Cardiology Committee for the redefinition of myocardial infarction. J Am Coll Cardiol (2000) 36:959–69.
[13] Assomull RG, Prasad SK, Lyne J, Smith G, Burman ED, Khan M, et al. Cardiovascular magnetic resonance, fibrosis, and prognosis in dilated cardiomyopathy. J Am Coll Cardiol (2006) 48:1977–85.
[14] Guyatt GH, Sullivan MJ, Thompson PJ. The 6-minute walk: a new measure of exercise capacity in patients with chronic heart failure. Can Med Assoc J (1985) 132:919–23.[Abstract]
[15] Rector TS, Kubo SH, Cohn JN. Patient's self-assessment of their congestive heart failure. Content, reliability and validity of a new measure—The Minnesota living with heart failure questionnaire. Heart Failure (1987) 3:198–207.
[16] Ritter P, Padeletti L, Gillio-Meina L, Gaggini G. Determination of the optimal atrioventricular delay in DDD pacing. Comparison between echo and peak endocardial acceleration measurements. Europace (1999) 1:126–30.
[17] Albertsen AE, Nielsen JC, Pedersen AK, Hansen PS, Jensen HK, Mortensen PT. Left ventricular lead performance in cardiac resynchronization therapy: impact of lead localization and complications. Pacing Clin Electrophysiol (2005) 28:483–8.[CrossRef][Medline]
[18] Cerqueira MD, Weissman NJ, Dilsizian V, Jacobs AK, Kaul S, Laskey WK, et al. Standardized myocardial segmentation and nomenclature for tomographic imaging of the heart: a statement for healthcare professionals from the Cardiac Imaging Committee of the Council of the American Heart Association. Circulation (2002) 105:539–42.
[19] Allman KC, Shaw LJ, Hachamovitch R, Udelson JE. Myocardial viability testing and impact of revascularization on prognosis in patients with coronary artery disease and left ventricular dysfunction: a meta-analysis. J Am Col Cardiol (2002) 39:1151–8.
[20] Wu E, Judd RM, Vargas JD, Klocke FJ, Bonow RO, Kin RJ. Visualisation of presence, location and transmural extent of healed Q-wave and non-Q-wave myocardial infarction. Lancet (2001) 357:21–28.[CrossRef][Web of Science][Medline]
[21] Kim RJ, Wu E, Rafael A, Chen E-L, Parker MA, Simonetti O, Klocke FJ, Bonow RO, Judd RM. The use of contrast-enhanced magnetic resonance imaging to identify reversible myocardial dysfunction. N Engl J Med (2000) 343:1445–53.
[22] Bellenger NG, Yousef Z, Kajappan K, Marber MS, Pennell DJ. Infarct viability influences ventricular remodelling after late recanalisation of an occluded infarct related artery. Heart (2005) 91:478–83.
[23] Bello D, Shah DJ, Farah GM, Di Luzio S, Parker MA, Johnson M, et al. Gadolinium cardiovascular magnetic resonance predicts myocardial dysfunction and remodelling in patients with heart failure undergoing beta-blocker therapy. Circulation (2003) 108:1945–53.
[24] Meluzin J, Cerny J, Frelich M, Stetka F, Spiranova F, Popelova J, et al. Prognostic value of the amount of dysfunctional but viable myocardium in revascularized patients with coronary artery disease and left ventricular dysfunction. J Am Col Cardiol (1998) 32:912–20.
[25] Lee KS, Marwick TH, Cook SA, Go RT, Fix JS, James KB, et al. Prognosis of patients with left ventricular dysfunction, with and without viable myocardium after myocardial infarction. Relative efficacy of medical therapy and revascularization. Circulation (1994) 90:2687–94.
[26] White JA, Yee R, Yuan X, Krahn A, Skanes A, Parker M, et al. Delayed enhancement magnetic resonance imaging predicts response to cardiac resynchronization therapy in patients with intraventricular dyssynchrony. J Am Coll Cardiol (2006) 48:1953–60.
[27] Reddy VY, Wrobleski D, Houghtaling C, Josephson ME, Ruskin JN. Combined epicardial and endocardial electroanatomic mapping in a porcine model of healed myocardial infarction. Circulation (2003) 107:3236–42.
[28] Schwartzman D, Chang I, Michele JJ, Moritznik MS, Foster KR. Electrical impedance properties of normal and chronically infarcted ventricular myocardium. J Interv Card Electrophysiol (1999) 3:213–24.[CrossRef][Web of Science][Medline]
CiteULike 
Connotea 
Del.icio.us What's this?
This article has been cited by other articles:
|
|
 |
|
  P. Lancellotti, M. Senechal, M. Moonen, E. Donal, J. Magne, E. Nellessen, E. Attena, B. Cosyns, P. Melon, and L. Pierard Myocardial contractile reserve during exercise predicts left ventricular reverse remodelling after cardiac resynchronization therapy Eur J Echocardiogr, July 1, 2009; 10(5): 663 - 668. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 F. Z. Khan, M. S. Virdee, S. P. Fynn, and D. P. Dutka Left ventricular lead placement in cardiac resynchronization therapy: where and how? Europace, May 1, 2009; 11(5): 554 - 561. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||