652 Myocardial work in patients undergoing transcatheter aortic valve implantation: clinical value and implications for outcome

Aims Non-invasive myocardial work (MW) quantification has emerged in the last years as an alternative echocardiographic tool for myocardial function assessment. This new parameter provides a less loading-dependent evaluation of myocardial performance through the combined assessment of global longitudinal strain (GLS) and non-invasive left ventricle (LV) pressures. The role of MW as a marker of cardiac dysfunction and reverse remodelling in patients with severe aortic stenosis (AS) after aortic valve implantation (TAVI) has not been adequately investigated. This study aims to evaluate MW indices as early echocardiographic markers of LV reverse remodelling within a month after TAVI and their prognostic value. Methods and results We conducted a single-centre prospective study, enrolling 70 consecutive patients (mean age 80.1 ± 5.5 years) with severe AS undergoing TAVI between 2018 and 2020, selected from the EffecTAVI registry. Exclusion criteria were prior valve surgery, severe mitral stenosis, permanent atrial fibrillation, left bundle branch block (LBBB) at baseline, and suboptimal quality of speckle-tracking image analysis. Echocardiographic assessment was performed before TAVI and at 30-day follow-up. Clinical, demographic, and resting echocardiographic data were recorded, including quantification of 2D global longitudinal strain (GLS), global work index (GWI), global constructive work (GCW), global wasted work (GWW), and global work efficiency (GWE). LV peak systolic pressure was estimated non-invasively from the sum of systolic blood pressure and trans-aortic mean gradient. One month after the procedure, there was a significant improvement of LV GLS (−17.94 ± 4.24% vs. −19.35 ± 4.31%, before and after TAVI respectively, P = 0.002), as well as a significant reduction of GWI (2430 ± 586 mmHg% vs. 1908 ± 472 mmHg%, P < 0.001), GCW (2828 ± 626 mmHg% vs. 2206 ± 482 mmHg%, P < 0.001), and GWW (238 ± 207 mmHg% vs. 171 ± 118 mmHg%, P = 0.006). Conversely, MWE did not significantly change early after intervention (90.53 ± 6.05% vs. 91.45 ± 5.05%, P = 0.204). After TAVI, 30 patients (42.8%) developed LV dyssynchrony due to LBBB or pacemaker implantation. When the population was divided according to the presence or absence of LV dyssynchrony at 30-day follow-up, a significant reduction in GWW was found only in those without dyssynchrony (244 ± 241 vs. 141 ± 110 mmHg% with and without dyssynchrony respectively, P = 0.002). Consistently, in this subgroup, MWE significantly improved post-TAVI (90 ± 7 vs. 93 ± 5%, P = 0.002), while a trend of MWE reduction was observed in patients who developed dyssynchrony post-TAVI (91 ± 4 vs. 89 ± 5%, P = 0.164). In the overall population, a baseline value of MWE< 92% was associated with an increased rate of cardiovascular events (composite of all-cause death and rehospitalization for heart failure) at 1-year follow-up (22.2 vs. 3.1%, long rank, P = 0.016). Conclusions In patients with severe AS undergoing TAVI a significant reduction of GWW and improvement of MWE can be detected only in those who did not develop LV dyssynchrony. In this setting, MWE lower than 92% at baseline is associated with poor outcome. Thus, MWE could represent an alternative tool for myocardial function assessment in patients receiving TAVI.

Left ventricular dyssynchrony and post-systolic shortening in young bodybuilders using anabolic-androgenic steroids

Background: Left ventricular (LV) remodeling, characterized by increased LV hypertrophy and depressed function, is observed in strength-trained athletes who use anabolic-androgenic steroids (AAS). Previous studies reported an increase in cardiac fibrosis in these athletes, which could promote intraventricular dyssynchrony. In this context, this study evaluated LV dyssynchrony in strength-trained athletes using AA; hypothesizing that the use of AAS leads to an increase in LV dyssynchrony with an increase in post-systolic shortening. Methods: Forty-four participants (aged 20-40 years) were divided into three age-matched groups: strength-trained athletes using AAS (users, n=14) and those who were not (non-users, n=15), and healthy sedentary men (controls, n=15),. After completing a survey, each participant was assessed with 2D-strain echocardiography. Left ventricular dyssynchrony was quantified using the standard deviation of the time to peak for longitudinal strains (SD), the longitudinal strain delay index (LSDI) and the segmental post-systolic index (PSI). Results: Users exhibited a greater LV mass index and higher systolic and diastolic functions than both controls and non-users. The decrease in LV strains in users was predominantly observed at the interventricular segments. The SD, LSDI and PSI, calculated on the basal inferoseptal, basal anteroseptal and basal inferolateral segments, were higher in users. Conclusion: The results strongly support that the specific LV remodeling observed in young AAS users was associated with an increase in LV dyssynchrony. The correlations with ejection fraction suggested that wasted energy, due to post-systolic shortenings, contributed in part to the decrease in LV function in strength-trained athletes using AAS.

The utility of a novel approach to quantify dyssynchrony by multidetector computed tomography

Funding Acknowledgements Type of funding sources: None. Background Quantification of left ventricular (LV) dyssynchrony is of great interest for resynchronization therapy (CRT). Recently, cardiac computed tomography (CCT) is feasible for evaluation of dyssynchrony. Our aim was to assess a novel simplified approach using CCT to quantify LV dyssynchrony. Methods We studied 346 consecutive patients with a wide range of QRS width and ejection fractions (EF). Electrocardiogram-gated contrast-enhanced 256-slice multidetector CT (Brilliance 256 iCT, Philips Medical Systems) was performed before CRT. After CCT scan, the LV endocardial boundaries from short-axis images reconstructed at 5% increments of cardiac cycle were automatically detected, and a time from R-wave to maximal wall motion was calculated for each of the 16 standardized segments for all slices using software "Myocardial Contraction Map" (Argus, Inc Ehime, Japan). The standard deviation of all segments modified by mean heart rate (%SD) was respectively calculated as the global parameter of dyssynchrony. LVEF was also measured using MDCT. Results %SD was feasible in all patients, respectably. %SD was significantly different between the different QRS duration groups; narrow QRS (<120ms): 9 ± 5%, relatively wide QRS (120-150 ms): 11 ± 6%, and significantly wide QRS (>150 ms): 14 ± 7% (p <0.001). Moreover, there was significantly difference in %SD between the different morphology groups; normal: 9 ± 7%, Non-left bundle branch block (Non-LBBB): 10 ± 6%, LBBB: 17 ± 7% (p <0.001). Conclusion This novel simplified approach by CCT can quantify dyssynchrony in different QRS duration and morphology groups. This method has promise for clinical applications to the evaluation of patients for CRT. Abstract Figure.

Prognostic significance of cardiac sympathetic innervation and contractility in heart failure patients submitted to cardiac resynchronization therapy

Introduction In chronic heart failure patients, cardiac resynchronization therapy (CRT) does not lead to the expected result in 30% of cases. There is a lack of prognostic data related to the cardiac sympathetic activity and contractility assessment in ischemic (IHF) and non-ischemic (CHF) heart failure patients. Purpose To assess the prognostic value of radionuclide cardiac sympathetic innervation and contractility assessment in IHF and NIHF patients submitted to CRT. Methods This study included 38 HF patients (24 male; mean age of 56±11 years), who were submitted to CRT: NYHA class II/III (n=10/28), mean QRS=159.3±17.9ms. The etiology of HF was ischemic in 16 patients and non-ischemic in 22 of them. Before CRT all patients underwent 123I-metaiodobenzylguanidine (123I-MIBG) imaging for cardiac sympathetic activity evaluating. The following indexes were estimated: early and delayed heart to mediastinum ratio (eH/M and dH/M), summed MIBG Score (eSMS and dSMS). Moreover all patients underwent gated myocardial perfusion scintigraphy with the assessments of LV dyssynchrony indexes: standard deviation (SD) and histogram bandwidth (HBW). In addition, all patients underwent gated blood-pool SPECT with both ventricles ejection fraction (EF) and stroke volume (SV) assessment. Results One year after CRT all patients were divided into two groups: responders (IHF group n=11; NIHF group n=15) and non-responders (IHF group n=5; NIHF group n=7). Among baseline scintigraphic parameters the following ones showed significant differences between responders vs. non-responders. In IHF patients - HBW: 162 (115.2–180) degree vs. 115.2 (79.2–136.8) degree, p<0.05; RV_EF: 54.5 (41–56)% vs. 44.5 (37–49.5)%, p<0.05; RV_SV: 80 (69–101)ml vs. 55.5 (50–72.5)ml, p<0.05. In group of NIHF patients responders and non-responders were significantly differed in the following preoperative parameters: eH/M: 2.27 (2.02–2.41) vs. 1.64 (1.32–2.16), p<0.05; dH/M: 2.18 (2.11–2.19) vs. 1.45 (1.23–1.61), p<0.05; eSMS: 7 (5–7) vs. 15.5 (10–28.5), p<0.05; dSMS: 10 (10–13) vs. 16.5 (15.5–29), p<0.05, SD: 54.3 (43–58) degree vs. 65 (62–66) degree, p<0.05; HBW: 179.5 (140–198) degree vs. 211 (208–213) degree, p<0.05. Univariate logistic regression in IHF patients showed that LV dyssynchrony indexes – SD (OR=1.55; 95% CI 1.09–2.2; p<0.5) and HBW (OR=1.13; 95% CI 1.02–1.24; p<0.5), as well as RV indexes – RV_EF (OR=1.11; 95% CI 1.001–1.23; p<0.5), RV_SV (OR=1.07; 95% CI 1.003–1.138; p<0.5) were predictors of CRT response. In the group of NIHF patients, dH/M (OR=1.47; 95% CI 1.08–2; p<0.5), SD (OR=0.83; 95% CI 0.73–0.95; p<0.5), HBW (OR=0.96; 95% CI 0.93–0.99; p<0.5) showed the predictive value in terms of CRT response. Conclusion(s) The positive response to CRT in IHF patients showed a link with LV dyssynchrony and preserved RV contractility. Whereas in NIHF patients the functional state of cardiac sympathetic activity, as well as LV dyssynchrony, were associated with CRT response. Funding Acknowledgement Type of funding source: Public grant(s) – National budget only. Main funding source(s): Russian Foundation for Basic Research

P1779 Myocardial work is a predictor of exercise tolerance in patients with dilated cardiomyopathy and left ventricular dyssynchrony

Background the assessment of myocardial work (MW) by pressure-strain loops is a recently introduced tool for the assessment of myocardial performance. Aim of the present study is to evaluate the relationship between myocardial work and exercise tolerance in patients with dilated cardiomyopathy (DCM) Methods 51 patients with DCM (mean age 57 ± 13 years, left entricular ejection fraction : 32 ± 9%) underwent cardiopulmonary exercise test (CPET) to assess exercise performance. Trans-thoracic echocardiography (TTE) was performed CPET. The following indices of myocardial work (MW) were measured regionally and globally: constructive work (CW), wasted work (WW), and work efficiency (WE). Left ventricular (LV) dyssynchrony (DYS) was defined by the presence of septal flash or apical rocking at TTE. Results LV-DYS was observed in 16 (31%) patients and associated with lower LV ejection fraction (LVEF), GLS, global and septal WE, and higher global and septal WW (Table 1). In patients with LV-DYS, septal WE was the only predictor of exercise peak VO2max at multivariable analysis (Figure 1), whereas LVEF (β=0.47, p = 0.05) and age (β=-0.42, 47, p= 0.04) were predictors of exercise capacity in patients without LV-DYS. Conclusions In patients with DCM, LV-DYS is associated with an heterogeneous distribution of myocardial work. Septal WE is the best predictor of exercise performance in these patients. Table 1 All n = 51 No-dyssynchrony n = 35 (69%) LV-Dyssynchrony n = 16 (31%) p-value LVEF, % 32 ± 9 34 ± 10 28 ± 7 0.04 GLS, % -12 ± 3 -13 ± 3 -10 ± 3 0.001 GCW, mmHg% 1325 ± 398 1342 ± 354 1287 ± 491 0.65 GWW, mmHg% 201 ± 147 154 ± 95 304 ±191 <0.0001 GWE, % 85 ± 9 88 ± 7 78 ±10 <0.0001 CWsept, mmHg% 1172 ± 459 1274 ± 398 949 ± 516 0.017 CWlat, mmHg% 1518 471 1472 ± 386 1620 ± 622 0.30 WWsept, mmHg% 283 ± 275 174 ± 98 522 ±376 <0.0001 WWlat, mmHg% 135 ± 88 117 ± 81 176 ± 92 0.02 WEsept, % 78 ± 16 84 ± 9 62± 18* <0.0001 WElat, % 90 ± 7 91 ± 7 88 ± 7 0.16 Abstract P1779 Figure.

P895 Relationship between left ventricular function components and cardiovascular risk factors in asymptomatic individuals

Funding Acknowledgements none Background and Aim Coronary artery disease is commonly related to conventional cardiovascular (CV) risk factors. The exact role of those risk factors in early development of CV disease or left ventricular (LV) dysfunction before the development of sign and symptoms remains debated. We studied the relationship between conventional risk factors and LV systolic, diastolic and synchronous function in a population sample of asymptomatic individuals. Methods All participants underwent a detailed echocardiographic examination as part of a cross-sectional survey for the prevalence of coronary risk factors in randomly selected individuals from general population. LV end-systolic and end-diastolic dimensions, and LV volumes and ejection fraction (EF) were all calculated. From the spectral Doppler flow, LV early diastolic (E wave) and atrial systolic (A wave) velocities were measured and E/A ratio calculated. LV filling time (FT) was also measured from the onset of E wave to the end of A wave, and LV ejection time (ET) from the onset to the end of aortic Doppler velocity. Global LV dyssynchrony was assessed using total isovolumic time (T-IVT) as 60 – (total filling time + total ejection time), and Tei index was also calculated. Results The study population comprised 184 individuals (96 male and 88 female, mean age 55.9 (11.3), range 25-78 years). There was no relationship between systolic LV function expressed by EF and CV risk factors. Markers of diastolic function: LV filling velocities and E/A ratio, were correlated with age (r= -0.36, p < 0.000, r= -0.57, p < 0.000, respectively), with glycemia (r= -0.21, p < 0.000, r= -0.14, p = 0.004,) and with systolic blood pressure (r= -0.31, p < 0.000, r= -0.34, p < 0.000). Markers of LV dyssynchrony, in the form of prolonged T-IVT, and raised Tei index, directly correlated with age, glycemia and systolic blood pressure (r = 0.58, p < 0.000, r = 0.18, p < 0.000, r = 0.33, p < 0.000, respectively). However, when these correlations were adjusted for age in a multivariate analysis, the statistical significance was strongly reduced (LV filling) or completely lost (IVT and E/A). Conclusions In normal asymptomatic population, age, rather than CV risk factors, is the main determinant of changes in diastolic and synchronous function.

P3355Stress-induced left ventricular dyssynchrony predicts future cardiac events in patients with known or suspected coronary artery disease

Background Prognostic value of stress induced left ventricular (LV) dyssynchrony has not been fully understood. The aim of this study was to evaluate the possible impact between cardiovascular events and stress induced worsening LV dyssynchrony. Methods and results One hundred and eighty consecutive subjects with known or suspected coronary artery disease (CAD) (142 men, mean age 68±12 years) underwent both gated myocardial single photon emission computed tomography (SPECT) with 99mTc-sestamibi or tetrofosmin according to a standard same day stress-rest protocol and coronary angiography or coronary computed tomography. The summed difference score (SDS) was calculated in every subjects. LV ejection fraction (EF) and phase Entropy at after stress and rest were determined by cardioREPO software. We determined %ΔEntropy = (stress Entropy - rest Entropy)/rest Entropy x100, as an indicator of stress-induced LV dyssynchrony. In the study population, the mean SDS was 2.7±3.9 and LVEF was 58±16%, stress and rest Entropy were 0.62±0.15 and 0.57±0.13, respectively. %ΔEntropy was higher in patients with CAD than in those without CAD (3.3±11.5 vs. 10.2±15.0, respectively). Moreover, there was a strict correlation between the presence of CAD and %ΔEntropy, indicator of stress induced LV dyssynchrony (non-CAD vs. CAD and/or 1 vessel disease vs. multivessel disease: 4.3±12.5 vs. 8.8±15.6 vs. 12.7±14.3, respectively. p<0.05) We examined all study subjects and they were divided into 2 groups by cut off value of the %ΔEntropy constructed with receiver operating characteristic curve (=15.4). Kaplan-Meier analysis revealed that future cardiovascular event rate was significantly higher in %ΔEntropy >15.4 group (20/57) than in %ΔEntropy <15.4 group (24/123) (Log-rank p<0.01). On the other hand, summed stress score and SDS were no significant differences between 2 groups. However, SDS was higher in patients with future cardiovascular event than in those without cardiovascular event (4.4±5.4 vs. 2.2±3.2, respectively. p=0.001). Conclusion In patients with known or suspected CAD, stress-induced worsening LV dyssynchrony may predict the presence of CAD and future cardiac events. Acknowledgement/Funding None