Myocardial deformation imaging in early prediction of heart failure development after STEMI is better than conventional echocardiography: true or false?

Funding Acknowledgements Type of funding sources: None. onbehalf PREDICT-VT Heart failure (HF) still develops in 4% up to 28% of STEMI pts treated by pPCI, with the highest incidence in the first year. Accurate and early identification of high-risk patients would allow targeted and personalized intensive treatment . Aim the current study is a sub-study of PREDICT-VT study (NCT03263949). Its aim is to define multi-parametric model for early HF prediction in STEMI patients treated by pPCI, based on clinical data, conventional echocardiographic data and data from myocardial deformation analysis obtained by early speckle tracking echocardiography. Methods in 307 consecutive pts enrolled in PREDICT-VT, early echocardiography (5 ± 2 days after pPCI) was done and included LA and multilayer LV deformation analysis with longitudinal (L), radial (R) and circumferential (C) strain (S; %) and strain rate (SR, 1/sec). LV indices of post systolic shortening for longitudinal (PSS LS) and circumferential (PSS CS) strains were also calculated . Results From 242 patients who completed 1-year follow-up, 9 % develop HF NYHA class 3 or 4, 27 % NYHA class 2 and remaining 64% were in NYHA class I. Significant univariate NYHA predictors were: from clinical parameters - female gender (ß =0.156, p = 0.015; 95% CI -0.431 to – 0.047), older age (ß =0.130, p = 0.044; 95% CI 0.000 to 0.017), Killip class on admission (ß=0.131, p = 0.043; 95% CI 0.007 to 0.435) and previous atrial fibrillation (ß=0.181, p = 0.005; 95% CI 0.175 to 0.960); from conventional echo parameters- LVEF (ß=-0.302, p < 0.001; 95% CI -0.029 to -0.012), LAVI (ß=0.134, p = 0.046; 95%CI 0.000 to 0.030), degree of diastolic dysfunction (ß=0.297, p < 0.001; 95% CI 0.192 to 0.465) and TAPSE (ß=-4.255, p < 0.001); from parameters of longitudinal LV deformation – peak systolic epicardial LS (ß=0.293, p < 0.001; 95% CI 0.030 to 0.074), SRs (ß=0.274, p < 0.001; 95% CI 0.398 to 1.069) and epicardial PSS (ß=0.336, p < 0.001; 95%CI 0.925 to 2.019); from parameters of LV circumferential deformation – peak systolic endocardial CS (ß=0.254, p < 0.001; 95% CI 0.013 to 0.041), SR E (ß= -0.247, p < 0.001; 95%CI -0.556 to -0.173) and epicardial PSS CS (ß=0.206, p = 0.003; 95% CI 0.302 to 1.473); from left atrial mechanics - LA strain (ß=-0.231, p = 0.001; 95% CI -0.025 to -0.007). Predictive power of model based on clinical variables (Killip class on admission, female gender, and history of atrial fib) for HF development was significantly improved when conventional ehocardiographic variables were added (LVEF, TAPSE, degree of diastolic function) (R2 from 0.076 to 0.197, p < 0.001). However, addition of MDI parameters (longitudinal and cirumferential PSS on epicardial levels) increased it further (R2 from 0.200 to 0.229, p < 0.001). Conclusion above from clinical and conventional echocardiographic parameters, amount of left ventricular post-systolic deformation in longitudinal and circumferential directions, expressed as LV indexes of post-systolic shortening, significantly improved early prediction of HF after pPCI.

Performance of different myocardial tissue tracking algorithms and acquisition-based strain imaging to characterise myocardial pathology

Background Myocardial deformation imaging is superior in risk-stratification compared to volumetric approaches. Myocardial Feature-Tracking (FT) allows easy post-processing of routinely acquired cine images. Since there is no clear recommendation regarding FT post-processing we sought to compare different FT-strains with reference standard techniques including tagging and strain encoded (SENC) magnetic resonance imaging. Methods CMR-FT software from 4 different vendors (TomTec, Medis, Circle, Neosoft), CMR tagging (Segment) and fastSENC (MyoStrain) were used to determine left ventricular (LV) global longitudinal and circumferential strains (GLS and GCS) in 12 healthy volunteers and 12 heart failure patients. Variability and agreements were assessed using intraclass correlation coefficients, coefficients of variation and Bland Altman plots. Results Compared to tagging, FT-based strain was software independently significantly higher except for GCS using Medis (p=0.178). Compared to fSENC, mean-differences of GLS were smaller within a range of ±1.5%. For GCS this only applied to CVI and Medis (<1.5%) but not TomTec (>7%) or Neosoft (>4%). Absolute agreements comparing FT to tagging were best for CVI (GLS ICC0.70) and Medis (GCS ICC0.85). Compared to fSENC agreement of GLS was generally excellent (ICC>0.77), but only CVI and Medis revealed excellent agreement for GCS (ICC0.88 and 0.85). Consistency and correlation of GLS were software independently high compared with tagging and fSENC (ICC>0.86, r>0.76) while being lower for GCS (ICC>0.68, r>0.72). Conclusion Although agreement differs between deformation assessment approaches, consistency and correlation are high irrespective of the method chosen, thus indicating reliable strain assessment. Further standardisation and introduction of uniform references is warranted for clinical routine implementation. Funding Acknowledgement Type of funding source: Public grant(s) – National budget only. Main funding source(s): DZHK - German Centre for Cardiovascular Research

P1381 The utility of left ventricle deformation in patients with myocarditis with midle-range and preserved ejection fraction

Background Predicting malignant ventricular arrhythmias and heart failure in patients (pts) with acute myocarditis and middle-range and preserved EF is challenge Aim: to define whether quantification of myocardial mechanics in early, acute phase of myocarditis offers more information to predict six months outcome of patients.Methods: In the 36 consecutive pts with myocarditis, middle age 32.86 ± 12.04yr, 75% males, echocardiography exam was done 1-3 day of diseases, including conventional parameters and comprehensive speckle tracking LV deformation analysis with longitudinal (L), circumferential (C) strain (S;%), strain rate (SR, 1/sec) and rotational LV mechanics. Results: The most patients were present as infarct-like myocarditis (80.56%), the others patients were present as heart failure-like (11.11%) and arrhythmia-like myocarditis (8.33%). At admission 27 (90%) pts had chest pain, 20 (66.7%) pts had ECG changes, 15 (50%) pts had symptoms of heart failure, 5 (16.7%) pts had arrhythmias. Amount of edema and fibrosis assessed by cardiovascular magnetic resonance (CMR) and echo correlate significantly. Classical and conventional parameters of LV systolic function, and deformation were not significantly different between groups. However, mechanical dispersion index (IMD) of global LS and systolic S were significantly different between groups (p < 0.05). Conclusion: Myocardial deformation imaging, like speckle tracking echocardiography, offers deeper insight into complex mechanical abnormalities during not only LV contraction but LV relaxation in longitudinal directions in patients with acute myocarditis. Infarct-like Arrhythmia-like Heart failure-like p EF (%) 57.5 ± 5.42 54.7 ± 12.9 58.3 ± 6.8 NS GLS endo (%) -20.8 ± 2.59 -19.78 ± 2.27 -17.36 ± 5.65 NS GLS (mid (%) -18.31 ± 2.4 -17.31 ± 1.52 -15.3 ± 5.10 NS GLS epi (%) -16.15 ± 2.28 -15.20 ± 0.92 -13.55 ± 4.68 NS IMD LS (ms) 37.04 ± 7.71 33.04 ± 6.58 60.75 ± 38.56 0.008 CS endo (%) -26.39 ± 6.93 -21.59 ± 3.88 -25.17 ± 6.48 NS CS mid (%) -17.32 ± 6.77 -13.03 ± 2.07 -15.95 ± 4.41 NS CS epi (%) -10.99 ± 6.89 -7.13 ± 0.72 -9.53 ± 2.73 NS IMD CS (ms) 47.69 ± 8.86 41.43 ± 23.92 41.01 ± 20.51 NS IMD SL peak S* 12.27 (21) 13.96 (4) 20.28 (84) 0.042 *Median and range values are presented.

EACVI survey on standardization of cardiac chambers quantification by transthoracic echocardiography

Aims To evaluate standard reporting of cardiac chambers size and function by transthoracic echocardiography (TTE), the EACVI Scientific Initiatives Committee performed a survey across European centres. In particular, the routine use of three-dimensional echocardiography (3DE) and speckle tracking-derived myocardial deformation imaging (STE) was explored. Methods and results A total of 96 European Echocardiography Laboratories from 22 different countries responded to the survey, which consisted of 20 questions. For most of the standard parameters of cardiac chamber size and function, answers from the centres were homogeneous and demonstrated good adherence to current recommendations. In particular, all centres assessed left ventricular (LV) and left atrial (LA) size combining diameter measurements with volumes obtained using the bi-plane Simpson’s method. More variability was observed in the measurements of the right heart chambers and thoracic aorta. Interestingly, >90% of centres had access to 3DE and STE; however, the large majority of centres reserved the use of these techniques for selected cases, particularly for the measure of 3D LV volumes and ejection fraction and global longitudinal strain in patients being considered for cardiac device implantation, surgical intervention (valvular heart disease) or screened for cardiotoxicity. Only 10% of centres used 3DE for right ventricular and LA volumes. Also, <30% of the centres used LA strain imaging. Conclusion In Europe, a good adherence to current recommendations was observed for most of the standard parameters of cardiac chambers quantification by TTE. Advanced echocardiography modalities, such as 3DE and STE, are widely available but used only in selected cases.

Normal fetal cardiac deformation values in pregnancy; a prospective cohort study protocol

Background Myocardial deformation imaging offers the potential to measure myocardial function. Remodelling, the change in size, shape and function, appears as a result of pressure or volume changes and is thought to be the first sign of fetal adaptation to placental dysfunction. Deformation can be measured using speckle tracking echocardiography (STE). STE in the fetus might be useful for detection and follow up of the fetus endangered by placental dysfunction. Reference values for fetal myocardial deformation during gestation have not been comprehensively described and need further investigation before STE can be introduced in daily clinical practice. The aim of this study is to determine reference values for fetal myocardial deformation throughout gestation in uncomplicated pregnancies. Methods A longitudinal cohort will be performed. 150 Women, pregnant from a non-anomalous singleton, will be included from 19 to 21 + 6 weeks gestational age. Thereafter, fetal heart ultrasounds will be performed 4 weekly, until 41 weeks gestational age or delivery. Ultrasound data will be analysed using STE software to determine reference values for fetal cardiac deformation during gestation. Discussion Measuring cardiac deformation changes in pregnancy can be a promising tool to detect preclinical cardiac adaptation to placental dysfunction. However, previous studies used different ultrasound scans and STE software resulting in incomparable and contradictory results on deformation values. In this prospective study reference values during pregnancy, cardiac deformation values will be assessed with the same ultrasound and software package in 150 uncomplicated pregnancies. Trial registration National Trial Register number: NTR7132. Date of inclusion: 2018/04/06.

P1472Predicting significant ventricular arrhythmias in STEMI patients in middle-range and preserved EF

Background Predicting malignant ventricular and sudden cardiac death (SCD) in STEMI patients with middle-range and preserved EF is challenge. Aim To identify the best parameters to predict composite end-point defined as secondary VF, sustained/non-sustained VT and sudden death, 48h after and during the first year of follow up after STEMI in patients with middle-range and preserved EF. Methods In the 192 consecutive STEMI patients (pts) 57.8±10.4yr, 69.9% males, in PREDICT-VT study (NCT03263949) treated with pPCI, with EF ≥40%, early echo (5±2 days) was done including conventional parameters and comprehensive speckle tracking left ventricle (LV) deformation analysis with longitudinal (L), circumferential (C) strain (S; %) strain rate (SR, 1/sec), index mechanical dispersion (IMD) and rotational LV mechanics. Results Thirteen patients (8.3%) reached the end-point. Classical parameters of LV systolic function, including LVEF, wall motion score index and parameters of diastolic dysfunction were not significant predictors of the malignant arrhythmias. IMD of late rotation rate (63.7 vs. 40.7ms, p=0.055) and late diastolic untwisting rate (−48.85 vs. −63.18°/s, p=0.059) had trend to become the significant predictors. CS in papillary muscle level in endo and mid layers predicted the primary end-point (endo: −20.5±11.8 vs. −24.9±4.6, mid: −14.6±3.9 vs. −17.0±2.1, epi: −10.1±3.3 vs. −11.8±1.8) (table). Parameter of circumferencial mechanics ROC area 95% CI p Cutt-off Sens Spec PM endo (%) 0.302 0.146–0.458 0.038 −22.75 70 67 PM mid (%) 0268 0.153–0.383 0.015 −15.65 80 62 Conclusion Myocardial deformation imaging offers deeper insight into complex mechanical abnormalities during LV contraction and relaxation in STEMI patients with middle-range and preserved EF that predicts serious arrhythmic events.

P5977Predicting significant ventricular arrhythmias in STEMI patients: never-ending challenge, still more place for myocardial deformation imaging?

Background Malignant ventricular arrhythmias in STEMI patients carry ominous prognosis including sudden cardiac death (SCD). According to the current guidelines only EF<35%, 40 days after STEMI, is indication for ICD implantation. Recently, index of myocardial dispersion (IMD) estimated by myocardial deformation imaging (speckle tracking echocardiography) was documented to provide better risk stratification. Aim To define whether quantification of myocardial mechanics early after pPCI using modern echocardiography offers information more to predict malignant arrhythmias during the first year after STEMI. Methods In the 226 consecutive STEMI patients (pts) 57.8±10.4yr, 71.7% males, in PREDICT-VT study (NCT03263949) treated with pPCI early echo (5±2 days) was done including conventional parameters and comprehensive speckle tracking LV deformation analysis with longitudinal (L), circumferential (C) strain (S;%) and strain rate (SR, 1/sec) and rotational LV mechanics. ROC analysis was performed to identify the best parameters to predict composite end-point defined as secondary VF, sustained/non-sustained VT and SCD, 48h after pPCI and during the first year of follow up. Results Twenty two patients (9.7%) reached the end-point. Classical parameters of LV systolic function, including LVEF, wall motion score index; global, systolic LS, CS and parameters of diastolic dysfunction were not significant predictors of the malignant arrhythmias. Early L SR, systolic C SR, IMD of global rotation and late rotation rate predicted the primary end-point (table). Parameter ROC area 95% CI p Cutt-off Sens Spec Longirudinal mechanics SR E (1/sec) 0.687 0.577–0.796 0.019 0.69 64 65 IMD S (ms) 0.752 0.666–0.838 0.002 66.1 71 72 Circumferencial mechanics SR S (1/sec) 0.732 0.613–0.852 0.002 −1.22 71 67 Rotational mechanics Global IMD (ms) 0.329 0.177–0.481 0.036 82.9 63 62 Late rotation rate IMD (ms) 0.318 0.196–0.442 0.026 41.1 65 64 Conclusion Myocardial deformation imaging offers deeper insight into complex mechanical abnormalities during LV contraction and relaxation in longitudinal, circumferential and rotational directions (impaired and asynchronous deformations) in STEMI patients and predicts serious arrhythmic events.