230  Bibliography





                396. E.C. Adelstein, S. Saba, Scar burden by myocardial  ventricular dyssynchrony and scar tissue,
                    perfusion imaging predicts echocardiographic  European Heart Journal 30 (19) (2009) 2360–2367.
                    response to cardiac resynchronization therapy in  404. K.C. Bilchick, V. Dimaano, K.C. Wu, R.H. Helm,
                    ischemic cardiomyopathy, American Heart     R.G. Weiss, J.A. Lima, R.D. Berger, G.F. Tomaselli,
                    Journal 153 (1) (2007) 105–112.             D.A. Bluemke, H.R. Halperin, et al., Cardiac
                397. S. Chalil, P.W. Foley, S.A. Muyhaldeen, K.C. Patel,  magnetic resonance assessment of dyssynchrony
                    Z.R. Yousef, R.E. Smith, M.P. Frenneaux, F. Leyva,  and myocardial scar predicts function class
                    Late gadolinium enhancement-cardiovascular  improvement following cardiac resynchronization
                    magnetic resonance as a predictor of response to  therapy, JACC: Cardiovascular Imaging 1 (5) (2008)
                    cardiac resynchronization therapy in patients with  561–568.
                    ischaemic cardiomyopathy, Europace 9 (11) (2007)  405. V. Delgado, R.J. van Bommel, M. Bertini, C.J.W.
                    1031–1037.                                  Borleffs, N.A. Marsan, A.C. Ng, G. Nucifora, N.R.
                398. A.-C. Pouleur, D. Knappe, A.M. Shah, H. Uno, M.  van de Veire, C. Ypenburg, E. Boersma, et al.,
                    Bourgoun, E. Foster, S. McNitt, W.J. Hall, W.  Relative merits of left ventricular dyssynchrony,
                    Zareba, I. Goldenberg, et al., Relationship between  left ventricular lead position, and myocardial scar
                    improvement in left ventricular dyssynchrony and  to predict long-term survival of ischemic heart
                    contractile function and clinical outcome with  failure patients undergoing cardiac
                    cardiac resynchronization therapy: the madit-crt  resynchronization therapy, Circulation 123 (1)
                    trial, European Heart Journal 32 (14) (2011)  (2011) 70–78.
                    1720–1729.                             406. C. Ypenburg, M.J. Schalij, G.B. Bleeker, P.
                399. F.Leyva,R.J.Taylor, P.W. Foley, F. Umar,L.J.  Steendijk, E. Boersma, P. Dibbets-Schneider, M.P.
                    Mulligan, K. Patel, B. Stegemann, T. Haddad, R.E.  Stokkel, E.E. van der Wall, J.J. Bax, Impact of
                    Smith, S.K. Prasad, Left ventricular midwall  viability and scar tissue on response to cardiac
                    fibrosis as a predictor of mortality and morbidity  resynchronization therapy in ischaemic heart
                    after cardiac resynchronization therapy in patients  failure patients, European Heart Journal 28 (1)
                    with nonischemic cardiomyopathy, Journal of the  (2006) 33–41.
                    American College of Cardiology 60 (17) (2012)  407. A.Crozier,B.Blazevic, P. Lamata,G.Plank,M.
                    1659–1667.                                  Ginks, S. Duckett, M. Sohal, A. Shetty, C.A. Rinaldi,
                400. E.S. Chung, A.R. Leon, L. Tavazzi, J.-P. Sun, P.  R. Razavi, et al., The relative role of patient
                    Nihoyannopoulos, J. Merlino, W.T. Abraham, S.  physiology and device optimisation in cardiac
                    Ghio, C. Leclercq, J.J. Bax, et al., Results of the  resynchronisation therapy: a computational
                    predictors of response to crt (prospect) trial,  modelling study, Journal of Molecular and Cellular
                    Circulation (2008).                         Cardiology 96 (2016) 93–100.
                401. P.Lim,E.Donal,S.Lafitte,G.Derumeaux, G.  408. P.R. Huntjens, J. Walmsley, S. Ploux, P. Bordachar,
                    Habib, P. Réant, S. Thivolet, N. Lellouche, R.A.  F.W. Prinzen, T. Delhaas, J. Lumens, Influence of
                    Grimm, P. Gueret, Multicentre study using strain  left ventricular lead position relative to scar
                    delay index for predicting response to cardiac  location on response to cardiac resynchronization
                    resynchronization therapy (music study),    therapy: a model study, Europace 16 (suppl 4)
                    European Journal of Heart Failure 13 (9) (2011)  (2014), iv62–iv68.
                    984–991.                               409. E. Willemen, R. Schreurs, P.R. Huntjens, M. Strik,
                402. J. Lumens, S. Ploux, M. Strik, J. Gorcsan, H.  G. Plank, E. Vigmond, J. Walmsley, K. Vernooy, T.
                    Cochet, N. Derval, M. Strom, C. Ramanathan, P.  Delhaas, F.W. Prinzen, et al., The left and right
                    Ritter, M. Haïssaguerre, et al., Comparative  ventricles respond differently to variation of
                    electromechanical and hemodynamic effects of  pacing delays in cardiac resynchronization
                    left ventricular and biventricular pacing in  therapy: a combined experimental-computational
                    dyssynchronous heart failure: electrical    approach, Frontiers in Physiology 10 (2019) 17.
                    resynchronization versus left–right ventricular  410. A.W.Lee,A.Crozier,E.R.Hyde, P. Lamata,M.
                    interaction, Journal of the American College of  Truong,M.Sohal,T.Jackson, J.M. Behar, S.
                    Cardiology 62 (25) (2013) 2395–2403.        Claridge, A. Shetty, et al., Biophysical modeling to
                403. N.A. Marsan, J.J. Westenberg, C. Ypenburg, R.J. van  determine the optimization of left ventricular
                    Bommel,S.Roes, V. Delgado, L.F. Tops,R.J.van der  pacing site and av/vv delays in the acute and
                    Geest, E. Boersma, A. de Roos, et al., Magnetic  chronic phase of cardiac resynchronization
                    resonance imaging and response to cardiac   therapy, Journal of Cardiovascular
                    resynchronization therapy: relative merits of left  Electrophysiology 28 (2) (2017) 208–215.