Parametrization of an in-silico circulatory simulation by clinical datasets – towards prediction of ventricular function following assist device implantation

Abstract Background: Left ventricular assist device (LVAD) therapy has revolutionized the way end stage heart failure is treated today. Analysis of LVAD interaction with the whole cardiovascular system and its biological feedback loops is often conducted by means of computer models. Generating real time pressure volume loops (PV-loops) in patients, not using conductance catheters but routine diagnostics to feed an in-silico model could help to predict postoperative complications. Methods: Routinely obtained hemodynamic measurements to evaluate myocardial function prior to LVAD implantation like pressure readings in the aorta, the left atrium and the left ventricle and simultaneous three-dimensional (3D) echocardiography recordings were assessed to parametrize a reduced computational model of the cardiovascular system. An automatic parameter identification procedure has been developed. Results: The results constitute a patient-individual computational simulation model. An exemplary in-silico study focusing on the effect of different ventricular assist device (VAD) speeds has been conducted. Results allow for estimation of the resulting hemodynamic parameters and changes of the PV-loops. Conclusion: The model improves understanding and prediction of the interaction between pump and ventricles. Future modifications in exporting and merging routinely assessed real time hemodynamic patient data are necessary to investigate various clinical and pathological conditions of LVAD recipients.

[1]  T. Hayashi,et al.  Single‐Beat Estimation of the Slope of the End‐Systolic Pressure‐Volume Relation in the Human Left Ventricle , 1991, Circulation.

[2]  K. Sagawa,et al.  The use of left ventricular end-ejection pressure and peak pressure in the estimation of the end-systolic pressure-volume relationship. , 1984, Circulation.

[3]  Y. Shimada,et al.  A meta-analysis and investigation for the source of bias of left ventricular volumes and function by three-dimensional echocardiography in comparison with magnetic resonance imaging. , 2011, The American journal of cardiology.

[4]  Ewart R. Carson,et al.  Modelling a complex biological system: the human cardiovascular system—1. Methodology and model description , 1983 .

[5]  Jeroen J. Bax,et al.  Clinical and functional effects of restrictive mitral annuloplasty at midterm follow-up in heart failure patients. , 2010, The Annals of thoracic surgery.

[6]  Dirk Abel,et al.  Cardiac Modeling: Identification of Subject Specific Left-Ventricular Isovolumic Pressure Curves , 2015 .

[7]  H. Ramakrishna,et al.  Clinical update in cardiac imaging including echocardiography. , 2010, Journal of cardiothoracic and vascular anesthesia.

[8]  W. Zimmermann Strip and Dress the Human Heart. , 2016, Circulation research.

[9]  Ulrich Steinseifer,et al.  Implementation of intrinsic lumped parameter modeling into computational fluid dynamics studies of cardiopulmonary bypass. , 2014, Journal of biomechanics.

[10]  V. Roger Epidemiology of Heart Failure , 2013, Circulation research.

[11]  Yih-Choung Yu,et al.  Mathematical modeling of ventricular suction induced by a rotary ventricular assist device , 2006, 2006 American Control Conference.

[12]  Truls Myrmel,et al.  Pressure-volume-based single-beat estimations cannot predict left ventricular contractility in vivo. , 2002, American journal of physiology. Heart and circulatory physiology.

[13]  S. Buccheri,et al.  Reference Values for Real Time Three‐Dimensional Echocardiography–Derived Left Ventricular Volumes and Ejection Fraction: Review and Meta‐Analysis of Currently Available Studies , 2015, Echocardiography.

[14]  J. Chalmers,et al.  Central control of blood pressure. , 1992, European heart journal.

[15]  J. Clark,et al.  A dynamic model of ventricular interaction and pericardial influence. , 1997, The American journal of physiology.

[16]  Thomas Schmitz-Rode,et al.  Benefits of object-oriented models and ModeliChart: modern tools and methods for the interdisciplinary research on smart biomedical technology , 2017, Biomedizinische Technik. Biomedical engineering.

[17]  M. Ursino,et al.  Interaction between carotid baroregulation and the pulsating heart : a mathematical model , 1998 .

[18]  P Steendijk,et al.  Ventricular pressure-volume relations in vivo. , 1992, European heart journal.

[19]  Jessica L. Howard,et al.  Predicting right ventricular failure in the modern, continuous flow left ventricular assist device era. , 2013, The Annals of thoracic surgery.

[20]  S. Miyagawa,et al.  Should Destination Therapy with Implantable Left Ventricular Assist Device Replace Heart Transplantation , 2015 .

[21]  Berend E. Westerhof,et al.  The arterial Windkessel , 2009, Medical & Biological Engineering & Computing.

[22]  V. Spitzer,et al.  The visible human dataset: The anatomical platform for human simulation , 1998, The Anatomical record.

[23]  M. Marber,et al.  Advancements in pressure–volume catheter technology – stress remodelling after infarction , 2013, Experimental physiology.

[24]  Pascal Verdonck,et al.  Modeling Ventricular Function during Cardiac Assist: Does Time-Varying Elastance Work? , 2006, ASAIO journal.

[25]  F. Colacino,et al.  Left Ventricle Load Impedance Control by Apical VAD Can Help Heart Recovery and Patient Perfusion: A Numerical Study , 2007, ASAIO journal.

[26]  Stefanie Heinke,et al.  Modeling and simulation of the cardiovascular system: a review of applications, methods, and potentials / Modellierung und Simulation des Herz-Kreislauf-Systems: ein Überblick zu Anwendungen, Methoden und Perspektiven , 2009, Biomedizinische Technik. Biomedical engineering.

[27]  Nader Moazami,et al.  Right ventricular failure in patients with the HeartMate II continuous-flow left ventricular assist device: incidence, risk factors, and effect on outcomes. , 2010, The Journal of thoracic and cardiovascular surgery.