Simulation of Left Atrial Function Using a Multi-Scale Model of the Cardiovascular System

cardiovascular system; mathematical model; left atrium; parameter identification; parameter estimation; preload; multi-scale model; time-varying elastance; pressure-volume loop; a wave; v wave; hemodynamics

Abstract :

[en] During a full cardiac cycle, the left atrium successively behaves as a reservoir, a conduit and a pump. This complex behavior makes it unrealistic to apply the time-varying elastance theory to characterize the left atrium, first, because this theory has known limitations, and second, because it is still uncertain whether the load independence hypothesis holds. In this study, we aim to bypass this uncertainty by relying on another kind of mathematical model of the cardiac chambers. In the present work, we describe both the left atrium and the left ventricle with a multi-scale model. The multi-scale property of this model comes from the fact that pressure inside a cardiac chamber is derived from a model of the sarcomere behavior. Macroscopic model parameters are identified from reference dog hemodynamic data. The multi-scale model of the cardiovascular system including the left atrium is then simulated to show that the physiological roles of the left atrium are correctly reproduced. This include a biphasic pressure wave and an eight-shaped pressure-volume loop. We also test the validity of our model in non basal conditions by reproducing a preload reduction experiment by inferior vena cava occlusion with the model. We compute the variation of eight indices before and after this experiment and obtain the same variation as experimentally observed for seven out of the eight indices. In summary, the multi-scale mathematical model presented in this work is able to correctly account for the three roles of the left atrium and also exhibits a realistic left atrial pressure-volume loop. Furthermore, the model has been previously presented and validated for the left ventricle. This makes it a proper alternative to the time-varying elastance theory if the focus is set on precisely representing the left atrial and left ventricular behaviors.

Disciplines :

Cardiovascular & respiratory systems
Engineering, computing & technology: Multidisciplinary, general & others

Author, co-author :

Pironet, Antoine ; Université de Liège - ULiège

Dauby, Pierre ; Université de Liège - ULiège > Département d'astrophys., géophysique et océanographie (AGO) > Thermodynamique des phénomènes irréversibles

Paeme, Sabine ; Université de Liège - ULiège > Département d'astrophys., géophysique et océanographie (AGO) > Thermodynamique des phénomènes irréversibles

Kosta, Sarah ; Université de Liège - ULiège > Département d'astrophys., géophysique et océanographie (AGO) > Thermodynamique des phénomènes irréversibles

Chase, J. Geoffrey

Desaive, Thomas ; Université de Liège - ULiège > Département d'astrophys., géophysique et océanographie (AGO) > Thermodynamique des phénomènes irréversibles

Language :

English

Title :

Simulation of Left Atrial Function Using a Multi-Scale Model of the Cardiovascular System

Publication date :

April 2013

Journal title :

PLoS ONE

eISSN :

1932-6203

Publisher :

Public Library of Science, San Franscisco, United States - California

Volume :

Issue :

Pages :

e65146

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

http://dx.doi.org/10.1371%2Fjournal.pone.0065146

Available on ORBi :

since 11 June 2013

Statistics

Number of views

130 (37 by ULiège)

Number of downloads

288 (16 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Roşca M, Lancellotti P, Popescu BA, Piérard LA, (2011) Left atrial function: pathophysiology, echocardiographic assessment, and clinical applications. Heart 97: 1982-1989.
Pagel PS, Kehl F, Gare M, Hettrick DA, Kersten JR, et al. (2003) Mechanical function of the left atrium: new insights based on analysis of pressure-volume relations and doppler echocardiography. Anesthesiology 98: 975-994.
Stefanadis C, Dernellis J, Toutouzas P, (2001) A clinical appraisal of left atrial function. European heart journal 22: 22-36.
Wong KK, Sun Z, Tu J, Worthley SG, Mazumdar J, et al. (2012) Medical image diagnostics based on computer-aided ow analysis using magnetic resonance images. Computerized Medical Imaging and Graphics 36: 527-541.
Saito S, Araki Y, Usui A, Akita T, Oshima H, et al. (2006) Mitral valve motion assessed by high-speed video camera in isolated swine heart. European journal of cardio-thoracic surgery 30: 584-591.
Suga H, Sagawa K, Shoukas AA, (1973) Load independence of the instantaneous pressure-volume ratio of the canine left ventricle and effects of epinephrine and heart rate on the ratio. Circulation Research 32: 314-322.
Burkhoff D, (1994) Explaining load dependence of ventricular contractile properties with a model of excitation-contraction coupling. Journal of molecular and cellular cardiology 26: 959-978.
Kass DA, Beyar R, Lankford E, Heard M, Maughan WL, et al. (1989) Inuence of contractile state on curvilinearity of in situ end-systolic pressure-volume relations. Circulation 79: 167-178.
Burkhoff D, Sugiura S, Yue DT, Sagawa K, (1987) Contractility-dependent curvilinearity of endsystolic pressure-volume relations. American Journal of Physiology-Heart and Circulatory Physiology 252: H1218-H1227.
Vaartjes SR, Boom H, (1987) Left ventricular internal resistance and unloaded ejection ow assessed from pressure-ow relations: a ow-clamp study on isolated rabbit hearts. Circulation research 60: 727-737.
Shroff SG, Janicki JS, Weber KT, (1985) Evidence and quantitation of left ventricular systolic resistance. American Journal of Physiology-Heart and Circulatory Physiology 249: H358-H370.
Burkhoff D, de Tombe PP, Hunter WC, Kass DA, (1991) Contractile strength and mechanical efficiency of left ventricle are enhanced by physiological afterload. American Journal of Physiology-Heart and Circulatory Physiology 260: H569-H578.
Stevenson D, Revie J, Chase JG, Hann CE, Shaw GM, et al. (2012) Algorithmic processing of pressure waveforms to facilitate estimation of cardiac elastance. BioMedical Engineering OnLine 11: 28.
Stevenson D, Revie J, Chase JG, Hann CE, Shaw GM, et al. (2012) Beat-to-beat estimation of the continuous left and right cardiac elastance from metrics commonly available in clinical settings. Biomedical engineering online 11: 73.
Pironet A, Desaive T, Kosta S, Lucas A, Paeme S, et al. (2013) A multi-scale cardiovascular system model can account for the load-dependence of the end-systolic pressure-volume relationship. Biomedical engineering online 12: 8.
Alexander J, Sunagawa K, Chang N, Sagawa K, (1987) Instantaneous pressure-volume relation of the ejecting canine left atrium. Circulation Research 61: 209-219.
Hoit BD, Shao Y, Gabel M, Walsh RA, (1994) In vivo assessment of left atrial contractile performance in normal and pathological conditions using a time-varying elastance model. Circulation 89: 1829-1838.
Dernellis JM, Stefanadis CI, Zacharoulis AA, Toutouzas PK, (1998) Left atrial mechanical adaptation to long-standing hemodynamic loads based on pressure-volume relations. The American journal of cardiology 81: 1138-1143.
Kehl F, Kress TT, Mraovic B, Hettrick DA, Kersten JR, et al. (2002) Propofol alters left atrial function evaluated with pressure-volume relations in vivo. Anesthesia & Analgesia 94: 1421-1426.
Gare M, Schwabe DA, Hettrick DA, Kersten JR, Warltier DC, et al. (2001) Desurane, sevourane, and isourane a_ect left atrial active and passive mechanical properties and impair left atrial-left ventricular coupling in vivo: analysis using pressure-volume relations. Anesthesiology 95: 689-698.
Korakianitis T, Shi Y, (2006) A concentrated parameter model for the human cardiovascular system including heart valve dynamics and atrioventricular interaction. Medical engineering & physics 28: 613-628.
Lau VK, Sagawa K, (1979) Model analysis of the contribution of atrial contraction to ventricular filling. Annals of biomedical engineering 7: 167-201.
Olansen J, Clark J, Khoury D, Ghorbel F, Bidani A, (2000) A closed-loop model of the canine cardiovascular system that includes ventricular interaction. Computers and biomedical research 33: 260-295.
Chung DC (1996) Ventricular interaction in a closed-loop model of the canine circulation. Master's thesis, Rice University, Houston, Texas.
Luo C, Ware D, Zwischenberger J, Clark J, (2007) Using a human cardiopulmonary model to study and predict normal and diseased ventricular mechanics, septal interaction, and atrio-ventricular blood ow patterns. Cardiovascular Engineering 7: 17-31.
Tse Ve Koon K, Le Rolle V, Carrault G, Hernandez AI (2009) A cardiovascular model for the analysis of pacing configurations in cardiac resynchronization therapy. In: Computers in Cardiology, 2009. IEEE, 393-396.
Lu K, Clark J, Ghorbel F, Ware D, Bidani A, (2001) A human cardiopulmonary system model applied to the analysis of the valsalva maneuver. American Journal of Physiology-Heart and Circulatory Physiology 281: H2661-H2679.
van Meurs W (2011) Modeling and Simulation in Biomedical Engineering: Applications in Cardiorespiratory Physiology. McGraw-Hill Professional.
Maughan WL, Shoukas AA, Sagawa K, Weisfeldt ML, (1979) Instantaneous pressure-volume relationship of the canine right ventricle. Circulation research 44: 309-315.
Yue DT, (1987) Intracellular [Ca2+] related to rate of force development in twitch contraction of heart. American Journal of Physiology-Heart and Circulatory Physiology 252: H760-H770.
Nygren A, Fiset C, Firek L, Clark J, Lindblad D, et al. (1998) Mathematical model of an adult human atrial cell: the role of K+ currents in repolarization. Circulation Research 82: 63-81.
Negroni JA, Lascano EC, (1996) A cardiac muscle model relating sarcomere dynamics to calcium kinetics. Journal of molecular and cellular cardiology 28: 915-929.
Negroni JA, Lascano EC, (1999) Concentration and elongation of attached cross-bridges as pressure determinants in a ventricular model. Journal of molecular and cellular cardiology 31: 1509-1526.
Bo Shim E, Hun Leem C, Abe Y, Noma A, Shim EB, et al. (2006) A new multi-scale simulation model of the circulation: from cells to system. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 364: 1483-1500.
Smith BW, Chase JG, Nokes RI, Shaw GM, Wake G, (2004) Minimal haemodynamic system model including ventricular interaction and valve dynamics. Medical engineering & physics 26: 131-139.
Smith BW, Geoffrey Chase J, Shaw GM, Nokes RI, (2005) Experimentally veri_ed minimal cardiovascular system model for rapid diagnostic assistance. Control engineering practice 13: 1183-1193.
Starfinger C, Hann C, Chase J, Desaive T, Ghuysen A, et al. (2007) Model-based cardiac diagnosis of pulmonary embolism. Computer methods and programs in biomedicine 87: 46-60.
Revie JA, Stevenson DJ, Chase JG, Hann CE, Lambermont BC, et al. (2011) Clinical detection and monitoring of acute pulmonary embolism: proof of concept of a computer-based method. Annals of intensive care 1: 1-12.
Starfinger C, Chase J, Hann C, Shaw G, Lambermont B, et al. (2008) Model-based identification and diagnosis of a porcine model of induced endotoxic shock with hemofiltration. Mathematical biosciences 216: 132-139.
Courtois M, Kovacs Jr SJ, Ludbrook P, (1988) Transmitral pressure-ow velocity relation. Importance of regional pressure gradients in the left ventricle during diastole. Circulation 78: 661-671.
Klabunde R (2011) Cardiovascular physiology concepts. Lippincott Williams & Wilkins.
Guyton AC, Hall JE (2006) Textbook of medical physiology. Elsevier Saunders.
Stpeanek J, Christen P, et al. (1975) Pulmonary arterial pressure in conscious and anaesthetized dogs. Bulletin de physio-pathologie respiratoire 11: 295.
Ferasin L, Ferasin H, Little C, (2010) Lack of correlation between canine heart rate and body size in veterinary clinical practice. Journal of Small Animal Practice 51: 412-418.
Lamb AP, Meurs KM, Hamlin RL, (2010) Correlation of heart rate to body weight in apparently normal dogs. Journal of Veterinary Cardiology 12: 107-110.
Oh JK, Seward JB, Tajik AJ (2006) The echo manual. Lippincott Williams & Wilkins.
Nattel S, (2002) New ideas about atrial fibrillation 50 years on. Nature 415: 219-226.
Paeme S, Moorhead KT, Chase JG, Lambermont B, Kolh P, et al. (2011) Mathematical multi-scale model of the cardiovascular system including mitral valve dynamics. application to ischemic mitral insufficiency. Biomedical engineering online 86.
Revie JA, Stevenson DJ, Chase JG, Hann CE, Lambermont BC, et al. (2011) Validation of subjects pecific cardiovascular system models from porcine measurements. Computer Methods and Programs in Biomedicine.
Burkhoff D, Tyberg JV, (1993) Why does pulmonary venous pressure rise after onset of lv dysfunction: a theoretical analysis. American Journal of Physiology-Heart and Circulatory Physiology 265: H1819-H1828.
Finsterer U, Prucksunand P, Brechtelsbauer H, (1973) Critical evaluation of methods for determination of blood volume in the dog. Plugers Archiv 341: 63-72.