Passive Stiffness of Myocardium From Congenital Heart Disease and Implications for Diastole

Background— In ventricular dilatation or hypertrophy, an elevated end-diastolic pressure is often assumed to be secondary to increased myocardial stiffness, but stiffness is rarely measured in vivo because of difficulty. We measured in vitro passive stiffness of volume- or pressure-overloaded myocardium mainly from congenital heart disease. Methods and Results— Endocardial ventricular biopsies were obtained at open heart surgery (n=61; pressure overload, 36; volume-overload, 19; dilated cardiomyopathy, 4; normal donors, 2). In vitro passive force-extension curves and the stiffness modulus were measured in skinned tissue: muscle strips, strips with myofilaments extracted (mainly extracellular matrix), and myocytes. Collagen content (n=38) and titin isoforms (n=16) were determined. End-diastolic pressure was measured at cardiac catheterization (n=14). Pressure-overloaded tissue (strips, extracellular matrix, myocytes) had a 2.6- to 7.0-fold greater force and stiffness modulus than volume-overloaded tissue. Myocyte force and stiffness modulus at short stretches (0.05 resting length, L0) was pressure-overloaded >normal≈volume-overloaded>dilated cardiomyopathy. Titin N2B:N2BA isoform ratio varied little between conditions. The extracellular matrix contributed more to force at 0.05 L0 in pressure-overloaded (35.1%) and volume-overloaded (17.4%) strips than normal myocardium. Stiffness modulus increased with collagen content in pressure-overloaded but not volume-overloaded strips. In vitro stiffness modulus at 0.05 L0 was a good predictor of in vivo end-diastolic pressure for pressure-overloaded but not volume-overloaded ventricles and estimated normal end-diastolic pressure as 5 to 7 mm Hg. Conclusions— An elevated end-diastolic pressure in pressure-overloaded, but not volume-overloaded, ventricles was related to increased myocardial stiffness. The greater stiffness of pressure-overloaded compared with volume-overloaded myocardium was due to the higher stiffness of both the extracellular matrix and myocytes. The transition from normal to very-low stiffness myocytes may mark irreversible dilatation.

[1]  J. Bronzwaer,et al.  Diastolic Stiffness of the Failing Diabetic Heart: Importance of Fibrosis, Advanced Glycation End Products, and Myocyte Resting Tension , 2008, Circulation.

[2]  H. Granzier,et al.  Protein Kinase A Phosphorylates Titin’s Cardiac-Specific N2B Domain and Reduces Passive Tension in Rat Cardiac Myocytes , 2002, Circulation research.

[3]  M C Leake,et al.  Passive Stiffness Changes Caused by Upregulation of Compliant Titin Isoforms in Human Dilated Cardiomyopathy Hearts , 2004, Circulation research.

[4]  Marion L Greaser,et al.  Vertical agarose gel electrophoresis and electroblotting of high‐molecular‐weight proteins , 2003, Electrophoresis.

[5]  Simon N. Wood,et al.  Generalized Additive Models: An Introduction with R , 2006 .

[6]  T. Irving,et al.  Passive tension in cardiac muscle: contribution of collagen, titin, microtubules, and intermediate filaments. , 1995, Biophysical journal.

[7]  Chiara Tesi,et al.  Tension generation and relaxation in single myofibrils from human atrial and ventricular myocardium , 2007, Pflügers Archiv - European Journal of Physiology.

[8]  Wolfgang A Linke,et al.  Myocardial Structure and Function Differ in Systolic and Diastolic Heart Failure , 2006, Circulation.

[9]  T Centner,et al.  Series of exon-skipping events in the elastic spring region of titin as the structural basis for myofibrillar elastic diversity. , 2000, Circulation research.

[10]  J W Covell,et al.  Diastolic Geometry and Sarcomere Lengths in the Chronically Dilated Canine Left Ventricle , 1971, Circulation research.

[11]  W. Linke,et al.  Pulling single molecules of titin by AFM—recent advances and physiological implications , 2008, Pflügers Archiv - European Journal of Physiology.

[12]  R. Wait,et al.  Detection and Mapping of Widespread Intermolecular Protein Disulfide Formation during Cardiac Oxidative Stress Using Proteomics with Diagonal Electrophoresis* , 2004, Journal of Biological Chemistry.

[13]  J. Bronzwaer,et al.  Hypophosphorylation of the Stiff N2B Titin Isoform Raises Cardiomyocyte Resting Tension in Failing Human Myocardium , 2009, Circulation research.

[14]  P. Janmey,et al.  Nonlinear elasticity in biological gels , 2004, Nature.

[15]  O. Hess,et al.  Left ventricular myocardial structure in aortic valve disease before, intermediate, and late after aortic valve replacement. , 1989, Circulation.

[16]  I. LeGrice,et al.  3‐Dimensional configuration of perimysial collagen fibres in rat cardiac muscle at resting and extended sarcomere lengths , 1999, The Journal of physiology.

[17]  D. Kass,et al.  What Mechanisms Underlie Diastolic Dysfunction in Heart Failure? , 2004, Circulation research.

[18]  Istvan Edes,et al.  Cardiomyocyte Stiffness in Diastolic Heart Failure , 2005, Circulation.

[19]  G. Laurent,et al.  Application of high-pressure liquid chromatography to studies of collagen production by isolated cells in culture. , 1990, Analytical biochemistry.

[20]  O. Hess,et al.  Age dependency of left ventricular diastolic function in pressure overload hypertrophy. , 1997, Journal of the American College of Cardiology.

[21]  Daniel J. Muller,et al.  Single-cell force spectroscopy , 2008, Journal of Cell Science.

[22]  Y. Goldman,et al.  Relaxation of rabbit psoas muscle fibres from rigor by photochemical generation of adenosine‐5'‐triphosphate. , 1984, The Journal of physiology.

[23]  Nadine Aubry,et al.  Aging increases stiffness of cardiac myocytes measured by atomic force microscopy nanoindentation. , 2003, American journal of physiology. Heart and circulatory physiology.

[24]  M. Yacoub,et al.  Enhanced deposition of predominantly type I collagen in myocardial disease. , 1990, Journal of molecular and cellular cardiology.

[25]  P. Garzella,et al.  Absence of mechanical evidence for attached weakly binding cross‐bridges in frog relaxed muscle fibres. , 1995, The Journal of physiology.

[26]  L. Sharples,et al.  Brain death leads to abnormal contractile properties of the human donor right ventricle. , 2006, The Journal of thoracic and cardiovascular surgery.

[27]  Alan Y. Chiang,et al.  Generalized Additive Models: An Introduction With R , 2007, Technometrics.

[28]  D. Kass Getting Better Without AGE New Insights Into the Diabetic Heart , 2003, Circulation research.

[29]  Wolfgang A. Linke,et al.  Isoform Diversity of Giant Proteins in Relation to Passive and Active Contractile Properties of Rabbit Skeletal Muscles , 2005, The Journal of general physiology.

[30]  W Grossman,et al.  Wall stress and patterns of hypertrophy in the human left ventricle. , 1975, The Journal of clinical investigation.

[31]  A. J. Brady,et al.  Mechanical properties of isolated cardiac myocytes. , 1991, Physiological reviews.

[32]  C. Poggesi,et al.  Active and passive forces of isolated myofibrils from cardiac and fast skeletal muscle of the frog. , 1997, The Journal of physiology.

[33]  K W Ranatunga,et al.  Temperature‐dependent changes in the viscoelasticity of intact resting mammalian (rat) fast‐ and slow‐twitch muscle fibres , 1998, The Journal of physiology.

[34]  A. Redington,et al.  Noradrenaline Use in the Human Donor and Relationship with Load-Independent Right Ventricular Contractility , 2004, Transplantation.

[35]  Jane Clarke,et al.  Hidden complexity in the mechanical properties of titin , 2003, Nature.

[36]  Siegfried Labeit,et al.  PKC Phosphorylation of Titin’s PEVK Element: A Novel and Conserved Pathway for Modulating Myocardial Stiffness , 2009, Circulation research.

[37]  Are weakly binding bridges present in resting intact muscle fibers? , 1992, Biophysical journal.

[38]  T. Hisada,et al.  Microtubules Modulate the Stiffness of Cardiomyocytes Against Shear Stress , 2005, Circulation research.

[39]  K E Muffly,et al.  Structural Remodeling of Cardiac Myocytes in Patients With Ischemic Cardiomyopathy , 1992, Circulation.

[40]  I. Mirsky,et al.  The Effects of Geometry, Elasticity, and External Pressures on the Diastolic Pressure‐Volume and Stiffness‐Stress Relations: How Important is the Pericardium? , 1979, Circulation research.

[41]  M. Weisfeldt,et al.  Influence of Aging on Left Ventricular Hemodynamics and Stiffness in Beagles , 1979, Circulation research.

[42]  K W Ranatunga,et al.  The viscous, viscoelastic and elastic characteristics of resting fast and slow mammalian (rat) muscle fibres. , 1996, The Journal of physiology.

[43]  S. Houser,et al.  Regression of cellular hypertrophy after left ventricular assist device support. , 1998, Circulation.

[44]  J. Covell,et al.  Left Ventricular Performance Following Correction of Free Aortic Regurgitation , 1970, Circulation.

[45]  M. Gautel,et al.  Activation of Myocardial Contraction by the N-Terminal Domains of Myosin Binding Protein-C , 2006, Circulation research.

[46]  Yiming Wu,et al.  Altered Titin Expression, Myocardial Stiffness, and Left Ventricular Function in Patients With Dilated Cardiomyopathy , 2004, Circulation.

[47]  Roger J Hajjar,et al.  Titin Isoform Switch in Ischemic Human Heart Disease , 2002, Circulation.

[48]  H. Dodge,et al.  Pressure-volume characteristics of the diastolic left ventricle of man with heart disease , 1962 .

[49]  K. Wang,et al.  Regulation of skeletal muscle stiffness and elasticity by titin isoforms: a test of the segmental extension model of resting tension. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[50]  J. Trinick,et al.  Titin and the sarcomere symmetry paradox. , 2001, Journal of molecular biology.

[51]  H. E. Keurs,et al.  Dynamics of viscoelastic properties of rat cardiac sarcomeres during the diastolic interval: involvement of Ca2+ , 1997, The Journal of physiology.

[52]  H. Suga,et al.  Assessment of systolic and diastolic ventricular properties via pressure-volume analysis: a guide for clinical, translational, and basic researchers. , 2005, American journal of physiology. Heart and circulatory physiology.

[53]  Christian Andresen,et al.  Protein kinase G modulates human myocardial passive stiffness by phosphorylation of the titin springs , 2008, Circulation research.

[54]  T Centner,et al.  Differential expression of cardiac titin isoforms and modulation of cellular stiffness. , 2000, Circulation research.

[55]  K S McDonald,et al.  Force‐velocity and power‐load curves in rat skinned cardiac myocytes , 1998, The Journal of physiology.

[56]  S. Glantz,et al.  Left ventricular mechanical adaptation to chronic aortic regurgitation in intact dogs. , 1987, The American journal of physiology.