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8/31/09 Learning Objectives Evaluation of Diastolic Dysfunction Using Cardiac MRI 1. To highlight the importance and study the patho-physiology of diastolic dysfuncion. 2. To study the parameters in diagnosing diastolic dysfunction including their individual strengths and weaknesses. 3. To investigate the role of CMR in evaluation of these parameters. Dr. Tarun Pandey MD, FRCR. Assistant Professor, MRI Division, University of Arkansas for Medical Sciences Understanding Normal Cardiac Function Outline • What is Diastology? – Epidemiology and Pathophysiology of Diastolic Dysfunction. • Which parameters to study on MRI and how? • Which parameter to rely on? LV Pressure Ejection – Morphological: Indexed LA volume and Indexed LV mass. – Mitral valve flow-velocity: E/A ratio, Decceleration time. – Pulmonary vein: Systolic and diastolic flow peaks, S/D ratio & A-wave reversal. IVRT: Isovolumetric relaxation IVCT: Isovolumetric contraction ESV: End Systolic Volume EDV: End Diastolic Volume SV IVCT IVRT – Strengths and weaknesses of individual parameter. • What more can be done? Filling – Recent advances: Strain imaging. ESV The cardiac cycle consists of four phases shown in the diagram. Notice the pressure-vol. changes during the cycle, in particular during IVRT and ventricular filling. EDV LV volume Understanding the Terminology: What is Diastolic Dysfunction? Understanding Diastolic Function • Isovolumetric relaxation Early rapid diastolic filling Diastasis Late diastolic atrial filling Notice that the Trans-mitral Pressure Gradient (TMPG) is the actual determinant of LV filling. TMPG is influenced by: – LV relaxation – LV compliance (which affects LA pressures) Ao Pressure 1. 2. 3. 4. • Aortic Closure Opening Diastole, in turn, is divided into four stages: LV Peak Exercise Mitral Closure Opening LA IVRT IVCT Aortic Closure Opening Distance • Pulmonary Wedge Pressure (mm Hg) Rest Peak Exercise Rest LV-End Diastolic Volume (ml) Mitral Closure Opening Time The inability to fill the left ventricle, during rest or exercise, to a normal end diastolic volume without an abnormal increase in LV end-diastolic or mean left atrial pressure Or, a failure to increase LVEDV, & therefore cardiac output during exercise represents diastolic dysfunction. While diastolic heart failure refers to the clinical syndrome of heart failure in the setting of a normal ejection fraction, DD refers to the abnormality of diastolic function regardless of the clinical status of the patient [1]. 1 8/31/09 Understanding the Problem at Hand: Epidemiology • Both DD and diastolic heart failure are very common, particularly in the elderly population [2]. – The prevalence of asymptomatic DD in individuals > 45 years is approximately 25-30% [3]. – Up to 40% of heart failure patients have DD which is a cause of significant morbidity in this group [4]. The condition often precedes the progression of systolic dysfunction and is a major determinant of the symptoms of patients with systolic heart failure. • Hence assessment of diastolic LV function and estimation of filling pressures is an important part of the management of patients with heart disease. Understanding the Pathophysiology of Diastolic dysfunction • Impaired Relaxation – Aging – Ischemia – Cardiomyopathy • Reduced Compliance – LV Hypertrophy (HTn, Valvular and Cong. Heart Diseases – Myocardial fibrosis (Infarction) – Restrictive Cardiomyopathy • Extrinsic Compression – Constrictive pericarditis – Pericardial Tamponade Interplay of Reduced LV compliance and Impaired Relaxation on Grading of Diastolic Dysfunction LV Pressure LA Pressure LA Pressure LA Pressure A E E PVs PVa Time A EA Ratio, DT & IVRT DT PVs PVd Time Grade 2 Grade 3 (Impaired Relaxation) (Pseudonormal) (Restrictive) <15 15-25 > 25 < 15 EA ratio >1 <1 1-1.5 >2 DT (ms.) 150-220 > 250 > 150 < 150 PVd PVd PVa LA Pressure Grade 1 (mm Hg) A IVRT PVs PVd LV/LA Pressure Curves E E A Normal LV Pressure LV Pressure LV Pressure LA Pressure Physiological changes with increasing Diastolic Dysfunction PVs PVa Time PVa Pulmonary Vein Curves IVRT (ms.) <90 >90 <90 < 70 PVs/ PVd >1 >1 <1 <<1 Time Legend: DT- Deceleration time; IVRT- Isovolumetric relaxation time PVs- 2nd systolic pulmonary vein peak; PVd- Pulmonary vein diastolic peak Parameters in evaluation of Diastolic Dysfunction Parameters in evaluation of Diastolic Dysfunction • Morphological • Morphological – Indexed Left Atrial Volume – Indexed Left Ventricular mass • Mitral flow and velocity – EA ratio (Ratio of peaks of E and A waves) – DT: Deceleration time. – E wave upslope: • Pulmonary vein flow – SD ratio (Ratio of peaks of the S and D waves) – A wave amplitude and duration. – Indexed Left Atrial Volume – Indexed Left Ventricular mass • Mitral flow and velocity – EA ratio (Ratio of peaks of E and A waves) – DT: Deceleration time. – E wave upslope: • Pulmonary vein flow – SD ratio (Ratio of peaks of the S and D waves) – A wave amplitude and duration. 2 8/31/09 Morphological parameters: How to calculate LA Vol. on CMR? Morphological parameters: How to calculate LV mass on CMR? Biplane Area-Length method used for MR evaluation of Left atrial volume on Cine-true FISP 4-CH and 2-CH views LA Volume = (0.85 x A1 x A2)/ L L= LA length A1= LA area in 2-CH view A2= LA area in 4-CH view Parameters in evaluation of Diastolic Dysfunction Mitral Valve evaluation: How to obtain Mitral Flow and Velocity Curves on CMR? • Morphological – Indexed Left Atrial Volume – Indexed Left Ventricular mass • Mitral flow and velocity – EA ratio (Ratio of peaks of E and A waves) – DT: Deceleration time. – E wave upslope. • Pulmonary vein flow – SD ratio (Ratio of peaks of the S and D waves) – A wave amplitude and duration. Mitral valve evaluation: How to calculate EA ratio, DT and E-wave upslope from the flow / velocity curves? • Morphological E-wave Peak E-wave upslope Parameters in evaluation of Diastolic Dysfunction A-wave Peak DT – Indexed Left Atrial Volume – Indexed Left Ventricular mass • Mitral flow and velocity – EA ratio (Ratio of peaks of E and A waves) – DT: Deceleration time. – E wave upslope: • Pulmonary vein flow – SD ratio (Ratio of peaks of the S and D waves) – A wave amplitude and duration. 3 8/31/09 Pulmonary vein evaluation: How to obtain pulmonary vein flow curve on CMR? Pulmonary vein evaluation: How to calculate pulmonary vein SD ratio, A wave amplitude & duration on CMR? Systolic Peak Diastolic Peak A-wave Duration A-wave Amplitude Phase contrast cine MR image through the pulmonary vein Left Atrial Volume Understanding individual parameters: Strengths & weaknesses Left Atrial Volume Strength Weakness • Provides morphologic and physiologic evidence for chronic elevation in filling pressure • Severity scale based on clinical outcomes • May be enlarged in other medical conditions including chronic anemia, athletic heart, chronic valvular disease without increase in LV filling pressure. • LA volume is regarded as a barometer of chronicity of diastolic dysfunction. • In echo literature, Left atrial volume is graded relative to risk, – Mild =28 to 33ml/m2; – Moderate = 34 to 39 ml/m2; – Severe = 40ml/m2 Mitral valvular flow (E/A ratio and E-wave upslope) • E wave (E): represents early mitral inflow velocity and is influenced by the relative pressures between the LA and LV. • A wave (A): represents the atrial contractile component of mitral filling and is influenced by LV compliance and LA contractility. • E-wave upslope: Reflects the rapid growth of early diastolic atrio-ventricular pressure gradient. 4 8/31/09 Mitral valvular flow (DT) Deceleration time (DT): Interval from E wave peak to a point of intersection of the deceleration of flow with the baseline. It correlates with time of pressure equalization between the LA and LV. As the early LA and LV filling pressures either evolve toward or away from equivalence, so will the DT either shorten or lengthen respectively. Mitral valvular flow: E/A ratio, E-wave upslope and DT Strength • Can be obtained in all patients • Provides diagnostic and prognostic information Pulmonary Vein Flow Pulmonary Vein Flow • Pulmonary venous pattern: – The S-wave, occurring during LV systole, depends on atrial relaxation and mitral annulus motion. – The D-wave occurring during LV diastole reflects LV filling, and – The A-wave, which is opposite to the other waves and occurs during atrial contraction, reflects changes in LV compliance. Strength Weakness • Complements mitral flow • Can be difficult to obtain parameters especially when especially in a patient who fusion of E and A wave cannot breath hold (differentiating normal vs. (especially on Echo). pseudo-normal pattern). • The relationship of PV-A reversal (PVAR) duration to mitral A duration is the only marker specific for elevation in LVEDP Myocardial Strain Imaging Myocardial Strain Imaging • Used to measure torsion and its rate of recoil. • Noninvasive markers or ‘Tags' are imprinted on the myocardium by selective RF saturation of planes perpendicular to the imaging plane. • These change the magnetization of the protons in the tagged plane compared with the neighboring non-tagged regions, resulting in a difference in signal intensity. • When placed at end diastole and then imaged throughout the cardiac cycle, tags reveal the deformation and displacement of the myocardium on which they were placed. • Tags may be positioned in: – A radial pattern , which is ideal for the measurement of torsion, or, – A grid pattern , which is commonly used for calculation of a full strain field. Weakness • Highly preload dependant • Difficult to obtain without good EKG tracing • Problematic at high heart rates, atrial fibrillation, heart block. Diastole Systole 5 8/31/09 Mitral valve MR Pulmonary Vein Mitral valve Echo Pulmonary Vein CMR versus Echocardiography • Very low inter and intra observer variability of MRI parameters in diastolic dysfunction. • Body habitus is not a limiting factor in assessment. • Comprehensive LV assessment available for etiology during the same study. Phase contrast MR Flow patterns (Top two rows) and Doppler Echo images (Bottom two rows) through the mitral valves and pulmonary veins in patients with Grade 1 (left), Grade 2 (Middle) and Grade 3 Diastolic Dysfunction. References 1. 2. 3. 4. Lester SJ, Tajik AJ, Nishimura RA, Oh JK, Khandheria BK, Seward JB.Unlocking the mysteries of diastolic function: deciphering the Rosetta Stone 10 years later. J Am Coll Cardiol. 2008 Feb 19;51(7): 679-89. Mandinov L, Eberli FR, Seiler C, Hess OM. Diastolic heart failure. Cardiovasc Res. 2000 Mar;45(4):813-25. Abhayaratna WP, Marwick TH, Smith WT, Becker NG. Characteristics of left ventricular diastolic dysfunction in the community: an echocardiographic survey. Heart 2006;92:1259–64. van Kraaij DJ, van Pol PE, Ruiters AW, de Swart JB, Lips DJ, Lencer N, Doevendans PA. Diagnosing diastolic heart failure. Eur J Heart Fail. 2002 Aug;4(4):419-30. 6