Background Patients with signs and symptoms of heart failureand a normal left ventricular ejection fraction are said tohave diastolic heart failure. It has traditionally been thoughtthat the pathophysiological cause of heart failure in thesepatients is an abnormality in the diastolic properties of theleft ventricle; however, this hypothesis remains largely unproven.
Methods We prospectively identified 47 patients who met thediagnostic criteria for definite diastolic heart failure; allthe patients had signs and symptoms of heart failure, a normalejection fraction, and an increased left ventricular end-diastolicpressure. Ten patients who had no evidence of cardiovasculardisease served as controls. Left ventricular diastolic functionwas assessed by means of cardiac catheterization and echocardiography.
ResultsThe patients with diastolic heart failure had abnormalleft ventricular relaxation and increased left ventricular chamberstiffness. The mean (±SD) time constant for the isovolumic-pressuredecline () was longer in the group with diastolic heart failurethan in the control group (59±14 msec vs. 35±10msec, P=0.01). The diastolic pressure–volume relationwas shifted up and to the left in the patients with diastolicheart failure as compared with the controls. The corrected leftventricular passive-stiffness constant was significantly higherin the group with diastolic heart failure than in the controlgroup (0.03±0.01 vs. 0.01±0.01, P<0.001).
Conclusions Patients with heart failure and a normal ejectionfraction have significant abnormalities in active relaxationand passive stiffness. In these patients, the pathophysiologicalcause of elevated diastolic pressures and heart failure is abnormaldiastolic function.
Heart failure is a common cause of cardiovascular disease anddeath and may occur in the presence of either a normal or anabnormal left ventricular ejection fraction.1,2,3 Patients withheart failure who have a normal ejection fraction differ substantiallyfrom those with heart failure and a decreased ejection fractionin several ways, including demographic characteristics, ventricularremodeling, ventricular function, the mortality rate, underlyingcausal mechanisms, and pathophysiological mechanisms.4,5,6,7,8,9,10,11,12,13,14It is widely accepted that the pathophysiology of heart failurein patients with a decreased ejection fraction involves a predominant(though not isolated) decrease in systolic function; this associationhas justified the use of the term "systolic heart failure."1,15,16In contrast, the underlying pathophysiology in patients withheart failure and a normal ejection fraction involves a predominant(though not isolated) abnormality in diastolic function, justifyingthe use of the term "diastolic heart failure."4,5,10,14,17,18However, a recent editorial questioned this conventional wisdomand concluded that "there exists no consistent abnormality ofintrinsic diastolic properties that can explain the occurrenceof heart failure" in these patients.19
We performed a prospective clinical study in which we analyzedmeasurements of both active relaxation and passive stiffnessin patients with heart failure and a normal ejection fraction.All patients in the study met the criteria of Vasan and Levyfor definite diastolic heart failure.20 Thus, we tested thehypothesis that patients with heart failure and a normal ejectionfraction have abnormalities in active relaxation and an increasein passive stiffness — changes that are sufficient toexplain their increased left ventricular diastolic pressuresand their signs and symptoms of heart failure.
Methods
In this multicenter, prospective study, we used left ventricularpressure and Doppler echocardiographic data to assess the diastolicproperties of the left ventricle in 47 patients who had diastolicheart failure and 10 normal controls who had no evidence ofheart disease. The research protocol used in this study wasreviewed and approved by the institutional review board of eachparticipating center. All the patients were enrolled after writteninformed consent had been obtained.
Patients
Patients with a history of heart failure and a normal left ventricularejection fraction (>50 percent) who had been scheduled fordiagnostic cardiac catheterization were evaluated for participationin the study. All the patients met the Framingham criteria forcongestive heart failure.20 Patients with pulmonary disease,renal disease, heart-valve disease, atrial fibrillation, orevidence of hypertrophic cardiomyopathy were excluded. Echocardiographicindexes of diastolic function were not used as inclusion criteria.Forty-seven patients met the inclusion criteria and underwentcombined catheterization and echocardiographic studies. Dataon the left ventricular end-diastolic pressure and left ventricularfilling dynamics in these 47 patients have been reported previously.21However, data on these patients' left ventricular volume andpassive stiffness (the relation between diastolic pressure andvolume) have not been previously published. All 47 patientsmet the criteria of Vasan and Levy for definite diastolic heartfailure. There were 31 men and 16 women; their mean (±SD)age was 59±12 years.
The 10 controls had a mean age of 58±16 years. They underwentcardiac catheterization for the evaluation of symptoms of chestpain. They had no history of cardiovascular disease, and all10 had angiographically normal epicardial coronary arteriesand normal left ventricular volume, ejection fraction, and wallmotion.
Cardiac Catheterization
Cardiac catheterization was performed with the use of standardtechniques. A high-fidelity micromanometer catheter was placedin the left ventricle, Doppler echocardiographic recordingswere obtained, and left ventricular pressures and the time constantof the isovolumic-pressure decline () were measured. The leftventricular minimal diastolic pressure was defined as the lowestpressure after the opening of the mitral valve, the left ventriculardiastolic pre–A-wave pressure was defined as the diastolicpressure before atrial contraction, and the left ventricularend-diastolic pressure was defined as the pressure after atrialcontraction, just before the rise in left ventricular systolicpressure. Pressure data were digitized at intervals of 5 msec,and was calculated by the method of Weiss et al.22 Analysisof the pressure data was performed in a core laboratory.21
Echocardiography
The dimensions and wall thickness of the left ventricle weremeasured according to the recommendations of the American Societyof Echocardiography. Calculations of left ventricular volumeand mass were made with standard published methods.23 Analysisof the echocardiographic data was performed in a core laboratory.21
Total stroke volume was calculated on the basis of the echocardiographicmeasurements. The increment in left ventricular diastolic volumethat occurred between the opening of the mitral valve and thepoint of minimal diastolic pressure was calculated first bydetermining, with the use of Doppler echocardiographic techniques,the fraction of the total left ventricular inflow velocity integralthat occurred during this period. Next, the total stroke volumewas multiplied by this fraction and added to the end-systolicvolume. The result was the volume at the time of minimal diastolicpressure. A similar technique was used to calculate the volumeat the point of pre–A-wave pressure.
Calculation of Passive Diastolic Stiffness
Diastolic stiffness was assessed with the use of three leftventricular diastolic pressure–volume coordinates: end-diastolicpressure and volume, pre–A diastolic pressure and volume,and pressure and volume at the time of minimal diastolic pressure.The diastolic pressure–volume relation can be describedby an exponential equation, P=AeV, where P is the left ventriculardiastolic pressure, V is the left ventricular diastolic volume,and A and are curve-fitting constants used to quantify passivestiffness.4
We reasoned that the abnormally slow rate of ventricular relaxationin our patients with diastolic heart failure would precludefull relaxation of the myocardium in early diastole. Thus, incompleterelaxation at the point of left ventricular minimal diastolicpressure might cause the latter value to be higher than it wouldbe if it reflected the purely passive stiffness of the ventricle.Therefore, a corrected value of left ventricular minimal diastolicpressure was obtained by subtracting the contribution to pressureof slow (or incomplete) relaxation from the measured pressurevalue. This corrected pressure was used to calculate a correctedpassive-stiffness constant.
The method used to make this correction, illustrated in Figure 1,is based on standard engineering concepts and published experimentaldata.24,25,26,27,28 In brief, the time course of the declinein left ventricular pressure was plotted from the point of aortic-valveclosure to the time that the left ventricular pressure wouldapproach zero if relaxation proceeded in the absence of filling.This approach was based on the concept that relaxation is essentiallycomplete after a time interval equal to 3.5.24,25,26,27,28 Thenthe time from the closure of the aortic valve to the point ofleft ventricular minimal diastolic pressure was measured, andthe pressure at this time was determined from the plot of thenatural log of pressure versus time. This contribution of slowedrelaxation to pressure represents the extent to which the leftventricular minimal diastolic pressure exceeds the purely passivepressure. By subtracting the pressure contribution of slowedrelaxation from the measured value of the left ventricular minimaldiastolic pressure, we obtained a corrected left ventricularminimal diastolic pressure. This corrected pressure was usedto calculate the corrected passive-stiffness constant.
Figure 1. Diagram of the Method Used to Correct the Measured Value of Left Ventricular Minimal Diastolic Pressure for Slow Relaxation Rate.
In Panel A, the decline in left ventricular pressure is illustrated for three values of the relaxation time constant (). For example, if equals 60 msec and the minimal early diastolic pressure (Pmin) occurs 130 msec after aortic-valve closure (indicated by the vertical arrow), the contribution of slowed relaxation to pressure (Psr) is 7 mm Hg. In Panel B, measured and corrected pressure tracings in a patient with diastolic heart failure are shown in relation to a normal (control) pressure tracing. AVC denotes aortic-valve closure, and DHF diastolic heart failure.
Statistical Analysis
The 47 patients with definite diastolic heart failure had participatedin a previous clinical trial21; the 10 controls had not participatedin that trial. The sample size for the control group was basedon the hypothesis that the mean value for the corrected stiffnessconstant in the group with diastolic heart failure would betwo times as high as that of the control group. Therefore, usinga sample size of 47 patients with diastolic heart failure and10 controls would yield 80 percent power to detect a twofolddifference in the corrected stiffness constant with the useof a conservative standard deviation of 0.01 and a two-sidedalpha level of 0.05. Differences between the group with diastolicheart failure and the control group were examined with the useof an unpaired t-test. A P value of less than 0.05 was consideredto indicate statistical significance. All reported P valuesare two-sided. Data were collected at each of the seven studysites and analyzed in the two core laboratories. Additionaldata analysis was performed and the manuscript was written bythe authors.
Results
Left Ventricular Active Relaxation
In the patients with diastolic heart failure, was abnormal,the left ventricular early minimal diastolic pressure was increased,and there was a positive correlation between and the minimaldiastolic pressure (R2=0.77). In these patients, the left ventricularminimal diastolic pressure occurred a mean of 138±5 msecafter closure of the aortic valve, which occurred before 3.5(i.e., before 218±5 msec). Thus, relaxation was incompleteat the time of left ventricular minimal diastolic pressure inall the patients with diastolic heart failure; incomplete relaxationaccounted for 7±1 mm Hg of the measured value of thispressure. By contrast, relaxation was complete at the time ofleft ventricular minimal diastolic pressure in all the controls.
Left Ventricular Passive Stiffness
The end-diastolic pressure was higher and the end-diastolicvolume was lower in the group of patients with diastolic heartfailure than in the control group (Table 1). These data alonesuggest the presence of increased chamber stiffness in the patientswith diastolic heart failure. As shown in Figure 2A, the entirediastolic pressure–volume relation was displaced up andto the left in the patients with diastolic heart failure ascompared with the controls. The left ventricular chamber-stiffnessconstant and curve-fitting constant, when calculated on thebasis of measured values, were higher in the patients with diastolicheart failure than in the controls. When the corrected valuesfor left ventricular minimal diastolic pressure were used tocalculate the chamber stiffness (Figure 2B), the differencein passive stiffness was even more pronounced. As shown in Figure 3,the chamber-stiffness constant was higher in the patientswith diastolic heart failure than in the controls.
Figure 2. Diastolic Pressure–Volume Relation in Patients with Diastolic Heart Failure and in Controls.
Panel A shows measured values for the minimal left ventricular pressure, and Panel B shows values for the minimal left ventricular pressure, corrected for slow relaxation. The exponential value in the equation for pressure (P) is the stiffness constant. The data in both panels indicate that there was a significant increase in the passive stiffness of the left ventricle in the patients with diastolic heart failure. V denotes volume, and the I bars represent the standard error.
Cardiogenic pulmonary edema in patients with diastolic heartfailure is often the result of sodium retention and expansionof the central blood volume.7 Neurohormonally mediated increasesin venous tone and systemic arterial pressure may contributeto a shifting of the blood to the central circulation and therebycause a substantial increase in left ventricular diastolic pressurein such patients.29 Alterations in arterial stiffness may alsocontribute by exacerbating the underlying abnormalities in activerelaxation and passive stiffness. However, none of these individualfactors (sodium retention, neurohormonal activation, increasedvenous tone, or increased arterial stiffness) cause heart failurein patients with normal left ventricular structure and function.It is the increased left ventricular stiffness in patients withdiastolic heart failure that makes them especially vulnerableto the development of pulmonary edema. Increased passive stiffnessof the left ventricle dictates the association of very smallchanges in volume with large changes in left ventricular diastolicpressure.4,5 Indeed, significant changes in pressure may beseen even with little or no detectable change in ventricularvolume.29,30 Thus, pulmonary edema in patients with diastolicheart failure is the direct consequence of increased passivechamber stiffness; the ventricle is unable to accept venousreturn adequately without high diastolic pressures. Such highfilling pressures result in decreased lung compliance, whichincreases the work of breathing and contributes to dyspnea.
A number of methods have been used to evaluate left ventriculardiastolic stiffness.24,32,33,34 Pak et al. showed that thereis agreement between measurements of passive chamber stiffnessobtained with "single-beat analysis" (i.e., multiple pressure–volumecoordinates from a single beat) and those obtained with "multiple-beatanalysis" (i.e., end-diastolic pressure–volume coordinatesfrom multiple beats) in patients with hypertensive heart disease,the disease process that most often leads to diastolic heartfailure.33 For this reason, and because the multiple-beat methodis difficult to apply in large clinical studies, we used a single-beatmethod of analysis. However, the accuracy of the curve-fittingconstants derived from the pressure and volume data is dependenton a number of factors, including the number of data pointsused in the calculation. In addition, the effects of slow orprolonged relaxation on early diastolic pressure can limit theaccuracy of the single-beat method. In the current study, weavoided this problem by correcting the early diastolic pressuresfor delayed relaxation. In the patients with diastolic heartfailure, such a correction yielded substantially higher passive-stiffnessconstants than those obtained with the traditional, uncorrectedmethod.
Many, but not all, of the structural, functional, and demographicfeatures of the patients in the current study are shared bythe patients examined in recently reported epidemiologic communitystudies of patients with diastolic heart failure.7,8,9,10,11,12For example, more than 75 percent of the patients in both thecurrent and the previous studies had hypertension. Thirty-eightpercent of the patients in the current study had left ventricularhypertrophy (defined as a left ventricular mass that exceeded125 g per square meter of body-surface area). These findingsare consonant with data from the studies by Chen et al.7 andKitzman et al.,10 in which 43 percent and 35 percent of patientswith diastolic heart failure, respectively, had left ventricularhypertrophy. Therefore, left ventricular hypertrophy is a commonfinding in patients with diastolic heart failure; its presencesupports but is not required for a diagnosis of diastolic heartfailure.20,21 Patients with diastolic heart failure generallyhave normal or even small left ventricular chamber volumes.10,13,35Echocardiographic studies have shown that the left ventricularend-diastolic volume is 103±20 ml (where the normalizedvalue indexed to body-surface area is 56±10 ml per squaremeter) in normal persons but 90±18 ml (where the normalizedvalue indexed to body-surface area is 47±5 ml per squaremeter) in patients with diastolic heart failure.10,13,35,36,37,38,39,40Data from the current study also indicate that left ventricularvolumes are normal or decreased in patients with diastolic heartfailure.
Despite these many similarities, there are some differencesbetween the current study and previous studies.6,7,8,9,10,11,12For example, the patients in the current study were youngerthan those in the previous studies, and a higher proportionof them were men. However, each of the patients examined inthe current study fulfilled the criteria of Vasan and Levy fordefinite diastolic heart failure — a requirement the epidemiologicstudies were not designed to meet. Therefore, we believe thatthe conclusions made in the current study are applicable toa wider population of patients, such as those described in theprevious studies.6,7,8,9,10,11,12
Patients who meet the criteria for definite diastolic heartfailure have abnormal active relaxation and increased passivestiffness. The predominant pathophysiological cause of heartfailure in these patients is abnormal diastolic function. Therefore,it is appropriate to use the term "diastolic heart failure"to describe the abnormalities in these patients.
Supported by a grant from Mitsubishi Pharma.
We are indebted to the principal investigators, associate investigators,and nurse coordinators at each of the seven study sites (MedicalUniversity of South Carolina, Lahey Clinic Medical Center, Universityof Colorado Health Sciences Center, University of Texas HealthScience Center San Antonio, University of Massachusetts MedicalCenter, Rush Medical College, and Cardiac Centers of Louisiana)for recruiting patients and performing data collection; to thestaff of the core laboratories at Rush Medical College and Universityof Colorado Health Sciences Center; to Robin Sgrosso for secretarialsupport; and to Bev Ksenzak for assistance in the preparationof the manuscript.
Source Information
From the Cardiology Division, Department of Medicine, Gazes Cardiac Research Institute, Medical University of South Carolina; and the Ralph H. Johnson Department of Veterans Affairs Medical Center — both in Charleston, S.C. (M.R.Z., C.F.B.); the Department of Cardiovascular Medicine, Lahey Clinic, Burlington, Mass. (W.H.G.); and the Division of Cardiovascular Medicine, University of Massachusetts Medical School, Worcester, Mass. (W.H.G.).
Address reprint requests to Dr. Zile at Cardiology/Medicine, Medical University of South Carolina, 135 Rutledge Ave., Suite 1201, P.O. Box 250592, Charleston, SC 29425, or at zilem{at}musc.edu.
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Diastolic Heart Failure
Maurer M. S., Packer M., Burkhoff D., King D. L., Grieff M., Zile M. R., Baicu C. F., Gaasch W. H., Redfield M. M.
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Writing Committee Members, , McLaughlin, V. V., Archer, S. L., Badesch, D. B., Barst, R. J., Farber, H. W., Lindner, J. R., Mathier, M. A., McGoon, M. D., Park, M. H., Rosenson, R. S., Rubin, L. J., Tapson, V. F., Varga, J.
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) was longer in the group with diastolic heart failure than in the control group (59±14 msec vs. 35±10 msec, P=0.01). The diastolic pressure–volume relation was shifted up and to the left in the patients with diastolic heart failure as compared with the controls. The corrected left ventricular passive-stiffness constant was significantly higher in the group with diastolic heart failure than in the control group (0.03±0.01 vs. 0.01±0.01, P<0.001). 
V, where P is the left ventricular diastolic pressure, V is the left ventricular diastolic volume, and A and 
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