Estimation of diastolic intraventricular pressure gradients by Doppler M-mode echocardiography

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Estimation of diastolic intraventricular pressure gradients by Doppler M-mode echocardiography

Neil L. Greenberg¹, Pieter M. Vandervoort², Michael S. Firstenberg¹, Mario J. Garcia¹, and James D. Thomas¹

¹ Cardiovascular Imaging Center, Department of Cardiology, The Cleveland Clinic Foundation, Cleveland, Ohio 44195; and ² Heart Center Limburg, Genk 3600, Belgium

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Previous studies have shown that small intraventricular pressure gradients (IVPG) are important for efficient filling of theleft ventricle (LV) and as a sensitive marker for ischemia. Unfortunately,there has previously been no way of measuring these noninvasively,severely limiting their research and clinical utility. Color DopplerM-mode (CMM) echocardiography provides a spatiotemporal velocitydistribution along the inflow tract throughout diastole, whichwe hypothesized would allow direct estimation of IVPG by usingthe Euler equation. Digital CMM images, obtained simultaneouslywith intracardiac pressure waveforms in six dogs, were processedby numerical differentiation for the Euler equation, then integratedto estimate IVPG and the total (left atrial to left ventricularapex) pressure drop. CMM-derived estimates agreed well with invasivemeasurements (IVPG: y = 0.87x + 0.22, r = 0.96, P < 0.001, standarderror of the estimate = 0.35 mmHg). Quantitative processing ofCMM data allows accurate estimation of IVPG and tracking of changesinduced by $beta$ -adrenergic stimulation. This novel approach providesunique information on LV filling dynamics in an entirely noninvasiveway that has previously not been available for assessment of diastolicfilling andfunction.

diastole; hemodynamics; ventricles

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

NORMAL DIASTOLIC FUNCTION of the left ventricle can be defined as the ability of the ventricle to adequately fill under lowfilling pressures. Diastolic dysfunction is present in a numberof cardiac diseases and often precedes left ventricular systolicdysfunction, leading to symptoms of heart failure in patientswith preserved systolic function. Whereas regional pressure differencesbetween the left ventricle, the left ventricular outflow tract,and the aorta during ejection have been recognized for some time(10), the importance of regional pressure differences withinthe ventricle during diastole has only recently gained attention.Although the presence of such intraventricular pressure differencesbetween the left ventricular base and apex during early diastolewas first reported in canine models by Ling et al. (9) in 1979and Falsetti et al. (4) in 1980, the possible clinical implicationsof these observations have not been fully appreciated. Falsettiet al. (4) also observed a gradual increase in the magnitudeof the intraventricular pressure differences with graded infusionsof isoproterenol and a decrease of these intraventricular pressuredifferences with propanolol. Courtois et al. (2) found in ananimal model that these intraventricular diastolic pressure differencesdisappeared during ischemia induced by coronary occlusion. Morerecently, Smiseth et al. (13) demonstrated a relationship betweenearly filling and the pressure difference between the left ventricularapex and outflow tract. Work from this group has also demonstratedthat the delay of apical filling in acute ischemic failure wasattributed to a decrease in the intraventricular driving pressure(15). Whereas these findings suggest the critical importanceof the diastolic intraventricular pressure gradients in assuringadequate left ventricular filling, this information can only beobtained currently during invasive left heart catheterizationwith careful pressure measurements in the left atrium (LA) andmultiple points in the left ventricle, a very impractical procedurefor diagnosis and follow-up of patients in the clinicalsetting.

In recent years, color Doppler M-mode echocardiography has been proposed as a new and promising approach to evaluate leftventricular diastolic function noninvasively. Color Doppler M-modeprovides velocity information, not only at a single point as seenwith traditional pulsed Doppler methods, but along the entireinflow tract from the LA across the mitral valve into the leftventricle and this throughout the entire diastolic filling period.Several studies (1, 3, 5, 14, 16, 18) observeddifferences in the left ventricular inflow patterns as detectedby color Doppler M-mode echocardiography in different diseasestates and physiological conditions. Multiple parameters havebeen proposed to describe these differences in filling patterns,but all of these proposed methods have the following similar disadvantages:1) only a very limited amount of the velocity information availableis used, 2) some measurements are difficult and rather subjective,and 3) the methods are only indirectly related to diastolic function.We (7) recently developed a novel concept to calculate transmitralpressure differences across a normal mitral valve incorporatingthe inertial forces into the unsteady flow form of the Bernoulliequation by using the full digital velocity map. In this study,we extend this concept and apply basic hydrodynamic principlesto the noninvasively obtained spatiotemporal velocity distributionof left ventricular inflow to calculate intraventricular pressuregradients. This approach provides unique information on left ventricularfilling dynamics in an entirely noninvasive way that has neverbeen availablebefore.

Glossary

v	Three-component vector of local blood velocity
P	Local pressure
B	Body forces (such as gravity) acting on the fluid
$rho$	Blood density, 1.05 g/cm³
µ	Blood viscosity, 0.02 cm²/s
s	Distance along the central streamline from the left atrium to left ventricle
$partial$ v/ $partial$ t	Partial derivative of velocity with respect to time
$partial$ v/ $partial$ s	Partial derivative of velocity with respect to space (left atrium to leftventricle)
$partial$ P/ $partial$ s	Partial derivative of pressure with respect to space
$Delta$ _IV	Doppler-derived instantaneous intraventricular pressure difference
$Delta$ _MV	Instantaneous transmitral pressure difference derived from Doppler measurements
$Delta$ _T	Instantaneous total pressure difference derived from Doppler measurements
v_N	Nyquist velocity
PRF	Pulse-repetition frequency
P_LA(t)	Instantaneous left atrial pressure(catheter)
P_base(t)	Instantaneous basal left ventricular pressure(catheter)
P_apex(t)	Instantaneous apical left ventricular pressure(catheter)
$Delta$ P_T	Instantaneous total pressure difference based on catheter measurements
$Delta$ P_MV	Instantaneous transmitral pressure difference based on catheter measurements
$Delta$ P_IV	Instantaneous intraventricular pressure difference based on catheter measurements

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Theoretical Background

Fluid dynamics of diastolic intraventricular flow. Three-dimensional (3-D) flow across a normal mitral valve, from the LA to the left ventricular apex (LV_apex), is governedby the Navier-Stokes equations for incompressible fluid as shownin Eq. 1, where v is a three-component vector of localblood velocity, P is the local pressure, B represents bodyforces (such as gravity) acting on the fluid, and $rho$ and µ areblood density and viscosity, respectively. Note that Eq. 1 isthe differential form of the continuity equation

∇·<IT>v</IT><IT>=0</IT>

−<IT>∇</IT>P<IT>+</IT>B<IT>+&mgr;∇2</IT><IT>v</IT><IT>=&rgr;</IT><FENCE><FR><NU><IT>∂</IT><IT>v</IT></NU><DE><IT>∂t</IT></DE></FR><IT>+</IT>(<IT>v</IT><IT>·∇</IT>)<IT>v</IT></FENCE> (1)

This complex set of coupled differential equations can be simplified by the following assumptions: 1) the viscous term, µ $nabla$ ²v, is very small and can be neglected (19, 22); and2) the gravitational force is balanced by hydrostatic buoyancy,and thus B = 0. If we consider flow along a streamline,this becomes the one-dimensional Euler equation as shown in Eq.2, where the vector notation has been dropped as the focus hasshifted to the velocity in one direction

<FR><NU>∂p</NU><DE>∂s</DE></FR>=−<IT>&rgr;</IT><FENCE><FR><NU><IT>∂v</IT></NU><DE><IT>∂t</IT></DE></FR><IT>+v </IT><FR><NU><IT>∂v</IT></NU><DE><IT>∂s</IT></DE></FR></FENCE> (2)

Integrating the Euler equation along an inflow streamline, from the LV base (LV_base) to apex, yields the nonsteady Bernoulliequation, a noninvasive estimate of the intraventricular pressuredifference as shown in Eq. 3

&Dgr;<A><AC>P</AC><AC>ˆ</AC></A>IV[<IT>t</IT>]<IT>=</IT><LIM><OP>∫</OP><LL>base</LL><UL>apex</UL></LIM> <FR><NU><IT>∂</IT>P</NU><DE><IT>∂s</IT></DE></FR> d<IT>s</IT> (3)

The instantaneous pressure difference is the sum of convective and inertialcomponents.

Animal Model

After approval by the institutional review board, simultaneous pressure and velocity data were obtained from six adult mongreldogs, which were anesthetized with pentobarbital sodium (25 mg/kgiv), intubated, and ventilated with the use of room air. A peripheralvein, the right internal jugular vein, and the right femoral arterywere cannulated for administration of medication and hemodynamicmonitoring. Pulmonary artery pressure and arterial pressure weremeasured using fluid-filled catheters and monitored throughoutthe experiments. After a midline sternotomy was performed, thesternum was split widely and the heart suspended in a pericardialcradle, ensuring an adequate echocardiographic imagingwindow.

High-fidelity pressure measurements. In the first experiment, we used a combination of single- and dual-sensor micromanometer catheters (Millar Instruments; Houston,TX) to obtain pressure measurements from the LA, LV_base, and LV_apex.A catheter with dual pressure sensors separated by 5 cm was usedto record the intraventricular pressures. The catheters were positionedso that the spacing between the LA and LV_base sensors was ~2 cm.This was achieved by advancing the dual catheter 1 cm past aninitial position, where the pressure signal from the proximalsensor switched from LA to LV, and then pulling back 1 cm on thesingle- sensor catheter from a similar initial position. In thesubsequent experiments, we used a multisensor catheter with 5-cmspacing between LV pressure measurements and 2-cm spacing betweenthe sensors for the LA and LV_base pressures. Before introduction,the catheters were immersed in a saline solution for over 1 hto minimize "drift" and calibrated relative to atmospheric pressure,20 and 100 mmHg, respectively. To account for hydrostatic pressuredifferences, LA and LV pressures were aligned during a long diastolictime interval on a postextrasystolic beat. The pressure signalswere amplified by using a universal amplifier (Gould; Valley View,OH) with a flat frequency response up to 500 Hz. LA and LV pressureswere digitized at 1,000 Hz by using a multifunction data-acquisitioncard (model AT-MIO-16, National Instruments; Austin, TX) and transferredfor storage on a 486/50 personal computer (Gateway; N. Sioux City,SD) with the use of a custom-designed acquisition program developedin the LabView (National Instruments)environment.

Doppler ultrasound measurements. Velocity estimation is made in color Doppler echocardiography by comparing the phase shifts in a series of ultrasound pulsesby using autocorrelation techniques along the scanline (8).Visualization of the spatial distribution is provided as an overlayof color- encoded velocity data over structural information. Incontrast to the low temporal resolution of two-dimensional (2-D)color imaging (10-20 Hz), color M-mode directs successive pulsesin a constant direction, allowing the velocity along a singlescanline to be recorded at 200 Hz. Color Doppler imaging obtainedusing this M-mode format provides the spatial velocity distributionalong the Doppler scanline (y-axis) and its temporal changes duringthe cardiac cycle (x-axis).

A 5-MHz imaging transducer (3.7-MHz Doppler frequency) was used with an echocardiograph (Sonos model 1500, Hewlett-Packard;Andover, MA) equipped with digital storage and retrieval capabilities.From the apical scanning window, the Doppler cursor was alignedin parallel with diastolic inflow with the use of 2-D color Dopplerflow imaging. Color Doppler M-mode velocity maps were stored onoptical disk, allowing digital processing of the color Dopplervelocity information. The velocity data were aligned with thepressure waveforms using a timing marker signal that was generatedwithin the data-acquisition program and stored with both the hemodynamicsignals and the color Doppler M-modeimages.

The velocity data were stored in the Hewlett-Packard digital storage and retrieval image format with 5-ms temporal resolution(200 Hz) resulting from the selection of the fastest sweep speedsetting from the echocardiograph. The velocity resolution of thissystem is dependent on the Nyquist velocity (v_N), which is determinedby the system for settings of imaging depth and the pulse-repetitionfrequency (PRF). In this experiment PRF typically varied between5 and 7.5 kHz, depending on imaging depth, leading to a v_N between48 and 81 cm/s. This system stores Doppler data with an 8-bitvalue: 5 bits for the velocity and 3 bits for the variance. The5-bit encoding allows 32 possible values within the range of ±v_N.Therefore, in this experiment, velocity resolution was 3-4 cm/s.The diastolic filling velocity distribution across the mitralvalve has a spatial resolution of ~0.5mm.

Data Analysis

Data were obtained from 10 cardiac cycles under baseline hemodynamic conditions in all 6 animals and from an additional 10cardiac cycles in 4 animals after intravenous administration ofisoproterenol (0.1 µg · kg¹ · min¹).

Calculation of the Invasive Pressure Differences

Instantaneous transmitral pressure differences ( $Delta$ P_MV) were computed from the direct measurements of the LA and LV_base pressures( $Delta$ P_MV[t] = P_LA[t] $-$ P_base[t]). The intraventricular pressure difference( $Delta$ P_IV) was computed from the direct measurements of LV apicaland basal pressures ( $Delta$ P_IV[t] = P_base[t] $-$ P_apex[t]) in the samecardiac cycles. The total pressure difference ( $Delta$ P_T) is the sumof the transmitral and intraventricular pressure gradients ( $Delta$ P_T[t]= $Delta$ P_MV[t] + $Delta$ P_IV[t] = P_LA[t] $-$ P_apex[t]). From these instantaneouspressure differences, we measured the peak pressure differences([ $Delta$ P_T]_max; [ $Delta$ P_IV]_max) during early filling and the time from mitralvalve opening (pressure crossover) to the peak filling pressuredifferences (t_[P(T)]max; t_[P(IV)]max).We also measured the mitral and intraventricular pressure differencesat the maximum total pressure difference ([ $Delta$ P_MV]_{[P(T)]max};[ $Delta$ P_IV]_{[P(T)]max}) to calculate the relativecontribution of the transmitral and intraventricular pressuredifferences to the total pressuredifference.

Calculation of the Noninvasive Pressure Differences

Preprocessing of color Doppler M-mode images. Assuming that the Doppler M-mode cursor closely approximates an inflow streamline, the color-coded Doppler velocity map providesthe spatiotemporal velocity distribution (v[s,t]) along an inflowstreamline from the LV_base to LV_apex. The velocity distributionwas extracted from the raw image file by using a customized analysisprogram developed in LabView (National Instruments). The programallows the user to identify regions within the image where theflow velocities have aliased beyond v_N. With these regions identified,an unaliasing algorithm is used to convert the color scale intotrue velocities given the Nyquist limit stored with the image.Final calibration of the velocity distribution is based on thespatial and temporal resolution coded in the header of the rawimagefile.

As shown in Eq. 3, the instantaneous value of the intraventricular pressure difference ( $Delta$ &Pcirc;

_IV) is calculated by integrationof the pressure gradient ( $partial$ P/ $partial$ s) between the LV_base and LV_apex.Pressure differences between the LA and LV_apex and LV_base ( $Delta$ &Pcirc;

_Tand $Delta$ &Pcirc;

_MV) are computed by varying the limits of integration inEq. 3. The pressure gradient is computed as the product of blooddensity ( $rho$ ) with the sum of the convective (v · $partial$ v/ $partial$ s) and inertialcomponents ( $partial$ v/ $partial$ t). These partial derivatives of the velocitydistribution with respect to space (s) and time (t) are evaluatedby convolving v[s,t] with Sobel operators as shown in Eqs. 4 and5

<FR><NU>∂v[s, t]</NU><DE>∂t</DE></FR>=v[s, t] ⊗ <FENCE><AR><R><C>−<IT>1</IT></C><C>0</C><C>1</C></R><R><C>−<IT>2</IT></C><C>0</C><C>2</C></R><R><C>−<IT>1</IT></C><C>0</C><C>1</C></R></AR></FENCE>

(4)

<FR><NU>∂v[s, t]</NU><DE>∂s</DE></FR>=v[s, t] ⊗ <FENCE><AR><R><C>1</C><C>2</C><C>1</C></R><R><C>0</C><C>0</C><C>0</C></R><R><C>−<IT>1</IT></C><C>−<IT>2</IT></C><C>−<IT>1</IT></C></R></AR></FENCE>

(5)

An example of the simultaneous Doppler velocity and intracardiac pressure data acquired in this experiment is shown in Fig.1. After the Doppler scanline was positioned (Fig. 1, left), thespatiotemporal velocity distribution (Fig. 1, middle) was acquiredwith color-coded blood flow velocities on a 5-bit scale such thatzero velocity is black, velocities toward the transducer are red/yellow,and velocities away from the transducer are blue/cyan. The maximum,or Nyquist, velocity was held constant in this experiment at ±81cm/s. The simultaneous intraventricular and LA pressure measurements(Fig. 1, right) are aligned with the use of a timing marker andelectrocardiogram waveforms.

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Fig. 1. Left: two-dimensional echocardiographic (ECG) sector image showing the position of the scanline from the left ventricular apex (LV_apex), across the mitral valve (MV), and into the left atrium (LA). Middle: color Doppler M-mode spatiotemporal velocity distribution of diastolic inflow in two cardiac cycles, each with early (E) and atrial (A) filling waves. Right: simultaneous intraventricular pressure measurements for these cardiac cycles after alignment with the velocity distribution.

After extraction of the early filling wave, the pressure gradient ( $partial$ P/ $partial$ s) is calculated using the one-dimensional Euler equationas shown in Fig. 2. A noninvasive Doppler estimate of the $Delta$ &Pcirc;

_IVis computed by integration of the pressure gradient, $partial$ P/ $partial$ s, overthe range in depth ( $Delta$ s = 5 cm) corresponding to the distance betweenthe transducers located on the catheter at the LV base and apex.

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Fig. 2. Graphical solution to the one-dimensional Euler equation. The pressure gradient ( $partial$ P/ $partial$ s) is computed from the color Doppler M-mode velocity distribution (v) and its partial derivatives in time ( $partial$ v/ $partial$ t) and space ( $partial$ v/ $partial$ s). Spatiotemporal velocity distribution of E filling (v) shows diastolic inflow propagating from the LA to the LV_apex. Spatial range, or image height, is 5 cm and the temporal range, or image width, is 300 ms. Acceleration (+ $partial$ v/ $partial$ t or $partial$ v/ $partial$ s) is color coded in yellow, whereas deceleration ( $-$ $partial$ v/ $partial$ t or $partial$ v/ $partial$ s) is coded in blue. Brightness of the color display indicates the magnitude of acceleration or deceleration. Acceleration of the E wave, as indicated by the yellow region in the $partial$ v/ $partial$ t image, is followed by a period of deceleration shown in blue. $partial$ v/ $partial$ s also provides a similar pattern, with acceleration of blood from the LA through the MV and deceleration within the ventricle.

Statistical Analysis

The estimates of the magnitude of the peak intraventricular ([ $Delta$ &Pcirc;

_IV]_max) and total pressure ([ $Delta$ &Pcirc;

_T]_max) differences were comparedwith the directly measured maximum pressure differences ([ $Delta$ P_T]_max,[ $Delta$ P_IV]_max) by using linear regression analysis and by paired t-tests.The timings of the peak intraventricular and total pressure differenceswere also compared with the directly measured maximum pressuredifferences. The errors ( $epsilon$ ) between the measured and computedmaximum pressure difference magnitudes of intraventricular error( $epsilon$ _IV) and total error ( $epsilon$ _T) and temporal locations ( $Delta$ t_IV and $Delta$ t_T)were assessed with the use of paired t-tests.

In addition to comparing the maximum pressure differences, the instantaneous pressure difference waveforms were also comparedto assess the accuracy of the methodology throughout diastole.The mean error ( $epsilon$ ) and mean absolute error ( $Delta$ ) were computed duringearly filling ( $epsilon$ _E, $Delta$ _E) and throughout diastole( $epsilon$ _E+A, $Delta$ _E+A)for both the intraventricular and total pressuredifferences.

The intraventricular pressure differences were also compared with standard indices of diastolic function. [ $Delta$ P_IV]_max was comparedwith Doppler early and atrial filling velocities (E, A, and E/A),peak negative first derivative of pressure development over time(dP/dt) and the relaxation time constant ( $tau$ ) by linear regressionanalysis. Statistical significance was defined at P < 0.05. Dataare expressed as means ±SD.

Numerical Simulation

A central assumption of our methodology is that the color Doppler M-mode cursor lies along a streamline of flow. Because thisclearly cannot hold in all situations throughout diastole, wefelt it incumbent to determine the sensitivity of our resultsto this assumption with a numerical simulation. We therefore analyzeda previously described 3-D finite element simulation of flow acrossthe mitral valve (7). By using cross-sectional geometry obtainedby echocardiography, we designed (with the use of Ansys/Flotran)a simplified axisymmetric model of the LA, mitral valve, and theLV. The simulated mitral valve and LV diameters were 3 and 6 cm,respectively. Simulated pulsatile flow resulted in a solutionproviding spatiotemporal velocity and pressure data in a seriesof 2-D images with 5-ms temporal resolution. The spatiotemporalvelocity distribution along particular scanlines and actual flowstreamlines were extracted and used to compute the pressure differencesby using the Euler equation. Spatiotemporal velocity distributionswere extracted from the model to assess the effects of the approximationof inflow streamlines by a simulated scanline. To assess the importanceof scanline placement in the flow distribution, the estimatedintraventricular pressure drop was compared with the true dropfor parallel scanline displacements of 0-1.5 cm from the midlineand misalignments of 0-30° from the LV longaxis.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Under baseline conditions, the [ $Delta$ P_IV]_max by direct catheter measurement was 1.80 ± 0.47 mmHg. This represented 71.1 ± 12.6%of the [ $Delta$ P_T]_max, which was 2.58 ± 0.66 mmHg. The percentage ofthe intraventricular pressure difference at the time of peak totalpressure difference ([ $Delta$ P_IV]_{[P(T)]max})was slightly less (68.1 ± 12.1%).

The average noninvasive estimate of the [ $Delta$ &Pcirc; _IV]_max for the baseline data was 1.77 ± 0.53 mmHg, representing 68.0 ± 7.2% ofthe [ $Delta$ &Pcirc; _T]_max. Again the percentage of the intraventricular pressuredifference at the time of peak total pressure difference was slightlyless (66.1 ± 7.8%). Linear regression analysis comparing catheter(x) and Doppler-derived (y) measurements demonstrated significantagreement for both intraventricular [y = 0.97x + 0.031, r = 0.84,standard error of the estimate (SEE) = 0.34 mmHg, P < 0.001] andtotal (y = 1.06x $-$ 0.12, r = 0.95, SEE = 0.31 mmHg, P < 0.001)maximum pressure differences. Figure 3A demonstrates this agreementat baseline between invasive and noninvasive measurements of theintraventricular pressure difference. A paired t-test demonstratedthat the difference, or $epsilon$ , between invasive and noninvasive estimatesof both the intraventricular ( $epsilon$ _IV = [ $Delta$ &Pcirc; _IV]_max $-$ [ $Delta$ P_IV]_max = 0.03± 0.29 mmHg) and total ( $epsilon$ _T = [ $Delta$ &Pcirc; _T]_max $-$ [ $Delta$ P_T]_max= $-$ 0.04 ± 0.23mmHg) pressure differences were not significantly different fromzero. The standard deviations of these differences provide anindication of the unsigned scatter in the error. The time to peakfilling pressure differences was also measured and used to computethe temporal errors ( $Delta$ t) between the invasive and noninvasivemeasures for both the maximum total

&Dgr;tT<IT>=t</IT>[<IT>&Dgr;</IT>ˆPT]max<IT>−t</IT>[<IT>&Dgr;</IT>PT]max<IT>=0.012±0.045 </IT>s

and intraventricular pressure differences

&Dgr;tIV<IT>=t</IT>[<IT>&Dgr;</IT>ˆPIV]max<IT>−t</IT>[<IT>&Dgr;</IT>PIV]max<IT>=</IT>−<IT>0.018±0.023 </IT>s

After we administered isoproterenol to four of the six animals, the invasive measurement of the maximum total and intraventricularpressure difference increased significantly ([ $Delta$ P_T]_max, 2.82 ±0.42 to 5.32 ± 1.52 mmHg; [ $Delta$ P_IV]_max, 1.89 ± 0.3 to 4.43 ± 1.29mmHg; P < 0.01). The relative contribution of the intraventricularpressure difference to the total difference also increased significantlyfrom 68.0 ± 12.1% at baseline to 83.3 ± 5.3% during isoproterenolinfusion. These changes were also tracked well by the noninvasiveDoppler-derived estimates. The errors between the Doppler-derivedestimates and catheter measurements were not significantly different( $epsilon$ _T, $-$ 0.04 ± 0.23 at baseline vs. $-$ 0.12 ± 0.49 mmHg with isoproterenol; $epsilon$ _IV, 0.03 ± 0.29 at baseline vs. 0.35 ± 0.49 mmHg with isoproterenol).Data from both conditions (baseline and isoproterenol) were comparedwith the simultaneously measured pressure differences by catheterusing linear regression analysis. Figure 3B demonstrates the relationshipfor the combined intraventricular pressure differences at bothconditions. Linear regression results for each animal (animals1, 2, 3, and 6) are provided along with the overall relationshipof [ $Delta$ &Pcirc; _IV]_max versus [ $Delta$ P_IV]_max; y = 0.87x + 0.22, SEE = 0.35 mmHg,r = 0.96, P < 0.001.

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Fig. 3. Relationship between the magnitude of catheter and Doppler-derived peak intraventricular pressure differences for data obtained from all animals at baseline (A) and data from four animals at baseline and after administration of isoproterenol (B). Results from linear regression analysis in B are shown for each animal as well as the aggregate. See text for definitions of abbreviations.

In addition to comparing the peak pressure differences, the instantaneous estimates of intraventricular ( $Delta$ &Pcirc; _IV[t]) and total( $Delta$ &Pcirc; _T[t]) pressure differences throughout diastole were also evaluatedand compared with the catheter-based waveforms. The $epsilon$ and $Delta$ duringearly filling and throughout diastole were computed for both theintraventricular and total pressure differences. The $Delta$ &Pcirc; _IV[t]closely tracked the catheter-based profile during early filling(r_E(IV) = 0.88 ± 0.16, $Delta$ _E(IV) = 0.40 ± 0.18 mmHg, $epsilon$ _E(IV) = 0.22± 0.30 mmHg) and throughout diastole (r_E+A(IV) = 0.72 ± 0.14, $Delta$ _E+A(IV) = 0.67 ± 0.36 mmHg, $epsilon$ _E+A(IV) = $-$ 0.16 ± 0.53mmHg). Close agreement between $Delta$ &Pcirc; _T[t] and $Delta$ P_T[t] was also observedduring early filling (r_E(T) = 0.95 ± 0.04, $Delta$ _E(T) = 0.44 ± 0.21mmHg, $epsilon$ _E(T) = $-$ 0.10 ± 0.40 mmHg) and throughout diastole (r_E+A(T)= 0.89 ± 0.08, $Delta$ _E+A(T) = 0.59 ± 0.32 mmHg, $epsilon$ _E+A(T) = $-$ 0.03 ± 0.41 mmHg). Figure 4 shows an example of the correlationbetween instantaneous estimated pressure differences (A, $Delta$ &Pcirc; _IV[t];B, $Delta$ &Pcirc; _T[t]) and the direct catheter measurements.

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Fig. 4. Example of the estimated instantaneous intraventricular (A) and total pressure difference waveforms (B) (dashed curves) with the simultaneously recorded catheter-based pressure differences (solid curves).

The maximum intraventricular pressure difference ([ $Delta$ P_IV]_max, x, mmHg) was related to standard Doppler indices of diastolicfilling (E, y [cm/s] = 8.394x + 29.0, r = 0.84; E/A, y [dimensionless]= 0.36x + 1.003, r = 0.68) as well as the maximal rate of pressuredecrease over time ( $-$ dP/dt_max) (y [mmHg/s] = 238.4x + 577.7, r= 0.51) and $tau$ (y [ms] = $-$ 11.2x + 90.2, r = 0.54).

Numerical Simulation

Figure 5 demonstrates the impact of scanline misalignment from the midline streamline of the inflow tract. For parallel displacementas great as 0.9 cm, the mean squared error in estimation remains<0.26 mmHg, with a correlation between predicted and actual pressuredrop of r = 0.93 (see Fig. 5A). Given that the simulated mitralvalve orifice was 3 cm, the scanline can be placed within thecentral 60% of the valve [(2 × 0.9 cm)/3 cm] to achieve this result.Similarly, Fig. 5B shows that for angular misalignments as greatas 20°, the mean squared error remains <0.18 mmHg, with a correlationof r = 0.95.

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Fig. 5. Numerical simulation results comparing the modeled intraventricular pressure difference distribution and the pressure distribution computed by using velocity data extracted along a simulated scanline. Mean squared error and correlation coefficient are displayed as a function of the displacement of the scanline from the centerline axis (A) and the angulation of the scanline through the mitral orifice (B).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The diagnosis of LV diastolic dysfunction remains a challenge in clinical practice. The most complete information on LV relaxationand compliance can be obtained from intraventricular pressuremeasurements combined with simultaneous volume measurements toreconstruct pressure-volume loops. Because this requires an invasiveprocedure with high-fidelity pressure measurements in the LV andtedious tracing of ventricular contours on angiograms to obtainLV volume estimates, this is rarely performed in clinical practice.The most commonly used technique to assess LV diastolic functionclinically is the pulsed-Doppler measurement of the LV inflowvelocities at the level of the mitral valve. Although characteristicinflow patterns have been described, this method is limited becausethe transmitral velocity profile is also affected by several parametersother than LV diastolic function, such as heart rate, atrioventricularconduction interval, and left atrialpressure.

The use of color Doppler M-mode echocardiography to assess LV inflow was introduced by Brun et al. (1) in 1992 and hasbeen shown to provide information on LV diastolic function inaddition to traditional measurements of the transmitral pulsed-Dopplervelocity profile. Stugaard et al. (16) noticed a significantchange in the color Doppler M-mode inflow pattern with delayedapical filling during ischemia caused by balloon occlusion ofthe left anterior descending coronary artery. We hypothesizedthat color Doppler M-mode profiles, representing flow velocitieswithin the ventricle between base and apex, could provide informationon intraventricular pressuregradients.

The presence of these intraventricular gradients during early diastole was first reported by Ling et al. (9) in an animalmodel. Falsetti et al. (4) showed an increase in intraventriculargradients during $beta$ -stimulation and a decrease in the magnitudeof the intraventricular gradients during $beta$ -blockade, suggestingthe close linkage between the LV rate of relaxation and intraventricularpressure gradients. Courtois et al. (2) subsequently showedthe disappearance of these intraventricular gradients in an ischemicmodel during left anterior descending occlusion. Smiseth et al.(13) showed in both animals and humans that the pressure gradientbetween the ventricular apex and outflow tract strongly correlatedwith peak early transmitral flow and stroke volume. These observationssuggest the critical importance of intraventricular pressure gradientsto ensure efficient LV diastolic filling and its close linkagewith more traditional parameters of LV diastolicfunction.

In this study, we propose a novel concept to apply basic hydrodynamic principles to the color Doppler M-mode spatiotemporalvelocity distribution to reconstruct noninvasively the intraventricularpressure gradients present between LV base and apex during diastole.Color Doppler echocardiography is usually used in a qualitativeway to assess normal and abnormal blood flows in the cardiac chambers.Although quantitative algorithms have been developed using colorDoppler images to calculate cardiac output (17, 20) or toquantify severity of regurgitant valves (12, 21), these arerelatively simplistic. This study uses the local spatial and temporalvelocity distribution measured by color Doppler M-mode echocardiographyto calculate local pressure gradients using the Euler equation,integration of which allows us to calculate a pressure differencebetween two points along the inflow tract. In this study we focusedon the intraventricular component of the filling gradient, integratingthe pressure gradient between the base and apex of the left ventricleand comparing the results of this estimate with direct cathetermeasurement. This Doppler-derived pressure difference closelymatched the invasive measurement. The magnitude and timing ofthese noninvasively reconstructed pressure gradients between theLA and different levels in the ventricle closely matched the invasivemeasurements and also correspond well with data previously publishedin the literature. We also showed that this approach not onlyprovides accurate information under baseline conditions but isalso able to detect relatively small changes in transmitral andintraventricular gradients induced by pharmacologically alteringLV relaxation. During isoproterenol infusion, we observed an increasein the reconstructed intraventricular gradients, similar to observationsof Falsetti et al. (4) and consistent with the finding by Brunet al. (1) of increased flow propagation into the left ventriclein patients during intracoronary dobutamineinfusion.

This new application of color Doppler M-mode echocardiography allows us to reconstruct small intraventricular pressure gradientscompletely noninvasively, thus avoiding the risk and expense ofa cardiac catheterization. This method also enables us to detectchanges in these small intraventricular gradients induced by changingLV relaxation and is therefore a promising tool that may helpus understand and evaluate the complex phenomena underlying LVfilling. This new method is particularly attractive because itcan provide much more information than could ever be obtainedduring an invasive procedure. Because color Doppler M-mode velocitiesare measured as a continuum between the LA and the LV_apex at 0.5-mmspatial resolution, the derived pressure gradient distributionalong a scanline ( $partial$ P/ $partial$ s) can be integrated over space to producea pressure map. This pressure information can be displayed ina surface plot where pressure (relative to LA pressure) is graphed(z-axis) from the LA to the LV apex (y-axis) throughout the earlydiastolic filling wave (x-axis) (Fig. 6). This type of informationon LV filling pressures has never been available before to researchersor clinicians and opens up entirely new perspectives to evaluateLV diastolic filling and function.

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Fig. 6. Relationship between the derived intraventricular pressure distribution (surface with red and blue representing positive and negative pressure differences, respectively) and the direct catheter pressure differences between the LA and the LV base (white) and apex (green).

The time required for the color Doppler M-mode image analysis and extraction of pressure waveforms is ~1 min using the customizedsoftware we developed. The processing time is much quicker (afew seconds) after the semiautomatic preprocessing of the colorDoppler M-mode data. The preprocessing step requires the userto identify regions within the color Doppler M-mode image wherealiasing has occurred. By using this information, the softwareperforms an unaliasing procedure and provides v[s,t] for the calculationof $partial$ P/ $partial$ s by using the Euler equation. With known locations forthe spatial sample locations (depths corresponding to LA, LV_base,and LV_apex pressure transducer locations), transmitral and intraventricularpressure difference waveforms are instantly calculated. Becausethere is a potential of clinical application of this method, wehave extended this methodology to allow pressure differences tobe calculated from digital echocardiographic images collectedby a variety of equipment, including Acuson and ATL. For thesesources, however, a color lookup table is generated from the colorbar to provide quantitative velocity data because current implementationsof the DICOM (digital imaging and communications in medicine)standard do not provide information to calculate the velocityassociated with thismapping.

The accuracy of pressure difference estimates results in part from the accuracy of color Doppler M-mode velocity data usedin the noninvasive calculation of pressure differences. Shandaset al. (11) compared ultrasound color Doppler imaging to thereference standard laser Doppler velocimetry technique, establishingthe accuracy of using models of steady and pulsatile flow acceleration.By using data from this paper, we estimate the standard errorbetween laser and color Doppler to be 6.8 cm/s, nearly equal tothe resolution of color Doppler with a Nyquist velocity of 81cm/s. In addition to this velocity resolution, the temporal andspatial resolutions of color Doppler M-mode images are importantas they determine the degree of accuracy for the partial derivativeterms of the Euler equation. The accuracy of the pressure estimateis also related to the degree to which the ultrasound scanlineapproximates an inflow streamline through the center of the mitralvalve. We have shown through the computational model describedin this paper that accurate results are achieved when the scanlineis placed within the central 60% of the valve orifice ( $epsilon$ < 0.26mmHg, r = 0.93) or when an angular misalignment is made up to20° ( $epsilon$ < 0.18 mmHg, r = 0.95).

Pressure difference estimates can be made reproducibly using this technique. The average absolute difference in the noninvasivepeak intraventricular pressure differences calculated by two userswas only 0.05 mmHg. This small degree of variability between usersis due to the limited steps required to compute the noninvasivepressure differences from color Doppler M-mode images, namelyselecting aliased regions and defining spatial locations (or transducerpositions) over which the pressure gradient isintegrated.

Limitations

A critical assumption of our methodology is that of scanline alignment with a streamline of flow. Given the complex 3-D geometryof the LV inflow tract, no straight line could ever be expectedto coincide with a streamline throughout diastole. However, simplificationssuch as this are commonly made in medical measurements (the Gorlinand simplified Bernoulli equations, to name two), and it is reassuringthat our numerical analysis suggests relatively little sensitivityof our results to precise alignment of the scanline. Indeed, theerror remains relatively small (mean squared error <0.26 mmHg)when the scanline is over halfway to the edge of the valve ormisaligned by up to 20°. Of particular concern is the presenceof vortices that form at the leaflet tips. However, these formoutside the central flow region and thus should not greatly impactour recordings. The fact that these vortices grow throughout diastolemay explain why our results in early diastole are somewhat betterthan atrialfilling.

The numerical model used to evaluate the impact of scanline misalignment is also a simplification of the 3-D/4-D actual valvulargeometry by using 2-D cross-sectional geometry obtained by echocardiography.Limitations of the modeling tools available also required thatventricular cavity was not dynamically changing during diastole.Whereas the resulting spatiotemporal velocity distributions weresomewhat representative of actual color Doppler M-mode images,actual fluid-structure interactions may provide a step in realizinga more accuratemodel.

Other noninvasive imaging modalities may offer the possibility to acquire 3-D velocity data and calculate pressure differenceson the basis of a less simplified version of the Navier-Stokesequations. Whereas real-time 3-D echocardiographic assessmentof flow velocities is possible, the necessary tradeoffs resultin a greatly decreased temporal resolution (10 frames/s). Magneticresonance imaging techniques such as phase encoding and particletracking have been utilized to determine ventricular flow characteristicsincluding streamline assessment, but these procedures are generallynot available and also have tradeoffs in terms of temporal resolution.More advanced models of ventricular filling utilizing interactionsbetween structural mechanics and fluid dynamics may provide aless simplified analysis of potential errors in ourmethodology.

Hemodynamic data were available only at three points within the LV inflow tract, and thus we were able to assess the abilityof color M-mode to measure pressure differences within the ventriclerather than true spatial pressure gradient. Future work with themultisensor Millar catheter may refine this validation, but thisremains fundamentally an issue of an inadequate gold standardagainst which to compare our noninvasive findings. These resultswere obtained in canine model with open chest and open pericardiumand thus full validation in humans in a clinical setting awaitsfurtherwork.

In conclusion, it is very encouraging that though sophisticated, through very straightforward application of basic hydrodynamicprinciples to color Doppler M-mode data, we are able to measureaccurately and noninvasively intraventricular pressure differencesthroughout diastole. The potential for applying this approachin physiological research and clinical practice appears very significant,because noninvasive diastolic filling gradients have previouslybeen available with only the most meticulous invasivetechnique.

	ACKNOWLEDGEMENTS

This work was supported by National Heart, Lung, and Blood Institute Grant RO1-HL-56688-01A1 (to J. D. Thomas), American HeartAssociation (AHA) Grant 93013880 (to J. D. Thomas), AHA NortheastOhio Affiliate Grant 94-069-GIA (to P. M. Vandervoort), and NationalAeronautics and Space Administration Grant NCC9-60 (to J. D.Thomas).

	FOOTNOTES

Address for reprint requests and other correspondence: N. L. Greenberg, Dept. of Cardiology, Desk F15, The Cleveland ClinicFoundation, 9500 Euclid Ave., Cleveland, OH 44195 (E-mail: greenbn{at}ccf.org).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 7 December 1999; accepted in final form 8 January 2001.

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				Y. Notomi, M. G. Martin-Miklovic, S. J. Oryszak, T. Shiota, D. Deserranno, Z. B. Popovic, M. J. Garcia, N. L. Greenberg, and J. D. Thomas Enhanced Ventricular Untwisting During Exercise: A Mechanistic Manifestation of Elastic Recoil Described by Doppler Tissue Imaging Circulation, May 30, 2006; 113(21): 2524 - 2533. [Abstract] [Full Text] [PDF]

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				S. Urheim, T. Edvardsen, K. Steine, H. Skulstad, E. Lyseggen, O. Rodevand, and O. A. Smiseth Postsystolic shortening of ischemic myocardium: a mechanism of abnormal intraventricular filling Am J Physiol Heart Circ Physiol, June 1, 2003; 284(6): H2343 - H2350. [Abstract] [Full Text] [PDF]

				J. D. Thomas, M. S. Firstenberg, P. M. Vandervoort, N. L. Greenberg, N. G. Smedira, P. M. McCarthy, and M. J. Garcia Reply J. Am. Coll. Cardiol., July 1, 2001; 38(1): 291 - 292. [Full Text] [PDF]