Cardiac resynchronization therapy restores optimal atrioventricular mechanical timing in heart failure patients with ventricular conduction delay

Auricchio, Angelo; Ding, Jiang; Spinelli, Julio; Kramer, Andrew; Salo, Rodney W.; Hoersch, Walter; KenKnight, Bruce H.; Klein, Helmut U.

doi:10.1016/s0735-1097(02)01727-8

Cited by 196 publications

(131 citation statements)

References 15 publications

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“…[1][2][3][4][5][6] These pioneering small studies paved the way for large randomized controlled trials that demonstrated reductions in morbidity and mortality in heart failure. [7][8][9][10][11][12][13] Surprisingly, the effects of biventricular pacing on coronary blood flow have been little studied.…”

mentioning

confidence: 99%

Improvement in Coronary Blood Flow Velocity With Acute Biventricular Pacing Is Predominantly Due to an Increase in a Diastolic Backward-Travelling Decompression (Suction) Wave

Kyriacou

Whinnett²,

Sen³

et al. 2012

Circulation

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Background-Normal coronary blood flow is principally determined by a backward-traveling decompression (suction) wave in diastole. Dyssynchronous chronic heart failure may attenuate suction, because regional relaxation and contraction overlap in timing. We hypothesized that biventricular pacing, by restoring left ventricular (LV) synchronization and improving LV relaxation, might increase this suction wave, improving coronary flow. Method and Results-Ten patients with chronic heart failure (9 males; age 65Ϯ12; ejection fraction 26Ϯ7%) with left bundle-branch block (LBBB; QRS duration 174Ϯ18 ms) were atriobiventricularly paced at 100 bpm. LV pressure was measured and wave intensity calculated from invasive coronary flow velocity and pressure, with native conduction (LBBB) and during biventricular pacing at atrioventricular (AV) delays of 40 ms, 120 ms, and separately preidentified hemodynamically optimal AV delay. In comparison with LBBB, biventricular pacing at separately preidentified hemodynamically optimal AV delay (BiV-Opt) enhanced coronary flow velocity time integral by 15% (7%-25%) (Pϭ0.007), LV dP/dt max by 15% (10%-21%) (Pϭ0.005), and neg dP/dt max by 17% (9%-22%) (Pϭ0.005). The cumulative intensity of the diastolic backward decompression (suction) wave increased by 26% (18%-54%) (Pϭ0.005). The majority of the increase in coronary flow velocity time integral occurred in diastole (69% [41%-84% ]; Pϭ0.047).The systolic compression waves also increased: forward by 36% (6%-49%) (Pϭ0.022) and backward by 38% (20%-55%) (Pϭ0.022). Biventricular pacing at AV delays of 120 ms generated a smaller LV dP/dt max (by 12% [5%-23% ], Pϭ0.013) and neg dP/dt max (by 15% [8%-40% ]; Pϭ0.009) increase than BiV-Opt, against LBBB as reference; BiV-Opt and biventricular pacing at AV delays of 120 ms were not significantly different in coronary flow velocity time integral or waves. Biventricular pacing at AV delays of 40 ms was no different from LBBB. Conclusions-When biventricular pacing improves LV contraction and relaxation, it increases coronary blood flow velocity, predominantly by increasing the dominant diastolic backward decompression (suction) wave. (Circulation. 2012;126:1334-1344.)

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mentioning

confidence: 99%

Improvement in Coronary Blood Flow Velocity With Acute Biventricular Pacing Is Predominantly Due to an Increase in a Diastolic Backward-Travelling Decompression (Suction) Wave

Kyriacou

Whinnett²,

Sen³

et al. 2012

Circulation

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“…Although AV-delay optimisation can clearly impact hemodynamics in patients undergoing CRT, (32,33) it has less infl uence on LV function than the optimal pacing site (34) . An optimal AV delay is that which allows completion of the end-diastolic fi lling fl ow prior to ventricular contraction, thereby providing the longest diastolic fi lling time.…”

Section: Optimising Atrio-ventricular Delaymentioning

confidence: 99%

“…It has been recommended that the VV-interval be optimised before the AVinterval, to prevent inappropriate AV-delay programming, which might reduce LV fi lling (33) .…”

Section: Vol 4 No 2 2007mentioning

confidence: 99%

Cardiac Resynchronisation Therapy: The Role of Echocardiography in Patient Selection and Follow-up

Middlemost¹

2017

SAHJ

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“…CRT reduces clinical symptoms of heart failure, decreasing incidence of hospitalization, and also signifi cantly decreasing mortality in these patients [3,4]. The success of CRT depends on many factors such as appropriate location of the left ventricular (LV) electrode, and optimal timing of atrioventricular (AV) and VV delays [5,6]. Optimal programming of AV and VV delays plays an important role in reducing the proportion of patients who derive no apparent benefi t from CRT (the so called "non-responders"), despite correct positioning of the LV electrode [7].…”

Section: Introductionmentioning

confidence: 99%

Whether noninvasive optimization of AV and VV delays improves the response to cardiac resynchronization therapy

Urbanek

Chudzik²,

Klimczak³

et al. 2013

Cardiol J

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Cardiac resynchronization therapy restores optimal atrioventricular mechanical timing in heart failure patients with ventricular conduction delay

Cited by 196 publications

References 15 publications

Improvement in Coronary Blood Flow Velocity With Acute Biventricular Pacing Is Predominantly Due to an Increase in a Diastolic Backward-Travelling Decompression (Suction) Wave

Improvement in Coronary Blood Flow Velocity With Acute Biventricular Pacing Is Predominantly Due to an Increase in a Diastolic Backward-Travelling Decompression (Suction) Wave

Cardiac Resynchronisation Therapy: The Role of Echocardiography in Patient Selection and Follow-up

Whether noninvasive optimization of AV and VV delays improves the response to cardiac resynchronization therapy

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