The Cardiac Effects of Pimobendan (But Not Amrinone) Are Preserved at Rest and During Exercise in Conscious Dogs with Pacing-Induced Heart Failure

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Vol. 282, Issue 1, 23-31, 1997

The Cardiac Effects of Pimobendan (But Not Amrinone) Are Preserved at Rest and During Exercise in Conscious Dogs with Pacing-Induced Heart Failure¹

Nobuyuki Ohte, Che-Ping Cheng, Makoto Suzuki and William C. Little

Cardiology Section, Bowman Gray School of Medicine of Wake Forest University, Winston-Salem, North Carolina

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

We compared the effects of pimobendan (0.25 mg/kg i.v.), a Ca⁺⁺ sensitizer, with some phosphodiesterase-III inhibition effects,and amrinone (1 mg/kg plus 10 µg/kg/min i.v.), a PDE-III inhibitor,on left ventricular (LV) systolic and diastolic performance, bothat rest and during exercise, in seven conscious dogs before andafter pacing-induced congestive heart failure (CHF). Before CHF,under resting conditions, both pimobendan and amrinone causeda similar significant decrease in left ventricle size and end-systolicpressure, arterial elastance, and the time constant of LV relaxation.Similar results were obtained during exercise. Both agents alsoproduced a similar increase in E_ES, the slope of the LV end-systolicpressure-volume relation (3.4 ± 1.5 vs. 4.2 ± 1.1 mm Hg/ml; amrinonevs. pimobendan). After CHF, the vasodilatory effects of amrinoneand pimobendan were preserved both at rest and during exercise;however, the inotropic actions were different. After CHF, pimobendanincreased E_ES (3.9 ± 0.5 vs. 5.7 ± 0.4 mm Hg/ml, P < .05), decreasedthe time constant of LV relaxation, increased the maximum rateof LV filling (37 ± 19 ml/sec) (P < .05) and produced a downwardshift of the early diastolic portion of LV pressure-volume loop.Pimobendan also augmented LV contractile performance during CHFexercise. In contrast, after CHF, amrinone no longer produceda positive inotropic effect. Amrinone improved LV relaxation andfilling, both at rest and during exercise after CHF, but significantlyless than pimobendan. We conclude that after CHF, the cardiacresponse to a PDE-III inhibitor is attenuated, but the responseto Ca⁺⁺ sensitizer is preserved. Thus, after CHF, pimobendan is moreeffective than amrinone in enhancing LV contractile state, LVrelaxation and LV filling both at rest and during exercise.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

In CHF, neurohumoral mechanisms are activated that help acutely maintain cardiac output and perfusion pressure (Packer, 1988).The continuous beta-adrenergic stimulus in CHF leads to down-regulationand functional uncoupling of cardiac beta-1 adrenoceptors, resultingin a blunted inotropic response to beta adrenoceptor agonists(Bohm et al., 1988a; Bohm et al., 1988b; Bristow et al., 1986).Similarly, the failing myocardium has a reduced response to cAMP-dependentinotropic agents such as PDE-III inhibitors (Perreault et al.,1992; Bohm et al., 1988b). Thus PDE-III inhibitors have a reducedeffectiveness in improving inotropic state in the failing heart.

Agents with other mechanisms of inotropic action might have greater effect in improving LV performance in CHF. Pimobendan,a pyridazinone benzimidazole derivative, is reported to inhibitPDE-III and has the additional effect of increasing the sensitivityof the contractile proteins to activation by Ca⁺⁺ (Bohm et al., 1991; Brunkhorst et al., 1989; Hagemeijer et al.,1989; Fujino et al., 1988; Duncker et al., 1987). Although thepositive inotropic effect of pimobendan has been demonstrated,the relative contributions of PDE-III inhibition and Ca⁺⁺ sensitization to its positive inotropic effect in failing myocardiumare not known. Because the effect of PDE-III inhibition may bedepressed in CHF, we hypothesized that the inotropic responseto pimobendan due to Ca⁺⁺ sensitization may be relatively preserved after the developmentof CHF when compared with a more selective PDE-III inhibitor,such as amrinone (Remme, 1993). Therefore, this study was undertakento compare the effects of pimobendan and amrinone on LV systolicand diastolic performance at rest and during exercise in consciousdogs before and after CHF.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Instrumentation

Seven healthy, adult, heart worm-negative mongrel dogs (weight 25-36 kg) were instrumented under anesthesia after inductionwith xylazine (2 mg/kg i.m.) and sodium thiopental (6 mg/kg i.v.)and maintained with halothane (0.5-2.0%). They were intubatedand ventilated with oxygen-enriched room air to maintain arterialoxygen pressure greater than 100 mm Hg and pH between 7.38 and7.42. A sterile left lateral thoracotomy was performed, and pericardiumwas widely opened. Micromanometer pressure transducers (KonisbergInstruments, Inc., Pasadena, CA) and polyvinyl catheters (1.1mm I.D.) for transducer calibration were inserted into the LVthrough an apical stab wound and into the LA. Three pairs of ultrasoniccrystals (5 MHz) were implanted in the endocardium of the LV tomeasure the anterior-to-posterior, septal-to-lateral, and base-to-apex(long-axis) dimensions, using the method previously describedfrom our laboratory (Cheng et al., 1993). Hydraulic occluder cuffswere placed around the inferior and superior venae cavae. A pacinglead was attached to the right ventricle and connected to a programmablepacemaker (model 8329, Medtronic Inc., Minneapolis, MN) implanteds.c. All wires and tubings were exteriorized through the posteriorneck.

Data Collection

Studies were performed after full recovery from instrumentation (from 10 days to 2 weeks after surgery) with the dogs standingand then running on a motorized treadmill (model 1849C, QuintonInc., Seattle, WA). The LV and LA catheters were connected topressure transducers (Statham P23Db, Gould, Cleveland, OH) calibratedwith a mercury manometer. The signal from the micromanometerswas adjusted to match that of the catheters. The LA micromanometerwas adjusted to match LV pressure at the end of long periods ofdiastasis.

The analog signals were recorded on an eight-channel chart-recorder (Astro-Med, West Warwick, RI), digitized with an on-lineanalog-to-digital converter (Data Translation Devices, Marlboro,MA) at 200 Hz and were stored on a magneto-optical disk memorysystem.

Experimental Protocol

The effects of amrinone and pimobendan were assessed in seven dogs before and after CHF. The order in which the drugs werestudied was randomly determined, and at least 24 hr elapsed betweenstudies.

Studies before CHF. Steady-state data and data during transient caval occlusion were recorded at rest while the animals stood on a motorized treadmill.Three sets of variably loaded P-V loops were generated by cavalocclusion. The animals then ran on the treadmill. The treadmillspeed was gradually increased over 1 to 2 min from 2.5 miles/hrto the maximum level tolerated for exercise (5.5-8.0 miles/hr).The animals exercised at this level until they could no longerkeep up with the treadmill. The total exercise time ranged from7 to 12 min. We analyzed the data recorded at rest and duringthe last minute of exercise. After a 30 min rest after controlexercise, amrinone (1 mg/kg i.v. followed by 10 µg/kg/min infusion)or pimobendan (0.25 mg/kg i.v.) was administered. Forty minutesafter drug administration, steady-state and caval occlusion dataat rest were collected, and then the treadmill exercise protocolwas repeated and steady-state data were collected.

Studies during the development of CHF. After completion of the base-line exercise studies, the pacemaker rate was adjusted, using the external magnetic control unit,to 220 to 250 beats per minute. Three times per week, the pacemakerrate was adjusted below the spontaneous rate. The animal was allowedto equilibrate for 30 minutes, and then data were collected. Aftereach study, pacing rate was returned to 220 to 250 beats per minute.After pacing for 4 to 5 weeks, when the LV P_ED during the nonpacedperiod had increased by more than 15 mm Hg over the prepacingcontrol level, CHF data were obtained. This level of CHF was chosenbecause the animals had begun to show clinical evidence of CHF(anorexia, mild ascites, and pulmonary congestion) but were stillable to exercise.

Studies after the onset of CHF. Studies in dogs with CHF were performed after the animal stabilized for at least 30 min after discontinuing pacing. Steady-stateand caval occlusion data were collected with the animal standingat rest. Then the animal ran on the treadmill as the speed wasincreased and adjusted to the maximum tolerated steady-state level,and data were collected while the animal was running. After CHF,the maximum level of exercise was decreased to 3.5 to 6.0 miles/hr.The total exercise duration was also reduced (range from 4 to7 min). Then, after a 30 min rest, the same amount of amrinone(1 mg/kg i.v. followed by 10 µg/kg/min infusion) or pimobendan(0.25 mg/kg i.v.), as used in the studies conducted before CHF,was administrated. Forty minutes after drug administration, restingsteady-state and caval occlusion data were collected, and thentreadmill exercise was performed.

Data Processing and Analysis

V_LV was calculated as a modified general ellipsoid using the following equation:

VLV<IT>=</IT>(<IT>&pgr;/6</IT>)<IT>D</IT>AP<IT> · D</IT>SL<IT> · D</IT>LA

where D_AP is the anterior-to-posterior LV diameter, D_SL is the septal-to-lateral LV diameter, and D_LA is the long-axis LVdiameter. We have previously demonstrated that this method givesa consistent measure of V_LV despite changes in LV loading conditions,configurations and HR (Cheng et al., 1993; Little et al., 1988;Little et al., 1989). To account for respiratory changes in intrathoracicpressure, steady-state measurements were averaged over the 12-to 15-sec recording period that spanned multiple respiratory cycles.End-diastole was defined as the relative minimum of LV pressureoccurring after the A wave. End-systole was defined as the upperleft corner of the LV P-V loop. The time of mitral valve openingwas defined to be when LV pressure fell below LA pressure. LVend-diastolic, end-systolic and minimum pressure were measured.We also measured LV V_ED and V_ES. The mean LA pressure was determined.

The derivatives of LV pressure (dP/dt) and LV volume (dV/dt) were calculated using the five-point Lagrangian method. Strokevolume was calculated as V_ED minus V_ES. Cardiac output was determinedas stroke volume times HR. We also calculated SW by point-by-pointintegration of the LV P-V loop for each beat. The rate of LV relaxationwas analyzed by determining the time constant of the isovolumicfall of LV pressure. LV pressure from the time of minimum dP/dtuntil mitral valve opening was fit to an exponential equation:

P=PA exp(−<IT>t/T+P</IT>B)

where P is LV pressure, t is time and P_A, P_B and T are constants determined by data. Although the fall in isovolumic pressureis not exactly exponential, the time constant, derived from theexponential approximation, provides an index of the rate of LVrelaxation (Gilbert and Glantz, 1989). The effective E_A was calculatedas LV P_ES divided by stroke volume. We also calculated TSR asP_ES divided by cardiac output. Ejection fraction was calculatedas stroke volume divided by V_ED.

Analyses of LV P-V loop during caval occlusion. Only caval occlusions that produced a fall in LV P_ES of approximately 30 mm Hg were analyzed. Premature beats and the subsequentbeat were excluded from analysis.

The LV P_ES-V_ES data during the fall of LV pressure, produced by each caval occlusion, were fit using the least-squares methodto

P<SUB>ES</SUB><IT>=E</IT><SUB>ES</SUB>(<IT>V</IT><SUB>ED</SUB><IT>−V</IT><SUB><IT>0,</IT>ES</SUB>)

where E_ES, the slope of linear P_ES-V_ES relation, represents the LV end-systolic elastance, and V_0,ES is the intercept withthe volume axis. The volume (V_100,ES) associated with a P_ES of100 mm Hg was calculated as

V<SUB>100,ES</SUB><IT>=V</IT><SUB><IT>0,</IT>ES</SUB><IT>+100/E</IT><SUB>ES</SUB>

The dP/dt_max-V_ED and SW-V_ED relations were quantified by fitting the data from the same beats from each caval occlusion usedto evaluate the P_ES-V_ES relation to

dP/dt<SUB>max</SUB><IT>=dE/dt</IT><SUB>max</SUB>(<IT>V</IT><SUB>ED</SUB><IT>−V</IT><SUB><IT>0,dP/dt</IT></SUB>)

and

SW=M<SUB>SW</SUB>(<IT>V</IT><SUB>ED</SUB><IT>−V</IT><SUB><IT>0,</IT>SW</SUB>)

The position of the dP/dt_max-V_ED and SW-V_ED relations were calculated by determining the V_ED associated with dP/dt = 2000mm Hg/sec and SW = 2000 mm Hg · ml:

V<SUB>2000,dP/dt</SUB>=V<SUB>0,dP/dt</SUB>+2000/(dE/dt<SUB>max</SUB>)

V<SUB>2000,SW</SUB><IT>=</IT><IT>V</IT><SUB><IT>0,</IT>SW</SUB><IT>+2000/M</IT><SUB>SW</SUB>

The slopes, volume-axis intercepts and positions in each of the three relations for each condition were evaluated as themean values of the two or three caval occlusions performed undereach condition (Little et al., 1989

The LV PVA was determined as the area under the P_ES-V_ES relation and the systolic P-V trajectory and above the end-diastolicP-V relations curve. The mechanical efficiency of the heart wascalculated as SW/PVA (Nozawa et al., 1994

). The coupling of theLV and arterial system was quantitated as E_ES/E_A (Little and Cheng,1993

Post-mortem Evaluation

At the conclusion of the studies, the animals were sacrificed by lethal injections of sodium thiopental (100 mg/kg i.v.),and the heart was examined to confirm the proper position of theinstrumentation.

Statistical Analysis

Statistical comparisons were made with Student's t test for paired observations and analysis of variance with the Bonferronimethod of multiple-paired comparisons as appropriate. Significancewas accepted when P < .05. Data for steady state are expressedas mean ± S.D.; values for LV P-V relations are expressed as mean± S.E.M.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Effects of Pimobendan and Amrinone Administered Before CHF at Rest and During Exercise

Steady-state measurements. Steady-state hemodynamic changes produced with amrinone and pimobendan before CHF at rest and during exercise are summarizedin table 1. At rest, both amrinone and pimobendan (fig. 1) evokedsignificant (P < .05) and equivalent decreases in LV P_ES and TSR.Amrinone and pimobendan also produced similar significant (P <.05) increases in HR (121 ± 11 vs. 132 ± 11, 122 ± 9 vs. 131 ±9 bpm), dP/dt_max and ejection fraction but caused no significantchanges in stroke volume. During exercise, both drugs producedsimilar increases in HR (188 ± 16 vs. 194 ± 15, 182 ± 14 vs. 193± 17 bpm) and similar and significant decreases in minimum LVpressure. Compared with exercise without drugs, both amrinoneand pimobendan did not significantly alter the SV or cardiac output.As shown in table 1, at rest both amrinone and pimobendan causeda significant decrease in T (27.9 ± 2.8 vs. 24.3 ± 3.5; 27.1 ±4.8 vs. 21.1 ± 3.6 msec) and had no effect on the peak rate ofLV filling (dV/dt_max).

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TABLE 1
Effects of amrinone and pimobendan on LV steady-state hemodynamics in normal dogs at rest and during exercise

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Fig. 1. Steady-state LV P-V loops obtained at rest (upper panels) and during exercise (lower panels) in a normal dog before (control)and after administration of amrinone or pimobendan. Both agentsshifted the P-V loops toward the left at rest and during exercise.

Pressure-volume analysis. As shown in table 2 and fig. 2, in normal dogs, amrinone and pimobendan produced similar significant increases in the slopesof the P_ES-V_ES relation (3.4 ± 1.5 vs. 4.2 ± 1.1 mm Hg/ml), thedP/dt_max-V_ED relation (37.7 ± 30.9 vs. 41.8 ± 18.4 mm Hg/sec/ml)and the SW-V_ED relation (20.5 ± 11.6 vs. 26.3 ± 4.4 mm Hg). Therewere also significant leftward shifts of all three relations inthe physiologic range, manifested by significant decreases inV_100,ES (24.0 ± 8.2 vs. 21.5 ± 7.8; 24.6 ± 6.8 vs. 20.1 ± 6.7ml), V_2000,dP/dt and V_2000,SW (46.3 ± 7.1 vs. 42.0 ± 7.0; 45.4± 5.6 vs. 37.4 ± 6.7 ml). The increases in slopes and leftwardshifts of LV P-V relations with amrinone and pimobendan indicatethat they produced a similar enhancement of LV contractile performancein normal dogs.

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TABLE 2
Effects of amrinone and pimobendan on LV pressure-volume relations in normal dogs

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Fig. 2. LV P-V loops produced by transient caval occlusion during control and after administration of amrinone (left panel) or pimobendan(right panel) in a normal dog. The LV end-systolic P-V relationsare indicated by lines. Both amrinone and pimobendan shifted theLV end-systolic P-V relations toward the left with an increasein slope, indicating similar positive inotropic action in thisnormal animal.

Effect of pacing-induced CHF. After the development of CHF at rest, the mean P_ED increased from 11.3 ± 2.9 to 27.7 ± 4.5 mm Hg (P < .05) (tables 1 and3). The minimum LV pressure (0.6 ± 2.3 vs. 5.6 ± 3.3 mm Hg, P< .05) and mean LA pressure (6.9 ± 1.7 vs. 18.6 ± 3.8 mm Hg, P< .05) also increased. The LV V_ES and V_ED increased, whereas cardiacoutput was decreased because of a fall in stroke volume. The timeconstant T increased (27.5 ± 3.8 vs. 35.3 ± 3.0 msec, P < .05).LV contractility was also significantly impaired, as indicatedby the decreased slopes and rightward shifts of the P-V relations(table 4). Furthermore, after CHF, the LV response to exercisewas altered. As shown in figure 3, with CHF, exercise caused significantelevation of minimum LV pressure and P_ED. The early diastole portionof the LV P-V loop was shifted upward. T significantly increased.

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TABLE 3
Effects of amrinone and pimobendan on LV function parameters in dogs with congestive heart failure

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TABLE 4
Effects of amrinone and pimobendan on LV pressure-volume relations in dogs with congestive heart failure

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Fig. 3. LV P-V loops obtained at rest (upper panels) and during exercise (lower panels) in the same animal after development of pacing-inducedCHF. Amrinone had little effect at rest or during exercise. Incontrast, pimobendan produced a leftward shift of the LV P-V loopand reduced early diastolic LV pressure.

Effects of Pimobendan and Amrinone in Dogs with CHF at Rest and During Exercise

Steady-state data measurements. The steady-state hemodynamic response produced by amrinone and pimobendan at rest and during exercise after CHF is summarizedin table 3. After CHF, both amrinone and pimobendan produceda similar decrease in E_A and TSR. After CHF, pimobendan markedlyincreased SV. Therefore, P_ES did not decrease with pimobendanafter CHF. There were no significant differences in the HR. However,only pimobendan caused a marked improvement in LV diastolic performanceas indicated by a significant decrease in T ( $-$ 1.0 ± 0.7 vs. $-$ 9.5± 4.1 msec, P < .05), an increase in dV/dt_max and a decrease inminimum LV pressure. Amrinone did not improve these parameters.Furthermore, pimobendan produced a greater reduction in P_ED andmean LA pressure. These effects of pimobendan persisted duringexercise (table 3).

Pressure-volume analysis. The changes of P-V relations by amrinone and pimobendan after CHF are summarized in table 4. Typical examples of the effectof amrinone and pimobendan on variably loaded P-V relations fromone animal with CHF are shown in figure 4. After CHF, amrinonecaused a slight leftward shift of the LV P_ES-V_ES relation, butthe slope of this relation was relatively unchanged. Amrinoneproduced no significant change in the slope of the dP/dt_max-V_EDrelation (35.5 ± 6.7 vs. 42.2 ± 9.1 mm Hg/sec/ml) or of the SW-V_ED(52.2 ± 6.3 vs. 61.4 ± 11.3 mm Hg) relation. In contrast, pimobendanproduced a markedly leftward shift of the P_ES-V_ES relation withan increased slope (3.7 ± 0.3 vs. 3.8 ± 0.4; 3.9 ± 0.6 vs. 5.7± 0.4 mm Hg/ml, P < .05). In addition, pimobendan increased theslope of the dP/dt_max-V_ED relation (38.8 ± 8.4 vs. 57.1 ± 6.6mm Hg/sec/ml, P < .05) and that of the SW-V_ED relation (53.6 ±4.5 vs. 83.6 ± 10.4 mm Hg, P < .05).

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Fig. 4. LV P-V loops produced by bicaval occlusion after the development of pacing-induced CHF in the same animal. Amrinone producedlittle change in the LV end-systolic P-V relation (shown by line),whereas the slope of the relation was increased by pimobendan.This indicates that pimobendan's inotropic effect persisted afterCHF, whereas the effect of amrinone was diminished.

Left Ventricular-Arterial Coupling and Work Efficiency of the LV

We evaluated left ventricular-arterial coupling and the SW/PVA ratio in normal dogs and dogs with CHF at rest. Data are summarizedin table 5, A and B. SW was altered by neither amrinone nor pimobendanin normal dogs. Amrinone and pimobendan significantly increasedthe E_ES/E_A ratio to a similar extent (0.70 ± 0.24 vs. 0.79 ± 0.22,P = NS, amrinone vs. pimobendan) in normal animals. The SW/PVAratio was also increased by both drugs to similar magnitude (0.12± 0.03 vs. 0.14 ± 0.06, P = NS).

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TABLE 5A
Effects of amrinone and pimobendan on LV E_ES/E_A, SW and work efficiency in normal dog

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TABLE 5B
Effects of amrinone and pimobendan on E_ES/E_A, SW and work efficiency in dogs with CHF

In dogs with CHF, pimobendan significantly increased SW; however, amrinone did not. The E_ES/E_A ratio was significantly increasedby both drugs (0.10 ± 0.05 vs. 0.44 ± 0.08, P < .05). The SW/PVAratio was also significantly augmented by both drugs, though themagnitude was higher with pimobendan than with amrinone (0.05± 0.03 vs. 0.18 ± 0.05, P < .05).

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

We studied the acute effect of i.v. doses of pimobendan and amrinone that produced equivalent inotropic and arterial vasodilatoryactions in normal, instrumented animals at rest and during exercise.After the induction of pacing-induced CHF, the vasodilatory effectsof amrinone and pimobendan persisted. However, after CHF, amrinone'sinotropic effects at rest and during exercise were markedly attenuated.In contrast, pimobendan's inotropic effect persisted after CHF.Thus pimobendan, a Ca⁺⁺ sensitizer with some PDE-III inhibitor effects, was more effectivethan amrinone, a relatively pure PDE-III-inhibitor, in enhancingLV contractile state in CHF.

The bipyridine derivative amrinone produces positive inotropic effects and arterial vasodilation under normal circumstances(Honerjager, 1991). These effects are mediated by inhibition ofPDE-III in cardiomyocytes (Honerjager, 1991; Morgan et al., 1986)and in vascular smooth muscle cells (Morgan et al., 1986; Honerjageret al., 1981). The increased cAMP in cardiomyocytes induced byPDE-III inhibition enhances the slow Ca⁺⁺ inward current, producing a larger Ca⁺⁺ transient (Honerjager, 1991). This increased Ca⁺⁺ transient results in increased contractile force. Phosphorylationof phospholamban by cAMP-dependent phosphokinase also enhancesCa⁺⁺ uptake into the sarcoplasmic reticulum (Honerjager, 1991), speedingthe rate of relaxation. Vascular smooth muscle cells contain acAMP-dependent protein kinase, which activates a sarcolemmal Ca⁺⁺ pump (Honerjager, 1991; Morgan et al., 1986). Thus increasedcAMP in vascular smooth muscle cells decreases intracellular Ca⁺⁺, resulting in vasodilation (Honerjager, 1991; Morgan et al.,1986). Amrinone does not have a Ca⁺⁺-sensitizing effect in cardiomyocytes (Berger et al., 1985).

The benzimidazole derivative pimobendan is also an inotropic agent with vasodilating properties (Bohm et al., 1991; Brunkhorstet al., 1989; Hagemeijer et al., 1989; Fujino et al., 1988; Dunckeret al., 1987). Pimobendan decreases PDE-III activity in cardiomyocytesand vascular smooth cell, producing pimobendan's vasodilatoryaction (Fujimoto, 1994; Fujimoto and Matsuda, 1990). The positiveinotropic action of this drug is at least partly associated withpotentiation of the slow Ca⁺⁺ inward current in cardiomyocytes (Morgan et al., 1986; Hagemeijeret al., 1989). However, Berger et al. (1985) reported that pimobendaninhibits PDE-III activity only by 20 to 30% at the concentrationproducing a maximal positive inotropic effect in guinea pig papillarymuscles, a result that suggests an additional mechanism for itsinotropic action. Several investigators have shown that pimobendanincreases the Ca⁺⁺ sensitivity of cardiac myofilament by a direct effect on Ca⁺⁺-binding affinity of myofilament troponin C (Fujino et al., 1988;van Meel, 1987; Duncker et al., 1987; Ruegg et al., 1984). Pimobendanis demethylated rapidly in the body to an active metabolite, UD-CG212 C1 (Honerjager, 1991). UD-CD 212 C1 elicits positive inotropicand vasodilating effects mediated by inhibition of PDE-III (Endohet al., 1991; Hagemeijer et al., 1989; Duncker et al., 1987),and Ca⁺⁺ sensitization under some circumstances (van Meel et al., 1995a;van Meel et al., 1995b).

In failing myocardium, the positive inotropic response to PDE-III inhibitors is impaired (Perreault et al., 1992; Bohm etal., 1988b; Feldman et al., 1987). The reduced response to thoseagents may be due to reduced basal cAMP formation in the failingheart (Perreault et al., 1992; Bohm et al., 1988b), beta-adrenergicreceptor down-regulation (Bohm et al., 1988a; Bristow et al.,1986) and an increase in the Gi $alpha$ , $alpha$ -subunit of the guanine nucleotide-bindingprotein that inhibits adenyl cyclase activity in myocardial membranes(Marzo et al., 1991; Bohm et al., 1990; Feldman et al., 1988).

In a result consistent with these observations, we found that the inotropic effects of amrinone were decreased after CHF.However, pimobendan's positive inotropic effect persisted. Thusit appears unlikely that PDE-III inhibition from pimobendan andits metabolite contributed to pimobendan's inotropic effect afterCHF. Instead, pimobendan's inotropic effect after CHF appearsto be due to Ca⁺⁺ sensitization.

Pimobendan and amrinone produced equivalent amounts of arterial vasodilation at rest and during exercise both before and afterCHF. This suggests that the vasodilator effects in both drugs,which are mediated by PDE-III inhibition in vascular smooth muscle,are not attenuated in CHF. This is consistent with previous reportsthat amrinone and pimobendan decrease arterial resistance evenin severe CHF (Katz et al., 1992; Baumann et al., 1989; Konstamet al., 1986; Bayliss et al., 1983).

During exercise (both normally and after CHF), the heart is exposed to increased adrenergic stimulation (Chidsey et al., 1962).The increased adrenergic stimulation may enhance the inotropicresponse to PDE-III inhibitors (Cheng et al., 1992; Perreaultet al., 1992). However, we observed that after CHF, pimobendanhad a much greater inotropic effect during exercise than did amrinone.

Before CHF, amrinone and pimobendan had similar effects on parameters of LV diastolic performance (minimum LV pressure, Tand dV/dt_max) both at rest and during exercise. After CHF, pimobendanproduced a greater reduction than amrinone in minimum LV and LApressure at rest and during exercise. Both amrinone and pimobendanincreased the rate of relaxation after CHF at rest and duringexercise. This may have been at least partially due to a reductionin afterload. However, pimobendan's effects were greater thanthose of amrinone.

Our results should be compared with those of Asanoi et al. (1994), who also studied the effect of pimobendan in dogs withpacing-induced CHF. In agreement with our findings, they foundthat pimobendan's inotropic and lusitropic effects persisted afterCHF. In contrast, they found that the inotropic effects were reducedcompared with control.

In conclusion, our study suggests that the inotropic response to PDE-III inhibitors is attenuated in CHF, whereas the responseto Ca⁺⁺ sensitizer is preserved. Thus the drugs that increase contractileprotein Ca⁺⁺ sensitivity may be more effective in producing acute inotropicsupport to the failing heart.

	Acknowledgments

This study was supported in part by grants from the National Institutes of Health (HL45258 and HL53541) and the American HeartAssociation (94006140). We gratefully acknowledge the computerprogramming of Ping Tan, the technical assistance of Mack Williamsand the secretarial assistance of Carol S. Corum.

	Footnotes

Accepted for publication March 21, 1997.

Received for publication December 20, 1996.

¹ A preliminary report was presented at the Scientific Sessions of the American Heart Association, November, 1996. Study supportedin part by grants from NIH (HL45258 and HL42364) and the AmericanHeart Association.

Send reprint requests to: William C. Little, M.D., Cardiology Section, Bowman Gray School of Medicine, Medical Center Boulevard, Winston-Salem, NC 27157-1045.

	Abbreviations

CHF, congestive heart failure; PDE-III, phosphodiesterase-III; LV, left ventricle; LA, left atrium; P-V, pressure-volume; P_ES, end-systolic pressure; P_ED, end-diastolic pressure; TSR, total systemic resistance; T, time constant of LV relaxation; V_LV, left ventricular volume; V_ES, left ventricular end-systolic volume; V_ED, end diastolic volume; SW, left ventricular stroke work; E_A, arterial elastance; PVA, LV pressure-volume area; SV, stroke volume; E_ES, slope of the LV P_ES-V_ES relation; dV/dt_max, maximum rate of LV filling; M_SW, slope of the SW-V_ED relation; dE/dt_max, slope of the dP/dt_max-V_ED relation.

	References

Top Abstract Introduction Materials & Methods Results Discussion References

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The Cardiac Effects of Pimobendan (But Not Amrinone) Are Preserved at Rest and During Exercise in Conscious Dogs with Pacing-Induced Heart Failure¹