Long-term angiotensin-converting enzyme and angiotensin I--receptor inhibition in pacing-induced heart failure: effects on myocardial interstitial bradykinin levels.

BACKGROUND: We examined whether and to what degree long-term angiotensin-converting enzyme (ACE) inhibition, angiotensin type 1 (AT(1))-receptor blockade, or combined inhibition in developing congestive heart failure (CHF) alter myocardial interstitial bradykinin (BF) levels. METHODS AND RESULTS: Pigs (27-30 kg) underwent rapid pacing-induced CHF (240 bpm, 3 weeks; n = 10); pacing CHF with concomitant ACE inhibition (benezaprilat, 3.75 mg/day; n = 10); pacing CHF and concomitant AT(1)-receptor blockade (valsartan, 60 mg/day; n = 10); pacing CHF and combined inhibition (benezaprilat/valsartan, 1.87/60 mg/day, respectively; n = 10); or served as controls (no pacing, no treatment; n = 10). Steady-state myocardial interstitial BK levels were quantitated by microdialysis. Cardiac output decreased to 1.95 +/- 0.18 L/min in pacing CHF compared with control (3.78 +/- 0.38; P < .05). Cardiac output increased from untreated CHF values with concomitant ACE inhibition (3.91 +/- 0.27 L/min), AT(1)-receptor blockade (3.30 +/- 0.41 L/min), or combined ACE/AT(1)-receptor inhibition (4.13 +/- 0.32 L/min; all P < .05 v CHF). With pacing CHF, myocardial interstitial BK levels were reduced by approximately 50% from control values and were normalized in the ACE inhibition and combined inhibition groups. CONCLUSIONS: Long-term ACE inhibition increases myocardial interstitial BK levels with CHF; addition of AT(1)-receptor blockade does not seem to abrogate these effects.

Myocardial bradykinin following acute angiotensin-converting enzyme inhibition, AT1 receptor blockade, or combined inhibition in congestive heart failure.

BACKGROUND: The present study examined the effects of acute angiotensin-converting enzyme inhibition (ACEI), AT(1) receptor blockade (AT(1) block), or combined treatment on in vitro and in vivo bradykinin (BK) levels. METHODS: BK levels were measured in isolated porcine myocyte preparations (n = 13) in the presence of exogenous BK (10(-8) M); with an ACEI (benezaprilat; 0.1 mM) and BK; an AT(1) block (valsartan; 10(-5) M) and BK; and combined treatment and BK. In a second study, myocardial microdialysis was used to measure porcine interstitial BK levels in both normal (n = 14) and pacing-induced congestive heart failure (CHF) (240 beats/min, 3 weeks, n = 16) under the following conditions: baseline, following ACEI (benezaprilat, 0.0625 mg/kg) or AT(1) block (valsartan, 0.1 mg/kg), and a combined treatment (benezaprilat, 0.0625 mg/kg; valsartan, 0.1 mg/kg). RESULTS: In the left ventricular myocyte study, BK levels increased over 93% with all treatments compared to untreated values (P < 0.05). In the in vivo study, basal interstitial BK values were lower in the CHF group than in controls (2.64 +/- 0.57 vs 5.91 +/- 1.4 nM, respectively, P < 0.05). Following acute infusion of the ACEI, BK levels in the CHF state increased from baseline (57% +/- 22; P < 0.05). Following combined ACEI/AT(1) block, BK levels increased from baseline in both control (42% +/- 11) and CHF groups (60% +/- 22; P < 0.05 for both). CONCLUSION: These findings suggest that ACEI, or combined ACEI/AT(1) block increased BK at the level of the myocyte and potentiated BK levels in the CHF myocardial interstitium.

Selective vasopressin, angiotensin II, or dual receptor blockade with developing congestive heart failure.

With developing congestive heart failure (CHF), activation of the vasopressin V(1a) and angiotensin II type 1 (AT(1)) receptors can occur. In the present study, we examined the direct effects of V(1a) receptor blockade (V(1a) block), selective AT(1) receptor blockade (AT(1) block), and dual V(1a)/AT(1) receptor blockade (dual block) with respect to left ventricular (LV) function and contractility during the progression of CHF. LV and myocyte functions were examined in pigs with pacing CHF (rapid pacing, 240 beats/min, 3 weeks, n = 10), pacing CHF with concomitant V(1a) block (SR49059, 60 mg/kg, n = 8), pacing CHF with concomitant AT(1) block (irbesartan, 30 mg/kg, n = 7), or pacing CHF with dual block (n = 7). LV end-diastolic dimension and peak wall stress were reduced in all receptor blockade groups compared with CHF values. However, LV fractional shortening was increased only in the dual block group compared with CHF values (29 +/- 3 versus 21 +/- 2, P <.05). Basal LV myocyte percent shortening increased in the dual block group compared with CHF values (3.44 +/- 0.23 versus 2.88 +/- 0.11, P <. 05). Although V(1a) or AT(1) block reduced LV loading conditions, only dual block resulted in improved LV and myocyte shortening.

Brain blood flow patterns after the development of congestive heart failure: effects of treadmill exercise.

OBJECTIVE: Congestive heart failure (CHF) is associated with left ventricular (LV) failure, neurohormonal system activation, and diminished exercise capacity. Although alterations in systemic vascular resistive properties have been recognized to occur with CHF, whether and to what degree perfusion abnormalities occur within the brain after the development of CHF remain poorly understood. Accordingly, the present study measured brain blood flow patterns in pigs after the development of pacing-induced CHF at rest and after treadmill-induced exercise. MEASUREMENTS AND MAIN RESULTS: Adult pigs (n = 6) were studied before and after the development of pacing-induced CHF (240 beats/min, 3 wks) at rest and with treadmill exercise (3 mph, 15 degrees incline, 10 mins). At rest, LV stroke volume was reduced nearly 45% with CHF compared with normal (20+/-2 vs. 36+/-3 mL; p<.05) and was associated with a more than four-fold increase in plasma catecholamines, renin activity, and endothelin concentration. At rest, global brain blood flow was reduced with CHF compared with the normal state (1.06+/-0.13 vs. 0.81+/-0.06 mL/min/g; p<.05). At rest, blood flow to the frontal lobe, cerebellum, and medullary regions was reduced by approximately 30% in the CHF group (p<.05). With treadmill exercise, LV stroke volume remained lower and neurohormonal concentrations remained higher in the pacing CHF state. Global brain blood flow increased significantly with treadmill exercise in both the normal and CHF states (4.58+/-1.36 and 2.01+/-0.29 mL/min/g; p<.05) but remained reduced in the CHF state compared with normal values (p<.05). In the CHF group, the relative increase in blood flow with exercise was significantly blunted in the parietal and occipital regions of the cerebrum and the suprapyramidal region of the medulla. CONCLUSIONS: The development of pacing-induced CHF was associated with diminished brain perfusion under resting conditions and with treadmill exercise. These perfusion abnormalities with pacing CHF were pronounced in specific regions of the brain. The defects in brain perfusion with the development of CHF may contribute to abnormalities in centrally mediated processes of cardiovascular regulation.

Bradykinin degradation and relation to myocyte contractility.

BACKGROUND: Past studies have demonstrated that exogenous bradykinin (BK) causes vasodilation and increases coronary blood flow, effects that may be beneficial in the setting of cardiac disease states. An important pathway for BK degradation is through angiotensin-converting enzyme (ACE), which results in the formation of a degradative peptide, BK((1-7)). The goal of this study was to examine the effects of BK, BK((1-7)), and the potential modulation of BK by ACE inhibition on myocyte contractility. METHODS AND RESULTS: Contractile function was examined in isolated adult porcine (n = 15) left ventricular (LV) myocyte preparations in the presence or absence of BK (10(-8) mol/L), BK((1-7)) (10(-8) mol/L), and with pretreatment by ACE inhibition (benazaprilat). Myocyte velocity of shortening fell by over 15% in the presence of BK and by 8% with BK((1-7)) (P <.05 vs basal). ACE inhibition blunted the negative effect of BK on myocyte velocity of shortening by over 60% (P <.05). Furthermore, robust ACE activity coupled with significant BK degradation was demonstrated in LV-isolated myocyte preparations, and BK proteolysis was influenced by ACE inhibition. CONCLUSION: These results suggest that BK has a direct effect on LV myocyte contractility, and that this effect may be mediated by proteolysis of BK at the level of the LV myocyte sarcolemma.

Effects of growth hormone supplementation on left ventricular morphology and myocyte function with the development of congestive heart failure.

BACKGROUND: Release of growth hormone (GH), putatively through alterations in insulin growth factor-1 (IGF-1) levels, has been implicated to influence left ventricular (LV) myocardial structure and function. The objective of this study was to determine contributory mechanisms by which GH supplementation may influence LV function with the development of congestive heart failure (CHF). METHODS AND RESULTS: Pigs were assigned to the following groups: (1) chronic pacing at 240 bpm for 3 weeks (n = 10), (2) chronic pacing and GH supplementation (200 microg x kg(-1) x d(-1), n = 10), and (3) controls (n = 8). GH treatment increased IGF-1 plasma levels by nearly 2.5-fold throughout the pacing protocol. In the untreated pacing CHF group, LV fractional shortening was reduced and peak wall stress increased. In the pacing CHF and GH groups, LV fractional shortening was higher and LV wall stress lower than untreated CHF values. Steady-state myocyte velocity of shortening was reduced with pacing CHF and was unchanged from CHF values with GH treatment. In the presence of 25 nmol/L isoproterenol, the change in myocyte shortening velocity was reduced in the untreated CHF group and increased in the GH-treated group. LV sarcoplasmic reticulum Ca(2+)-ATPase abundance was reduced with pacing CHF but was normalized with GH treatment. CONCLUSIONS: Short-term GH supplementation improved LV pump function in pacing CHF as a result of favorable effects on LV remodeling and contractile processes. Thus, GH supplementation may serve as a novel therapeutic modality in developing CHF.

Amlodipine therapy in congestive heart failure: hemodynamic and neurohormonal effects at rest and after treadmill exercise.

This study examined the acute effects of amlodipine treatment on left ventricular pump function, systemic hemodynamics, neurohormonal status, and regional blood flow distribution in an animal model of congestive heart failure (CHF), both at rest and with treadmill exercise. A total of 14 pigs were studied under control conditions and after the development of pacing-induced CHF (240 beats per minute, 3 weeks, n = 7) or with CHF and acute amlodipine treatment for the last 3 days of pacing (1.5 mg/kg per day, n = 7). Under resting conditions, left ventricular stroke volume (mL) was reduced with CHF compared with the normal state (15+/-2 vs. 31+/-1, p<0.05) and increased with amlodipine treatment (23+/-4, p<0.05). At rest, systemic vascular resistance increased with CHF compared with the normal state (3,078+/-295 vs. 2,131+/-120 dyne x s cm(-5), p<0.05) and was reduced after amlodipine treatment (2,472+/-355 dyne x s cm(-5), p<0.05). With exercise, left ventricular stroke volume remained lower and systemic vascular resistance higher in the CHF group, but was normalized with amlodipine treatment. With exercise, left ventricular myocardial blood flow increased from resting values, but was reduced from the normal state with CHF (normal: 1.69+/-0.12 to 7.62+/-0.74 mL/min per gram vs. CHF: 1.26+/-0.12 to 4.77+/-0.45 mL/min per gram, both p<0.05) and was normalized with acute amlodipine treatment (1.99+/-0.35 to 6.29+/-1.23 mL/min per gram). Resting plasma norepinephrine was increased by >5-fold in the CHF group at rest and was not affected by amlodipine treatment. However, with exercise, amlodipine treatment blunted the increase in plasma norepinephrine by >50% when compared with untreated CHF values. Resting plasma endothelin levels increased with CHF compared with the normal state (10.9+/-0.9 vs. 2.8+/-0.4 fmol/mL, p<0.05) and was reduced with amlodipine treatment (7.5+/-1.5 fmol/mL, p<0.5). In other vascular beds, acute amlodipine treatment with CHF improved pulmonary and renal blood flow both at rest and with exercise; however, there were no effects observed on skeletal muscle blood flow. With the development of CHF, acute amlodipine treatment does not negatively influence left ventricular pump function, but rather may provide favorable hemodynamic and neurohormonal effects.

Inducible lethal ventricular arrhythmias in swine with pacing-induced heart failure.

INTRODUCTION: Rapid pacing-induced heart failure provides an excellent animal model for the study of heart failure. We studied the development of ventricular tachyarrhythmias using programmed stimulation in a pacing-induced heart failure model. We also studied action potential characteristics and the relationship between action potential and heart rate. METHODS AND RESULTS: Ten pigs were instrumented and were studied before the onset and every week after rapid pacing was instituted. Weekly echocardiograms and programmed stimulation were done in a sedated state. In vitro electrophysiologic studies were done on left ventricular myocardium in 4 heart-failure animals and 4 controls. All animals developed progressive heart failure with left ventricular dilatation and reduced percentage fractional shortening. No arrhythmias were induced at baseline or the first and second weeks. Ventricular fibrillation was induced in one animal on the third week and 4 animals on week 4, while there was no appreciable worsening in echocardiographic indices of ventricular dysfunction between weeks 3 and 4. Ventricular effective refractory period was unchanged during the 4 weeks. In vitro studies showed action potential prolongation in heart failure myocardium. However, action potential duration at pacing rates >100 bpm were similar to controls. No early or delayed afterdepolarizations were observed. CONCLUSION: This study demonstrated an increased susceptibility to ventricular fibrillation with the development of heart failure which was not related to the degree of ventricular dysfunction. Also, the normalization of action potential duration at higher heart rates suggests that the increased incidence of inducible ventricular fibrillation in this model may not be solely due to prolonged action potential duration.

Chronic amlodipine treatment during the development of heart failure.

BACKGROUND: This study examined the effects of chronic amlodipine treatment on left ventricular (LV) pump function, systemic hemodynamics, neurohormonal status, and regional blood flow distribution in an animal model of congestive heart failure (CHF) both at rest and with treadmill exercise. In an additional series of in vitro studies, LV myocyte contractile function was examined. METHODS AND RESULTS: Sixteen pigs were studied under normal control conditions and after the development of chronic pacing-induced CHF (240 bpm, 3 weeks, n=8) or chronic pacing and amlodipine (1.5 mg . kg-1 . d-1, n=8). Under ambient resting conditions, LV stroke volume (mL) was reduced with CHF compared with the normal control state (16+/-2 versus 31+/-2, P<0.05) and increased with concomitant amlodipine treatment (29+/-2, P<0.05). At rest, systemic and pulmonary vascular resistance (dyne . s-1 . cm-5) increased with CHF compared with the normal control state (3102+/-251 versus 2156+/-66 and 1066+/-140 versus 253+/-24, respectively, both P<0.05) and were reduced with amlodipine treatment (2108+/-199 and 480+/-74, respectively, P<0.05). With CHF, LV stroke volume remained reduced and was associated with a 40% reduction in myocardial blood flow during treadmill exercise, whereas chronic amlodipine treatment normalized LV stroke volume and improved myocardial blood flow. Resting and exercise-induced plasma norepinephrine levels were increased by >5-fold in the CHF group and were reduced by 50% from CHF values with chronic amlodipine treatment. Resting plasma endothelin (fmol/mL) increased with CHF compared with the normal state (10.4+/-0.9 versus 3.1+/-0.3, P<0.05) and was reduced with amlodipine treatment (6.6+/-1.1, P<0.5). With CHF, LV myocyte velocity of shortening ( microm/s) was reduced compared with normal controls (39+/-1 versus 64+/-1, P<0.05) and was increased with chronic amlodipine treatment (52+/-1, P<0.05). CONCLUSIONS: Chronic amlodipine treatment in this model of developing CHF produced favorable hemodynamic, neurohormonal, and contractile effects in the setting of developing CHF.

Angiotensin converting enzyme inhibition, AT1 receptor inhibition, and combination therapy with pacing induced heart failure: effects on left ventricular performance and regional blood flow patterns.

BACKGROUND: AT1 receptor activation has been demonstrated to cause increased vascular resistance properties which may be of particular importance in the setting of congestive heart failure (CHF). The overall goal of this study was to examine the effects of ACE inhibition (ACEI) alone, AT1 receptor blockade alone and combined ACEI and AT1 receptor blockade on LV pump function, systemic hemodynamics and regional blood flow patterns in the normal state and with the development of pacing induced CHF, both at rest and with treadmill induced exercise. METHODS AND RESULTS: Pigs (25 kg) were instrumented in order to measure cardiac output (CO), systemic (SVR) and pulmonary vascular (PVR) resistance, neurohormonal system activity, and myocardial blood flow distribution in the conscious state and assigned to one of 4 groups: (1) rapid atrial pacing (240 bpm) for 3 weeks (n = 7); (2) ACEI (benazeprilat, 3.75 mg/day) and pacing (n = 7); (3) AT1 receptor blockade (valsartan, 60 mg/day) and rapid pacing (n = 7); and (4) ACEI and AT1 receptor blockade (benazeprilat/valsartan, 1/60 mg/day, respectively) and pacing (n = 7). Measurements were obtained at rest and with treadmill exercise (15 degrees, 3 miles/h; 10 min) in the normal control state and after the completion of the treatment protocols. With rapid pacing, CO was reduced at rest and with exercise compared to controls. ACEI or AT1 blockade normalized CO at rest, but remained lower than control values with exercise. Combination therapy normalized CO both at rest and with exercise. Resting SVR in the CHF group was higher than controls and SVR fell to a similar degree with exercise; all treatment groups reduced resting SVR. With exercise, SVR was reduced from rapid pacing values in the ACEI and combination therapy groups. PVR increased by over 4-fold in the rapid pacing group both at rest and with exercise, and was reduced in all treatment groups. In the combination therapy group, PVR was similar to control values with exercise. Plasma catecholamines and endothelin levels were increased by over 3-fold with chronic rapid pacing, and were reduced in all treatment groups. In the combination therapy group, the relative increase in catecholamines and endothelin with exercise were significantly blunted when compared to rapid pacing only values. LV myocardial blood flow at rest was reduced in the rapid pacing only and monotherapy groups, but was normalized with combination therapy. CONCLUSION: These findings suggest that with developing CHF, combined ACE inhibition and AT1 receptor blockade improved vascular resistive properties and regional blood flow distribution to a greater degree than that of either treatment alone. Thus, combined ACEI and AT1 receptor blockade may provide unique benefits in the setting of CHF.

Myocardial matrix metalloproteinase activity and abundance with congestive heart failure.

The left ventricular (LV) myocardial collagen matrix has been proposed to participate in the maintenance of LV geometry. Thus alterations in the composition of the LV myocardial collagen matrix may influence LV function. The matrix metalloproteinases (MMPs) are a family of enzymes that contribute to extracellular remodeling in several disease states. However, the types of MMPs expressed in the normal and congestive heart failure (CHF) state and the relation to MMP activity remained unclear. Accordingly, after 3 wk of pacing (240 beats/min), changes in LV function, substrate-specific MMP activity, and MMP subclass abundance were measured in comparison with control pigs (n = 6). Changes in LV function and geometry were measured by echocardiography; LV end-diastolic dimension increased (3.6 +/- 0.1 vs. 6.0 +/- 0.1 cm, P < 0.05) and LV fractional shortening decreased (47 +/- 1 vs. 15 +/- 1%, P < 0.05) compared with controls. Degradation of fibrillar collagen is achieved through the combined action of interstitial collagenase (MMP-1), gelatinase A (MMP-2), and stromelysin (MMP-3) (He, C., S. Wilheilm, A. Pentland, B. Marmer, G. Grant, A. Eisen, and G. Goldberg. Proc. Natl. Acad. Sci. USA 86:2632-2636, 1989; Woessner, J. FASEB J. 5: 2145-2154, 1991). Accordingly, the relative abundance of specific MMPs (MMP-1, MMP-2, and MMP-3) was examined by immunoblotting. With pacing CHF, the relative abundance for MMP-1 increased to 319 +/- 94%, MMP-2 increased to 194 +/- 31%, and MMP-3 increased to 493 +/- 159% (all P < 0.05). With pacing CHF, LV myocardial zymographic activity for the substrate gelatin increased by 119% (P < 0.05) and for the substrate collagen III by 153% (P < 0.05) over controls. Caseinolytic activity also increased with pacing CHF by 139% (P < 0.05) over controls. In conclusion, LV myocardial MMP activity and abundance increased with pacing-induced CHF. These findings demonstrate that pacing-induced CHF leads to changes in myocardial MMP activity and expression that may be responsible for LV remodeling in CHF.

Amlodipine monotherapy, angiotensin-converting enzyme inhibition, and combination therapy with pacing-induced heart failure.

In patients with congestive heart failure (CHF) receiving therapy with angiotensin-converting enzyme (ACE) inhibition, institution of calcium channel antagonism with amlodipine provided favorable effects. The goal of the present study was to define potential mechanisms for these effects by measuring left ventricular function, hemodynamics, and neurohormonal system activity in a model of CHF in which amlodipine treatment had been instituted either as a monotherapy or in combination with ACE inhibition. Thirty-two pigs were instrumented to allow measurement of cardiac index, total systemic resistance index, and neurohormonal activity in the conscious state and assigned to one of four groups: (1) rapid atrial pacing (240 bpm) for 3 weeks (n = 8), (2) amlodipine (1.5 mg x kg(-1) x d[-1]) and pacing (n = 8), (3) ACE inhibition (fosinopril 1.0 mg/kg BID) and pacing (n = 8), and (4) amlodipine and ACE inhibition (1.0 mg x kg(-1) x d(-1) and 1.0 mg/kg BID, respectively) and pacing (n = 8). Measurements were obtained in the normal control state and after the completion of the treatment protocols. With rapid pacing, basal resting cardiac index was reduced compared with control values (2.7+/-0.2 versus 4.7+/-0.1 L x min(-1) x m(-2), respectively, P<.05) and increased from rapid pacing-only values with either amlodipine or combination therapy (3.7+/-0.3 and 4.4+/-0.5 L x min(-1) x m(-2), respectively, P<.05). Basal resting total systemic resistance index was higher in the rapid pacing-only group compared with control values (2731+/-263 versus 1721+/-53 dyne x s x cm(-5) x m2, respectively, P<.05), was reduced with either amlodipine treatment or ACE inhibition (2125+/-226 and 2379+/-222 dyne x s x cm(-5) x m2, respectively, P<.05), and was normalized with combination therapy. Plasma catecholamines, renin activity, and endothelin levels were increased threefold with rapid pacing. Amlodipine, either as a monotherapy or in combination with ACE inhibition, did not result in increased plasma catecholamines and renin activity compared with the rapid pacing-only group. Furthermore, combination therapy reduced steady state norepinephrine and normalized epinephrine levels. The results of the present study demonstrated that monotherapy with either amlodipine or ACE inhibition provides beneficial effects in this pacing model of CHF. Combined amlodipine and ACE inhibition provided greater benefit with respect to vascular resistance properties and neurohormonal system activity compared with either monotherapy.

AT1 angiotensin II receptor inhibition in pacing-induced heart failure: effects on left ventricular performance and regional blood flow patterns.

BACKGROUND: AT1 angiotensin II (AT1 Ang II) receptor activation has been shown to cause increased vascular resistance in the systemic (SVR), pulmonary (PVR), and coronary vasculature which may be of particular importance in the setting of congestive heart failure (CHF). The overall goal of this study was to examine the effects of acute AT1 Ang II receptor inhibition on left ventricular (LV) pump function, systemic hemodynamics, and regional blood flow patterns in the normal state and with CHF, both at rest and with treadmill-induced exercise. METHODS AND RESULTS: Pigs (25 kg) were instrumented to measure cardiac output (CO), SVR, and PVR, and LV myocardial blood flow distribution in the conscious state and were assigned to one of two groups: (1) pacing-induced CHF (240 bpm for 3 weeks, n = 6) or (2) sham controls (n = 5). Measurements were obtained at rest and after treadmill exercise (15 degrees for 10 minutes). Studies were repeated 30 minutes after intravenous infusion of a low (1.1 mg/kg) or high (125 mg/kg) dose of the AT1 Ang II antagonist, valsartan. The low dose of valsartan reduced the Ang II pressor response by approximately 50% but had a minimal effect on arterial pressure, whereas the high dose eliminated the Ang II pressor response and reduced resting blood pressure by approximately 20%. With CHF, CO was reduced at rest (2.5+/-0.2 v 3.9+/-0.1 L/min) and with exercise (6.4+/-0.5 v 7.8+/-0.5 L/min) compared with controls (P < .05). Valsartan at the low and high dose increased resting CO by 28% in the control and CHF groups, but did not affect CO with exercise. Resting SVR in the CHF group was higher than controls (2,479+/-222 v 1,877+/-65 dyne x s x cm(-5), P < .05), but SVR fell to a similar degree with exercise (1,043+/-98 v 1,000+/-77 dyne x s x cm(-5)). The low and high dose of valsartan reduced resting SVR by more than 30% in both the control and CHF groups. PVR was increased by more than twofold in the CHF group at rest. The high dose of valsartan reduced resting PVR with CHF, but had no further effect with exercise. LV myocardial blood flow was reduced with pacing CHF, particularly with exercise. With exercise and CHF, a low or high dose of valsartan reduced coronary vascular resistance, but LV myocardial blood flow remained reduced from normal values. CONCLUSIONS: Heightened AT1 Ang II receptor activity occurred in this model of CHF, which contributed to alterations in systemic hemodynamics and vascular resistive properties. By using a low dose of a selective AT1 Ang II receptor antagonist reduced SVR, PVR, and coronary vascular resistive properties and therefore may provide beneficial effects in a setting of CHF.

Angiotensin AT1 receptor inhibition in pacing induced heart failure: effects on left ventricular myocardial collagen content and composition.

The progression of left ventricular (LV) dilation with congestive heart failure (CHF) is associated with an increased incidence of morbidity and mortality. The LV myocardial extracellular matrix has been implicated to play an important role in maintaining chamber shape and myocyte alignment. While angiotensin II AT1 receptor (Ang AT1) receptor activation has been demonstrated to contribute to increased vascular resistance with the CHF, whether activation of the myocardial Ang AT1 receptor system contributes to LV dilation and myocardial collagen remodelling with CHF remains unclear. The goal of this study was to examine the effects of Ang AT1 receptor inhibition on LV geometry and myocardial collagen content and structure with the development of pacing CHF. Pigs (25 kg) were instrumented in order to measure LV function in the conscious state and were assigned to one of three groups: (1) Pacing CHF: rapid atrial pacing (240 bpm) for 3 weeks (n = 7); (2) Pacing CHF and Ang AT1 Block: concomitant Ang AT1 receptor blockade (valsartan, Novartis, Basel 60 mg/day) and rapid pacing (n = 7); (3) sham controls (n = 7). The Ang AT1 receptor antagonist was delivered by osmotic minipump and this dose has been demonstrated previously to significantly blunt the Ang-II pressor response. LV pump function and geometry was assessed by echocardiography and LV myocardial collagen content by computer assisted histomorphometry and biochemistry. In the pacing CHF group, LV fractional shortening was reduced (17 +/- 2 v 45 +/- 1%) and LV end-diastolic dimension increased (5.91 +/- 0.09 v 3.75 +/- 0.07 cm) compared to controls (P<0.05). In the pacing CHF and Ang AT1 blockade group, LV pump function and dimensions were similar to untreated pacing CHF values. The relative content of LV myocardial fibrillar collagen was reduced with pacing CHF (7.6 +/- 0.4 v 11.3 +/- 0.6%) compared to controls (P<0.05), and was similarly reduced in the pacing CHF and Ang AT1 receptor blockade group (8.3 +/- 0.4%, P<0.05). LV myocardial hydroxyproline was reduced with pacing CHF compared to controls (2.35 +/- 0.21 v 2.89 +/- 0.42 mg/gdwt, P<0.05). While reduced with pacing CHF and Ang AT1 receptor blockade (2.54 +/- 0.25 mg/gdwt), this was not significantly different from controls (P=0.23). Ang AT1 receptor inhibition in this model of CHF did not appear to favorably affect the degree of LV dilation and myocardial collagen structure. These results suggest that activation of the myocardial Ang AT1 receptor may not significantly contribute to LV remodelling with pacing CHF.

Modulation of the renin-angiotensin pathway through enzyme inhibition and specific receptor blockade in pacing-induced heart failure: I. Effects on left ventricular performance and neurohormonal systems.

BACKGROUND: The goal of this study was to determine the effects of ACE inhibition (ACEI) alone, AT1 angiotensin (Ang) II receptor blockade alone, and combined ACEI and AT1 Ang II receptor blockade on LV function, systemic hemodynamics, and neurohormonal system activity in a model of congestive heart failure (CHF). METHODS AND RESULTS: Pigs were randomly assigned to each of 5 groups: (1) rapid atrial pacing (240 bpm) for 3 weeks (n=9), (2) ACEI (benazeprilat, 0.187 mg x kg(-1) x d(-1)) and rapid pacing (n=9), (3) AT1 Ang II receptor blockade (valsartan, 3 mg x kg(-1) x d(-1)) and rapid pacing (n=9), (4) ACEI and AT1 Ang II receptor blockade (benazeprilat/valsartan, 0.05/3 mg x kg(-1) d(-1)) and rapid pacing (n=9), and (5) sham controls (n=10). In the pacing group, LV fractional shortening (LVFS) fell (13.4+/-1.4% versus 39.1+/-1.0%) and end-diastolic dimension (LVEDD) increased (5.61+/-0.11 versus 3.45+/-0.07 cm) compared with control (P<.05). With AT1 Ang II blockade and rapid pacing, LVEDD and LVFS were unchanged from pacing-only values. ACEI reduced LVEDD (4.95+/-0.11 cm) and increased LVFS (20.9+/-1.9%) from pacing-only values (P<.05). ACEI and AT1 Ang II blockade reduced LVEDD (4.68+/-0.07 cm) and increased LVFS (25.2+/-0.9%) from pacing only (P<.05). Plasma norepinephrine and endothelin increased by more than fivefold with chronic pacing and remained elevated with AT1 Ang II blockade. Plasma norepinephrine was reduced from pacing-only values by more than twofold in the ACEI group and the combination group. ACEI and AT1 Ang II receptor blockade reduced plasma endothelin levels by >50% from rapid-pacing values. CONCLUSIONS: These findings suggest that the effects of ACEI in the setting of CHF are not solely due to modulation of Ang II levels but rather to alternative enzymatic pathways and that combined ACEI and AT1 Ang II receptor blockade may provide unique benefits for LV pump function and neurohormonal systems in the setting of CHF.

Pulmonary hemodynamics and endothelin levels in pacing-induced heart failure: during rest and exercise.

Elevated plasma levels of endothelin (ET) have been reported to accompany the development of heart failure (HF), and therefore, this potent vasoconstrictive peptide has been postulated to contribute to the altered pulmonary hemodynamics that occur in this disease process. The overall goal of this study was to examine more carefully the relationship between ET levels in the pulmonary system and pulmonary hemodynamics in the normal and HF states, during both rest and exercise. This study used a porcine model of chronic rapid pacing that has been shown in previous studies to produce left ventricular dysfunction and neurohormonal system activation consistent with the syndrome of HF. Pigs (n = 10) were chronically instrumented to measure pulmonary and systemic hemodynamics, parenchymal flow, and ET content and to obtain blood samples from the pulmonary circuit in the conscious state. Measurements were performed in the normal control state and again following the development of pacing-induced HF (240 beats/min per 21 days), both at rest and during treadmill exercise (3 mph, 15 degrees incline, 12 minutes). With HF, under ambient resting conditions, a threefold increase in pulmonary plasma ET occurred and was accompanied by a fivefold increase in pulmonary vascular resistance. During treadmill exercise, pulmonary plasma ET and pulmonary vascular resistance remained elevated in the HF group when compared with the normal state and were associated with a sixfold decrease in pulmonary parenchymal flow. Pulmonary parenchymal ET content was increased with HF when compared with values for normal control subjects (8.5 +/- 0.6 vs 5.6 +/- 0.8 fmol ET/mg protein, P < .05). Thus, the findings of this study suggest that in this model of HF, increased ET within the pulmonary circuit contributed to abnormalities in resistive properties and parenchymal flow.