Mark J. Clair

Matrix Metalloproteinase Inhibition During the Development of Congestive Heart Failure Effects on Left Ventricular Dimensions and Function

The development of congestive heart failure (CHF) is associated with left ventricle (LV) dilation and myocardial remodeling. The matrix metalloproteinases (MMPs) play a significant role in extracellular remodeling, and recent studies have demonstrated increased MMP expression and activity with CHF. Whether increased MMP activity directly contributes to the LV remodeling with CHF remains unknown. Accordingly, this study examined the effects of chronic MMP inhibition (MMPi) on LV size and function during the progression of CHF. Pigs were assigned to the following groups: (1) CHF, rapid pacing for 3 weeks at 240 bpm (n=12); (2) CHF/MMPi, rapid pacing and concomitant MMPi (PD166793, 20 mg/kg per day [n=10]), and (3) control (n=11). With pacing CHF, LV fractional shortening was reduced (19+/-1 versus 45+/-1%), and end-diastolic dimension increased (5.67+/-0.11 versus 3.55+/-0.05 cm), compared with baseline values (P<0.05). In the CHF/MMPi group, LV endocardial shortening increased (25+/-2%) and the end-diastolic dimension was reduced (4.92+/-0.17 cm) compared with CHF-only values (P<0.05). LV midwall shortening was reduced to a comparable degree in the CHF-only and CHF/MMPi groups. LV peak wall stress increased 3-fold with pacing CHF compared with controls and was significantly reduced in the CHF/MMPi group. LV myocardial stiffness was unchanged with CHF but was increased in the CHF/MMPi group. LV myocyte length was increased with pacing CHF compared with controls (180+/-3 versus 125+/-4 microm, P<0.05) and was reduced in the CHF/MMPi group (169+/-4 microm, P<0.05). Basal-state myocyte shortening velocity was reduced with pacing CHF compared with controls (33+/-2 versus 66+/-1 microm/s, P<0.05) and was unchanged in the CHF/MMPi group (31+/-2 microm/s). Using an ex vivo assay system, myocardial MMP activity was increased with pacing CHF and was reduced with chronic MMPi. In summary, concomitant MMPi with developing CHF limited LV dilation and reduced wall stress. These results suggest that increased myocardial MMP activity contributes to LV myocardial remodeling in developing 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.

Modulation of the Renin-Angiotensin Pathway Through Enzyme Inhibition and Specific Receptor Blockade in Pacing-Induced Heart Failure: II. Effects on Myocyte Contractile Processes

BACKGROUND The goal of this study was to determine the effects of ACE inhibition alone, AT1 angiotensin (Ang) II receptor blockade alone, and combined ACEI and AT1 Ang II receptor blockade in a model of congestive heart failure (CHF) on isolated LV myocyte function and fundamental components of the excitation-contraction coupling process. METHODS AND RESULTS Pigs were randomly assigned to one of five groups: (1) rapid atrial pacing (240 bpm) for 3 weeks (n=9), (2) concomitant ACEI (benazeprilat, 0.187 mg x kg(-1) x d(-1)) and rapid pacing (n=9), (3) concomitant AT1 Ang II receptor blockade (valsartan, 3 mg/kg/d) and rapid pacing (n=9), (4) concomitant ACEI and AT1 Ang II receptor blockade (benazeprilat/valsartan, 0.05/3 mg x kg(-1) x d(-1)) and rapid pacing (n=9), and (5) sham controls (n=10). LV myocyte shortening velocity was reduced with chronic rapid pacing compared with control (27.2+/-0.6 versus 58.6+/-1.2 microm/s, P<.05) and remained reduced with AT1 Ang II receptor blockade and rapid pacing (28.0+/-0.5 microm/s, P<.05). Myocyte shortening velocity increased with ACEI or combination treatment compared with rapid pacing only (36.9+/-0.7 and 42.3+/-0.8 microm/s, respectively, P<.05). Myocyte beta-adrenergic response was reduced by >50% in both the rapid pacing group and the AT1 Ang II blockade group and improved by 25% with ACEI and increased by 54% with combined treatment. Both L-type Ca2+ channel density and the relative abundance of sarcoplasmic reticulum Ca2+ ATPase density were reduced with rapid pacing and returned to control levels in the combined ACEI and AT1 Ang II blockade group. CONCLUSIONS The unique findings of this study were twofold. First, basic defects in specific components of the myocyte excitation-contraction coupling process that occur with CHF are reversible. Second, combined ACEI and AT1 Ang II blockade may provide unique benefits on myocyte contractile processes in the setting of CHF.

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.

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.

Effects of Combined Angiotensin II and Endothelin Receptor Blockade With Developing Heart Failure Effects on Left Ventricular Performance

BackgroundThe goal of this study was to determine the comparative effects of angiotensin II type 1 (AT1) receptor inhibition alone, endothelin-1 (ET) receptor blockade alone, and combined receptor blockade on left ventricular (LV) function, contractility, and neurohormonal system activity in a model of congestive heart failure (CHF). Methods and ResultsPigs were randomly assigned to each of 5 groups: (1) rapid atrial pacing (240 bpm) for 3 weeks (n=9), (2) concomitant AT1 receptor blockade (valsartan, 3 mg/kg per day) and rapid pacing (n=8), (3) concomitant ET receptor blockade (bosentan, 50 mg/kg BID) and rapid pacing (n=8), (4) concomitant combined AT1 and ET receptor inhibition and rapid pacing (n=8), and (5) sham-operated control (n=9). LV stroke volume was reduced from the control value after rapid pacing, was unchanged with either AT1 or ET receptor blockade alone, but was improved with combination treatment. LV peak wall stress was reduced in both groups with ET receptor blockade compared with the rapid pacing group. Plasma norepinephrine levels were increased by >3-fold after rapid pacing, remained increased in the monotherapy groups, but were reduced after combination treatment. LV myocyte velocity of shortening was reduced after rapid pacing–induced CHF, remained reduced after AT1 receptor blockade, increased after ET receptor blockade (compared with rapid pacing–induced CHF values), and returned to within control values after combined blockade. ConclusionsCombined AT1 and the ET receptor blockade in this model of CHF improved LV pump function, and contributory factors included the effects of LV loading conditions, neurohormonal system activity, and myocardial contractile performance. Thus, combined receptor blockade may provide a useful combinatorial therapeutic approach in CHF.

Direct and interactive effects of cardioplegic arrest and protamine on myocyte contractility

BACKGROUND Cardioplegic arrest with rewarming and protamine administration have been implicated in causing transient left ventricular dysfunction perioperatively. However, whether interactive effects between cardioplegic arrest and rewarming with protamine occur with respect to myocyte contractile processes remains unclear. Accordingly, using an isolated myocyte model, the present study tested the hypothesis that simulated cardioplegic arrest with rewarming and protamine would have direct and interactive effects on myocyte contractile function. METHODS Left ventricular isolated myocyte contractile function was examined using computer-aided videomicroscopy under normothermic conditions (37 degrees C, cell medium; n = 183) and after simulated hypothermic, hyperkalemic cardioplegic arrest with rewarming (4 degrees C, 24 mEq/L K+, 2 hours; then 37 degrees C, cell medium, 5 minutes; n = 268). Myocyte function was then examined in the presence of protamine (10 to 40 micrograms/mL) under normothermic conditions (n = 102) and after cardioplegic arrest with rewarming (n = 175). RESULTS Myocyte contractile function decreased by 43% from baseline after simulated cardioplegic arrest with rewarming. Under normothermic conditions, protamine (20 micrograms/mL) reduced myocyte contractile function by 43.9% +/- 4.3%, whereas myocyte contractile function decreased by only 31.1% +/- 2.7% with protamine (20 micrograms/mL) after cardioplegic arrest with rewarming. Thus, the negative effects of protamine on myocyte contractility were attenuated after cardioplegic arrest when compared with normothermic conditions. CONCLUSIONS The present study demonstrated that simulated cardioplegic arrest with rewarming and protamine have direct and interactive effects on myocyte contractile function, which are not additive or synergistic.

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.

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

AbstractIntroduction: 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 disfunction. 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.