Experiments were performed according to the principles of laboratory animal care (NIH publication No. 86-23, revised 1985) and the Brazilian College of Animal Experimentation and were approved by the Institutional Animal Care Committee (protocol 55/2009). Male Wistar rats (100-120 g) provided by the animal facilities at the Federal University of Viçosa, Brazil were randomly assigned to the following groups: control (SHAM; n = 15); sedentary lifestyle and MI (SED-MI; n = 20); and exercise training and MI (ET-MI; n = 20). The large initial number of animals was chosen to provide at least six rats per group for each of the measurements, as a high mortality rate is expected for rats subjected to MI (30-40%). The animals were kept under a 12:12 hour light-dark cycle in a temperature-controlled (22°C) room with free access to standard laboratory chow (Nuvital, Colombo, Paraná, Brazil) and tap water.

The ET-MI group underwent AET on a motor-driven treadmill (Insight Scientific Equipments, Ribeirão Preto, São Paulo, Brazil) five days per week for eight weeks prior to MI surgery. The running speed, treadmill inclination and session duration were progressively increased throughout the protocol in such a way that by the 6th week, the rats were running continuously for 60 min at 18 m.min-1 and a 10° grade, which was maintained until the end of the protocol. The running speed of 18 m.min-1 was chosen because a pilot study in our lab failed to verify cardiomyocyte adaptations after AET at lower intensities. To verify the relative intensity of the training protocol, a subset of five sedentary rats underwent graded treadmill running tests at a 10° grade until exhaustion to measure the maximum running workload. Treadmill running tests performed until exhaustion in a separate batch of age-matched rats revealed that 18 m.min-1 corresponded to 55-70% of the maximal running speed in all animals; therefore, the AET protocol was performed at a moderate intensity. SHAM and SED-MI groups were placed on the treadmill twice a week and walked for 10 min at 20% of the speed of the exercise-trained group to mimic the running stress associated with the experimental protocol and maintenance of exercise skills. Forty-eight hours after the last training session (ET-MI) or adaptation (SHAM and SED-MI), all animals underwent a graded treadmill exercise test until exhaustion, as described by Koch and Britton (19). Briefly, the initial treadmill speed was 10 m.min-1, which was increased by 1 m.min-1 every 2 min until the rats were no longer able to run. The tests were carried out by experienced observers (LHMB and MFS) over the course of three days.

Coronary artery occlusion was performed in the MI groups 48 hours after the last graded treadmill running test. Rats were deeply anesthetized with ketamine (50 mg/kg, ip) and xylazine (10 mg/kg, ip), and a left thoracotomy was then performed. The mediastinum was accessed by incising the intercostal muscles between the 3rd and 4th ribs, the heart was carefully exteriorized, and then the left anterior descending (LAD) coronary artery was occluded with a 6-0 thread. After LAD ligation, the thorax was closed, and lung collapse was prevented by rapid withdrawal of air from the pleural cavity using a syringe. Sham-operated animals underwent a similar left thoracotomy and cardiac exteriorization but did not undergo LAD ligation. The peri-operative mortality was 30% in sedentary and 15% in exercise-trained animals. After MI induction, the animals were kept sedentary, and all measurements were performed 15 days after the surgical procedures. A similar number of animals from each of the three groups was allocated for either (1) the in vivo assessment of hemodynamic parameters and cardiac structure or (2) isolated cardiomyocyte structure and function evaluation.

Fifteen days after the surgical procedures, the animals were deeply anesthetized with ketamine (70 mg.kg-1, ip) and xylazine (10 mg.kg-1, ip) for LV catheterization. The right common carotid artery was separated from its connective tissue and catheterized with a fluid-filled polyethylene catheter (P50). The catheter was connected to a pressure transducer (TRI 21, Letica Scientific Instruments, Hospitalet, Barcelona, Spain) and to a digitalizing unit (Powerlab/4SP ML750, ADInstrument, Sidney, New South Wales, Australia) for data recording. After acquiring arterial systolic (SBP) and diastolic blood pressure (DBP) values, the catheter was moved to the left ventricle to obtain the following parameters: heart rate (HR); left ventricular systolic (LVSP) and end-diastolic pressures (LVEDP); and the maximum rates of pressure rise (+dP/dt) and fall (-dP/dt).

After hemodynamic measurements were collected, each heart was arrested with 3 M KCl (0.2 mL, iv), and a double lumen catheter (P50 inserted into P200) was inserted into the left ventricle through the aorta to determine the in situ left ventricle diastolic pressure-volume relationship, as previously described (20). Briefly, the atrio-ventricular groove was occluded, and a small incision was made in the right ventricular free wall to hinder any compression effect. Then, 0.9% NaCl was infused with an infusion pump (Insight Scientific Equipments, Ribeirão Preto, São Paulo, Brazil) at a constant rate of 0.68 mL.min-1 into the P200, and pressure was continuously monitored through the P50. The pressure followed a linear pattern during volume infusion from 0 to 5 mmHg, indicating the passive distention of ventricular wall; therefore, the slope was used to estimate LV dilatation because no stiffness was observed up to 5 mmHg (20).

After in vivo hemodynamic measurements, the heart was removed, mounted for routine histological procedures, transversely sectioned in 5 μm-thick sections and stained with picrosirius red for analysis of infarct size and collagen content. Endocardial and epicardial circumferences of the infarcted tissue and left ventricle were determined using Image J software (NIH, Bethesda, Maryland, USA). Infarct size was calculated as (endocardial + epicardial circumference of infarcted tissue)/(endocardial + epicardial circumference of the left ventricle) and was expressed as a percentage. The infarcted wall thickness was measured at the medial point of the scar area. The stereological parameter of collagen volume density (Vv) was estimated from the remote region by point counting for collagen according to the following formula: Vv[collagen] = PP[collagen]/72; where PP is the number of points that hit the structure and 72 is the total number of test points. A points test system was used for analysis in a standard test area of 0.15 mm2 (21).

Cardiac myocytes from a region adjacent to the MI were enzymatically isolated as previously described (22). Briefly, after euthanasia, the heart was removed rapidly, and extraneous tissue was dissected away. The heat was then flushed with a modified Hepes-Tyrode solution at room temperature containing the following ingredients: 130 mM Na+, 5.4 mM K+, 1.4 mM Mg2+, 140 mM Cl-, 0.75 mM Ca2+, 5 mM Hepes, 10 mM glucose, 20 mM taurine and 10 mM creatine, pH 7.3. The heart was then blotted dry and weighed before being mounted on a custom-designed Langendorff apparatus. After perfusion for 3 min with a 750 μM CaCl2 solution, the heart was perfused for 3-5 min with a Ca2+-free solution containing EGTA (0.1 mM). Afterwards, the heart was perfused for 15-20 min with a solution containing 1 mg.mL-1 collagenase type II (Worthington, Lakewood, New Jersey, USA). After tissue digestion, fragments of the MI-adjacent region were obtained, and single cells were isolated by mechanical dispersion and stored at 5°C until use.

Cellular contractility was measured as previously described (22). Briefly, isolated cardiomyocytes were placed in an experimental chamber with a glass coverslip base mounted on the stage of an inverted microscope. The chamber was perfused with HEPES Tyrode's solution containing 0.6, 1 or 5 mM CaCl2 and field-stimulated at a frequency of 3 Hz (20 V, 5 ms-long square pulses) at room temperature (25 - 30°C). Cells were imaged using a digital video camera in partial scanning mode, and these images were used to measure cell shortening (our index of contractility) in response to electrical stimulation using a video-edge detection system (Milton, Massachusetts, Ionoptix, USA). Cell images were sampled at a frame rate of 240 Hz. Cell shortening (expressed as a percentage of resting cell length), shortening velocity and relengthening velocity were calculated as previously described (22). Only Ca2+-tolerant, quiescent and rod-shaped myocytes showing clear cross striations were studied. The same images were also used to determine cell length and width, which were used to estimate myocyte volume (23) (130-180 cells per experimental group).

The data are presented as the mean ± SEM. The Student's t-test was used to analyze infarct size and ventricular wall thickness. The other parameters were analyzed using the Kruskal-Wallis test followed by Dunn's test (nonparametric data) or a one-way analysis of variance (ANOVA) followed by Tukey's test (parametric data). Statistical significance was defined as a p value below 0.05.

To verify the AET efficacy, all animals underwent graded treadmill running tests until exhaustion at the end of the training period prior to MI induction. As expected, the time until exhaustion, i.e., the running capacity, was substantially increased in exercise-trained rats (Table 1). Importantly, prior to the surgical procedure, the running capacity of the SHAM and SED-MI groups was similar, demonstrating homogeneity between these two groups at that time point.

Fifteen days after infarction, significant LV remodeling had occurred. MI-induced cardiac macroscopic alterations were verified by increased heart weights (HW) and heart weight to body weight ratios (HW/BW) in both MI groups as compared to the SHAM animals (Table 1). No significant effect of prior AET was found for HW or the HW/BW ratio (Table 1). Pulmonary congestion, estimated according to the lung wet-to-dry ratio, was detected in both MI groups, without a significant difference between the SED-MI and ET-MI groups (Table 1). Histological analysis revealed that MI extension was greater in SED-MI than ET-MI animals (Fig. 1A and B), and infarcted wall thickness was also greater in ET-MI as compared to SED-MI animals (Fig. 1A and C). MI also increased cardiac collagen content in both groups, although this occurred to a lesser extent in rats that had undergone AET (Fig. 1D).

Figure 1.

A Representative photomicrography of cardiac tissue. B Myocardial infarct extension. C Infarcted wall thickness. D Cardiac collagen content. SHAM, control. SED-MI, sedentary and given a MI. ET-MI, exercise trained and given a MI. Vv, volume density. Data are presented as the mean±SEM. ∗p<0.05 vs. SHAM; #p<0.05 vs. SED-MI (ANOVA followed by Tukey's test).

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HR, SBP and DBP under anesthesia were similar among groups (Table 1). MI decreased LVSP in the SED-MI group, which was not observed in the ET-MI group (Fig. 2A). However, AET did not prevent the elevation of LVEDP by MI (Fig. 2B). Inotropic function, evaluated according to +dP/dt, was reduced in SED-MI animals, and prior AET significantly attenuated inotropic dysfunction in MI rats (Fig. 2C). Accordingly, prior AET partially restrained the effects of MI on lusitropic function (-dP/dt) (Fig. 2D).

Figure 2.

A Left ventricular systolic pressure (LVSP). B Left ventricular end-diastolic pressure (LVEDP). C Inotropic function (+ dP/dt). D Lusitropic function (- dP/dt). SHAM, control. SED-MI, sedentary and given a MI. ET-MI, exercise trained and given a MI. ∗p<0.05 vs. SHAM; #p<0.05 vs. SED-MI (ANOVA followed by Tukey's test).

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The linear rise in LV pressure up to 5 mmHg in response to fluid infusion indicates passive chamber filling. Thus, the LV volume at 5 mmHg was compared among groups and provided an estimate of LV dilation (20). As shown in Figure 3, SED-MI animals displayed LV dilation as compared to SHAM animals, which was prevented by prior AET.

Figure 3.

In situ LV pressure-volume relationship. SHAM, control. SED-MI, sedentary and given a MI. ET-MI, exercise trained and given a MI. Data are presented as the mean±SEM. ∗p<0.05 vs. SHAM; #p<0.05 vs. SED-MI (ANOVA followed by Tukey's test).

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As illustrated in Figure 4, increased myocyte length without any change in cell width was observed in the SED-MI group. In contrast, the ET-MI group displayed myocyte length and width values greater than those observed in the SED-MI and SHAM groups (Fig. 4A and B). Estimated cardiomyocyte volume was increased only in ET-MI animals (Fig. 4C). Interestingly, increased cardiomyocyte dimensions in the ET-MI group were paralleled by preserved cell shortening at 1 mM and 5 mM concentrations of extracellular Ca2+ ([Ca2+]e), whereas SED-MI animals demonstrated reduced cell shortening. No difference in cell shortening was observed among groups at 0.6 mM of [Ca2+]e (Fig. 5A), and MI did not impair maximal cell shortening and relengthening velocities at any [Ca2+]e. In contrast, prior AET significantly increased both parameters in MI rats (Fig. 5B and C).

Figure 4.

Cardiomyocyte morphology. A Cell length. B Cell width. C Cell volume. SHAM, control. SED-MI, sedentary and given a MI. ET-MI, exercise trained and given a MI. Data are presented as the mean±SEM. ∗p<0.05 vs. SHAM; #p<0.05 vs. SED-MI (Kruskal-Wallis followed by Dunn's test).

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Figure 5.

Cardiomyocyte contractile function. A Cell shortening (% of resting cell length). B Shortening velocity. C Relengthening velocity. SHAM, control. SED-MI, sedentary and given MI. ET-MI, exercise trained and given MI. Data are presented as the mean±SEM. ∗p<0.05 vs. SHAM; #p<0.05 vs. SED-MI. +p<0.05 vs. lower [Ca+2] (Kruskal-Wallis followed by Dunn's test).

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We cannot exclude the possibility of variations in the ischemic region between SED-MI and ET-MI animals. To minimize this potential effect, the surgeries were performed by an experienced surgeon (MPB) who was blinded to the animal groupings. Correlations between in vivo global cardiac function and cardiomyocyte parameters from the same rats were not possible because such experiments were performed in distinct subsets of animals; however, our findings of improved cardiac function and cardiomyocyte contractility in trained animals suggest an association between these variables. Although the absence of an exercise-trained SHAM group did not allow us to directly confirm that exacerbated cellular hypertrophy in the ET-MI group was due to physiological cardiac remodeling promoted by AET, this hypothesis is supported by several previous publications (16,18,44) as well as our data on cardiac and myocyte function.