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put, biological system alters the autonomic control of the heart and vessels favouring
the sympathetic activity, thus increasing cardiac chronotropism (frequency) and inot-
ropism (strength), as well as the activity of molecules associated with adrenergic
control as catecholamines and RAAS [ 8 ]. Even if such alterations act beneficially in
the first hours after MI – collaborating to maintain blood perfusion to the tissues,
and, consequently, nutrients delivery - over time these compensatory alterations will
cause several malefic alterations in cardiac functioning and structure [ 8 , 30 ].
ROS activity is increased from the early remodelling phase to the late remodellingphase in response to cardiac ischemia with or without reperfusion [ 21 , 31 , 32 ]. ROS
synthesis and release are induced by several elements showed in the ischemic myo-
cardium including, but not limited to proinflammatory citokynes and RAAS [ 29 , 30 ,
32 ]. Once activated, ROS pathway will act triggering alterations on cardiomyocyte,
collaborating, for example, with cardiac hypertrophy induced by proinflammatory
citokynes and RAAS [ 30 ]. On the other hand, activity of different elements of the
antioxidant milieu (e.g., vitamin E, catalase, superoxide dismutase [SOD]) seems to
successfully inhibit such alterations induced by ROS [ 21 , 30 ]. Indeed, the myocar-
dium of transgenic animals overexpressing SOD shows abolished free radical gen-
eration, ameliorated recovery of contraction function and lower infarcted area after
ischemia-reperfusion, in comparison with wild-type animals [ 20 , 21 ].
Even if there are no evidence indicating the effects of ET posterior to MI in theearly remodelling phase, an isolated result showed that 12 weeks of low-to- moderate
aerobic exercise performed during 50 min, 5 days per week previously to MI
induced by isoproterenol was effective to decreased infarction degree and ROS
expression and activity in the heart of the trained rats in comparison with sedentary
animals. Concomitantly, the authors observed decreased activity of antioxidant
enzymes, as superoxide dismutase and catalase in the heart of sedentary rats.
However, ET could attenuate this phenomenon [ 31 ]. However, the study did not
accomplish additional analyses, as cardiac functioning, and inferences about the
data are limited.
As abovementioned, besides its association with ROS, proinflammatory cito-kynes have a marked influence on MMPs [ 29 , 33 ]. Immediately after myocardial
injury caused by ischemia, neutrophils migrate to the MI area and recruit MMPs,
which induce collagen breakdown [ 29 ]. This phenomenon will induce fibroblast
migration and, posterior, differentiation in myofibroblasts, which are crucial to
fibrotic tissue formation (i.e., scar) [ 29 , 33 ]. In summary, myofibroblasts causes
accumulation of matrix collagen fibers, glycoprotein fibronectin, type III collagen
replaced by type I collagen, formation of the fibrin clot and collagen-based scar [ 33 ].
Experiments have been indicating that ET can modulate this response, since ETperformed previous and after MI reduces the components of the ECM remodelling.
Bozi et al. [ 34 ], for instance, observed that 8 weeks of moderate ET previous to
experimental MI decreased collagen content in the heart of rats. In relation to post-
MI effects, Xu et al. [ 22 ] and Yengo et al. [ 35 ], showed that moderate ET performed
during 8 and 10 weeks, respectively, decrease the collagen volume and content in
the infarcted area. Moreover, further analyses of Xu et al. [ 22 ], evaluated non-
reducible collagen cross-linking (hydroxylysyl pyridinoline, HP) content - a marker
9 Myocardial Infarction and Exercise Training: Evidence from Basic Science