Abstract

Altitude training has become increasingly popular in recent decades. Its central and peripheral effects are well-described; however, few studies have analyzed the effects of intermittent hypobaric hypoxia (IHH) alone on skeletal muscle morphofunctionality. Here, we studied the effects of IHH on different myofiber morphofunctional parameters, investigating whether contractile activity is required to elicit hypoxia-induced adaptations in trained rats. Eighteen male Sprague-Dawley rats were trained 1 month and then divided into three groups: (1) rats in normobaria (trained normobaric inactive, TNI); (2) rats subjected daily to a 4-h exposure to hypobaric hypoxia equivalent to 4,000 m (trained hypobaric inactive, THI); and (3) rats subjected daily to a 4-h exposure to hypobaric hypoxia just before performing light exercise (trained hypobaric active, THA). After 2 weeks, the tibialis anterior muscle (TA) was excised. Muscle cross-sections were stained for: (1) succinate dehydrogenase to identify oxidative metabolism; (2) myosin-ATPase to identify slow- and fast-twitch fibers; and (3) endothelial-ATPase to stain capillaries. Fibers were classified as slow oxidative (SO), fast oxidative glycolytic (FOG), fast intermediate glycolytic (FIG) or fast glycolytic (FG) and the following parameters were measured: fiber cross-sectional area (FCSA), number of capillaries per fiber (NCF), NCF per 1,000 μm2 of FCSA (CCA), fiber and capillary density (FD and CD), and the ratio between CD and FD (C/F). THI rats did not exhibit significant changes in most of the parameters, while THA animals showed reduced fiber size. Compared to TNI rats, FOG fibers from the lateral/medial fields, as well as FIG and FG fibers from the lateral region, had smaller FCSA in THA rats. Moreover, THA rats had increased NCF in FG fibers from all fields, in medial and posterior FIG fibers and in posterior FOG fibers. All fiber types from the three analyzed regions (except the posterior FG fibers) displayed a significantly increased CCA ratio compared to TNI rats. Global capillarisation was also increased in lateral and medial fields. Our results show that IHH alone does not induce alterations in the TA muscle. The inclusion of exercise immediately after the tested hypoxic conditions is enough to trigger a morphofunctional response that improves muscle capillarisation.

Highlights

  • Intermittent exposure to hypoxia involves a wide range of physiological, pathophysiological and environmental conditions that induce an wide spectrum of physiological responses

  • The training was stopped and the animals were randomly distributed into three groups (n = 6 each): (1) trained animals maintained in normobaric conditions; (2) trained animals subjected to daily sessions of hypobaric hypoxia; and (3) trained animals subjected to daily sessions of hypobaric hypoxia immediately before a session of light aerobic exercise (LAE) on a treadmill

  • Myosin ATPase and succinate dehydrogenase (SDH) staining revealed changes in the fiber type distribution in the tibialis anterior (TA) medial and posterior fields of rats exposed to intermittent hypobaric hypoxia (IHH) (Figure 3)

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Summary

Introduction

Intermittent exposure to hypoxia involves a wide range of physiological, pathophysiological and environmental conditions that induce an wide spectrum of physiological responses. These range from harmful maladaptations that can elicit severe health outcomes, such as pulmonary hypertension or fibrosis (Dopp et al, 2007; Schiza et al, 2015), to beneficial adaptations such as improved aerobic capacity and erythropoiesis stimulation (Rodríguez et al, 1999; Navarrete-Opazo and Mitchell, 2014), as well as enhanced cardiac and heart mitochondrial function (Magalhães et al, 2013, 2014). We proposed that the effects of IHH strongly depend on the degree of contractile activity of the analyzed muscle: the more active the muscle, the stronger the IHH-induced effects

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