key: cord-0997570-iu9fx0r1
authors: Ferreira-Júnior, João B.; Freitas, Eduardo D. S.; Chaves, Suene F. N.
title: Corrigendum: Exercise: A Protective Measure or an “Open Window” for COVID-19? A Mini Review
date: 2020-08-14
journal: Front Sports Act Living
DOI: 10.3389/fspor.2020.00101
sha: b24c73c363ea5f16cbb46d9eb5ce386f44794df1
doc_id: 997570
cord_uid: iu9fx0r1

[This corrects the article DOI: 10.3389/fspor.2020.00061.].

In the original article, the reference for Chen et al. (2020) was incorrectly written as Chen, P., Mao, L., Nassis, G. P., Harmer, P., Ainsworth, B. E., and Li, F. (2020) . Wuhan coronavirus (2019-nCoV): the need to maintain regular physical activity while taking precautions. J. Sport Heal. Sci. 9, 103-104. doi: 10.1016/j.jshs.2020.02.001. It should be Chen, P., Mao, L., Nassis, G. P., Harmer, P., Ainsworth, B. E., and Li, F. (2020) . Coronavirus disease : The need to maintain regular physical activity while taking precautions. J. Sport Health. Sci. 9, 103-104. doi: 10.1016/j.jshs.2020.02.001.

In the original article (Flynn et al., 1999) was not cited or it was replaced by Fahlman et al. (2000) . The citation has now been inserted in the section Can Training Status Protect Against COVID-19 Infection?. Paragraph five should read:

The contradictions displayed across the studies discussed above may be related to differences in the immune response to training status (more trained vs. less trained individuals). Some studies have reported reductions in the lymphocyte proliferative response (Papa et al., 1989) and suppressed neutrophil function (Lewicki et al., 1988; Baj et al., 1994) , whereas other studies have shown no alteration in either lymphocyte or neutrophil status after a period of exercise (Tvede et al., 1991; Flynn et al., 1999; Ferrari et al., 2013) , or even increases (Brunelli et al., 2014) when comparing different training statuses.

In addition, the citation has now been inserted in the section Can an Acute Exercise Session Increase the Risks for Covid-19 Infection?

Paragraph two Several studies have investigated the effects of a single exercise session on immune function by measuring acute changes in various parameters (Flynn et al., 1999; Fahlman et al., 2000; Steensberg et al., 2001; Kakanis et al., 2010) . However, few studies have utilized resistance exercise protocols (Nieman et al., 1995; Flynn et al., 1999) or home-based exercises, those likely to be performed during the current pandemic which most likely consist of adapted forms of resistance exercise. Nieman et al. (1995) had participants perform multiple sets of squat exercise to failure at 65% of one-maximum repetition (1-RM) and observed conflicting results with leukocytes counts increasing immediately post-exercise and remaining elevated up to 2 h after, whereas lymphocytes number increased postexercise but decreased below baseline levels 2 h post-exercise. Nonetheless, it is important to note that Nieman et al. (1995) utilized a sample of 10 resistance trained individuals with a mean age of ∼25 years, however, COVID-19 is particularly dangerous to older individuals, which represents most of the COVID-19related deaths reported to date (Verity et al., 2020) . Therefore, it is important to consider the potential immunosuppressive effects of resistance exercise for elderly participants. In this regard, Flynn et al. (1999) investigated the acute effects of a resistance exercise session performed at 80% 1-RM on several immune function parameters in women aged 67 and 84 years and reported no suppression of immune function during the recovery period from the exercise bout. Finally, it is important to highlight that URTI incidences were not assessed in any of these studies.

The different results across these studies may be due to the variability in the immune system responses to an acute exercise session. Although a number of studies have observed an immunosuppressive response after prolonged and intense exercise bouts (Steensberg et al., 2001; Kakanis et al., 2010) , no changes in immune function have also been observed (Flynn et al., 1999) .

In the original article, there was an error. Incorrect references were cited.

A correction has been made to the section Can Training Status Protect Against Covid-19 Infection?, paragraph three:

On the other hand, other studies have shown no protective effects of exercise training programs on URTI incidences (Nieman et al., 1990; Kostka and Praczko, 2007; Kostka et al., 2008; Walsh et al., 2011) . To illustrate, a study with obese sedentary women who completed 15 weeks of endurance training (walking at 60% heart rate reserve), five times a week, reported no differences in the number of URTI in comparison to the untrained control subjects (Nieman et al., 1990) . However, the number of days with URTI symptoms was lower in the exercise group in comparison to the control group, which was confirmed by additional studies (Kostka and Praczko, 2007; Kostka et al., 2008; Walsh et al., 2011 ). An additional study did not find any relationship between perceived physical fitness levels and URTI incidences (Kostka et al., 2008) .

The authors apologize for these errors and state that this does not change the scientific conclusions of the article in any way. The original article has been updated.

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Copyright © 2020 Ferreira-Júnior, Freitas and Chaves. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.