key: cord-0701463-5zdo4ad4 authors: Pérez-Gisbert, Laura; Torres-Sánchez, Irene; Ortiz-Rubio, Araceli; Calvache-Mateo, Andrés; López-López, Laura; Cabrera-Martos, Irene; Valenza, Marie Carmen title: Effects of the COVID-19 Pandemic on Physical Activity in Chronic Diseases: A Systematic Review and Meta-Analysis date: 2021-11-23 journal: Int J Environ Res Public Health DOI: 10.3390/ijerph182312278 sha: cbc84dc7fc880f7804defb24eee8751e529520c4 doc_id: 701463 cord_uid: 5zdo4ad4 The management of chronic diseases (CD) includes physical activity (PA). It is necessary to determine the effects of COVID-19 restrictions in CD. The aim was to review the research related to PA levels before and during the COVID-19 pandemic in people with CD. This review was designed according to PRISMA guidelines and registered in PROSPERO: CRD42020218825. The search was performed in CINAHL, Medline, Scopus, and Web of Science up to January 2021. The PICOS recommendations were applied. The search was conducted by two reviewers, who completed the data extraction of included articles. Methodological quality was assessed using the STROBE checklist, and a meta-analysis was conducted. The literature search strategy identified 227 articles. Five studies remained and were included. Only three studies were included in the meta-analysis. Two articles used accelerometers to objectively compare PA levels before and during the pandemic. Three studies made this comparison using an online survey. All articles showed a decrease in PA levels during the COVID-19 pandemic. The meta-analysis showed a significant reduction in PA levels during pandemic. PA levels during the COVID-19 pandemic have been reduced with respect to previous levels of PA in patients with CD. Coronavirus disease 2019 (COVID- 19) was declared a global pandemic on 11 March 2020 by the World Health Organization (WHO) [1] . Nowadays, there are 251 million cases worldwide and more than 5 million deaths. Unfortunately, these data increase every day. To prevent the spread of the virus, several countries imposed curfews, domiciliary confinement, or a limit or prohibition to go out or to participate in outdoor activities. Even if it is a priority to mitigate the immediate impact, there is great concern about the long-term effects of the pandemic [2] . These restrictions involve a compromise in health behaviors, specifically on physical activity (PA). This can be detrimental to all, but especially for people with chronic diseases because PA improves, in the long term, the prognosis of these diseases [1, 3] . Chronic diseases are defined by the WHO as long-lasting diseases, generally with slow progression [4] . These conditions are produced by a combination of environmental, behavioral, genetic, and physiological factors [5] . Chronic diseases are the main causes of disability and mortality globally and affect 5-8% of the population in developed countries [6, 7] . It has been estimated that 60% of deaths worldwide and 75% of public health expenditure are caused by chronic diseases [8, 9] . There are modifiable and non-modifiable risk factors for chronic diseases. Tobacco, unhealthy diet, and physical inactivity are the most important modifiable risk factors. Avoiding these risk factors is a critical part of treatment [4, 8, 10] . Studies retrieved during the searches were checked against the following inclusion criteria: (1) People with chronic diseases; (2) comparison of PA levels before and during the COVID-19 pandemic; (3) observational studies. Studies published before December 1, 2019, were excluded. Full texts in English, Spanish, or French were included. The search was conducted by two reviewers (L.P.-G. and I.T.-S.). We used a software package (Mendeley Desktop, London, UK) to standardize the references of identified articles and check the duplicates. The first screening was reading the titles and abstract of all articles retrieved. Then, reviewers had a meeting to resolve the disagreements, and after that, they carried out the second screening. In the second phase, the preliminary analysis of full texts of the selected articles was carried out. The results of the studies that met the selection criteria were screened for retrieval with their respective reasons for exclusion clearly stressed. These reasons for exclusion are shown in Appendix B. The following data were extracted from each study: in one table, the characteristic of the studies and the participants were included: (1) author and year [reference]; (2) study place; (3) design of the study; (4) disease (%); (5) sample size; (6) age; (7) gender (% males); (8) study period. In another table, the information of outcome measures of studies and the results were presented: (1) author and year [reference]; (2) method of PA assessment; (3) PA measuring instrument; (4) description of PA measuring instrument; (5) measured variable; (6) main results; (7) other outcome measures; (8) measuring instruments for other outcome measures. To obtain the missing information, we contacted authors via e-mail. Methodological quality was evaluated by the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) checklist [27] . After applying the checklist, we recorded the average compliance of all the articles. Furthermore, the compliance percentage of each parameter was calculated [28] . The STROBE checklist presents 22 items, so it was considered a 100% to check all the items [29] . When the number was below 60% of the maximum number of points, a low quality was defined. However, results up to and over 80% were considered high or very high quality, respectively [30] . Two independent researchers (L.P.-G. and M.C.V.) evaluated the included studies and met to compare and to discuss the results. Disagreements between the two researchers were settled by the third researcher (I.T.-S.). Following critical review of each study, a narrative synthesis was compiled. A metaanalysis was conducted with Review Manager (RevMan) 5 software [Computer program] (Version 5.3, The Nordic Cochrane Centre, Copenhagen, The Cochrane Collaboration, 2014) if at least two studies assessing this specific outcome were obtainable. In order to carry out the meta-analysis, we used mean and standard deviation (SD) or mean and confidence intervals (CI) in order to calculate SD from CI, and we also used the sample size. All results are presented as forest plots with 95% confidence intervals. The I 2 statistic was calculated to quantify the degree of heterogeneity between studies. The pooled effect measures were estimated based on a fixed effect model. The level of heterogeneity was classified as I 2 = 0-24%: low heterogeneity; I 2 = 25-49%: moderate heterogeneity; I 2 = 50-74%: substantial heterogeneity; and I 2 = 75-100%: considerable heterogeneity [31] . Funnel plots were not calculated due to the low number of studies included in the metaanalysis. According to Cochrane, a minimum of 10 studies are needed to calculate the general risk of bias. plots were not calculated due to the low number of studies included in the meta-analysis. According to Cochrane, a minimum of 10 studies are needed to calculate the general risk of bias. The search results and the finally included studies are shown in Figure 1 . In the initial search of the selected databases, 340 potential studies were identified. After removed duplicates, 227 studies remained. In the first screening, 202 were eliminated, leaving 25 studies for the second screening. Finally, five studies fulfilled the criteria for eligibility and were included in this systematic review. A total of three studies were included in metaanalysis. After searching for potential ongoing and unpublished studies, 19 were found; however none was eligible. The number of potentially relevant ongoing studies registered found in each database are shown in Figure 1 . The 19 registered entries were excluded after screening due to: one was not an observational study, two were not all adults with chronic diseases, nine did not compare PA levels before and during the pandemic, and seven were excluded for other reasons. After searching for potential ongoing and unpublished studies, 19 were found; however none was eligible. The number of potentially relevant ongoing studies registered found in each database are shown in Figure 1 . The 19 registered entries were excluded after screening due to: one was not an observational study, two were not all adults with chronic diseases, nine did not compare PA levels before and during the pandemic, and seven were excluded for other reasons. The characteristics of the included studies and the participants are shown in Table 1 . Studies were performed in Saudi Arabia [32] , Brazil [33] , Israel [1] , Spain [19] , and Republic of Macedonia [34] . A total of three of the studies were cross-sectional [1, 19, 34] and two longitudinal; one of them was prospective [33] , and the other was retrospective [32] . A total of 667 participants were enrolled in the included studies. The sample size varied from 35 to 315 participants across studies. Both genders were included in the studies and no exclusion was made by age. The characteristics related to outcome measures of included studies, as well as the main results, are shown in Table 2 . Two studies used objective instruments to evaluate PA: accelerometers. In one of the studies, patients received implantable cardioverter defibrillators or cardiac resynchronization therapy (ICD/CRT). These cardiac implantable electronic devices (CIEDs) with remote monitoring (RM) collect and store daily PA data through a built-in accelerometer [32] . The other study used the Actigraph GT3X [33] . Three studies used online questionnaires or survey created by the authors [1, 19, 34 ] to collect PA data; additionally, one study used a diary to complement the data obtained by an accelerometer [33] . PA was considered the main variable for each study and was evaluated in two moments: Prepandemic and during pandemic. In all of them, a decrease in PA levels was observed as a result of the COVID-19 pandemic. Al Fagih, A. et al. [32] , in their study, showed a decline in PA of 0.6 h/day (p = 0.000010). In the study of Browne R. et al. [33] , there was a reduction of 886 steps/day (p = 0.018), a reduction of 26.6 min/day of light PA (p = 0.053), and a reduction of 2.8 min/day of moderate-vigorous PA (p = 0.018). The magnitude of changes was greater on the weekend, mainly for steps/day and sedentary behavior. Moderate and vigorous PA also decreased significantly (p < 0.05) as a consequence of the pandemic in the study of López-Sánchez, G.F. et al. [19] . A decline of moderate PA was observed in the general sample of study, in males, in females, in patients aged between 18-44 years or between 55-64 years, for patients with multimorbidity, and patients diagnosed with asthma, hypercholesterolemia, chronic skin disease, or hemorrhoids. Furthermore, a reduction in vigorous PA was observed in males and patients with multimorbidity. Finally, in the study of Zorcec, T. et al. [34] , the number of patients performing more than two hours of PA per day decreased by 32% (p = 0.0001) and the number of patients performing few hours of PA per week increased by 18.8% (p = 0.0056). In the study by Elran-Barak, R. et al. [1] , the decrease of PA was higher in females. López-Sánchez, G.F. et al. [19] shared these same results for moderate intensity of PA; however, the decrease was higher in males for vigorous PA intensity. In the studies performed in Saudi Arabia [32] and Brazil [33] , results were not analyzed by gender, as well as in the study performed in Macedonia [34] , in which participants were children with a chronic disease. Three of the studies [1, 32, 33] showed significant differences for the decrease in PA levels before vs. during the COVID-19 pandemic in adults with chronic diseases. López-Sánchez, G.F. et al. [19] , in their study, also displayed a decrease in the PA levels grouped by age ranges. For vigorous PA, they showed no significant changes. However, for moderate PA, as age increased, the decrease in the min/day of PA increased, showing significant results. Finally, Zorcec, T. et al. [34] found a decrease in PA levels during the pandemic in children with chronic diseases. In order to collect data for other measures, all studies obtained information about the patients subjectively; patients had to fill out an online questionnaire. Besides, Al Fagih, A. et al. [32] , in their study, used Medtronic CareLink for the measure of Optivol fluid index and thoracic impedance of patients. The results of the quality assessment of observational studies using the STROBE checklist are summarized in Appendix C. The study by Al Fagih, A. et al. [32] reported 18/22 items of the STROBE, which resulted in a score of 82%. A score greater than 80% means that the study is of very high quality. The study by Browne, R. et al. [33] reported 19/22 items, therefore giving rise to a percentage equal to 86% (very high quality). The last study that also presented very high quality (82%) was the research performed by López-Sánchez, G.F. et al. [19] , which resulted in 18/22 items. Finally, the study by Zorcec, T. et al. [34] was considered weak (<60%), and the Elran-Barak, R. et al. [1] article was neutral, with 17/22 items (77%). The meta-analysis revealed the effects of pandemic on PA levels in patients with chronic diseases from prepandemic to during pandemic. Results of the meta-analysis are shown in Figure 2 . 18/22 items of the STROBE, which resulted in a score of 82%. A score greater than 80% means that the study is of very high quality. The study by Browne, R. et al. [33] reported 19/22 items, therefore giving rise to a percentage equal to 86% (very high quality). The last study that also presented very high quality (82%) was the research performed by López-Sánchez, G.F. et al. [19] , which resulted in 18/22 items. Finally, the study by Zorcec, T. et al. [34] was considered weak (<60%), and the Elran-Barak, R. et al. [1] article was neutral, with 17/22 items (77%). The meta-analysis revealed the effects of pandemic on PA levels in patients with chronic diseases from prepandemic to during pandemic. Results of the meta-analysis are shown in Figure 2 . Three studies which evaluated PA levels were included in the meta-analysis. One of them provided two datapoints of the same variable (moderate intensity shown in the figure of the meta-analysis, as López-Sánchez 2020a, and vigorous intensity shown in the figure of the meta-analysis, as López-Sánchez 2020b)). Both were included in the metaanalysis. One of the studies included in this systematic review which evaluates PA levels could not be included in the meta-analysis due to lack of data. The meta-analysis showed a significant reduction in PA levels during pandemic (StdMD = −0.29, 95% CI = −0.40 to −0.18, p < 0.00001). Data obtained in the meta-analysis on PA levels showed significant differences between the two moments (prepandemic and during pandemic) (p < 0.00001), I 2 = 13%; in the moment "during pandemic", patients presented lower physical activity levels compared with the moment "prepandemic". Three studies which evaluated PA levels were included in the meta-analysis. One of them provided two datapoints of the same variable (moderate intensity shown in the figure of the meta-analysis, as López-Sánchez 2020a, and vigorous intensity shown in the figure of the meta-analysis, as López-Sánchez 2020b)). Both were included in the meta-analysis. One of the studies included in this systematic review which evaluates PA levels could not be included in the meta-analysis due to lack of data. The meta-analysis showed a significant reduction in PA levels during pandemic (StdMD = −0.29, 95% CI = −0.40 to −0.18, p < 0.00001). Data obtained in the meta-analysis on PA levels showed significant differences between the two moments (prepandemic and during pandemic) (p < 0.00001), I 2 = 13%; in the moment "during pandemic", patients presented lower physical activity levels compared with the moment "prepandemic". The aim of this study was to systematically review the research related to PA levels before and during the COVID-19 pandemic in people with chronic diseases. The results of this systematic review suggest that the COVID-19 pandemic has had negative consequences for people with chronic diseases. During the COVID-19 pandemic, a decrease in PA levels compared to prepandemic levels has been found in all of the studies. The metaanalysis showed a significant reduction in physical activity levels during the pandemic (StdMD = −0.29, 95% CI = −0.40 to −0.18, p < 0.00001). There are different ways of evaluating PA: subjective, such as using questionnaires or diaries, and objective, such as using accelerometers or indirect calorimetry. In two of the studies included in our systematic review sample, the researchers used accelerometers for the objective measure of PA levels [32, 33] . Al Fagih, A. et al. [32] demonstrated, in their study, that the COVID-19 pandemic led to a decrease in levels of PA in patients with heart failure. Patients using CIEDs collected and stored daily PA data through a built-in accelerometer. Also using an accelerometer, Browne, R. et al. [33] reached the same conclusions in their study on hypertensive older adults. Three studies also showed a decrease in PA levels subjectively using online surveys as the main instrument for PA assessment in patients with different chronic diseases and children with chronic respiratory diseases [1, 19, 34] . Furthermore, some studies showed that the negative consequences of the COVID-19 pandemic were worse in certain circumstances. For example, the decline of PA is higher for women [1] . A lack of higher education, crowded housing conditions, longer illness duration, and loneliness make the impact worse [1] . Besides, the magnitude of changes was greater on the weekend [33] . During the pandemic, PA levels have not been the only factor affected as a consequence of COVID-19. Some studies included in our review showed an increase of sedentary behavior during the pandemic [33] , an increment in time spent on social media, a deterioration in mental health [34] and health behaviors such as vegetable consumption, and the feeling that in general, people were eating more [1] compared to prepandemic levels. In this line, other studies have also observed these consequences that the pandemic has had for people with chronic diseases. Prieto-Rodriguez, M. et al. [35] , in their study, showed the difficulty to maintain a healthy diet during confinement and an abandonment of selfcare habits. This makes the chronically ill one of the great populations harmed by the COVID-19 pandemic. To try to mitigate these unwanted physical and social confinement consequences, there are many studies that have given recommendations to follow after the pandemic. Altena et al. [36] showed the importance of performing regular PA, being active in daylight, not performing PA directly before sleep, and the importance of relaxation techniques during the confinement. Furthermore, Pietrobelli et al. [37] exhibited the possibility to access telemedicine lifestyle programs in the course of the pandemic. Recently, some reviews have also been carried out that provide important recommendations to carry out during confinement. Chevance et al. [38] defended the need for maintaining regular daily routines and to follow the recommendations of the WHO. Narici et al. [39] exposed the importance of performing low-to medium-intensity resistance exercises, to undertake exercise routines and daily exercise, and try to take 5000 steps per day. To end, Marçal, I. et al. [40] advised of the importance of carrying out a well-structured PA program (aerobic and/or resistance exercise programs) and healthy nutritional behavior in patients with chronic diseases during the COVID-19 pandemic. Now, after confinement, that the majority of the negative effects that the COVID-19 pandemic has brought are being known, it is necessary to follow these recommendations and stay active. Some reviews have also studied the negative effect of the COVID-19 pandemic in PA, but in the general population [41, 42] . Their results are in line with the results obtained in this review. Stavridou, A. et al. [41] proved a reduction in PA levels in the general public as a consequence of social distancing and isolation. Moreover, they also found a reaction of anguish, irritability, hopelessness, loss of pleasure from activities, and an increase in telephone use. Bentlage, E. et al. [42] expressed their concern about the decrease in the volumes of habitual PA, the increase in sedentary behavior, the increase in the mortality rate, and a worse physical and health condition in general as a consequence of COVID-19. These results show that the pandemic has generated similar consequences in chronic disease patients and also in the general population. This systematic review and meta-analysis will contribute to the literature by providing evidence of the negative impacts that the COVID-19 pandemic has had in PA level on chronically ill patients. It is of great relevance for clinical practice to provide critical information and training to patients with chronic diseases. Recommended PA should be used as a strategy to mitigate the negative consequences of the pandemic. One of the strengths of this review is the novelty, importance, and timeliness of the topic. To the authors' knowledge, this is the first systematic review to provide information on the impact of the COVID-19 pandemic on PA levels compared to prepandemic PA levels in chronic diseases. In addition, our review meets the criteria of the PRISMA guidelines and does not include gray literature. There are also some limitations in this review that should be considered. The authors of three studies in this systematic review used subjective online surveys as their main instrument for measuring PA and used a peculiar cross-sectional design. This is a limitation, but they also have the advantage of showing how the patient feels about the consequences of the restrictions imposed. People with low income, low status, or elderly people do not usually have access to these technological devices, so their ability to participate is limited. Furthermore, although the participants responded within a few days of being surveyed, the existence of a recall bias cannot be ruled out. One of the articles presented low methodological quality. Only three studies were included in the meta-analysis, so the results should be interpreted with caution. According to the Cochrane Handbook [43] , a meta-analysis can be carried out based on two studies. The studies of Ndwiga, D. et al. [44] and Hedlund, C. et al. [45] are an example of this. Additionally, we have to mention that this topic is very current and new and is restricted to an exceptional period of restrictions that we expect not to be repeated, so there is not much published yet, and the publication of new studies regarding this topic may be limited. The studies included in this systematic review reveal that PA levels during the COVID-19 pandemic have been reduced with respect to previous levels of PA in patients with chronic diseases. The meta-analysis confirms a significant reduction in PA levels during the pandemic. Furthermore, according to gender, two studies agree that this decrease in PA levels is higher in females for moderate PA. Finally, depending on age, the different studies showed that regardless of the age, all patients have experienced a decrease in PA levels as a consequence of the restrictions imposed during the COVID-19 pandemic. Future research may emerge from this systematic review. First, future studies could investigate if the decrease in PA levels during the COVID-19 pandemic varies depending on the different characteristics of the patients. Second, this negative impact of the COVID-19 pandemic should be taken into account to develop rehabilitation programs that mitigate the negative consequences on PA levels. ("Exercise"[Mesh] OR Exercise* OR "Physical Activit*" OR "Physical Exercise*" OR "Acute Exercise*" OR "Isometric Exercise*" OR "Aerobic Exercise*" OR "Exercise Training*" OR "Activity level*" OR "Physical fitness") TITLE-ABS-KEY (Exercise* OR "Physical Activit*" OR "Physical Exercise*" OR "Acute Exercise*" OR "Isometric Exercise*" OR "Aerobic Exercise*" OR "Exercise Training*" OR "Activity level*" OR "Physical fitness") Elran-Barak, R. et al. Zorcec, T. et al. (2020) [31] V V V X V V X X X X X X X V V X V V X V X X 10 45 Letter code: V: Reported on the article; X: Not reported on the article. 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