key: cord-0998660-vd07ika1 authors: Hoseini, Rastegar title: How to Exercise During Coronavirus Quarantine? date: 2020 journal: Caspian J Intern Med DOI: 10.22088/cjim.11.0.479 sha: 8aeee7e89cb21e97e1d5ac863090fcf7b155d55b doc_id: 998660 cord_uid: vd07ika1 The COVID-19 pandemic caused stress and anxiety in many people that can be reduced by regular physical activity. Regular physical exercise is essential for health. In the absence of COVID-19 symptoms, no limitation in physical activity is recommended. However, parameters such as frequency, intensity, type, and time need to be considered to prescribe the program and obtain the best results. Consequently, the level of physical activity that should be done during the outbreak has always been one of the most important and common questions. T he Coronavirus disease (COVID-19) first spread in China. It has led to 962 thousand deaths and at least 31.1 million infections worldwide from December 2019 to 22 September 2020 (1) . Germany, Italy, France, Canada, the United States, as well as several Asian countries, have reported a high incidence ever since. Iran's government reported 425000 people infected, and 24478 died. COVID-19 infects a new person through their mouth, nose, or eyes after exposure to air or a surface contaminated by sneezing or coughing of a patient (2) . Governments have closed all sports and exercising centers to keep people safe from the coronavirus (3) . Although quarantine and socio-physical distancing effectively decelerate the spread of the virus, they may have negative psychological and physiological effects on most people in the community that lead to nonconformity of health protocols (4, 5) . Regular exercise and physical activity improve physical fitness, mental health (reduces depression, anxiety, and aggression) (6), reduces the incidence of chronic diseases (7), physical disabilities (8) , and enhances the immune system (8) . The ACSM has also recently identified physical activity as an effective factor in combating the complications and mortality of COVID-19 (4, 9) . However, studies show a decrease in the individual's physical activity level during the COVID-19 epidemic (10) . Due to the positive physiological-psychological effects, performing physical activity seems necessary in the quarantine in all uninfected individuals (11, 12) . However, these activities must be performed, considering a safe FITT (frequency, intensity, type, and time). The present study reviews the published studies from 2000 to 2020 on the immune system and published studies from 2019 to 2020 on COVID-19. To find the relevant articles, the keywords coronavirus, exercise, and immune system were searched in Google Scholar, PubMed, and Science Direct sites. For all individuals of any age, being physically active is essential to be healthy. For this purpose,150-300 minutes of aerobic training with moderate-intensity and two sessions of resistance training is recommended per week (13) . Frequency: Generally, 3 days per week for beginners and 3-5 days per week are recommended in this quarantine situation for athletes, regarding that volume and intensity must be adapted. The higher the intensity, the lower the frequency (10, 14) . Intensity: Exercise can be classified as low, moderate, and high based on its intensity. The exercise intensity is determined by evaluating blood lactate levels, the maximum oxygen consumption (VO2max), and the maximal heart rate (HRmax). In low or moderate intensities, the lactate production remains steady between 2 and 4 mmol/L) (15) . While studies commonly use a percentage of VO2max and HRmax to express intensity. Thus, 20 to 50% of the VO2max and the HRmax refers to mild, 50-70% shows moderate, and above 80% is known as intense (16, 17) . The acute effects of a moderate exercise session on immunology cells are well established (18) (19) (20) . Different types and intensity may affect the immunological system diversely. While intense exercise weakens the body's defense mechanisms, moderate-intensity exercise seems to improve them (20, 21) . Intense exercises lead to neutrophilia, lymphopenia, and monocytosis (22) . In comparison, moderate exercise mediates the redistribution of these cells in the vascular compartment by creating catecholamine's (mostly adrenaline) dose-response in individuals (23) . The breceptor's expression in the different immune cells (24) , the adrenergic receptor's density, and the efficiency of the AMPc transduction system may provide the molecular grounding for the action of lymphocyte and many other substances (25, 26) . By a decreasing order, the neutrophils, NK cells, TCD8+ lymphocytes, the B lymphocytes, and finally, the TCD4+ lymphocytes seem to present a more significant number of receptors (27, 28) . Intense exercise may induce the higher activity of the NK cells, the proliferative lymphocytic response, and the plasmacytic production of antibodies (29, 30) . These changes may weaken the immune system against infection, oncogenic agents, allergic processes, and autoimmunity (31, 32) . On the other hand, increased leukocytes function had been observed after moderate-intensity interventions. Many researchers verified improvements in the oxidative activity of the neutrophils, chemotaxis, phagocytosis, and degranulation one hour after a moderate-intensity (60% VO2max) exercise (33, 34) . Therefore, establishing a link between moderateintensity exercises and promoting the immunological system is plausible. It is generally assumed that intense training protocols (>75% of O2max) and exhaustive competitions higher the risks to acquire upper respiratory tract infection (URTI) (35) . Exaggerated production of ORS and an increase of oxidative stress in the tissues are the primary mechanisms by which high-intensity exercises suppress the immune system (36, 37) . Changes in the body temperature, cytokine concentrations, stress hormone level, dehydration, and increased blood flow are the likely mechanisms involved in immune system responses to moderate-intensity exercise (38, 39) . Overall, moderate-intensity predominates the Th1 cells in the immune response, thus promotes protection against infections (40) . Conversely, high-intensity prevails the Th2 pattern responses to decrease damage in muscular tissue, causing an increase in susceptibility to infections (41, 42) . Type of exercise: Compared to a sedentary lifestyle, being regularly active is known to boost the immune system (43) . The primary mechanism of aerobic exercises might be through changing antibodies and white blood cell levels in circulation and causing a brief rise in body temperature during and right after exercise that may help the body fight infection better similar to what happens in pyrexia. However, resistance exercise can reduce the chance of infection indirectly by slowing down the stress hormone secretion. Generally, some studies reported that aerobic training stimulates a proinflammatory response and decreases the risk of infection. Others noted that it might promote a decrease in these same parameters, increasing the risk of infectious diseases (44, 45) . The same contradictory results are present for resistance training, as well (43) . It seems that the differences in intensity may lead to conflicting results; Thus, the intensity is known to affect the immune cell responses rather than resistance or aerobic training (16, 17) . Time: Prolonged vigorous exercise elevates the serum cortisol level above the normal values (46) . The suppression of both NK and T-cell function and production during recovery after a prolonged exercise is known to be related to Glucocorticoid levels (47) . It causes lymphocytopenia, eosinopenia, and neutrophilia as well (38, 39) . The neutrophil/lymphocyte ratio, which is the indicator of systemic inflammation, rises sharply after heavy, prolonged exercise (48) . Generally, these shreds of evidence convey that prolonged endurance activities are associated with decreased host protection, immunosuppression and higher infection risk (49) . It is also believed that stressful physical exercise may lead to similar outcomes (50) . However, few convincing data are supporting the theory that elite endurance athletes have higher risks of infection. Further research is needed. Prescribing an Applicable and Practical Exercise program: Nevertheless, moderate (<60% VO2max, <60 minutes/bout) versus vigorous (>75% VO2max, >90 minutes) exercise reduces the stress hormone response and enhances the immune defense. Considering the convincing evidence, advising low to moderate intensity exercise with shorter duration is more prudential. The following is recommended accordingly; Indoor Activities  Walk briskly with music on around the house or climb the stairs for a total of 30-45 min per day (10-15 min, 2-3 sets)  Dance to a favorite music total of 15 min  Butterfly, scissors, squat, step-ups, planks, and jumping without a rope (if having healthy joints)  Participate in an online exercise workout  Exercise with a treadmill, rowing machine, spinning bike, step mill (If you have them at home)  Use strength workouts that need no equipment  Inspire from bodyweight training videos  Increase the resting period  Perform yoga with deep breathing  Perform meditation and mindfulness Outdoor Activities (if allowed by your government): However, outdoor activities are not recommended, keep staying 6 feet away from others while doing outdoor activities, not touching the face, and washing the hands and clothes when geting home:  Walking or jogging around  Spending time in nature may enhance immune function.  Riding bicycle in solitude  Tending the lawn and garden  Play active games with family A graphical abstract is also included below: The COVID-19 epidemic Coronavirus disease 2019 (COVID-19): What we need to know Characteristics of and important lessons from the coronavirus disease 2019 (COVID-19) outbreak in China: summary of a report of 72 314 cases from the Chinese Center for Disease Control and Prevention Should, and how can, exercise be done during a coronavirus outbreak? An interview with Dr The novel coronavirus originating in Wuhan, China: challenges for global health governance Role of physical activity and sedentary behavior in the mental health of preschoolers, children and adolescents: a systematic review and meta-analysis Vitamin D increases PPARγ expression and promotes beneficial effects of physical activity in metabolic syndrome Co-treatment of vitamin D supplementation and aerobic training improves memory deficit in ovariectomized rat Coronavirus disease (COVID-19): The need to maintain regular physical activity while taking precautions Quarantine during COVID-19 outbreak: changes in Diet and physical activity increase the risk of cardiovascular disease Co-treatment with Vitamin D Supplementation and Aerobic Training in Elderly Women with Vit D Deficiency and NAFLD: A Singleblind Controlled Trial Effects of post-exercise recovery interventions on physiological, psychological, and performance parameters Association between the metabolic syndrome indices with physical activities level and dietary pattern in elderly women Effect of the COVID-19 epidemic on physical activity in communitydwelling older adults in Japan: A cross-sectional online survey Acute cardiopulmonary responses to strength training, highintensity interval training and moderate-intensity continuous training The influence of physical activity in the anti-tumor immune response in experimental breast tumor Training strategies to maintain immunocompetence in athletes Overtraining effects on immunity and performance in athletes The overtraining syndrome in athletes: a stress-related disorder Regular exercise participation improves genomic stability in diabetic patients: an exploratory study to analyse telomere length and DNA damage What are the physiological mechanisms for post-exercise cold water immersion in the recovery from prolonged endurance and intermittent exercise How does the Immune response to exercise differ from the immune response to infection? how can this be applied while advising athletes regarding return to activity/competition? Adrenergic Regulation of macrophage-mediated innate/inflammatory responses in obesity and exercise in this condition: role of β2 Adrenergic receptors Health, pre-disease and critical transition to disease in the psychoimmune-neuroendocrine network: Are there distinct states in the progression from health to major depressive disorder? Exercise training-induced adaptations of immune response are mediated by β-adrenergic receptors in aged but not young mice Maximal exercise limitation in functionally overreached triathletes: role of cardiac adrenergic stimulation The role of the neuroendocrine and immune systems in the pathogenesis of depression Neuroendocrine and immune contributors to fatigue Neuroendocrine-immune interactions and responses to exercise Exercise immunology: neuroendocrine regulation of NK-cells Immune parameters in patients with anxiety or depression during psychotherapy The subacute effects of exercise: concept, characteristics, and clinical implications Effect of a moderate intensity exercise training protocol on the metabolism of macrophages and lymphocytes of tumour-bearing rats Resistance exercise attenuates skeletal muscle oxidative stress, systemic pro-inflammatory state, and cachexia in Walker-256 tumor-bearing rats Immune dysfunction and increased oxidative stress state in dietinduced obese mice are reverted by nutritional supplementation with monounsaturated and n-3 polyunsaturated fatty acids High Intensity exercise for walking competency in individuals with stroke: a systematic review and meta-analysis Cardiac oxidative stress following maternal separation stress was mitigated following adolescent voluntary exercise in adult male rat Immune response to exercise Expression of corticosteroid-regulated genes by PBMCs in children with asthma Immunomodulation from moderate exercise promotes control of experimental cutaneous leishmaniasis Effect of moderate exercise under hypoxia on Th1/Th2 cytokine balance Effects of exercise training and supplementation with selenium nanoparticle on T-helper 1 and 2 and cytokine levels in tumor tissue of mice bearing the 4 T1 mammary carcinoma Can exercise affect immune function to increase susceptibility to infection? Every exercise bout matters: linking systemic exercise responses to breast cancer control Exercise regulates breast cancer cell viability: systemic training adaptations versus acute exercise responses Effect of carbohydrate-electrolyte consumption on insulin, cortisol hormones and blood glucose after high-intensity exercise Immunotherapy for the adjunctive treatment of sepsis: from immunosuppression to immunostimulation. Time for a paradigm change? The stress response and immune system share, borrow, and reconfigure their physiological network elements: Evidence from the insects Immune activity, but not physiological stress, differs between the sexes during the nesting season in painted turtles Effects of psychosocial and physical stress on lactate and anxiety levels All of the authors wish to thank Professor Parvin Babaei in Cellular & Molecular Research Center, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran. The authors declare that they have no competing interests.