key: cord-1012148-tzj2ft8i authors: Yu, Wanqi; Rohli, Kristen E.; Yang, Shujuan; Jia, Peng title: Impact of obesity on COVID-19 patients date: 2020-11-26 journal: J Diabetes Complications DOI: 10.1016/j.jdiacomp.2020.107817 sha: 4eb4bb54c83f0e95acd728e7cbc5ec1776c83915 doc_id: 1012148 cord_uid: tzj2ft8i With the increasing prevalence of obesity, there is a growing awareness of its impact on infectious diseases. In past epidemics of influenza A and Middle East respiratory syndrome (MERS) coronavirus, obesity has been identified as a risk factor influencing the severity of illness in infected persons. The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is responsible for a large number of deaths and health damages worldwide. Increasing numbers of reports have linked obesity to more severe COVID-19 disease and death. This review focuses on the impact of obesity on patients with COVID-19. We comprehensively analyzed the various mechanisms of obesity affecting the severity of the disease. In addition, on the basis of the vulnerability of people with obesity during the COVID-19 epidemic, we summarized both individual-level and hospital-level prevention and management measures for COVID-19 patients with obesity and discussed the impact of isolation on people with obesity. Such disproportionate burdens may also exist among patients infected by the coronavirus disease 2019 (COVID-19), which have resulted in 39.5 million infections including 1.1 million deaths worldwide as of October 17, 2020, also causing massive damage to the global economy, education, and medical treatment. Although few systematic reviews have been conducted between COVID-19 and obesity, a meta-analysis of obesity and influenza-related pneumonia 11 showed that, compared with people with a normal BMI, the risk of pneumonia among individuals with obesity (BMI ≥30 kg/m 2 ) was increased 1.33 times (95% CI: 1.05-1.63), and 4.6 times (95% CI: 2.2-9.8) among individuals with morbid obesity (BMI ≥40 kg/m 2 ) . Interestingly, the adult respiratory distress syndrome (ARDS) caused by severe lung infection has a high fatality rate, whereas patients with ARDS combined with obesity or morbid obesity have a lower mortality rate 12 . This paradox may be due to the fact that obesity-triggered low-grade inflammatory processes may constitute pre-conditioning insults or trigger anti-inflammatory adaptive mechanisms, thus providing a protective effect on ARDS 13 . More research is needed to confirm this mechanism. We should also consider whether there is such a paradox in the impact of obesity on COVID-19. A growing number of studies have tried to link obesity to COVID-19 severity and/or death [14] [15] [16] . For example, preliminary epidemiological data from the US Centers for Disease Control and Prevention showed that among COVID-19 patients with obesity, 69% had a body mass index (BMI) between 30-40 kg/m 2 , and 30.1% had severe obesity (BMI ≥40 kg/m 2 ) 17 . Also, the obesity rate after sex and age standardization among 340 severe COVID-19 patients in France was significantly higher than that among the general French adult population 18 . However, there have not been any comprehensive reviews on this association, which deserves to be systematically studied. This systematic review summarizes the epidemiological characteristics of (hospitalized or diagnosed) COVID-19 patients with obesity, where obesity is defined by the local BMI classification criteria. Then, the impact of obesity on the severity of COVID-19 in existing research is synthesized (Table 1) , with various mechanisms by which obesity may aggravate COVID-19 summarized. In addition, on the basis of the vulnerability of people with obesity during the COVID-19 epidemic, we summarize both individual-level and hospital-level management measures for COVID-19 patients with obesity. We also reviewed the impact of isolation on people with obesity and suggest additional prevention measures for this population. A comprehensive literature review was conducted in the PubMed bibliography databases on October 1, 2020. We searched titles or abstracts including any combination of the keywords in two groups: 1) "COVID-19", "COVID19", "coronavirus disease 2019", "2019 novel coronavirus disease", "2019-nCoV", "severe acute respiratory syndrome coronavirus 2", "SARS-CoV-2", and "SARS2"; and 2) "obesity", "overweight", "obese", "adiposity", "body mass index", "BMI", and "weight gain". Titles and abstracts of the articles identified through the keyword search were independently screened by two reviewers against the study selection criteria: 1) study design: observational studies including cross-sectional and longitudinal studies; 2) study subject: COVID-19 patients with overweight or obesity, excluding pregnant women and children; 3) study outcome: COVID-19 severity, including hospital stays, IMV needing, ICU admission, death of COVID-19 patients; 4) article type: peer-reviewed publications that are not letters, comments, editorials, study/review protocols, review articles, animal studies, mechanistic studies, or case reports; and 5) language: English. Potentially relevant articles were retrieved for an evaluation of the full text by two independent reviewers with discrepancies resolved by a third reviewer. A total of 64 articles were finally included in this review after the whole filtering process (Figure 1) . The basic characteristics of the 64 included studies, including the prevalence of obesity and obesity-related COVID-19 progression, were summarized ( Table 1) . Age is one of the most important factors in the hospitalization rate of COVID-19, with about 70% of the hospitalized cases aged over 45 19, 20 . Obesity, as the most common underlying condition for patients with COVID-19 aged under 64 years old, 17 could shift the COVID-19 risk to younger ages 19, 20 . Obesity can also increase the risk factors for these diseases and lead to unfavorable consequences. The clinical spectrum of COVID-19 is very broad, and the common symptoms of most patients with COVID-19 are non-specific, including fever (98%), cough (76%), and myalgia or fatigue (44%) 21 . For patients with comorbidities, COVID-19 may bring about acute respiratory illnesses, respiratory failure, and septic shock, and in the most severe cases, ARDS 22 . By studying the relationship between the severity of COVID-19 and obesity, we can deploy medical resources in the most cost-effective manner to prevent health systems from overloading and focus on the most fragile cohort of patients during all phases of the disease 23 . The recovery of patients with COVID-19 represents the gradual regression of clinical symptoms and signs of the body. The time taken for recovery is not only closely related to the severity of COVID-19 24 but also influences the spread of the virus and the additional economic burden 25 , in which obesity may play a role. In a small sample (n = 34) study 26 in Israel, the researchers used negative results from two of three genes (envelope protein gene (E), RNA-dependent RNA polymerase gene (RdRP), and nucleocapsid (N) gene) measured by RT-PCR as criteria for patient recovery. Patients with obesity had a higher mean length of hospital stay than patients without obesity (20.6 vs 16.0 days), suggesting that the recovery time of COVID-19 patients with obesity may be different from that of normal-weight patients, with longer discharge time. It also proves from another perspective that patients with obesity have a higher viral load and a slower antiviral response, thus affecting the disease progression of COVID-19 26 . Stronger evidence came from a paired cohort study in Wenzhou, China. In a group of 75 randomly matched patients by age and sex, the analysis found that patients with obesity had significantly longer hospital stays (23 vs 18 days, p=0.037) and a higher proportion of severe COVID-19 (33.3% vs. 14.7%, p=0.007) than patients without obesity, with a clear dose-effect 27 . The extension was even more pronounced in another study in Italy (21±8 vs 13±8 days, p=0.0008) 28 . The ICU is a special department that provides intensive treatment medicine in hospitals or health care institutions. Most of the patients treated in ICUs are experiencing or recovering from life-threatening situations. BMI of patients with COVID-19 was significantly correlated with ICU treatment 29, 30 . A study in Hubei Province of China (n=323) showed that patients with a BMI >25 kg/m 2 accounted for 22.1% of 172 severe and critically ill COVID-19 patients 31 . Some scholars have suggested that the high obesity rates among intensive care patients infected with SARS-CoV-2 may depend on the local obesity rate 32 . However, in a series of 3,615 patients with COVID-19 from New York, US, those under 60 years of age with a BMI ranging from 30 to 34 kg/m 2 had a 1.8-fold increase in the probability of ICU admission compared to patients with a BMI <30 kg/m 2 . This likelihood increased to 3.6-fold among patients with a BMI ≥35 kg/m 2.33 . Moreover, COVID-19 patients in ICUs had higher BMI than non-ICU patients (BMI, median 30.5 kg/m 2 vs 28.77 kg/m 2 ). Interestingly, among the published proportion of patients admitted to the ICU during hospitalization in various countries, the proportion of patients transferred to the ICU in countries with high obesity rates, such as the United States (39.8%) 34 and Italy (19%) 35 , was significantly higher than that in China (5.4%, non-Hubei region) 36 and South Korea (13.3%) 37 , which have low obesity rates. Considering that this may be due to differences in health technology and varying degrees of aging, we need to attach significance to the role of obesity in the severe forms of COVID-19. This is probably caused by chronic diseases associated with obesity. Among 1,591 patients treated in the ICU for COVID-19 patients in Lombardy, Italy, 68% (95% CI, 65%-71%) of the patients had at least one comorbidity, including hypertension (49%), cardiovascular diseases (21%), hypercholesterolemia (18%), and diabetes (17%) 38 , all of which have been linked to obesity in previous studies 39-41 . IMV is a means of life support, which is usually reserved as the last option for chronic obstructive pulmonary disease (COPD), which represents that patient's condition has entered a serious stage 42 . There has been a significant association between obesity and IMV 43, 44 . For example, among 393 patients in New York City, patients who received IMV had a higher obesity rate than those who did not (43.4% vs 31.9%) 45 . Likewise, in a retrospective cohort study in France, 124 patients with severe COVID-19 were analyzed, and IMV was used as a criterion to determine the severity of the disease. The results showed that the requirement of IMV significantly correlated with BMI (p<0.05); the proportion of patients who required IMV increased with BMI categories (p<0.01, chi-square test), and it was the greatest among patients with a BMI >35 kg/m 2 (85.7%). Additionally, BMI >35 kg/m 2 can increase the risk of IMV 7-fold and is associated with lower survival rates 43 . The same results were found in Ong's 44 , and Palaiodimos's 46 studies. These studies demonstrated that obesity increases the risk of IMV among patients with COVID-19. Obesity has also been associated with an increased risk of death in hospitalized patients with COVID-19 47, 48 . In a cohort study in the Bronx, New York, it was found that severe obesity was independently associated with higher inpatient mortality and overall poor inpatient outcomes 46 . Similarly, a study in Milan, Italy found that 48 out of 233 hospitalized patients with COVID-19 who died had a significantly higher prevalence of obesity than those who survived (27.1% vs 13.5%, p=0.029) 47 . In addition, obesity has also been increasingly common even in persons younger than 50 years old relative to other known risk factors (e.g., hypertension, cardiovascular, Type 2 diabetes), and this high prevalence predicted a shift in severe COVID-19 disease, such as the risk of death, to younger populations 19 . A retrospective study in New York that included 3,406 hospitalized patients with COVID-19 found that younger patients with a BMI over 40 kg/m 2 were 5 times more likely to die 49 . Obesity has also been associated with other COVID-19 severity outcomes [50] [51] [52] [53] . For example, among 212,802 patients diagnosed with COVID-19 in Mexico, obesity increased the J o u r n a l P r e -p r o o f risk of hospital admission by 1.29-fold (p<0.001) 54 . The BMI of patients with COVID-19 and pneumonia, a localized inflammation of the lungs, was significantly higher than those without pneumonia (23.81 vs 20.78 kg/m 2 , p=0.001) 55 . Also, obesity increased the risk of pneumonia by 1.327-fold (p=0.024) 53 . ARDS leads to acute diffuse lung injury and subsequent acute respiratory failure, characterized by respiratory distress and hypoxemia, and is almost one of the most severe consequences of COVID-19.The results of this study showed that the incidence of ARDS is significantly higher in the group with obesity compared to the lean group (5.00% vs 0%, p=0.024) 56 . The above content systematically summarizes the impact of obesity on the severity of COVID-19. Although most studies employed multivariate analysis to adjust the impact of obesity-related diseases (i.e., diabetes, hypertension and CVD) on the severity of COVID-19, making the role of obesity independent, we should not neglect the equal importance impact of obesity-related diseases due to the long-term accumulating effects on patients' physiology and psychology 57 . Among the 44,672 confirmed COVID-19 cases in China, the case fatality rate (CFR) was 2.3%, and 7.3% of the deaths (1,023) were patients with diabetes, 10.5% were patients with cardiovascular disease, and 6.0% were patients with hypertension 58 . This suggests that we should give attention not only to the obesity, but also to the impact of obesity-related diseases on COVID-19. Obesity would likely increase the severity of COVID-19 since SARS-CoV-2 is transmitted by droplets or contact. The first line of defense (skin and nasal mucosa) and the second line of defense (bactericidal substances and phagocytes) of an immunocompromised individual cannot prevent and destroy the virus, which enters the lungs through the respiratory tract. Spike protein binds to the angiotensin-converting enzyme 2 (ACE2) receptor on lung cells to enter the cell, where it replicates, assembles, and releases a large number of viruses (Figure 2 ). After the virus is phagocytized by alveolar epithelial macrophages, the target cells are lysed and killed by immune T cells through cellular immunity, and a large number of cytokines and complements are released. This autoinflammatory response leads to the destruction of lung cells, preventing the pulmonary alveoli from carrying out the normal blood oxygen exchange, inducing a series of clinical symptoms in patients. A large release of cytokines may lead to cytokine storms, and an excessive immune response may lead to a rapid decline in lung function, respiratory failure, viremia, ARDS and even multiple organ dysfunction syndrome (MODS). Obesity has detrimental effects on respiratory mechanics, the respiratory drive, and the physiology and anatomy of the upper respiratory function, directly affecting the respiratory function of patients with obesity 59 . Obesity leads to increased airway resistance, decreased respiratory muscle, reduced lung volume, and impaired gas exchange in patients. However, since SARS-CoV-2 is a virus that mainly attacks the respiratory system, patients' obesity status will further impair their respiratory function during an infection of COVID-19 and may even put them at risk of pulmonary complications 60 , leading to a poor prognosis 61 . Obesity is highly associated with obstructive sleep apnea (OSA) 62 , which can lead to repeated airway obstruction in patients with COVID-19, worsening pro-inflammatory processes in the lungs 63 . The negative effect of obesity on respiratory function may account for the higher risk of respiratory failure and necessity for mechanical ventilation in patients that have comorbid obesity with COVID-19 64-67 . Previous studies have found that obesity is a risk factor for admission to the hospital for H1N1 influenza A 4 and other respiratory infections 68 . This may be due to the fact that the baseline inflammatory state of obesity weakens the immune system's response to the virus, including systemic changes in the innate and adaptive responses, showing a delayed and sluggish antiviral response to viral infection 69 . Patients with obesity have chronically high levels of leptin and low levels of adiponectin. This adverse hormonal state can also lead to a maladjusted immune response 70 . Obesity makes individuals more susceptible to viral infection, increasing the exposure of the virus and the long-term infection of hosts with obesity. Obesity also affected influenza virus clearance. Compared to adults of normal weight, the amount of RNA shedding and the duration of positive samples of the H1N1 virus were increased in adults with obesity 5 . Obesity has also been shown to have a substantial impact on the immunity and pathogen defense, including the disruption of lymphoid tissue integrity and alterations in leukocyte development, phenotypes, and activity 71 . In a prospective observational study of the trivalent inactivated influenza vaccine (IIV3) in adults, the results have shown that the initial serum conversion rates are higher in people with obesity, but the vaccine efficacy declines more over time than in people without obesity 72 . This decline of vaccine efficacy may be due to the fact that overweight and obesity impairs vaccine response to pathogens. The immune-induced response of both obese adults and children is diminished 73 , and the vaccine-specific T cell responses of adults with obesity is weakened and impaired 74 , where T cells are necessary for the protection and recovery of viral infection. Cytokine storm is an important cause of death among COVID-19 patients 75 . It represents a phenomenon of immune hyperactivation and is characterized by increased levels of IL-6, interferon (IFN)-γ, and other cytokines, causing consequences and symptoms related to immune activation. Although some studies have found that higher levels of proinflammatory cytokines in severe COVID-19 reflect an increased viral burden rather than an inappropriate host response that needs to be corrected 76 , inflammatory cytokines (IL-1β, IL-1RA, IL-6, IL-8, IL-18, and TNF-α) associated with cytokine storm are no different than those associated with severe ARDS or sepsis 77 . But the pro-inflammatory environment of individuals with obesity may further exacerbate inflammation, exposing them to even higher levels of circulating inflammatory molecules 78 . Dysregulated immune and other inflammation-related responses of obesity patients may aggravate the cytokine storm and allow increased viral spread and extended infections, which accelerate the severity of COVID-19 in patients with obesity. Individuals with obesity have a low level of systemic chronic inflammation, and the TNF-α, IL-6, or c-reactive protein (CRP) is higher, increasing the circulating level of pro-inflammatory cytokines 61 . Clinical biochemical studies of COVID-19 metabolic obesity patients also found that IL-6 was significantly increased, and CRP was positively correlated with waist-to-hip ratio (WHR) 79 . Excess fat is also associated with over-activation of the complement system, which is an important host mediator of virus-induced diseases and exacerbates inflammation 80 . Furthermore, the prevalence of vitamin D deficiency is higher among people with obesity. Vitamin D, which in detriment has been linked to various inflammations, infections, and lung diseases, can also increase the risk of systemic infections J o u r n a l P r e -p r o o f and damage the immune response. Together, they may make obesity a risk factor for "cytokine storms". There is no specific medicine to prevent SARS-CoV-2 infection and cytokine storm caused by the virus 81 . Once the cytokine storm occurs, it is difficult for clinicians to reverse the adverse outcomes of patients. In addition to the exploration and research of drug therapy and new drugs, more attention should be given to warn patients of cytokine storms to achieve early detection and treatment, if necessary. It is of significance to suppress inflammatory response and support treatment. The changes of pulmonary imaging, respiratory function and laboratory indicators should be closely monitored, and once a patient's indicators fluctuate, they should be immediately transferred to the intensive care unit to suppress cytokine storm and prevent further intensification via medication and oxygen therapy 82 . The causes of variation in the inflammatory response in SARS-CoV-2 are unknown, but adipose tissue could contribute to this variation. Adipocytes, obesity-induced related inflammation, and immune system impairment may play an important role in infection by SARS-CoV-2 83 . Adipose tissue is among the tissues with the highest expression of the ACE2 receptor that binds the virus 84 and surrounds the heart and the connected vessels, opening the possibility that adipose tissue acts as a reservoir for the virus. In the COVID-19 infection, ACE2 is a binding receptor of the novel coronavirus. Since SARS-CoV-2 enters the host cells through (ACE2) receptors after the spike protein is activated by host cell protease, the cells and tissues expressing ACE2 are potential targets of SARS-CoV-2. Tissue analysis showed that the ACE2 expression in adipose tissue is higher than that in lungs, suggesting that people with obesity are more susceptible to the novel coronavirus 85 . In addition, chronic activation of renin-angiotensin-aldosterone system (RAAS) in patients with obesity is conducive to the high expression of ACE-2 and the low availability of angiotensin 1-7, which reduces the antiviral immunity and increases the susceptibility to SARS-CoV-2 86 . However, no study has been conducted to elucidate the relationship between SARS-CoV-2 and adipose tissue, or the incidence of COVID-19 and obesity, which needs to be further verified by clinical studies. Individuals with obesity are rich in epicardial adipose tissue (EAT), which can affect the cardiac function in patients with COVID-19 at an early stage. Moreover, EAT is a rich source of adipokines, including various pro-inflammatory mediators that contribute to inflammatory cytokine storms 87 . Obesity poses challenges to the patient's diagnosis and treatment, such as poor quality of diagnostic imaging, difficulties in airway management, and unresponsiveness to prone positioning 88 . Targeted therapies with specific drugs and vaccines still need time to be developed, so we should focus on prevention for people with obesity. The general preventive measures for COVID-19 should follow the national or local prevention and control guidelines for hand hygiene, wearing protective equipment, reducing contact, and avoiding non-essential travel to major affected areas. Surveillance and control of co-existing chronic diseases need to be J o u r n a l P r e -p r o o f strengthened. For example, patients with diabetes and hypertension need to monitor their blood sugar and blood pressure more frequently 89 . The European Association for the Study of Obesity advises people with obesity to pay attention to energy intake (e.g., protein nutrients), energy expenditure (e.g., moderate physical activity and exercise in non-crowded areas during the period of quarantine), sleep (e.g., sleep duration and quality), and mental health and resilience (e.g., healthy mental conditions) 90 . Patients with delayed bariatric outpatient follow-up appointments and bariatric surgery should adopt a healthier lifestyle during the epidemic; online weight management programs, evaluation of postoperative complications, and monitoring of weight loss response are also recommended 91 . Obesity increases the risk of severe COVID-19 progression, so we need to pay more attention to infection monitoring and clinical treatment in COVID-19 patients with obesity. Patients with obesity who have been exposed to COVID-19 patients or high-risk areas for COVID-19 infection, especially those who have subsequently developed suspected symptoms for COVID-19 (e.g., cold, coughing, runny nose, fever), should go to a medical institution for virus testing as soon as possible 92 ; those having mild symptoms can be consulted at home through telemedicine and should be self-isolated for 14 days after their symptoms disappear. COVID-19 patients with obesity aged over 60 should be referred to a hospital as soon as possible. Patients with other basic or chronic diseases (e.g., diabetes, hypertension, heart diseases) should seek medical attention urgently. During the treatment, they should continue to strictly comply with appropriate control of blood glucose, blood pressure, and blood lipids; appropriate hypoglycemic, hypotensive, and lipid-lowering regiments should be continued during the treatment 93 . Inflammatory response indicators (IL-6, TNF-α, CRP) and immune response indicators (immunoglobulin, CD4+, CD8+) should be monitored during treatment to prevent "cytokine storms" in a timely manner. When treating individuals with obesity, the feasibility of operations and appropriate tools should be considered in advance to avoid delay in treatment. We also suggest that everyone should control their weight gain during the epidemic period of COVID-19, so as to avoid the development of obese patients, thus increasing the risk of infection and progression to severe stage of COVID-19. At present , many countries and regions around the world adopted lockdown and school suspension measures to reduce the spread of the virus and recommended social isolation to reduce the risk of infection. Knowing that summer vacation may be a risk factor for students' weight gain 94 , we suspect that isolation during the outbreak may enhance the risk factors for obesity and weight gain. Studies have estimated that the prevalence of COVID-19 may double the number of out-of-school hours for children in the US 95 , and that prolonged isolation at home may lead to changes in personal lifestyles, sleep patterns, commuting style and psychological state, thereby indirectly affecting weight change. A recent study showed that adolescents with obesity tended to display unfavorable lifestyle changes during isolation, including unsafe, hyper-processed, high-calorie diets, and decreased exercise time, increased screen time and an increased amount of sleep 96 . These have been linked to obesity or weight gain in previous studies [97] [98] [99] . Furthermore, active commuting, including public transportation, walking, and cycling, was significantly associated with decreased BMI and body fat percentages among men and women 100 . A study in Hubei province, China, found that isolation and the rapid spread of SARS-CoV-2 led participants to exhibit higher levels of anxiety, depression, and J o u r n a l P r e -p r o o f lower levels of mental health 101 , and other mediating factors, such as diet and amount of sleep, that influence weight change 102, 103 . Rumors and information overload increase stress, which can also affect weight through biological behavioral and psychological mechanisms 104 . The COVID-19 pandemic is characterized by a high incidence of severe and acute organ damage, especially the lungs with SARS, but also acute cardiovascular events, in association with a pro-inflammatory cytokine-related storm. Such severe acute events are particularly prevalent among aged individuals and patients with co-morbidities such as obesity, hypertension, and Type 2 diabetes which have emerged as major contributors to the severity of symptoms and organ failure, whilst the current studies report a lower prevalence of severe COVID-19 infection among smokers and people with chronic lung diseases. These observations suggest the importance of the "metabolic disease exposome" 105 , including dietary lifestyle, glycaemic disorders, obesity, and sedentariness, among other potential disease severity modifiers, such as systemic hypertension and aging, leading to chronic low-grade inflammation, which may aggravate COVID-19-induced acute organ failure. Therefore, it is essential to precisely identify the factors underlying the severity and the clinical presentation of the disease, especially when considering the risk of a second wave of COVID-19 106 . Obesity is a risk factor for severe forms of COVID-19, through physiological, biochemical, immune, and anatomical mechanisms. Indeed, many countries worldwide are currently under lockdown to curb the dramatic increase in the number of patients in critical conditions. Staying at home during the COVID-19 pandemic also mediates changes in lifestyles and sleep patterns that increase the risk of obesity. Thus, the identification of optimal strategies to manage the health crisis after the lockdown is of critical importance for the decision makers on the management of the COVID-19 health crisis. One of those strategies would be the identification of vulnerable subjects in order to adapt social distancing strategies, using a personalized approach targeting this population at risk. Based on the characteristics of people with obesity, we suggest that individuals with obesity should not only follow the general preventive measures and health guidance but should also pay more attention to the control of other underlying diseases. Patients should seek the help of medical staff as soon as possible after being infected with the virus. The treatment of basic diseases should be considered in the treatment process, and the condition indicators should be closely monitored to alleviate the prognosis. In addition, we also recommend the use of telemedicine for obesity training and education. Some limitations in this review should also be mentioned, so future efforts could be built upon it. We covered several related themes and used a variety of indicators (e.g., recovery time, ICU admission, IMV necessity, death) to systematically examine the additional burden of obesity on patients with COVID-19, the impact of COVID-19 infection on which are difficult to be compared and quantified. Therefore, we could not conduct a series of meta-analyses of high quality to accompany this systematic review. Also, to include more national and regional studies to make this review more informative and convincing, we did not adopt a uniform criterion for obesity (e.g., BMI cutoff values) to filter the literature. Stratifying the included studies by different criteria of obesity is also expected to be realized in future as the number of studies is increasing. Determining the association between obesity and COVID-19 will require large, national or international, retrospective medical studies and autopsy studies. In the follow-up clinical treatment, it is important to measure and collect the parameters of human obesity, including The state of food security and nutrition in the world European guidelines on cardiovascular disease prevention in clinical practice. The Sixth Joint Task Force of the European Society of Cardiology and Other Societies on Cardiovascular Disease Prevention in Clinical Practice (constituted by representatives of 10 societies and by invited experts Body fat, metabolic syndrome and hyperglycemia in South Asians A novel risk factor for a novel virus: obesity and 2009 pandemic influenza A (H1N1) Prevalence of Diabetes in the 2009 Influenza A (H1N1) and the Middle East Respiratory Syndrome Coronavirus: A Systematic Review and Meta-Analysis Severe obesity, increasing age and male sex are independently associated with worse in-hospital outcomes, and higher in-hospital mortality 30-day mortality in patients hospitalized with COVID-19 during the first wave of the Italian epidemic: A prospective cohort study Features of 20 133 UK patients in hospital with covid-19 using the ISARIC WHO Clinical Characterisation Protocol: prospective observational cohort study Morbid Obesity as an Independent Risk Factor for COVID-19 Mortality in Hospitalized Patients Younger than 50 Independent Correlates of Hospitalization in 2040 Patients with COVID-19 at a Large Hospital System in Michigan, United States The Characteristics of 50 Hospitalized COVID-19 Patients With and Without ARDS Risk Factors for Hospitalization and Mortality due to COVID-19 in Espirito Santo State, Brazil Association Between Clinical Manifestations and Prognosis in Patients with COVID-19 Increased Risk of Hospitalization and Death in Patients with COVID-19 and Pre-existing Noncommunicable Diseases and Modifiable Risk Factors in Mexico Association between obesity and clinical prognosis in patients infected with SARS-CoV-2 Overweight and obesity are risks factors of severe illness in patients with COVID-19 Prevention of chronic disease in the 21st century: elimination of the leading preventable causes of premature death and disability in the USA Characteristics of and Important Lessons From the Coronavirus Disease 2019 (COVID-19) Outbreak in China: Summary of a Report of 72314 Cases From the Chinese Center for Disease Control and Prevention The effect of obesity on lung function Letter to the Editor: Obesity hypoventilation syndrome and severe COVID-19 Obesity a Risk Factor for Severe Weight Management in Obstructive Sleep Apnea: Medical and Surgical Options Obesity as a risk factor for poor outcome in COVID-19-induced lung injury: the potential role of undiagnosed obstructive sleep apnoea Obesity and COVID-19: an Italian snapshot The Association of Obesity, Type 2 Diabetes, and Hypertension with Severe Coronavirus Disease 2019 on Admission Among Mexican Patients Patient Characteristics and Outcomes of 11,721 Patients with COVID19 Hospitalized Across the United States Racial Disparities in Incidence and Outcomes Among Patients With COVID-19 Obesity and risk of infection: results from the Danish Blood Donor Study Impact of Obesity on Influenza A Virus Pathogenesis, Immune Response, and Evolution Insight into the relationship between obesity-induced low-level chronic inflammation and COVID-19 infection Impact of Obesity and Metabolic Syndrome on Immunity Increased risk of influenza among vaccinated adults who are obese The weight of obesity on the human immune response to vaccination Overweight and obese adult humans have a defective cellular immune response to pandemic H1N1 influenza A virus Cytokine storm intervention in the early stages of COVID-19 pneumonia Cytokine profile in plasma of severe COVID-19 does not differ from ARDS and sepsis COVID-19 and the role of chronic inflammation in patients with obesity Obesity and SARS-CoV-2: a population to safeguard COVID-19: Pathogenesis, cytokine storm and therapeutic potential of interferons How can cytokine storms be prevented Position paper of the European Society of Cardiology-working group of coronary pathophysiology and microcirculation: obesity and heart disease The ACE2 expression in human heart indicates new potential mechanism of heart injury among patients infected with SARS-CoV-2 Two Things about COVID-19 Might Need Attention Hypercoagulopathy and Adipose Tissue Exacerbated Inflammation May Explain Higher Mortality in COVID-19 Patients With Obesity Obesity accompanying COVID-19: the role of epicardial fat COVID 19 and the Patient with Obesity -The Editors Speak Out Clinical considerations for patients with diabetes in times of COVID-19 epidemic European Association for the Study of Obesity Position Statement on the Global COVID-19 Pandemic COVID-19 and Obesity-the Management of Pre-and Post-bariatric Patients Amidst the COVID-19 Pandemic Initial Public Health Response and Interim Clinical Guidance for the 2019 Novel Coronavirus Outbreak -United States A Longitudinal Study Dietary Patterns Independent of Fast Food Are Associated with Obesity among Korean Adults: Korea National Health and Nutrition Examination Survey A systematic review and meta-analysis of screen time behaviour among North American indigenous populations Concomitant changes in sleep duration and body weight and body composition during weight loss and 3-mo weight maintenance Active commuting and obesity in mid-life: cross-sectional, observational evidence from UK Biobank Epidemic of COVID-19 in China and associated Psychological Problems Stress and Obesity Obesity and anxiety symptoms: a systematic review and meta-analysis The mutual effects of COVID-19 and obesity From Metabolic Exposome to Onset of Diabetic Cardiomyopathy Expected impact of lockdown in Île-de-France and possible exit strategies Body Mass Index and Risk for Intubation or Death in SARS-CoV-2 Infection: A Retrospective Cohort Study The obesity paradox: Analysis from the SMAtteo COvid-19 REgistry (SMACORE) cohort. Nutr Metab Cardiovasc Dis Obesity as a Potential Predictor of Disease Severity in Young COVID-19 Patients: A Retrospective Study Factors Associated With Death in Critically Ill Patients With Coronavirus Disease 2019 in the US Lifestyle Risk Factors for Cardiovascular Disease in Relation to COVID-19 Hospitalization: A Community-Based Cohort Study of 387,109 Adults in UK. medRxiv. 2020. of obesity on COVID-19 complications: a retrospective cohort study A nomogram to predict the risk of unfavourable outcome in COVID-19: a retrospective cohort of 279 hospitalized patients in Paris area Obesity is Associated with Increased Risk for Mortality Among Hospitalized Patients with COVID-19 How important is obesity as a risk factor for respiratory failure, intensive care admission and death in hospitalised COVID-19 patients? Results from a single Italian centre Obesity and Mortality Among Patients Diagnosed With COVID-19: Results From an Integrated Health Care Organization What Factors Increase the Risk of Complications in SARS-CoV-2-Infected Patients? A Cohort Study in a Nationwide Israeli Health Organization BMI is Associated with Coronavirus Disease 2019 Intensive Care Unit Admission in African Americans Predicting Mortality Due to SARS-CoV-2: A Mechanistic Score Relating Obesity and Diabetes to COVID-19 Outcomes in Mexico Obesity and COVID-19 Severity in a Designated Hospital in Shenzhen Phenotypic characteristics and prognosis of inpatients with COVID-19 and diabetes: the CORONADO study COVID-19-Associated Critical Illness-Report of the First 300 Patients Admitted to Intensive Care Units at a New York City Medical Center Clinical characteristics of 145 patients with corona virus disease 2019 (COVID-19 Pre-existing traits associated with Covid-19 illness severity Clinical epidemiological analyses of overweight/obesity and abnormal liver function contributing to prolonged hospitalization in patients infected with COVID-19 Factors Associated With Intubation and Prolonged Intubation in Hospitalized Patients With COVID-19 Risk Factors for Intensive Care Unit Admission and In-hospital Mortality among Hospitalized Adults Identified through the U.S. Coronavirus Disease 2019 (COVID-19)-Associated Hospitalization Surveillance Network (COVID-NET) Severe Obesity as an Independent Risk Factor for COVID-19 Mortality in Hospitalized Patients Younger than 50 COVID-19 patients in a tertiary US hospital: Assessment of clinical course and predictors of the disease severity Italian National Institute of Health C-mg. Non-respiratory Complications and Obesity in Patients Dying with COVID-19 in Italy Obesity as a risk factor for COVID-19 mortality in women and men in the UK Biobank: comparisons with influenza/pneumonia and coronary heart disease Male Sex, Severe Obesity, Older Age, and Chronic Kidney Disease Are Associated With COVID-19 Severity and Mortality Diabetes as a Risk Factor for Poor Early Outcomes in Patients Hospitalized With COVID-19. Diabetes Care Demographics, comorbidities and outcomes in hospitalized Covid-19 patients in rural southwest Georgia The FIB-4 Index Is Associated with Need for Mechanical Ventilation and 30-day Mortality in Patients Admitted with COVID-19 Clinical Characteristics and Morbidity Associated With Coronavirus Disease 2019 in a Series of Patients in Metropolitan Detroit Patients with diabetes are at higher risk for severe illness from COVID-19 The mortality of COVID-19 patients in obesity group was higher than that in non-obesity group (OR=1.7, 95% CI 1.1-2.8 (p=0.016)).Comorbidities: diabetes (28.6%) and hypertension (52.9%) Rottoli (2020) 116 Cohort study •Comorbidities: diabetes (5.7%), hypertension (15.1%) and CVD (9.1%) •The proportion of hypertension in severe group was higher than that in non-severe group (23.08% / 12.67% (p=0.02)).•The proportion of CVD in severe group was higher than that in non-severe group (18.68% / 6.16% (p=0.001)). • COVID-19 with obesity patients were more severe than non-obesity patients (OR=6.32, 95% CI: 1.16-34.54 (p=0.033)). NA ARDSacute respiratory distress syndrome; BMIbody mass index; CIconfidence interval; CVDcardiovascular disease; GPUgeneral practice unit; ICUintensive care unit; NIVnon-invasive mechanical ventilation; IMVinvasive mechanical ventilation; aHRadjusted hazard ratio; aORadjusted odds ratio; NA not available; NAFLDnonalcoholic fatty liver disease; ORodds ratio; RRrelative ratio.