key: cord-0898752-764rnoq9
authors: Lordan, Ronan; Prior, Samantha; Hennessy, Elizabeth; Naik, Amruta; Ghosh, Soumita; Paschos, Georgios K.; Skarke, Carsten; Barekat, Kayla; Hollingsworth, Taylor; Juska, Sydney; Mazaleuskaya, Liudmila L.; Teegarden, Sarah; Glascock, Abigail L.; Anderson, Sean; Meng, Hu; Tang, Soon-Yew; Weljie, Aalim; Bottalico, Lisa; Ricciotti, Emanuela; Cherfane, Perla; Mrcela, Antonijo; Grant, Gregory; Poole, Kristen; Mayer, Natalie; Waring, Michael; Adang, Laura; Becker, Julie; Fries, Susanne; FitzGerald, Garret A.; Grosser, Tilo
title: Considerations for the Safe Operation of Schools During the Coronavirus Pandemic
date: 2021-12-16
journal: Front Public Health
DOI: 10.3389/fpubh.2021.751451
sha: 03a1a9f6194a6f800fd740d0a22df2ef6685c97b
doc_id: 898752
cord_uid: 764rnoq9

During the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic, providing safe in-person schooling has been a dynamic process balancing evolving community disease burden, scientific information, and local regulatory requirements with the mandate for education. Considerations include the health risks of SARS-CoV-2 infection and its post-acute sequelae, the impact of remote learning or periods of quarantine on education and well-being of children, and the contribution of schools to viral circulation in the community. The risk for infections that may occur within schools is related to the incidence of SARS-CoV-2 infections within the local community. Thus, persistent suppression of viral circulation in the community through effective public health measures including vaccination is critical to in-person schooling. Evidence suggests that the likelihood of transmission of SARS-CoV-2 within schools can be minimized if mitigation strategies are rationally combined. This article reviews evidence-based approaches and practices for the continual operation of in-person schooling.

The impact of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic on a generation of children can be anticipated to be extensive and long-lasting. In addition to the health consequences of coronavirus disease 2019 (COVID- 19) , the economic repercussions have brought financial insecurity to families and communities. Indeed, pre-existing social and health disparities has disproportionally affected many communities. School closures to reduce the number of person-to-person contacts and viral spread in the population (1) have caused prolonged interruptions to in-person learning and affected children's education and well-being. The benefit of formal education also is in the social, emotional, and behavioral dimensions that are difficult to replace in a distance learning environment. Therefore, enabling continuous in-person education is a central goal within the public health response to the pandemic.

Operating schools for in-person learning requires a dynamic approach as community spread fluctuates and more transmissible (and potentially more virulent) strains emerge (2) (3) (4) . Key concerns include health risks to members of the school community and their families; disruption of learning, social, emotional and physical well-being associated with school closures, remote or hybrid learning, and quarantine periods; and the potential contribution of schools to sustaining viral spread in the population.

COVID-19 is predicted to evolve into an endemic disease in regions with infection and vaccination rates that confer inadequate protective population-level immunity (5, 6) . Recurrent outbreaks among those who are not yet or are no longer immune are characteristic of many infectious diseases, including the common cold or influenza. Akin to their role in the infection dynamics of these seasonal respiratory infections, schools may become reservoirs of SARS-CoV-2 due to their dense social setting if sufficient protective measures are not taken to limit the propagation of natural infections among susceptible individuals (7) . Vaccination against SARS-CoV-2 markedly lessens, if not eliminates, most health concerns associated with in-person schooling for adults and children who are immunized-even in regions where highly transmissible viral variants predominate (8) (9) (10) (11) (12) (13) (14) . However, those in a school community who are not yet eligible for vaccination, who have not had an opportunity to be vaccinated, or who choose to delay or forgo vaccination remain at risk.

The susceptibility of unvaccinated school-aged children to SARS-CoV-2 infection and this population's likelihood of spreading the virus has been widely discussed since lower rates of reported infections in children than adults were noted (15) . However, the cause of this age-based disparity is likely multifactorial. Hypotheses include decreased exposure (16) , missed asymptomatic cases (17) , and a lower biological susceptibility to being infected (15, 18, 19) . The interplay of these factors may contribute to heterogeneity in reports on pediatric susceptibility to SARS-CoV-2 infection. While some contact tracing studies estimated a reduced infection risk of children and adolescents (15, (20) (21) (22) (23) (24) , others found no difference when compared with adults (25, 26) . Similarly, although some seroprevalence studies found SARS-CoV-2 antibodies as a marker of past infection in fewer children than adults, others observed no or only small effects of age (27) . Additionally, evidence of potential differences in the risk of SARS-CoV-2 infection between younger and older school-aged children are not uniformly supported and may relate more to study design than age-dependent biology (15, (20) (21) (22) (23) (24) (25) (26) . For example, a large surveillance testing study in Austria found no differences in the infection rates among 6-10 and 11-14 year olds, suggesting that primary and middle school students have similar risks of infection (28) .

There is more clarity regarding children's ability to spread the virus. Minor age-based differences between nasopharyngeal viral loads exist, but they do not suggest that children are substantially less infectious than adults (29) . Indeed, data from India provide evidence that children and adolescents of all ages are effective transmitters of the disease (30) . This is supported by reports of increased prevalence of SARS-CoV-2 in children, particularly among adolescents. For example, during the second pandemic wave in the UK (November 2020), the highest prevalence of SARS-CoV-2 positive tests was obtained from adolescents who attended school (31) . This was in the context of the more transmissible virus variant Alpha (B.1.1.7) (31). When the highly transmissible Delta (B.1.617.2) variant began to spread in the British population (June 2021), this age group again showed the highest infection rate in the population (32) and it appeared that some case clusters were associated with schools (4). Similarly, a rapid increase of infections and hospitalizations in children and adolescents was observed in the U.S. when Delta began to spread in July 2021 (14, 33) . By October 2021 ∼25% of newly reported COVID-19 infections occurred in children under the age of 18 years, an age group that makes up 22 % of the population in the U.S. (34) . These findings are in accordance with a contact tracing study that saw the highest probability of transmission among students aged 10-19 years (35) . Because of our evolving understanding of how susceptible to infection with increasingly transmissible virus variants children are and how they contribute to the spread of SARS-CoV-2, schools should not rely on an assumed natural protection of (and by) children. Mitigation plans for all age groups continue to be necessary to curb the spread of virus variants in schools.

While the age dependency of infection risk is controversial, there is strong evidence that children who are infected with SARS-CoV-2 have a substantially lower risk of severe outcomes than adults. Most are diagnosed with asymptomatic or minimally symptomatic infections (36) (37) (38) (39) (40) (41) or experience a mild form of respiratory disease that will typically resolve within a week or two (25, (42) (43) (44) (45) (46) . Increasing evidence suggests that the airway epithelium of children may have a better ability to sense infection with SARS-CoV-2 and may mount a more pronounced immune response than adults, resulting in faster viral clearance (47) (48) (49) . However, even in mild cases, individuals can experience persistent symptoms for weeks following a SARS-CoV-2 infection. These prolonged post-acute sequelae of SARS-CoV-2 infection, referred to as "PASC" or "long-COVID, " have only begun to be studied in children. As in adults, symptoms include fatigue, dyspnea, chest pain, cardiac palpitations, myalgia, gastrointestinal issues, headache, anosmia, and issues with memory and concentration (50, 51) . Preliminary studies suggest that the most common persistent symptoms in children are fatigue and cough, although longstanding insomnia, headache, and pain were also frequently reported (52) (53) (54) . One study found that ∼40 % of children diagnosed with COVID-19 reported at least one persistent symptom 2 months post infection (55) . Another study estimated that 10% of children may still experience symptoms 3 months post infection (56) . In a large, matched cohort study, the incidence rate of health problems was ∼30% higher in the COVID-19 cohort than in matched controls at least 3 months after infection (57) . Symptoms including fatigue, cough, throat or chest pain, headache, fever, and abdominal pain occurred 1.45 to 2.28 times more frequently in the COVID-19 than in the control cohort. Another study that focused on severely ill children that were hospitalized with COVID-19 estimated that 25% may experience persistent symptoms 5 months post discharge with higher risk in those with pre-existing allergic diseases. Some symptoms persisted even longer (58) . The impact of this persistent symptomatology on academic participation and performance is still to be determined.

Despite its overall rarity, children can become severely ill with COVID-19 (59, 60) and just as in adults, racial, ethnic, and socioeconomic disparity in disease severity is evident (25, 61) . Exact rates of severe disease are difficult to estimate because of the large number of undetected infections and prophylactic admission to hospitals, which result in an overestimate in unadjusted health statistics of COVID-19 severity (17) . Considering these limitations, a reported cumulative (October 2021) hospitalization rate of 0.8% of all laboratory confirmed infections in the pediatric U.S. population represents a conservative estimate of the rate of severe disease (62) . Notably, over one quarter had a pre-existing condition such as obesity, type I diabetes, asthma, and neurodevelopmental disorders (63) . Youths (12-17 years) and young children (0-4 years) were ∼2-3 times more frequently hospitalized than 5-11 year old children (64) . Approximately one in four children admitted to a hospital in the U.S. received intensive care (14, 65) . In Germany where the hospitalization rate of 1-17 year olds with a documented SARS-CoV-2 infection has also been ∼1%, it was determined that between 1% and 10% of children admitted to a hospital received intensive care (66) .

A rare, severe, delayed consequence of COVID-19 is multisystem inflammatory syndrome in children (MIS-C), also referred to as pediatric inflammatory multisystem syndrome temporally associated with SARS-CoV-2 (PIMS-TS) (67) (68) (69) (70) (71) (72) (73) . MIS-C is characterized by persistent fever and systemic inflammation, involving at least two organs (i.e., lungs, heart, kidneys, skin, blood, gastrointestinal tract, and brain), weeks after infection with SARS-CoV-2. As of November, 2021, the Centers for Disease Control and Prevention (CDC) report a median age of 9 years (interquartile range 5-13 years) for MIS-C in the U.S. (74) . Initial estimates suggest an MIS-C incidence of ∼2 per 100,000 children and adolescents in the U.S. population during the first year of the pandemic (68) before the number of infected children rose steeply when the Delta variant began to spread. During the same period (pre Delta) ∼3,500 COVID-19 infections per 100,000 children and adolescents were laboratory confirmed (34) . Because the number of total infections including undetected infections can be expected to be markedly higher (17) , a rough estimate might be that between 1 in 1,000 and 1 in 10,000 infected children and adolescents have developed MIS-C in the U.S.. An analysis of MIS-C reports in seven U.S. states during the first months of the pandemic estimated that ∼3 in 10,000 infected children developed MIS-C (75, 76) . German registry data found rates of 7 in 1,000 and 4 in 10,000 for 1-10 and 12-17 year old children and youths with documented infections suggesting that the case rate is similar in both regions (66) . Emerging data indicates that while many children with MIS-C require intensive care, most recover fully or with minimal residual functional impairment (70) . However, as of November, 2021, the CDC's national registry lists 46 deaths among 5,217 patients (∼0.9 %) meeting the MIS-C case definition (75) .

An infection fatality rate (IFR) can be estimated as a risk for death among infected individuals. This value accounts for both laboratory confirmed and imputed undetected infections. The IFR of the H1N1 pandemic 2009 influenza is estimated to be <1 in 100,000 infected school-aged children (77, 78) , and the fatality rate of measles may approximate 1-2 in 1,000 infected schoolaged children (79) . In school-aged children with SARS-CoV-2, an IFR of 1-3 in 100,000 has been estimated (80, 81) . The IFR may be higher in children under the age of 4 years (80, 81) . In comparison, the estimated IFR for adults aged 35 to 44 years ranges from 40 to 75 in 100,000 infected persons and the IFR for adults aged 65 to 74 years ranges from 1,075 to 1,670 in 100,000 infected persons (80) .

At the population level, COVID-19 ranked among the 10 leading causes of death among U.S. children throughout most of 2021 (82) . A mortality rate of ∼0.2 in 100,000 children has been attributed to COVID-19 during the first year of the pandemic (83, 84) . Children aged 3-10 had the lowest COVID-19 related mortality (85) . Notably, the COVID-19 related mortality was about two-fold higher than the typical mortality rate of influenza in school-aged children in prior years (range 0.10-0.13 in 100,000) (85, 86) . However, comparison of COVID-19 related mortality with historical influenza data is complicated, because COVID-19 deaths occurred despite unprecedented protective public health measures. There were 144 to 198 annual pediatric influenza deaths in the U.S. in the 3 years prior to the 2020/21 season (October to May), during which only one influenzarelated pediatric death occurred (87) . This suggests that the public health measures instituted, including school closures and hybrid learning, may have had broad impact on reducing the transmission of other viruses. In contrast to the isolated pediatric death from influenza in the 2020/21 season, over 220 pediatric COVID-19 deaths were reported in the U.S. during the same time (34, 62) . These observations highlight inherent differences in infection dynamics between these two diseases.

As public health mitigation measures are lifted in increasingly vaccinated populations, it remains unclear how this will impact COVID-19 related morbidity and mortality in school age children. Additionally, there is an unmet need to understand the frequency and severity of PASC in children. The emergence of more transmissible (and potentially more virulent) variants may also affect disease burden in the pediatric population. Moreover, the ethical considerations regarding phasing out protective measures for children who are age-eligible but remain unvaccinated are different from those in the adult population. Because of these evolving uncertainties, protecting students should remain a priority, even when many adults and age-eligible students have been immunized.

Since the beginning of the pandemic, education has rotated between remote and in-person learning. However, even when inperson learning was offered quarantine and isolation periods for COVID-19 infections and exposures affected as many as 20% of students during pandemic waves in both Spain and China (3, 88, 89) . Shifts between modes of learning have led to negative social, emotional, educational, and physical consequences not only through reduced physical presence in school buildings, but also through loss of essential services for children provided by schools (90) (91) (92) . Many receive their main source of nutrition in schools. For others school is a place of refuge and protection. For example, child maltreatment was underreported by an estimated 27% in the U.S. during the pandemic, likely because it went unnoticed or unreported due to lack of face-to-face interactions with teachers or other school personnel during school closures and remote programs (93) . Many schools were unable to provide mental and behavioral health services to students while working remotely, which may have contributed to under recognition of child maltreatment and more generally increases in stress and anxiety (94, 95) .

The impact of the extended school closures during the pandemic remains to be fully appreciated, but students in the Netherlands showed little progress while learning from home during the first lockdown (96) . In the U.S., it was projected that students would have ∼40-50% of the learning gains in mathematics and 60-70% of the learning gains in reading relative to a typical school year, although the top third of students may have been impacted less (97) . Learning loss was reported to be more prevalent for students of color and for socioeconomically disadvantaged students (96, 98) . Moreover, students with disabilities were less likely to have had access to educational support (99) .

Despite being a necessary public health response to the pandemic, even limited quarantine measures and temporary school closures in response to infections and outbreaks in the school community can have negative consequencesperhaps most for children of working parents. Remote learning may disadvantage students further if the household is not digitally competent (88) . Academic outcomes are thought to be similarly affected by transitions to distance learning as they are by absenteeism (100) . Home confinement for just 8-10 days can measurably impair emotion regulation and increase symptoms of anxiety and depression (101) . Increased screen time can negatively affect sleep patterns and limit exercise, which impacts both physical and mental health (102) . Perhaps most fundamentally, interruptions to daily in-person interactions with classmates, and a network of caring adults may potentially cause damaging isolation-related effects such as anxiety and depression (101, 103) . Disadvantaged children, such as refugees, migrants, and those with cognitive and/or physical disabilities are likely to have faced greater exclusion from learning (104) . Therefore, minimizing disruption of continuous in-person learning by encouraging vaccination and implementing proactive infection control measures that identify potentially infected individuals early and limit the likelihood of spread is a central goal of school operation plans.

At its peak, COVID-19-related school closures, which were based on the response plans to influenza pandemics, affected an estimated 1.5 billion or 90% of the world's learners (105, 106) . Estimating the contribution of specific interventions to overall mitigation during countrywide general lockdowns is challenging. However, retrospective modeling analyses suggest that schools may have played an important role in disseminating infections into the population during the initial wave of SARS-CoV-2 before mitigation measures were implemented (1, 16, 107) . Indeed, large viral outbreaks among students and teachers, which spread to family members and other close contacts outside of school, have been documented when preventive measures were insufficient or were insufficiently followed (38, (108) (109) (110) (111) (112) .

Early in the pandemic, in person schooling was associated with increased rates of infection (113) . In Sweden, family members of students and teachers who were physically present in school buildings had higher rates of infections than family members of students and teachers who engaged in remote learning (113) . As our experiences evolved, it was found that the risk for in-school transmission correlated with community exposure risk (109, (114) (115) (116) (117) (118) (119) (120) (121) . National and regional contact tracing and surveillance data collected in Europe, Australia, and Singapore during periods of low viral circulation (summer/fall 2020) found that clusters of cases or documented outbreaks were infrequent despite variable degrees of mitigation measures (109, (114) (115) (116) (117) (118) (119) (120) (121) . Most infections appeared to have been acquired outside of school. Employees were found to be at a higher risk of seeding SARS-CoV-2 infections than children in U.K. schools (114) . Random COVID-19 testing among Austrian school students and staff showed that the number of infections detected in schools increased with the surging incidence of infections in the broader community (28) . Similarly, widened viral circulation in a region coincided with a growing number of outbreaks in Australian schools (122) . Conversely, an increasing vaccination rate in the adult population was associated with a substantial decrease in cases in children and teenagers in Israel before they became age-eligible for vaccination (123) . This direct relationship between the infection dynamics in schools and the surrounding population highlights the importance for safe school operation of reducing the infections in the community.

The question of how much in-person learning contributed to the dissemination of infections into the regional population is difficult to address. Two analyses of German incidence data found that SARS-CoV-2 transmission in the population decreased following school reopening after the summer break 2020 under conditions of low baseline viral circulation. This was hypothesized to relate to reduced travel as the summer break ended and more widespread adoption of infection mitigation behaviors by the population (124, 125) . In Michigan and Washington, a temporal association between re-opening schools (fall 2020) and infections in the broader population was observed only in regions with high baseline infection activity (126) . Where incidence rates were low prior to the begin of in-person learning, no increase in viral transmission in the population was observed (126, 127) . Similar observations were made in schools in Sicily (128) . Moreover, a nationwide analysis showed no evidence of increased hospitalizations for COVD-19 in U.S. regions with low baseline disease activity where schools re-opened for hybrid or full in-person learning (129) . However, an impact of in-person schooling could not be excluded in counties with high baseline disease activity (129) . Indeed, a more recent nationwide analysis of U.S. counties found an overall increase of new COVID-19 cases and deaths in communities in temporal association with school opening from April to December, 2020 (130) . In counties where teaching resumed in-person but without a mask mandate in schools, the rise in case numbers and deaths was steeper and more pronounced than in counties where masks were required (130) .

Overall, these data suggest that the infection dynamics in schools and in the surrounding population are in dynamic equilibrium (Figure 1) . This illustrates the importance of continued suppression of viral transmission in the broader population while the vaccination rate increases through effective public health measures such as mask wearing and limits on social gatherings. Adults play a particular role in the infection of children with ∼70% of pediatric cases being secondary to an adult case (131) . However, young children are not yet age-eligible for vaccination in many regions in the world, or supply shortages limit availability of the SARS-CoV-2 vaccines for those who are eligible. Therefore, the interplay between community spread and outbreaks in schools supports a strategy of prioritizing older adults for vaccination where supply is limited, not only because they are most at risk but because mitigating their role in community spread can also be expected to render inperson learning safer (123) . However, this still requires mitigation of transmission within schools to minimize the risk of larger outbreaks. Adults bare the greater responsibility to monitor their actions within the community to prevent the spread of SARS-CoV-2 among children (132) .

Emerging evidence suggests that mitigation measures in schools are effective in maintaining low levels of SARS-CoV-2 transmission among students and teachers (secondary transmission) (133, 134) . A study in primary schools, nurseries, and kindergartens in Germany determined that asymptomatic spread among these age groups was low when mitigation measures including mask wearing, and classroom ventilation were appropriately applied (135) . An Australian study in schools that practiced hand hygiene, physical distancing, reduced mixing of students and reduced after-school activities, but not mask wearing or enhanced classroom ventilation or filtration, found 1 secondary infection case per 9 infectious students who attended school (15) . A German analysis of contact tracing data in schools with a 50% reduction of classroom occupancy through hybrid learning, regular room ventilation, limited contacts between cohorts, exclusion with minimal symptoms, but no mask wearing and no distancing in classrooms estimated a frequency of 1 secondary case per 12 infectious students who attended school (136) . A report on Norwegian schools that used similar mitigation measures but no masking in classrooms, found no secondary cases among 13 students who attended school while considered infectious (120) . A study conducted in Wisconsin observed 1 secondary case per 20 infectious students in schools that consistently practiced mask wearing, had cohort sizes of ≤ 20 students, limited contacts between cohorts, but had no symptom screening program (137) . Similarly, school districts in North Carolina detected 1 secondary infection per 24 communityacquired infections in schools that practiced mask wearing, physical distancing, hand hygiene, and reduced cohort mixing (138) . Collectively, these studies which were conducted before the Delta variant became dominant, indicate that instituting basic mitigation strategies can enable in-person schooling with a low risk of secondary SARS-CoV-2 transmission. However, the impact of more transmissible virus variants such as Delta remains less understood and can be expected to require additional preventive measures.

Presently, no single intervention, including vaccination, completely prevents viral transmission. However, combined mitigation strategies may be synergistically beneficial (133, (139) (140) (141) . In safety research this concept of risk management is sometimes described as the "Swiss Cheese Model", where multiple defensive layers are combined with the understanding that each individual layer has holes. The combination of multiple layers provides safety through redundancy (142) . Evidence based choices need to be made as to which mitigation strategies to combine to adapt to changing risk levels and maximize learning.

Given the association between cases in schools with burden of disease in the community, the most effective approach to enable safe in-person learning is to focus on broader public health measures that suppress viral spread in the population (Figure 1) . The SARS-CoV-2 vaccines are effective in preventing severe disease and reduce the likelihood of infection and transmission of the virus (123, 143) . As such, widespread vaccination of the eligible population is a potent tool in reducing viral spread in the unvaccinated, younger population. Household members are the primary source of infection of school-aged children, and extracurricular activities are a source of infection among adolescents (131, 140, 144) . Thus, the entire community of those who interact with unvaccinated children can contribute significantly to protecting schools by getting vaccinated.

Daily symptom-based surveillance combined with aggressive diagnostic testing for COVID-19 infections is effective in reducing the likelihood of having infectious students in FIGURE 1 | Infection dynamics in schools. Multiple factors and mitigation measures (in blue) modify the probabilities of (P 1 ) infection of students or teachers outside of school, (P 2 ) the import of infection into school, (P 3 ) the spread among students and teachers, (P 4 ) development of prolonged post-acute sequelae of SARS-CoV-2 infection ("long COVID"), (P 5 ) progression to severe acute COVID-19, and (P 6 ) development of multisystem inflammatory syndrome in children (MIS-C), also referred to as pediatric inflammatory multisystem syndrome temporally associated with SARS-CoV-2 (PIMS-TS). Viral circulation in the regional population is a key determinant of infection risk of students and teachers. Secondary transmission within schools can amplify infections in the regional population.

schools (140, 145) . As many symptomatic students who are infected with SARS-CoV-2 present with mild symptoms, such as rhinorrhea, cough, sore throat, or headache (146) , there should be a low threshold for diagnostic COVID-19 testing. Additionally, daily health screening affords the opportunity to gain insights into the overall risk profile of the larger school community including household members by asking about potential contacts of students with symptomatic or laboratory confirmed infected persons.

Silent transmission by individuals who have not yet developed symptoms ("presymptomatic") or who will never notice symptoms ("persistently asymptomatic") contribute to the difficulty in containing the pandemic. Surveillance testing approaches in schools are used for identifying pre-/ asymptomatic persons who are carrying the virus (147) . Most reliable and sensitive diagnostic tests detect the SARS-CoV-2 genome using reverse transcriptase polymerase chain reaction (RT-PCR) (148, 149) . Comparative studies suggest that saliva based diagnostic testing accuracy may be similar to that of nasopharyngeal swabs (150) . However, slow turn-around times to results of tests based on nucleic acid amplification may not allow for timely isolation of an infected person who has no symptoms. Rapid antigen tests detect viral proteins in a sample of either saliva or a swab of the nose or throat using a lateral flow method similar to pregnancy tests. These tests provide an opportunity to identify pre-or asymptomatic carriers in real-time (151) . Although they are generally less sensitive than RT-PCR tests, rapid antigen tests are effective for detecting individuals with high viral loads who would be considered presently infectious (149, (152) (153) (154) . Saliva-based rapid tests are easy to perform at home or in school, but their sensitivity appears to be substantially lower than those that use nasal swabs (155, 156) . Concerns related to surveillance testing include both false negative (the test is reported as negative, but the virus is present) and false positive (the test is reported as positive, but the virus is not present) results (157) . The consequences of a false positive test (i.e., unnecessary isolation) can be limited by confirmatory testing using RT-PCR. Regular, for example weekly or more frequent testing reduces the impact of false negative test results (158, 159) . Importantly, given the time course of viral load in throat and nose, the sensitivity of the test is less important for effective surveillance testing than the frequency of testing and turnaround time of result reporting (158) .

While limited studies have systematically examined surveillance testing in schools, even a testing frequency as low as every 2 weeks appears to provide some balance to the false negative vs. false positive detection rate among students (160, 161) . However, because a school wide testing-based surveillance system can identify some, but not all pre-/ asymptomatic individuals, even frequent testing should not be relied on as the only strategy to enable in-person schooling. Additionally, school wide testing-based surveillance is not feasible everywhere considering the complex logistics and the costs, particularly in less affluent regions. Despite these hurdles, nationwide surveillance testing for schools has been successfully implemented in many countries, (162, 163) , and is being planned or piloted in others (164) (165) (166) .

An approach to reducing disruptions of learning when COVID-19 positive individuals have been identified in schools is to quarantine only close unvaccinated contacts, i.e., immediate classroom neighbors of students presumed infectious, instead of quarantining all of the unvaccinated students in a learning cohort. Typically, this is combined with proactive COVID-19 testing among the cohort. Another approach is to allow even close unvaccinated contacts of a student presumed infectious to remain in the classroom but require them to test frequently ("test-to-stay"). Currently, there is little empirical data in support of either approach. However, computational simulation suggests that only quarantining close contacts of an infected student rather than the entire class cohort, would not be predicted to increase the probability of large outbreaks in a school as long as SARS-CoV-2 infections in the school community are infrequent and adequate mitigation procedures are in place (i.e., face masks, ventilation, distancing where possible) (161, 167) .

In addition to limiting individual health risks by decreasing the likelihood of illness, hospitalization, and death (8) (9) (10) (11) (12) (13) (14) , COVID-19 vaccines provide a potent additional layer of protection for the school community by reducing the likelihood of infection. For example, the mRNA BNT162b2 COVID-19 vaccine (Pfizer-BioNTech, Comirnaty) has been estimated to reduce the risk of infection with the Delta variant by approximatively four-fold in adults and 10-fold in adolescents (13, 168) . Although breakthrough infections can occur in vaccinated individuals (169) , emerging evidence suggests that their infectiousness even with the Delta variant might be reduced (170) . However, this effect declines with time and so a third (booster) vaccine dose may be needed. A recent study performed in Sweden observed that immunization extended protection from infection to family members who are not vaccinated (171) . For example, 2 immunized family members reduced the infection risk for the non-immune family members by 75 to 86%, whereas 3 immunized family members reduced the infection risk for the non-immunized family members by 91% to 94%. Therefore, it can be expected that the likelihood of COVID-19 outbreaks will decline substantially in increasingly vaccinated school communities (i.e., teachers, staff, students, families).

SARS-CoV-2 is spread through liquid particles that are generated by expiratory activities such as breathing, speaking, coughing, and sneezing (172) . Liquid particles vary in size by orders of magnitude, ranging from larger droplets to smaller particles dispersed as aerosols. Large droplets (e.g., >50-100 µm) can settle quickly out of the air onto surfaces, so that individuals who are farther away from the droplet source are less likely to inhale them. Viral transmission by large exhaled droplets and secreted respiratory fluids is the basis for physical distancing and hand hygiene recommendations. While 1.8 m (6 foot) separation in classrooms was recommended for U.S. school reopening in fall 2020 and 1.5 m (5 foot) for European schools, more recent observational data suggest that a 0.9 m (3 foot) separation may be sufficient when students are seated and wear facemasks in classrooms (173) . The impact of more transmissible variants on distancing requirements remains to be determined. Incorporating instruction on handwashing into the curriculum generally reduces the transmission of infectious diseases in schools (174) . Antibacterial adjuvants to soap do not have greater efficacy at preventing infection and may be associated with antibiotic resistance (175) . Hand sanitizers are an alternative, but they are not considered as effective as hand washing (176) and are an ingestion risk (177) .

Unlike droplets, aerosols (e.g., 10 −4 to 10 µm) can stay airborne for hours or until the air is exchanged (178) . The risk for virus transmission while outdoors is much lower than indoors because moving air disperses and dilutes aerosol concentrations quickly (179) . An important component of mitigation measures targeting indoor air quality is to reduce the release of aerosols by wearing facemasks and by limiting activities indoors that produce high concentrations of aerosols, such as shouting, singing, gym exercise, playing of wind instruments, or having large numbers of students in a classroom (180) (181) (182) (183) . Wellfitted face masks worn over mouth and nose effectively reduce viral transmission by reducing both emission and inhalation of viral particles (184, 185) . Guidance surrounding what age groups should be wearing masks varies (186) , but in the U.S., masking is generally recommended for children over 2 years old (187, 188) whereas the World Health Organization (WHO) recommends masks for children over 5 years old (189) . A recent study in France found that while many mild inconveniences were reported by parents of children wearing masks, overall, children tend to tolerate them well (190) . While wearing face masks does not impair the respiratory function of children (186) , even in those as young as 2 years old (191) , they reduce the capability to recognize emotional expressions and some mask types can impair speech intelligibility (192) (193) (194) . Adults interacting with children should be aware of these limitations and compensate where possible. In how far the impact of facemasks on visual and auditory cues may affect language development in young children has not yet been systematically examined.

Additionally, ventilation and filtration strategies can remove virus particles from the air. The effectiveness of ventilation by opening windows or expelling indoor air with fans can be monitored by measuring CO 2 levels as a proxy of the cumulative expiratory activity by the occupants (195) , which has been a strategy considered by school authorities in Ireland (196). To supplement ventilation, or when it is not practical, air filtration systems should be used. Coronaviruses are found associated with water vapors, proteins, and salts in aerosolized particles often >1.0 µm, which can be effectively removed by filtration (19) . Filters for heating, ventilation, and air conditioning (HVAC) systems with a minimum efficiency reporting value (MERV) of 13 have been suggested as a potential air purifying strategy in schools (197, 198) . Standalone portable air cleaners that have high efficiency particulate air (HEPA) filters, which are capable of filtering 0.3 µm particles at 99.97% efficiency can supplement or replace centrally located filters (199) . Schools that implemented measures to improve ventilation by keeping windows and doors open or using fans had a 35% lower incidence and schools that combined ventilation with filtration had a 48% lower incidence than schools that did not focus on indoor air quality (133) .

For most respiratory viruses, the risk of infection depends on the number of viral particles a person inhales, or the viral inhaled dose, which is a function of breathing rate, inhaled concentration, and time of exposure (200) . The dose of viral exposure may be proportional to the severity COVID-19 (201) (202) (203) (204) . It is plausible that prevention of transmission in schools is due to multiple layers of mitigation synergistically minimizing the viral dose students and teachers are exposed to rather than by eliminating exposure entirely.

Many of the infections in a population are spread by a disproportionately small number of people (205) . Studies estimate that only 10-20% of coronavirus patients are responsible for 80% of all new infections of the early virus strains (206, 207) . While more transmissible strains may spread more widely, outbreaks of viruses with such a hyperdispersed distribution are often driven by super-spreading events. Many super-spreading events involve crowded indoor places, loud speaking or singing, and inadequate use of protective measures such as face masks and physical distancing. The distribution of the sizes of reported outbreaks in schools reflects such a hyperdispersed distribution. Often, no or few new secondary infections are observed following exposures in school, while larger or very larger outbreaks are less frequent (167, 208) . Banning larger group gatherings is a practice that avoids super-spreading and is highly effective in suppressing viral spread (1) . Avoiding student mixing by creating protective (classroom) cohorts may allow clusters of infection to be more easily contained through limited quarantine measures. However, while this is feasible in early childhood, elementary and middle schools, a typical high school rotation structure creates much more complex networks of person-toperson contacts, which are predicted to result in a higher risk of outbreaks (161) . Indeed, a study in Catalonia which was conducted in schools that practiced cohorting found that the secondary attack rates were higher in high school students than in preschool students (208) . However, even in situations where protective cohorts are difficult to implement, a focus on limiting longer and closer interactions to members of the same group of individuals whenever feasible may still provide some benefit (209) .

Alternating ("hybrid") in-school and remote-learning models reduce the size of the protective cohort. Computational modeling suggests that weekly rotations (i.e., 5 days in school, 5 days remote) or groups of students rotating 2-3 days in school every week limit the number of contacts between students and teachers to reduce the likelihood of transmission events in schools (161, 210) . Existing out-of-school social networks among students may guide such cohort formation and lead to a more effective reduction of contacts (211) . However, whether these predictions translate into measurable effects on secondary cases in schools remains to be tested. At the population level, no difference in the incidence rates between hybrid and full in-person learning were apparent in Michigan (126) . Therefore, limiting the educational benefit of full in-person instruction by implementing hybrid models should be weighed carefully against mitigating measures such as mask wearing, maximizing distance between individuals and room ventilation / air filtration. Since reduction of in-school time may disadvantage younger students disproportionately, this mitigation tool should be reserved primarily for older middle and high school students.

Societies have struggled worldwide to balance the obligation to provide quality education with minimizing the infection risk. However, the role of the broader community in preventing infections in schools has been a largely neglected consideration. To protect the school communities, there must be a collective acceptance for continuing general public health measures such as wearing masks in dense social settings, limiting contacts, activities with elevated risks of viral spread, and to avail of vaccination and testing. While the risk of severe illness and death related to COVID-19 are low in school-aged children, it is not negligible, and marked uncertainties regarding the longterm sequelae exist. The role of school in community spread and the negative impact of disruptions to in-person schooling by quarantine measures remain strong arguments to focus on protecting schools. Children deserve safe access to education. To achieve this, schools need a dynamic mitigation plan (Figure 1) , community investment in public health measures, and the systematic collection of data to assess which strategies are most effective. 

Inferring the effectiveness of government interventions against COVID-19

School reopening without robust COVID-19 mitigation risks accelerating the pandemic

SARS-CoV-2 transmission in students of public schools of catalonia (Spain) after a month of reopening

19: Delta variant is now UK's most dominant strain and spreading through schools

Endemic SARS-CoV-2 will maintain post-pandemic immunity

The potential future of the COVID-19 pandemic: Will SARS-CoV-2 become a recurrent seasonal infection?

Strategies for pandemic seasonal influenza vaccination of schoolchildren in the United States

Comparative effectiveness of Moderna

Safety and efficacy of the BNT162b2 mRNA COVID-19 vaccine through 6 months

Sustained effectiveness of Pfizer-BioNtech and Moderna vaccines against COVID-19 associated hospitalizations among adults-United States

Effectiveness of COVID-19 vaccines against the B.1.617.2 (Delta) variant

Effectiveness of Pfizer-BioNtech mRNA vaccination against COVID-19 hospitalization among persons aged 12-18 Years-United States

Effectiveness of BNT162b2 vaccine against Delta variant in adolescents

Hospitalizations associated With COVID-19 among children and adolescents-COVID-NET

Susceptibility to SARS-CoV-2 infection among children and adolescents compared with adults: A systematic review and meta-analysis

Association between statewide school closure and COVID-19 incidence and mortality in the US

A public health antibody screening indicates a 6-fold higher SARS-CoV-2 exposure rate than reported cases in children

Intra-household and close-contact SARS-CoV-2 transmission among children -A systematic review

Recurrent Emergence of SARS-CoV-2 spike deletion H69/V70 and its role in the

Characteristics of household transmission of COVID-19

Age specificity of cases and attack rate of novel coronavirus disease (COVID-19)

Household Secondary Attack Rate of COVID-19 and Associated Determinants in Guangzhou China: a Retrospective Cohort study

The role of children in the spread of COVID-19: Using household data from Bnei Brak Israel, to estimate the relative susceptibility and infectivity of children

Agedependent effects in the transmission and control of COVID-19 epidemics

COVID-19 in children and adolescents in Europe: A multinational, multicentre cohort study

COVID-19, children schools: Overlooked at risk

Risk of infection and transmission of SARS-CoV-2 among children and adolescents in households, communities and educational settings: A systematic review and metaanalysis

Prevalence of RT-qPCR-detected SARS-CoV-2 infection at schools: First results from the Austrian School-SARS-CoV-2 prospective cohort study

Estimating infectiousness throughout SARS-CoV-2 infection course

Epidemiology and transmission dynamics of COVID-19 in two Indian states

REACT-1 round 7 updated report: Regional heterogeneity in changes in prevalence of SARS-CoV-2 infection during the second national COVID-19 lockdown in England

Exponential growth, high prevalence of SARS-CoV-2, and vaccine effectiveness associated with the Delta variant

Trends in COVID-19 cases emergency department visits, and hospital admissions among children and adolescents aged 0-17 years -United States

Children's Hospital Association Children COVID-19: State Data Report. A Joint Report From the American Academy of Pediatrics the Children's Hospital Association -Summary of Publicly Reported Data From 49 States NYC. DC PR, and HU

Contact tracing during coronavirus disease outbreak South Korea

Shedding of viable virus in asymptomatic SARS-CoV-2 carriers

Prevalence of SARS-CoV-2 in Spain (ENE-COVID): A nationwide, population-based seroepidemiological study

SARS-CoV-2 infection in schools in a Northern French city: A retrospective serological cohort study in an area of high transmission france

SARS-CoV-2 infection in Children

Children with COVID-19 in pediatric emergency departments in Italy

Pathogenesis symptomatology, and transmission of SARS-CoV-2 through analysis of viral genomics and structure

SARS-COV-2 infection in children and newborns: a systematic review

Why Is COVID-19 less severe in children? a review of the proposed mechanisms underlying the age-related difference in severity of SARS-CoV-2 infections

Systematic review of COVID-19 in children shows milder cases and a better prognosis than adults

Characteristics and outcomes of children with coronavirus disease 2019 (COVID-19) infection admitted to US and Canadian pediatric intensive care units

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

Pre-activated antiviral innate immunity in the upper airways controls early SARS-CoV-2 infection in children

Natural mucosal barriers and COVID-19 in children

Immune responses to SARS-CoV-2 infection in hospitalized pediatric and adult patients

Challenges in defining long COVID: Striking differences across literature electronic health records, and patient-reported information

Pediatric long-COVID: an overlooked phenomenon?

Post-Acute COVID-19 outcomes in children with mild and asymptomatic disease

Systematic severe acute respiratory syndrome coronavirus 2 screening at hospital admission in children: A french prospective multicenter study

Updated Estimates of the Prevalence of Long COVID Symptoms

Preliminary evidence on long COVID in children

Update on Long COVID Prevalence Estimate (2021)

Post COVID-19 in children, adolescents, adults: results of a matched cohort study including more than 150,000 individuals with COVID-19

Risk factors for long covid in previously hospitalized Children Using the ISARIC global follow-up protocol: A prospective cohort study

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection in children and adolescents: A systematic review

Caring for critically ill children with suspected or proven coronavirus disease 2019 infection: Recommendations by the Scientific Sections' Collaborative of the European Society of Pediatric and Neonatal Intensive Care * . Pediatr

COVID-19 Laboratory-Confirmed Hospitalizations

Available online at

Underlying medical conditions associated with severe COVID-19 illness among children

Hospitalization of adolescents aged 12-17 years with laboratoryconfirmed COVID-19-COVID-NET

Characteristics and disease severity of US children and adolescents diagnosed with COVID-19

Available online at

Multisystem inflammatory syndrome in U.S. children and adolescents

Trends in geographic and temporal distribution of us children with multisystem inflammatory syndrome during the COVID-19 pandemic

Characteristics and outcomes of US children and adolescents with multisystem inflammatory syndrome in children (MIS-C) compared with severe acute COVID-19

6-Month multidisciplinary follow-up and outcomes of patients with pediatric inflammatory multisystem syndrome (PIMS-TS) at a uk tertiary pediatric hospital: a retrospective cohort study

Pediatric Multisystem inflammatory syndrome temporally associated with SARS-CoV-2 (PIMS-TS): Prospective, national surveillance United Kingdom and Ireland

Post-COVID Syndrome in non-hospitalized patients with COVID-19: a longitudinal prospective cohort study. The Lancet Regional Health-Europe

Identification and development of therapeutics for COVID-19

Centers for Disease Control and Prevention Epidemiology of COVID-19 in Children Aged 5-11 Years (2021)

Health Department-Reported Cases of Multisystem Inflammatory Syndrome in Children (MIS-C) in the United States (2021)

Incidence of multisystem inflammatory syndrome in children among us persons infected with SARS-CoV-2

infection fatality risk of the pandemic A(H1N1)2009 virus in Hong Kong

Case fatality rates based on population estimates of influenza-like illness due to novel H1N1 Influenza

The Resurgence of Measles in the United States, 1989-1990

Age-specific mortality and immunity patterns of SARS-CoV-2

Assessing the age specificity of infection fatality Rates for COVID-19: Systematic review, meta-analysis, and public policy implications

Peterson-KFF Health System Tracker: COVID-19 Continues to be a Leading Cause of Death in the U.S

Children and young people remain at low risk of COVID-19 mortality

Deaths in children and young people in england following SARS-CoV-2 infection during the first pandemic year: A national study using linked mandatory child death reporting data

COVID-19 mortality rate in children is U-shaped

Influenza-associated pediatric deaths in the United States

Remotelearning, time-use, and mental health of ecuadorian high-school students during the COVID-19 quarantine

Association of home quarantine and mental health among teenagers in Wuhan China during the COVID-19 pandemic

Association of children's mode of school instruction with child and parent experiences and well-being during the COVID-19 pandemic -COVID experiences survey United States

COVID-19, school closures, and child poverty: a social crisis in the making

Mental health and its correlates among children and adolescents during COVID-19 school closure: The importance of parent-child discussion

Suffering in silence: How COVID-19 school closures inhibit the reporting of child maltreatment

Distance learning and parental mental health during COVID-19

Children and the COVID-19 pandemic

Learning loss due to school closures during the COVID-19 pandemic

Projecting the potential impact of COVID-19 school closures on academic achievement

COVID-19 and Learning Loss -Disparities Grow and Students Need Help (2020)

Available online at: https://Insidesel. com/2020/11/19/the-Impact-of-the-Covid-19-Pandemic-on-Student-Learning-and-Social-Emotional-Development

The effects of absenteeism on academic and social-emotional outcomes: lessons for COVID-19

Effects of COVID-19 confinement on the mental health of children and adolescents in Spain

How Online Learning can Affect Student Health (2020)

Emergency department visits for suspected suicide attempts among persons aged 12-25 years before and during the COVID-19 pandemic -United States

Schools closures during the COVID-19 pandemic: a catastrophic global situation

Closure of schools during an influenza pandemic

Billion Learners Are Still Affected by School or University Closures, as Educational Institutions Start Reopening Around the World

The temporal association of introducing and lifting non-pharmaceutical interventions with the time-varying reproduction number (r) of SARS-CoV-2: a modeling study across 131 countries

A large COVID-19 outbreak in a high school 10 days after schools' reopening israel

Surveillance of COVID-19 school outbreaks Germany March to

Clusters of SARS-CoV-2 infection among elementary school educators and students in one school district-Georgia

Severe acute respiratory syndrome coronavirus 2 antibody prevalence in blood in a large school community subject to a coronavirus disease 2019 outbreak: A cross-sectional study

Outbreak associated With SARS-CoV-2 B. 1.617. 2 (Delta) variant in an elementary school-Marin County California

Svaleryd H. the effects of school closures on SARS-CoV-2 among parents and teachers

SARS-CoV-2 infection and transmission in educational settings: a prospective, crosssectional analysis of infection clusters and outbreaks in England

European Center for Disease Control COVID-19 in Children and the Role of School Settings in COVID-19 Transmission

Transmission of SARS-CoV-2 in Australian educational settings: a prospective cohort study

Article/Schools-Can-Open-Safely-During-Covid-the-Latest-Evidence-Shows/b (accessed

No evidence of secondary transmission of COVID-19 from children attending school in Ireland

Novel Coronavirus 2019 Transmission Risk in Educational Settings

Minimal transmission of SARS-CoV-2 from pediatric COVID-19 cases in primary schools

SARS-CoV-2 infections in italian schools: preliminary findings after 1 month of school opening during the second wave of the pandemic

COVID-19 in Victorian Schools: An Analysis of Child-Care and School Outbreak Data and Eviidence-Based Recommendations for Opening Schools and Keeping Them Open Murdoch Children's Research Institute and the University of

Community-level evidence for SARS-CoV-2 vaccine protection of unvaccinated individuals

Does re-opening schools contribute to the spread of SARS-CoV-2? Evidence from staggered summer breaks in Germany

Schà ¶Nberg U. The Role of Schools in Transmission of the SARS-CoV-2 Virus: Quasi-Experimental Evidence From Germany -CReAM Discussion Paper Series

To what extent does in-person schooling contribute to the spread of COVID-19? Evidence From Michigan and Washington

SARS-CoV-2 Transmission in educational settings during an early summer epidemic wave in Luxembourg

School Openings Affect Local COVID-19 Diffusion

The Effects of School Reopenings on COVID-19

Available online at: https://www.Reachcentered. org/Publications/the-Effects-of-School-Reopenings-on-Covid-19-Hospitalizations

The association of opening K−12 schools with the spread of COVID-19 in the United states: County-level panel data analysis

Household severe acute respiratory syndrome coronavirus 2 transmission and children: A network prospective study

Children and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) transmission: a step closer to better understanding and evidence-based interventions?

Mask use and ventilation improvements to reduce COVID-19 incidence in elementary schools -Georgia

Minimal SARS-CoV-2 transmission after implementation of a comprehensive mitigation strategy at a school -New Jersey

Weekly SARS-CoV-2 sentinel surveillance in primary schools kindergartens, and nurseries

Transmission of SARS-CoV-2 in children aged 0 to 19 years in childcare facilities and schools after their reopening in may 2020

COVID-19 cases and transmission in 17 K−12 schools -wood county wisconsin

Incidence and secondary transmission of SARS-CoV-2 infections in schools

Slight reduction in SARS-CoV-2 exposure viral load due to masking results in a significant reduction in transmission with widespread implementation

Household COVID-19 risk and in-person schooling

Reopening schools during COVID-19

Human error: Models and management

Initial report of decreased SARS-CoV-2 viral load after inoculation with the BNT162b2 vaccine

COVID-19 in children and the dynamics of infection in families

SARS-CoV-2 infection and transmission in school settings during the second COVID-19 wave: a cross-sectional study Berlin Germany

Clinical characteristics of children with COVID-19: a rapid review and meta-analysis

Assessment of SARS-CoV-2 screening strategies to permit the safe reopening of college campuses in the United States

Interpreting diagnostic tests for SARS-CoV-2

COVID-19 Testing: One size does not fit all

Comparison of saliva and nasopharyngeal swab nucleic acid amplification testing for detection of SARS-CoV-2: a systematic review and meta-analysis

Same-Day SARS-CoV-2 Antigen test screening in an indoor mass-gathering live music event: a randomized controlled trial

COVID-19 diagnostics in context

Antigenbased testing but not real-time polymerase chain reaction correlates with severe acute respiratory syndrome coronavirus 2 viral culture

point-of-care antigen and molecular-based tests for diagnosis of SARS-CoV-2 infection

Accuracy of rapid antigen detection test for nasopharyngeal swab specimens and saliva samples in comparison with RT-PCR and viral culture for SARS-CoV-2 detection

Accuracy of novel antigen rapid diagnostics for SARS-CoV-2: a living systematic review and meta-analysis

False negative tests for SARS-CoV-2 infection -challenges and implications

Test sensitivity is secondary to frequency and turnaround time for COVID-19 screening

Which policies most effectively reduce SARS-CoV-2 transmission in schools?

COVID-19 testing to sustain in-person instruction and extracurricular activities in high schools

Model-driven mitigation measures for reopening schools during the COVID-19 pandemic

But hurdles and uncertainties remain: scientific unknowns, access, and logistics are barriers to routine screening

Germany Makes Rapid Virus Tests a Key to Everyday Freedoms (2021)

Children Piloted for Rapid Antigen Test Use (2021)

Rapid Antigen Testing (2021)

As Schools Roll out Rapid Testing for COVID-19, Different Approaches Emerge Across Regions (2021)

COVID-19 in schools: Mitigating classroom clusters in the context of variable transmission

Monitoring Incidence of COVID-19 cases hospitalizations, and deaths, by vaccination status -13

Outbreak of SARS-CoV-2 infections including COVID-19 vaccine breakthrough infections associated with large public gatherings

Viral loads of Delta-variant SARS-CoV-2 breakthrough infections after vaccination and booster with BNT162b2

Association between risk of COVID-19 infection in nonimmune individuals and COVID-19 immunity in their family members

Identifying airborne transmission as the dominant route for the spread of COVID-19

Effectiveness of 3 vs. 6 ft of physical distancing for controlling spread of coronavirus disease 2019 among primary and secondary students and staff: a retrospective statewide cohort study

Proper handwashing promotes wellness in child care

Efficacy of triclosan as an antimicrobial hand soap and its potential impact on antimicrobial resistance: A focused review

Use of alcohol gel as an adjunct to handwashing in elementary school children

COVID-19 and frequent use of hand sanitizers; human health and environmental hazards by exposure pathways

The airborne lifetime of small speech droplets and their potential importance in SARS-CoV-2 transmission

Outdoor transmission of SARS-CoV-2 and other respiratory viruses: A systematic review

Aerosol emission and superemission during human speech increase with voice loudness

Statement of Work: Aerosol Generation From Playing Band Instruments Singing and Performing and Risk of Infectious Disease Transmission

Available online at

Articles/ Preliminary-Results-of-Performing-Arts-Aerosol-Study-Depict-Hopeful-Outlook-for-Future-Music-Activities

Reducing transmission of SARS-CoV-2

The impact of face masks on childrena mini review

Available online at

Available online at

The World Health Organization

Face masks in young children during the COVID-19 pandemic: Parents' and pediatricians' point of View

Assessment of respiratory function in infants and young children wearing face masks during the COVID-19 pandemic

The impact of facemasks on emotion recognition, trust attribution and reidentification

Speech intelligibility assessment of protective facemasks air-purifying respirators

The McGurk effect in the time of pandemic: age-dependent adaptation to an environmental loss of visual speech cues

Government of Ireland Department of Education. Practical Steps for the Deployment of Good Ventilation Practices in Schools V3

Novel Coronavirus (COVID-19) Pandemic: Built Environment Considerations To Reduce Transmission

Healthy Schools: Risk Reduction Strategies for Reopening Schools

Chan School of Public Health Healthy Buildings program

Harvard-Healthy-Buildings-Program-Schools-For-Health-Reopening-Covid19-June2020.pdf

Indoor air changes and potential implications for SARS-CoV-2 transmission

Minimum infective dose of the major human respiratory and enteric viruses transmitted through food and the environment

The evidence of SARS-CoV-2 infection on ocular surface

The Early Phase of the COVID-19 Outbreak in Lombardy Italy

Syrian hamsters as a small animal model for SARS-CoV-2 infection and countermeasure development

Inoculum at the time of SARS-CoV-2 exposure and risk of disease severity

Overdispersion in COVID-19 increases the effectiveness of limiting nonrepetitive contacts for transmission control

What settings have been linked to SARS-CoV-2 transmission clusters?

Clustering and superspreading potential of SARS-CoV-2 Infections in Hong Kong

Age-dependency of the propagation rate of coronavirus disease 2019 inside school bubble groups in catalonia Spain

Social network-based distancing strategies to flatten the COVID-19 curve in a post-lockdown world

An examination of school reopening strategies during the SARS-CoV-2 pandemic

Social network-based cohorting to reduce the spread of SARS-CoV-2 in secondary schools: a simulation study in classrooms of four european countries

LA serves on the medical advisory board of the MLD Foundation, CureMLD and "Don't Forget Morgan". She is a consultant for Orchard Therapeutics, Biogen, and Takeda. She receives compensation and/or research funding for these roles. Additionally, she serves as an uncompensated member of the Board of Trustees and the scientific COVID-19 advisory committee of the Waldorf School of Philadelphia. GF is a chief scientific advisor for the journal Science Translational Medicine and is a senior advisor to Calico Laboratories and receives compensation for both roles. TG serves as an editor for the journal Circulation Genomic and Precision and receives compensation from the American Heart Association for this work. He was an uncompensated member of the Board of Trustees of the Waldorf School of Philadelphia and serves on the school's scientific COVID-19 advisory committee without compensation.The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.Publisher's Note: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.