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      Update on guidance and best practices for nuclear cardiology laboratories during the coronavirus disease 2019 (COVID-19) pandemic: Emphasis on transition to chronic endemic state. An information statement from ASNC, IAEA, and SNMMI

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          Abstract

          Pandemics have different phases and transition scenarios. Regardless of the phase, health service providers must be prepared, have strategic response plans, and implement specific measures with the ultimate goal of continuing to provide essential services while protecting patients, staff, and the public to prevent the spread of disease. 1 The American Society of Nuclear Cardiology (ASNC) along with the Society of Nuclear Medicine and Molecular Imaging (SNMMI) have previously published two documents on guidance and best practices for nuclear cardiology laboratories during the COVID-19 pandemic. 2,3 The first document provided recommendations when early containment measures, such as lockdowns, quarantines, and curfews were adopted. The second document (which was also authored by The International Atomic Energy Agency [IAEA] and endorsed by the Infectious Diseases Society of America) primarily dealt with reopening laboratories following the lockdown period and issues such as the prioritization of cases. Other medical societies have published similar advice documents. 4–6 As the COVID-19 pandemic evolves, we have seen the emergence of several variants with changes in disease severity and transmissibility. Vaccination rates have increased, as have rates of post-infection immunity. However, scientists are in a race to identify how virus mutations could affect our immunity and the effectiveness of vaccines available. Cases of people experiencing break-through infections and re-infections are on the rise. On the positive side, newer oral and intravenous therapeutics have shown promise in treating patients with mild to moderate disease who are at high risk, as well as for certain high-risk patients pre-exposure. 7–9 Around the world, there remains a disparity in availability of resources. Particularly during times of increasing infection rates, the availability of personal protective equipment (PPE), mechanical ventilation systems, testing equipment, medical staff, and hospital beds—especially ICU beds—becomes more tenuous. Given these factors, we present updated guidance for best practices in nuclear cardiology as we move from a pandemic to a chronic endemic state. The approach to nuclear stress testing should be flexible A major takeaway from this guidance is that there is no status quo during this pandemic. Local case rates will be variable and may change rapidly. The decision to proceed with nuclear testing, as well as with any other cardiac imaging test, and the approach should include risk/benefit assessments for both the patient as well as analysis of the impact on the local healthcare system, including risk to the medical staff. Laboratories should also continue to vary their approach based on levels of infection in the community as well as local institutional and governmental policies. 4 Please see Figure 1. Table 1 lists practice recommendations that should be employed when case rates of COVID-19 are high or rising, and Table 2 lists the U.S. Centers for Disease Control definitions of levels of rates of transmission. 10 Figure 1 Recommendations: as the level of COVID-19 transmission severity increases in a community, laboratories should enhance levels of screening, PPE, social distancing practices, and hygienic measures, and perform stress testing predominantly with vasodilator pharmacologic agents rather than exercise. However, as levels of transmission are low and stable, these measures can and should be relaxed. See Table 2 for the U.S. Centers for Disease Control and Prevention definitions for the 4 levels of severity of transmission 9 Table 1 Recommended nuclear cardiology practices when COVID-19 cases are high or rapidly rising in a community Restrict visitors in the nuclear cardiology laboratory Provide screening questionnaires, temperature screening, and frequent COVID-19 testing for all patients, and PPE for all patients and staff Vasodilator stress rather than exercise for the majority of patients with the understanding that exercise testing, when needed, can be performed safely For patients who benefit from testing with exercise, routine use of rapid COVID-19 testing and enhanced PPE should be available Strong preference for PET MPI over SPECT MPI when pharmacologic stress is planned, and PET is available Restriction of testing to the highest priority patients when the case rates are extremely high, hospital resources are overwhelmed, or staffing shortages are extreme Table 2 CDC Definitions of County Transmission Severity 10 “Low” transmission ≤10 cases per 100,000 people, or a test positivity rate <5% “Moderate” transmission = 10 to 50 cases per 100,000 people, or positivity rate 5% to 8% “Substantial” transmission = 50 to 100 cases per 100,000, or a positivity rate 8% to 10% “High” transmission ≥100 cases per 100,000 people or a positivity rate >10% If a county has values in two different transmission levels, use the metric that is higher. Healthcare team wellbeing Nuclear cardiology laboratories continue to be impacted by major staffing issues. In prior guidance statements, COVID-19 best practices focused on methods to operate safely and efficiently. 2,3 During this stage of the pandemic, even greater attrition of healthcare personnel has been seen secondary to both the physical and mental stress of working during the pandemic. 11,12 In addition, more recent variants, such as Omicron, are highly infectious and have the capability to incapacitate large numbers of healthcare workers resulting in acute staffing shortages and test cancellations. Not only do laboratories need to optimize safety practices to prevent transmission to and from patients and try to mitigate service disruption to allow access for needed diagnostic tests, but they also need to manage the demands upon the general working environment for the healthcare providers. Thus, some practices to enhance access and social distancing, such as extending hours of operation, may not be advisable if it will tax the already stressed or short-handed workforce. Also, even if the level of COVID-19 infections in a community is low, services may nonetheless need to be restricted if the nuclear cardiology staff is inadequate. It is imperative that healthcare workers have proper supplies of PPE and have priority for vaccinations (and comply with appropriate local COVID-19 vaccine mandates). A workflow should be established at all testing locations for enforcing masking requirements, so the primary burden does not fall on the nuclear cardiology staff. In the long run, medical facilities will likely need to be designed and built to better accommodate features of sanitation and social distancing that have been developed during this pandemic. Guidance on exercise testing In the pre-COVID era, the guidance generally had been to utilize exercise as the preferred stress modality for SPECT imaging when (a) the patient was able to exercise adequately, and (b) there were no electrocardiographic or medical contraindications. During the COVID-19 pandemic, this approach has often been modified to limit exercise stress in favor of pharmacological testing, 2,3 reasoning that pharmacologic stress myocardial perfusion imaging (MPI) risk stratifies as well as exercise stress, 13 and it likely leads to less aerosolization. To date, there has been no evidence to support an increased risk of COVID transmission to patients who underwent exercise testing. Rather, the concern has been the potential increased risk to the healthcare team. Respiratory patterns change when patients undergo treadmill or bicycle exercise testing, and data support an increased risk of droplet spread, with a potential increase in the associated risk of infection to the healthcare team in the exercise/nuclear laboratory. 14–16 The functional assessment, hemodynamic, and electrocardiographic data obtained from exercise testing has value, and the benefit of this approach must be weighed against the potential risk to the healthcare team. In selecting a stress method, and in particular whether or not to perform exercise, we recommend consideration of several factors, including (a) availability of PPE; (b) room ventilation systems—laminar flow ventilation and appropriate air filters; 17–19 (c) availability of pre-test COVID-19 screening; (d) current local COVID-19 infection rates; (e) current local vaccination rates and individual vaccination status (patient and staff) to help balance the localized lab approach to utilization of exercise testing. There are clinical scenarios where exercise stress is indeed needed. For example, the utility of exercise testing is widely accepted in the management of patients with asymptomatic aortic valve stenosis, anomalous coronary arteries, myocardial bridging, and some patients with cardiac arrhythmias. In these cases, pharmacologic stress testing may not be an appropriate substitute. Moreover, vasodilator pharmaceutical stress agents are not available in some countries and add to the cost structure of the test. Where COVID-19 testing is available, appropriate PPE is worn, and other infection prevention and control policies apply, exercise testing can be performed with reasonable safety, in particular when rates of COVID-19 infections in a community are low. Patient screening can be done in several ways: questionnaires, temperature checks, and rapid antigen testing. Conditions in a community can change very quickly, and health insurance companies should give medical decision makers latitude in choosing the best testing strategy and should not mandate exercise stress. Nuclear cardiology testing in COVID-positive patients Myocardial perfusion imaging is generally an elective test, and for most patients who are ill with an acute COVID-19 respiratory infection, the test can be postponed until their quarantine period has ended, at the discretion of the testing physician. Those who test positive for COVID-19 and have non-urgent cardiovascular symptoms usually should have their stress test postponed until their quarantine period has ended. Emergency room and hospital-based patients should be assessed on a case-by-case basis to balance the risk of the procedure to the patient and staff versus the benefit of the information obtained. There are also patients who are COVID-19-positive (including virus asymptomatic patients), who urgently need MPI (e.g., preoperative testing prior to urgent vascular surgery), or those who need other types of nuclear cardiology tests, such as 18F-FDG metabolic imaging to evaluate possible endocarditis, device infections, myocardial viability, or cardiac sarcoidosis. In cases when a patient who has an active case of COVID-19 needs a nuclear cardiology test, laboratory-based protocols must be established, including the timing of the test (i.e., last test of the day to minimize exposure to other staff/patients), thorough cleaning and ventilation protocols, limiting the number of staff involved in the test, and use of appropriate PPE, which should include high-filtration masks (N95, FFP2, KN95, or KF94, as locally available), gloves, surgical gowns, and eye protection. 20 Affirmation of previously recommended best practices for nuclear cardiology It seems clear that some of the modifications laboratories have made to their standard operating procedures over the past two years will continue to be necessary. For example, COVID-19 screening, efforts at social distancing (including extra waiting room space), and increased use of PPE will remain very important. Also, the use of rapid and reliable COVID-19 testing, especially when prevalence rates are high, should be assessed locally on a case-by-case basis. Likewise, laboratory schedules must include time and resources for enhanced cleaning. The safety of healthcare workers and maintenance of high-quality imaging is critical. To emphasize, specific protocols that enhance social distancing and limit the exposure of patients and staff will remain important. Certain specific testing protocols (in addition to other benefits) can result in shorter test time and, therefore, limit COVID-19 related risk. For example, stress-first/stress-only SPECT imaging can shorten the test duration in some patients by more than 50%, and two-day SPECT MPI protocols can enhance social distancing. Also, PET MPI can be performed more quickly than SPECT and is routinely performed in one location rather than having the patient move between several rooms. Finally, in the case of SPECT-CT and PET-CT, it remains good practice to examine the CT images prior to the patient leaving the medical facility to detect possible occult COVID pneumonia as soon as possible to limit further transmission from the infected patient. Table 3 lists best practices that should endure even in times of relatively low levels of COVID activity in a community or if COVID-19 becomes an endemic disease. Table 3 Recommended nuclear cardiology practices regardless of whether COVID-19 cases are low, intermediate, or high in a community Maintain extra distancing in waiting areas and corridors in the laboratory Enhanced cleaning of imaging spaces and preparation areas between patients. Allow extra time between cases for enhanced cleaning and maintenance of social distancing Lengthen work hours as needed to allow extra time and physical distance between cases and to maintain access to testing if staffing is available Dedicated room for exercise testing, ideally with laminar flow ventilation and appropriate air filters Stress-first/stress-only SPECT MPI protocols when possible Encourage two-day SPECT MPI protocols (with weight-based radiotracer dosing) to enhance social distancing and improve laboratory efficiency when feasible PET MPI in preference to SPECT MPI when pharmacologic stress is planned, and PET is available For PET-CT and SPECT-CT cases, routine review of the CT images as soon as possible Staff, patients, and visitors should be encouraged to be fully vaccinated, practice frequent hand washing, and avoid large gatherings Conclusion Much has changed since the COVID-19 pandemic was declared in March 2020. Emphasis has been placed on protecting the lives and livelihoods of people around the world. Global efforts were made to have vaccines, specific treatments, and improved access to PPE. The global pandemic is not yet over; there is considerable uncertainty about the path the pandemic will take. Scientists predict that over time COVID-19 will become endemic, and there will continue to be sporadic outbreaks in which it spirals out of control. The transition from pandemic to endemic is likely to play out differently in different parts of the world. Nuclear cardiology laboratories have adapted in many ways and will continue to provide high-quality, patient-centered, and optimized care. This can be accomplished with a continued focus on efficient screening, implementation of infection prevention and control measures, such as physical social distancing and sharing best practices. Proper care of the healthcare workforce and dealing with staffing shortages has risen as a key focus. As we move forward, it will be important to continue to have a flexible approach, adjusting levels of caution based on local health and regulatory conditions. Many of the lessons learned during the first two years of the pandemic will continue to be valuable going forward. 21 Disclosures Dr. Al-Mallah has served as a consultant to Pfizer, Philips, and Jubilant; he has received grant support from Siemens. Dr. Bateman holds intellectual property rights in and receives royalties from Cardiovascular Imaging Technologies; he has served as a consultant to AIM, AstraZeneca, Curium, and GE Healthcare; and he has received grant support from Bracco, JDI Solutions, and GE Healthcare. Dr. Dilsizian has received grant support from GE Healthcare. Dr. Dorbala has received grant support from Pfizer, GE Healthcare, and Attalus; she serves on the advisory board for Pfizer, GE healthcare, Janssen, and Eidos; she serves on the speakers’ bureau for Ionetix. Dr. Einstein has received speaker fees from Ionetix; has received consulting fees from W. L. Gore & Associates; has received authorship fees from Wolters Kluwer Healthcare – UpToDate; and has received grants or grants pending to his institution from Attralus, Canon Medical Systems, Eidos Therapeutics, GE Healthcare, Pfizer, Roche Medical Systems, and W. L. Gore & Associates, and XyloCor Therapeutics. Dr. Ghesani serves on the advisory board for GE Healthcare; he serves on the speakers’ bureau for Blue Earth and Novartis. Dr. Gimelli serves on the advisory board for Pfizer and GE Healthcare. Dr. Phillips serves as a consultant to NovoNordisk. Dr. Skali serves as a consultant to Astellas and has received research support form ABT Associates. The following contributors have nothing relevant to disclose: Dennis A. Calnon, MD, MASNC; Suzanne F. Crews, MPA, RT, NMTCB; Maurizio Dondi, MD; Felix Keng Yung Jih, MBBS, MASNC; Diana Paez Gutierrez, MD; Randall C. Thompson, MD, MASNC.

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          Airborne Transmission of SARS-CoV-2: Theoretical Considerations and Available Evidence

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            COVID-19 pandemic: guidance for nuclear medicine departments

            Background Coronaviruses are non-segmented, enveloped positive-sense ribonucleic acid viruses from the Coronaviridae family. There are six types of the coronavirus known to infect humans. Four of them cause mild respiratory symptoms, while two of them, the Middle East respiratory syndrome coronavirus (MERS) and the severe acute respiratory syndrome (SARS), have caused epidemics with high mortality rates [1, 2]. In December 2019, a new type of coronavirus 2019-nCoV/SARS-CoV-2, causing COVID-19 disease, was extracted and identified from the lower respiratory tract samples of several patients in Wuhan, China [3]. These patients presented with symptoms of severe pneumonia, including fever, fatigue, dry cough, and respiratory distress. The coronavirus disease 19 (COVID-19) is a highly transmittable and pathogenic viral infection. It is believed to be transmitted via respiratory droplets and fomites during close unprotected contact between an infector and an infectee. The coronaviruses mainly infect epithelial cells in the lung, but SARS-CoV-2 has been detected in respiratory, fecal, and blood specimens of patients infected with the virus [4]. On February 3, 2020, the World Health Organization declared a public health emergency of international concern, and on March 11, declared COVID-19 a pandemic [5]. The total number of confirmed cases, deaths associated with COVID-19, and affected countries and territories continues to grow; detailed statistics can be found at the WHO–Coronavirus disease (COVID-19) Pandemic site [5] or the John Hopkins Coronavirus Resource Centre. [6]. Health care providers around the world are facing challenging decisions. They are rapidly adjusting their standard operating procedures (SOPs) to cope with the pandemic cases and deliver their services. This is done in line with local guidance, resources available, and the advice of the World Health Organization (WHO) Minimum Requirements for infection prevention and control (IPC) programmes [7]. This publication was prepared based on the systematic review of available literature on the subject and the contribution of a panel of international experts during the webinar entitled “Coronavirus disease (COVID-19) Pandemic: Challenges for the Nuclear Medicine Departments,” organized by the International Atomic Energy Agency (IAEA) and broadcasted live on Wednesday 25 March 2020 [8]. The objective of this guide is not to override any local guidance or national practice guidelines or rules, nor does it provide comprehensive advice on all aspects of nuclear medicine practice. It is solely intended as advice for nuclear medicine facilities during this time of adjustment and adaptation to the COVID-19 pandemic. We present suggested recommendations for nuclear medicine departments to follow, based on a typical patient’s “journey” through the department. General measures During the COVID-19 pandemic, SOPs in nuclear medicine (NM) departments should be adapted. In addition to the established procedures, special emphasis must be placed on minimizing the risk to staff, patients, and family members, as well as controlling the transmission of the virus while continuing to provide the essential and critical services. The World Health Organization (WHO) has published the “COVID-19: Operational Guidance for maintaining essential health services during an outbreak” [9] which includes six main processes that can be extrapolated to nuclear medicine facilities (Table 1). Table 1 Operational Processes. Adapted from “WHO–COVID-19: Operational Guidance for maintaining essential health services during an outbreak” I. Establish simplified purpose-designed governance and coordination mechanisms II. Identify context-relevant essential services III. Optimize service delivery settings and platforms IV. Establish effective patient flow (screening, triage, and targeted referral) at all levels V. Rapid re-distribution of health workforce capacity, including re-assignment of tasks VI. Identify mechanisms to maintain the availability of essential equipment and supplies Establish simplified purpose-designed governance and coordination mechanisms NM departments must be flexible and adapt, considering the stage of the epidemic in the population they serve. Establish a COVID-19 Incident Management Team and designate a focal point. Consideration for the reallocation of human, financial and material resources, and mobilizing additional resources are essential. All staff members should receive specific training in identifying COVID-19 symptoms, hygiene procedures, handling COVID-19 patients, disinfection procedures, and use of personal protective equipment (PPE), among others [10, 11]. Managers must inform staff not to report to work if they feel unwell or have any suspicion of having COVID-19 symptoms. Facilities must ensure that the waiting area has access to handwashing facilities and that hand sanitizers, tissue boxes, and masks are within reach so that patients can follow basic hygiene practices. The waiting areas need to be organized in such a way that it provides space for patients to sit at a distance from each other to reduce the risk of transmission. It is essential to ensure strict hand hygiene, maintaining at least 1 m (3 ft) distance [5] in all patient/staff interactions when possible, avoiding crowding at the workplace, etc. Implementation of cleaning and disinfecting procedures for equipment and accessories including camera gantries, patient beds, blood pressure cuffs, workstations, mouse, keyboards, and any other items of daily use. Develop a contingency and business continuity plan if one of the staff becomes sick with COVID-19. Identify context-relevant essential services NM departments should continue their operation. It is essential to exert flexibility and adapt the patient schedule to maintain the provision of essential services. Special attention must be paid to adjust the provision of services, taking into account the phase of the epidemic in the local population served. Essential procedures (scans and therapies) must be identified and prioritized. Postponing non-essential procedures as well as research activities should be considered. Teaching activities should be given through dedicated teleconferencing software or postponed. It is essential to establish a work plan to reinstate delayed services or events [12–15]. Optimize service delivery settings and platforms Use of communication technologies must be a primary consideration. Teleconsulting with patients prior to scheduling and the day before attending the nuclear medicine center must be established, in order to identify patients who may have COVID-19 symptoms. Patients should be instructed to attend their appointments alone, if their condition allows. In case assistance is required, only one accompanied person, ideally without risk factors, should be permitted. The risk factors should be stated during the phone appointment. Remote reporting should be considered, when possible, provided that national or local rules are followed. Teleconsultation with patients after radionuclide therapies is strongly encouraged. Establish virtual multidisciplinary meetings. Establish remote communication channels with referring physicians. Establish effective patient flow (screening, triage, and targeted referral) at all levels In addition to the established procedures including radiation protection, it is crucial to guarantee the adherence to recommendations, including (1) distancing, (2) hygiene, (3) separate spaces for patients with known or suspected COVID-19 to prevent spread, and (4) ensuring supplies are available. Departments sited in COVID-19 hot spot zones should instruct all front-line personnel to rigorously follow local PPE guidance before dealing with patients. The possibility of airborne transmission of COVID-19 continues to be debated [5, 16]. It is known that airborne viruses can spread in air conditioning and ventilation systems and therefore it can be expected that certain medical procedures associated with the generation of aerosols, such as ventilations scans and oxygen supplementation, carry an increased risk of transmission. Therefore, alternative options for test or procedure should be considered or special precautions especially for personnel conducting these tests must be taken. Patient arrival, waiting area Reception staff to be sited behind a glass or plastic screen if not already in place. Upon arrival, patients are asked to declare if they have been in contact with patients with COVID-19 or if they have any symptoms. It is useful to display information announcements at the reception, indicating possible symptoms and asking patients to inform staff if they have symptoms. Display posters to promote handwashing and proper respiratory hygiene measures. Consideration should be given to implement temperature control using electronic skin contact systems. Be vigilant in identifying patients with symptoms of COVID-19. Consider that there are asymptomatic patients and apply all protective and hygiene measures. When patients with COVID-19 are identified, they should be placed in a separate waiting area, and if available, appropriate consultation with the infectious diseases team should be sought. COVID-19 patients should wear a surgical mask to minimize the risk of transmission. Consider providing surgical masks to all patients and chaperones, to wear at all times while in the NM center. Remember that local or national regulations must be followed. During the injection and scan Use all aseptic and antiseptic techniques Apply all standard radiation protection and optimisation principles; Use the appropriate PPE Place special attention when removing the gloves and other protective elements Disinfect the devices used during patient preparation and injection Thoroughly sanitize hands after each procedure Dispose the used protective elements in a container for biosafety waste During the scan Apply all standard radiation protection and optimisation principles Use the appropriate PPE Use disposable protective elements for the scanners When the patient is scanned and goes home After scanning a COVID-19 patient, scanners and room surfaces should be disinfected to prevent possible spread of infection. If available, local recommendations and guidelines should be followed, e.g., Public Health England has released a guide for disinfecting scanners and clinic rooms with solutions containing 1000 ppm available chlorine, and appropriate training for environmental maintenance personnel is recommended. Before the patient is released, if the hybrid study involves a CT of the chest, it is imperative to look for incidental COVID-19 findings that might suggest COVID-19 infection. If incidental COVID-19 findings are detected in the lungs, it must be reported immediately to the referring clinician, and the patient triaged for the appropriate care pathway. Rapid re-distribution of health workforce capacity, including re-assignment of tasks Health care personnel are at a high risk for exposure and susceptible to contracting the virus. For this reason, we must be vigilant in recognizing symptoms [17]. The same precautions and screening tests that apply to patients upon arrival should be implemented for the nuclear medicine staff. Simple measures, such as staying home if you are not feeling well, are essential to reducing the risk of infection and transmission to the team. Consider segregating staff into teams to reduce the possibility of virus transmission between health care providers which could result in the inability of the department to function. Consider re-training of staff to cover other positions within the department. All required personal protective equipment (PPE) should be made available for staff at all times and all working sites. It is recommended to follow guidelines of the WHO–Rational use of personal PPE for coronavirus disease (COVID-19) [10]. Consider providing staff transportation and, if necessary, staff accommodation. Environmental services staff members who clean all departmental areas during, and out of, working hours must be specifically trained for professional cleaning of potentially contaminated surfaces after each contact with a high-risk patient. Establish periodic virtual staff meetings to update on the local status of the pandemic and enquire about their well-being. Psychological consultation for staff should be available. Identify mechanisms to maintain the availability of essential equipment and supplies Nuclear medicine centers rely on the availability of radioisotopes that are produced in a limited number of facilities worldwide and depend on adequate distribution channels. Due to the pandemic, the availability of international flights, including cargo, has been dramatically reduced. Shortages of kits and radioisotopes are therefore expected. At this point in time, some countries in Africa, Asia, and Latin America have reported shortages of radioiodine and have been informed by providers of the possible shortage of molybdenum-technetium generators. It is essential to ensure, as far as possible, the uninterrupted operation of cyclotrons to ensure the provision of PET services to oncologic patients. In the likely scenario where there is a shortage of supplies for SPECT studies, it might be useful to explore additional clinical applications of PET including cardiac, neurological, and infection/inflammation studies. It is essential for managers of nuclear medicine facilities and cyclotron centres to make a: List of required supplies List of all possible suppliers and distribution channels Maintain a detailed inventory and to coordinate the redistribution of supplies Conclusion The current COVID-19 pandemic poses many challenges for the practice of nuclear medicine. If adequately prepared, departments can continue to deliver their essential services, while mitigating the risk for patients and staff. This requires adapting the SOPs, as quickly as possible, to meet the new requirements. A multifactorial approach covering all elements from patient scheduling to reporting scans and paying attention to incidental COVID-19 suspected findings, must be adopted. A summary of which is presented in Table 2. Table 2 Essential considerations The robust screening process for patients and staff Identification of cases promptly Social distancing Training of staff members Posters to promote handwashing and proper respiratory hygiene Cleaning and disinfection of equipment and accessories Hand sanitizing dispensers Stay at home or working from home guidelines for staff Develop a contingency and business continuity plan Individual hygiene, disinfecting and cleaning, as well as the use of appropriate PPE, must be emphasized and practiced. The intention of this guide is to provide support to nuclear medicine centers for the COVID-19 pandemic; a more detailed guide is being prepared by the IAEA and will be available in due course.
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              Ventilation and air cleaning to limit aerosol concentrations in a gym during the COVID-19 pandemic

              SARS-CoV-2 can spread by close contact through large droplet spray and indirect contact via contaminated objects. There is mounting evidence that it can also be transmitted by inhalation of infected saliva aerosol particles. These particles are generated when breathing, talking, laughing, coughing or sneezing. It can be assumed that aerosol particle concentrations should be kept low in order to minimize the potential risk of airborne virus transmission. This paper presents measurements of aerosol particle concentrations in a gym, where saliva aerosol production is pronounced. 35 test persons performed physical exercise and aerosol particle concentrations, CO2 concentrations, air temperature and relative humidity were obtained in the room of 886 m³. A separate test was used to discriminate between human endogenous and exogenous aerosol particles. Aerosol particle removal by mechanical ventilation and mobile air cleaning units was measured. The gym test showed that ventilation with air-change rate ACH = 2.2 h−1, i.e. 4.5 times the minimum of the Dutch Building Code, was insufficient to stop the significant aerosol concentration rise over 30 min. Air cleaning alone with ACH = 1.39 h−1 had a similar effect as ventilation alone. Simplified mathematical models were engaged to provide further insight into ventilation, air cleaning and deposition. It was shown that combining ventilation and intensive air cleaning can reduce aerosol particle concentrations by factors of 2.3 up to 3.7 depending on aerosol size, compared to ventilation alone. This combination of existing ventilation supplemented with air cleaning is energy efficient and can also be applied for other indoor environments.
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                Author and article information

                Contributors
                rthompson@saint-lukes.org
                Journal
                J Nucl Cardiol
                J Nucl Cardiol
                Journal of Nuclear Cardiology
                Springer International Publishing (Cham )
                1071-3581
                1532-6551
                2 May 2022
                : 1-6
                Affiliations
                [1 ]GRID grid.266756.6, ISNI 0000 0001 2179 926X, Department of Cardiology, Saint Luke’s Mid America Heart Institute, , University of Missouri-Kansas City, ; Kansas City, MO USA
                [2 ]GRID grid.240324.3, ISNI 0000 0001 2109 4251, Division of Cardiology, , NYU Langone Medical Center, ; New York, NY USA
                [3 ]GRID grid.411024.2, ISNI 0000 0001 2175 4264, Department of Diagnostic Radiology and Nuclear Medicine, , University of Maryland School of Medicine, ; Baltimore, MD USA
                [4 ]GRID grid.420221.7, ISNI 0000 0004 0403 8399, Nuclear Medicine and Diagnostic Imaging Section, Division of Human Health, Department of Nuclear Sciences and Applications, , International Atomic Energy Agency, ; Vienna, Austria
                [5 ]GRID grid.413734.6, ISNI 0000 0000 8499 1112, Seymour, Paul, and Gloria Milstein Division of Cardiology, Department of Medicine, and Department of Radiology, , Columbia University Irving Medical Center and NewYork-Presbyterian Hospital, ; New York, NY USA
                [6 ]Nuclear Cardiology, Northeast Georgia Health System, Gainesville, GA USA
                [7 ]GRID grid.38142.3c, ISNI 000000041936754X, Division of Nuclear Medicine and Molecular Imaging, Department of Radiology, Brigham and Women’s Hospital, , Harvard Medical School, ; Boston, MA USA
                [8 ]GRID grid.38142.3c, ISNI 000000041936754X, Cardiovascular Division, Department of Medicine. Brigham and Women’s Hospital, , Harvard Medical School, ; Boston, MA USA
                [9 ]GRID grid.419385.2, ISNI 0000 0004 0620 9905, National Heart Centre, ; Singapore, Singapore
                [10 ]GRID grid.452599.6, ISNI 0000 0004 1781 8976, Fondazione Toscana Gabriele Monasterio, ; Pisa, Italy
                [11 ]GRID grid.63368.38, ISNI 0000 0004 0445 0041, Department of Cardiology, , Houston Methodist DeBakey Heart and Vascular Center, ; Houston, TX USA
                [12 ]GRID grid.416167.3, ISNI 0000 0004 0442 1996, Icahn School of Medicine, , Mount Sinai Hospital, ; New York, NY USA
                [13 ]GRID grid.430016.0, ISNI 0000 0004 0392 3548, OhioHealth Heart and Vascular Physicians, ; Columbus, OH USA
                [14 ]American Society of Nuclear Cardiology (ASNC), Fairfax, VA USA
                [15 ]GRID grid.420221.7, ISNI 0000 0004 0403 8399, International Atomic Energy Agency (IAEA), ; Vienna, Austria
                [16 ]GRID grid.437733.7, ISNI 0000 0001 2154 8276, Society of Nuclear Medicine and Molecular Imaging (SNMMI), ; Reston, VA USA
                Article
                2984
                10.1007/s12350-022-02984-9
                9059683
                35499661
                4ca00825-42a2-4415-b048-2396f1fab122
                © The Author(s) under exclusive licence to American Society of Nuclear Cardiology 2022

                This article is made available via the PMC Open Access Subset for unrestricted research re-use and secondary analysis in any form or by any means with acknowledgement of the original source. These permissions are granted for the duration of the World Health Organization (WHO) declaration of COVID-19 as a global pandemic.

                History
                : 18 April 2022
                : 18 April 2022
                Categories
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                Cardiovascular Medicine
                Cardiovascular Medicine

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