Healthcare | Free Full-Text | Nosocomial Coronavirus Disease 2019 during 2020–2021: Role of Architecture and Ventilation

Nosocomial coronavirus disease 2019 (COVID-19) is a major health threat for inpatients [1,2,3]. Although vaccination provides protective effects, the surge in Omicron infections was associated with a significant increase in hospital-onset severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infections [4]. Notably, nosocomial infections have higher mortality rates than community-acquired diseases, particularly in the elderly or patients who have suppressed immune systems [1,5,6]. Hence, this issue must be addressed to reduce mortality due to COVID-19. There is a continuum between droplets (particles > 5 µm) and particles (7], particularly in indoor settings [8]. Therefore, there is a risk for near-source as well as far-afield transmission caused by these particles, particularly within enclosed spaces and areas with inadequate ventilation [9,10,11]. Single rooms limit close contamination. Ventilation, and filtration procedures can reduce or remove the number of virus-laden aerosols and provide a determined volume of air changes per hour (ACH), reducing far-afield contamination among patients, healthcare workers (HCWs), and visitors [12,13]. Ventilation systems can be classified into natural and mechanical systems. Natural ventilation (NV) from outdoor air results in a low ACH, especially without regular aeration via opening of the windows, and it is present in households and older medical structures or long-term care facilities. New strategies in ventilation and building conception have been described following the COVID-19 pandemic to diminish viral transmission in healthcare settings; these modifications include increasing the ventilation rates, avoiding air recirculation, minimizing the number of people indoors [14], and using filtration and other purification techniques installed in the HVAC systems, mobile (high-efficiency particulate air) HEPA filtration units [8,15], or UV-based technologies [16].

Hôpitaux Civils de Colmar (Figure 1) is a tertiary hospital with two main establishments within the same geographical zone: a historical establishment (H) with multiple buildings built during the 20th century and having NV, except for toilets with exhaust fans (558 short-stay beds, 53% single rooms), and a modern establishment (M) opened in 2018 and having double-flow mechanical ventilation (MV), allowing fresh air to be injected into patients’ rooms (141 short-stay beds, 91% single rooms). The structural characteristics thus differ, mainly by a higher number of single rooms and enhanced ventilation in M. H is mainly dedicated to adults in medical and surgical departments, and M to patients in the pediatric and obstetrics and gynecology departments but also in the intensive care unit (ICU). Since the end of 2020 and the implementation of universal screening for hospitalized patients due to the COVID-19 pandemic, we aimed to retrospectively assess the burden of nosocomial COVID-19 (NC) and the impact of the type of building (ventilation) and the ratio of single/double rooms on the risk of NC.

During the study period, 33,718 patients were hospitalized, with an average hospital stay of 5.4 days (d), including 25,038 patients in H (74.3%) and 8680 in M (25.7%) with an average length stay of 5.5 and 4.7 d, respectively (Table 1). Overall, 1020 patients presented with COVID-19, which included 150 (14.7%) with NC. Nosocomial infection occurred at a median delay of 12 days (Q1: 7 d, Q3: 19 d). When comparing the 150 patients with NC to 870 with non-nosocomial COVID-19, patients with NC were older (79 vs. 72 years; p p Figure 2). A total of 149 (99.3%) cases were acquired in H and 1 (0.7%) in M, showing a significant difference when compared with the number of admissions during the study period of H (25,038 patients) and M (8680 patients) (p Table 2 shows patients’ characteristics and the site of infections.

In this study, NC cases accounted for 14.7% of inpatients diagnosed with COVID-19. Patients with NC who were older had a higher mortality rate of 32.7%, which was much higher than that in community-acquired cases, as previously described [1,5]. The rate of NC differed by period of stay and hospital [1], which shows the need to consider different factors when assessing NC. The study period, circulating variants, rates of immunization, and type of healthcare settings are key elements. In particular, modern healthcare settings with single rooms and MV cannot be compared with old healthcare settings. In this study, we assessed the role of architecture (single versus double room and ventilation) by assessing the site of infection (H vs. M healthcare facility), and the results indicated that M had a significantly lower rate (1%) of NC than H (99%). A single NC was diagnosed in M for a patient transferred to the room from a surgical department of H 48 h before performing the test; thus, even in this case, an acquisition in H seems probable. These results underscored the potential benefits of modern medical structures with single rooms and MV and are in accordance with new data on airborne pathogen transmission [11]. Half of the patients with NC were hospitalized in double rooms, with secondary cases diagnosed in 26 patients, probably via short-range contamination, as previously described [17,18]. The rate was, however, still high in patients who were infected in single or double rooms in the absence of identification of infected neighbors. For at least some of these cases without an unidentified infected source, a long-range contamination via virus-laden aerosols through corridors might be suspected, as reported by similar studies [19]. Although acquisition via HCWs or visitors cannot be ruled out, wearing a mask was mandatory for HCWs and visitors, and PPE was similarly recommended in M and H.

Low ACH due to NV in a department with a high rate of patients infected with COVID-19 (clusters), especially without regular ventilation in winter with low outdoor temperatures, may have contributed to these cases. Interestingly, in Park et al.’s study, aerosol contamination was favored by the fact that in winter, the windows were closed and doors were opened, allowing for contamination through the corridor [19]. The source of nosocomial infections is frequently unknown among airborne viral agents, and a high incidence of asymptomatic, pauci-symptomatic, or pre-symptomatic infections [20] makes the implementation of transmission-based precautions nearly impossible [8,21], emphasizing the potential interest of universal precautions integrating the airborne risk [12]. In addition to Park’s clinical study [19], the influence of MV and NV has already been emphasized in studies evaluating RNA detection, which is more common in healthcare settings with NV than in those with MV [13,22].

Ventilation and architecture (including single rooms) appear as key elements to prevent nosocomial airborne infections, and this study highlights the fact that nosocomial COVID-19 is easier to transmit in old settings without MV. Although it is difficult to assess the efficiency of each corrective measure, HCWs should be aware of these risks to implement corrective measures, especially in old healthcare settings. These corrective methods could include the integration of CO₂ captors monitoring CO₂ in medical departments, allowing alerts for levels >700 ppm, for example [23], and alerting HCWs to increase ACH by opening the windows. Modelization with the help of aerosol scientists of the natural airflow within a department is important to direct airflows “from clean to less clean” including when opening door and windows [12,19]. Moreover, adjusting exhaust fans to improve ACH can also be an easy way to ensure the best ACH. In the case of departments with low ACH mobile filtration units, the use of UV-based technologies could be discussed. The COVID-19 pandemic was also changed due to the high level of immunization among the population and the presence of the Omicron variant. Therefore, the most efficient collective protective equipment (MV with high ACH, HEPA mobile units, or UV-based technologies) should focus on departments accepting highly susceptible patients, such as those who are highly immunosuppressed and those who are critically ill, as well as departments treating patients with transmissible infections, such as infectious disease units, or departments or collective zones with a high number of inpatients, such as emergency wards or collective rooms in nursing homes. These modifications are necessary in daily practice, and they are critical during pandemics, when viral transmission is at a high risk, and there is an increased concentration of potentially infected patients in healthcare settings.

This study has several limitations. We defined nosocomial COVID-19 as being diagnosed >48 h after hospitalization rather than the widely accepted definition of presumptive nosocomial COVID-19 (3–14 days) and a definite delay of >14 days. However, all inpatients with NC had a negative PCR upon admission. Moreover, the median delay of acquisition was quite long (12 days). The difference in activities performed in H and M, with a longer hospital stay in H, and the fact that older patients are more susceptible to symptomatic COVID-19 is a clear limitation of this work. The four medical departments in H that were most affected were those which accepted a high number of patients from the emergency departments, usually those with a longer hospital stay. Although isolated from non-COVID departments, medical COVID units were located in H, except for the COVID ICU (located in M). These elements may have favored a higher density of virus in H than in M. A high concentration of infected patients within poorly ventilated spaces favors far-afield transmission [24]. Finally, the occurrence of clusters led to screening campaigns in departments, with NC favoring the diagnosis of nosocomial asymptomatic cases and a better awareness of nosocomial risk in physicians in H. Nevertheless, such a difference in patients with NC, with nearly no cases in M, underlines the potential importance of MV and single rooms in a context of missing real-live data. Other architectural characteristics are important, such as the position of beds in double rooms and the circulation of airflow in the rooms and departments, but these are complex elements to analyze, especially in H, which has different buildings built between 1937 and the beginning of the twenty-first century; thus, the surfaces of rooms and departments are very different. This study focused on preventing the transmission of airborne viruses. However, immunization is also important to prevent clusters, and inpatients’ vaccination status should be screened upon admission to implement supplementary vaccine doses when required [25].