Personal protective equipment (PPE) is used to protect healthcare personnel (HCP) and patients from exposure to transmissible diseases across a variety of healthcare activities. Infection prevention (IP) programs rely on public health guidance, clinical and epidemiologic evidence, and experience to limit infection transmission while assuring occupational safety with minimal disruption to patient care.
The arrival of severe acute respiratory coronavirus virus 2 (SARS-CoV-2) as a novel infectious pathogen has raised questions about the adequacy of PPE strategies to prevent transmission in healthcare settings. Early observations in China reported HCP infection rates 12-fold higher than in the community. Reference Zheng, Wang and Zhou1 Subsequent studies assessing HCP transmission in the setting of adequate PPE and IP protocols showed that acquisition of coronavirus disease 2019 (COVID-19) by HCP was predominantly due to community exposure. Reference Jacob, Baker and Fridkin2 Nevertheless, early in the pandemic, fear and perceived risk was understandably high among HCP due to the severity of illness and lack of a vaccine. Presymptomatic transmissibility furthered concerns about acquiring COVID-19 during patient care.
Concerns about infection led many HCP to question the effectiveness of IP strategies deployed to protect them. We assessed the early pandemic experiences of hospitals balancing HCP protection through PPE use and delivery of timely, high-quality patient care.
Methods:
We conducted a 32-question, structured survey of a convenience sample of hospital IP leaders recruited from 4 sources: (1) the Centers for Disease Control and Prevention Epicenters Program, (2) HCA Healthcare hospital system, (3) the University of California Health system, and (4) the California Metrics Group for Healthcare-Associated Infections. Surveys were emailed and received between May 4, 2020, and November 20, 2020. The survey closed November 30, 2020. Responses were restricted to 1 survey per hospital. Survey questions evaluated (1) HCP concerns leading to procedure avoidance or delays, (2) modifications in clinical or IP workflows, and (3) PPE-related occupational hazards. Data were aggregated across facilities. Percentages were calculated among respondents for each question. This research was exempt from human subjects review by the UC Irvine Institutional Review Board.
Result
Of 130 programs receiving the survey, responses were received from IP program leaders at 53 US hospitals across 15 states (response rate, 41%). All hospitals provided ICU care and 29 (55%) were academic facilities. By size, 22 facilities (42%) had <200 beds, 14 (26%) had 200–400 beds, and 17 (32%) had >400 beds. Care services for immunocompromised patients were provided by 22 facilities (41%) and level 1 trauma care was provided by 11 facilities (21%). Overall, 40 facilities (75%) had experienced a COVID-19 surge by the time of survey completion.
Table 1 summarizes responses to questions regarding procedure avoidance or delays due to HCP concerns about COVID-19 risk. Delays or changes in care delivery resulting in longer hospital lengths of stay were reported by 42 (79%) of 53 facilities. Delays due to preprocedure COVID-19 testing were reported by 46 (87%), with 40 (75%) reporting unexpected cancellations. Also, 37 facilities (70%) reported increases in emergency department (ED) visits due to COVID-19 disruption of routine medical management of chronic conditions (eg, diabetic ketoacidosis or hypertensive urgency).
Table 1. Healthcare Personnel Concerns Leading to Procedure Avoidance or Delays a
Note. IR, interventional radiology; TEE, transesophageal echocardiogram; EGD, esophagogastroduodenoscopy; OR, operating room; CABG, coronary artery bypass graft; ex-lap, exploratory laparotomy; PPE, personal protective equipment; IV, intravenous; BiPAP, bilevel positive airway pressure; CPAP, continuous positive airway pressure; ED, emergency department; PAPR, powered air purifying respirator.
a Percentages calculated among total respondents for each question.
b No. of hospital respondents = 53 for each question unless otherwise stated.
c “Ever” composite calculated as sum of response selections of “a few times,” “sometimes,” and “often.”
Almost all IP leaders, 51 (96%) of 53 responding facilities, received requests to increase air exchanges between patients occupying ED or operating rooms; 33 (64%) of 52 facilities received requests to change operative air pressure from positive to negative, and 30 (58%) reported requests for procedure modifications (eg, discouraging intraoperative cauterization due to aerosol concerns). Use of nonrecommended PPE affecting surgical procedure times was reported by 37 (71%) of 52 facilities, and 40 (75%) of 53 facilities reported difficulty completing a procedure due to reduced visibility through face shields or goggles.
Overall, 46 (87%) of 53 responding facilities reported clinician avoidance of both noninvasive respiratory treatments not known to have aerosol transmission risk, such as nebulizers (46 of 53, 87%) and high-flow nasal cannula (36 of 50, 72%), and avoidance of invasive respiratory procedures with known aerosolization risk such as intubation (37 of 52, 71%). On the other hand, 26 (49%) of 53 reported occurrences of early intubation (before definitive need) to reduce exposure risks through mechanical ventilation. Use of “intubation boxes” (ie, clear plastic barriers around a patient’s head to protect HCP from respiratory secretions) was reported by 22 (43%) of 51 facilities, and 11 (50%) of these 22 reported universal use for all patients regardless of COVID-19 status. Among facilities using intubation boxes, 13 (59%) of 22 reported difficulty performing intubation or code-blue procedures (4 of 22, 18%).
Respondents reported occupational health hazards of PPE overuse including facial skin irritation, dermatitis or skin breakdown due to face masks (52 of 53, 98%); carbon dioxide narcosis symptoms from N95 or double masking (29 of 53, 55%); and falling or tripping (7 of 52, 13%) (Table 2).
Table 2. Occupational Hazards Related to Personal Protective Equipment
Note. CO2, carbon dioxide; N95, facepiece respirator capable of filtering at least 95% of airborne particles; PPE, personal protective equipment.
a “Ever” is the composite calculated as sum of response selections of “a few times,” “sometimes,” and “often.”
b Percentages calculated among total respondents for each question.
Discussion
Early in the COVID-19 pandemic, HCP concerns about COVID-19 exposure resulted in broad application of overly cautious practices without differentiation between high- or low-exposure activities. Although pandemic responses necessitated changes in hospital operations (eg, cancelling nonurgent surgeries) to accommodate COVID-19 patients and HCP provided lifesaving care to innumerable patients, our results show that concerns about transmission risk added to procedure delays, cancellations, modifications, and unnecessary PPE use, adversely affecting HCP physical well-being and patient care delivery.
Procedural delays and unexpected cancellations were reported across a wide spectrum of transmission risk, including among those with minimal respiratory transmission risk. Many studies have shown the serious consequences of COVID-19–associated delays on surgical, cancer, cardiac, or diabetes care, underscoring the need to limit COVID-19 prevention practices to those that are truly necessary. Reference Joung, Nelson and Mullett3–Reference Johnson, Waddimba, Ogola, Fleshman and Preskitt6 Preprocedural testing contributed to care delays in large numbers of patients, most of whom did not have COVID-19. Reference Srinivasan, Gohil and Abeles7 Although clinical circumstances can warrant delaying surgery due to COVID-19, positive tests often resulted in reflexive cancellations despite the fact that positive PCRs often indicate convalescent disease and that many surgeries can be safely performed with appropriate PPE. This strategy has remained active in many facilities despite lower frequency and severity of COVID-19 in the postvaccine era and despite highly effective IP protocols. Reference Talbo, Hayden and Yokoe8
Concerns about aerosolization were similarly pervasive and included avoidance of noninvasive respiratory treatments not known to produce infectious aerosols. Standardized definitions of AGPs that constitute true pathogen transmission risk are needed to prevent exposure concerns from driving broader definitions that could have had untoward consequences. In addition, studies demonstrating real-world effectiveness of PPE and standardized IP processes are needed so that pandemic scenarios do not potentiate unnecessary fear and actions to avoid exposures.
The use of “extra” prevention practices beyond evidence-based strategies can undermine current standards for high-quality, safe patient care and the invaluable HCP care provided in the setting of a pandemic. Reference Alarfaj, Foula and Alshammary9,Reference Galanis, Vraka, Fragkou, Bilali and Kaitelidou10 Our findings of clinical practice modifications suggested that HCP concern about COVID-19 exposure superseded adherence to well-vetted clinical and IP guidelines. We also found that extra PPE layers compromised HCP visibility, mobility, and function with unintended effects on both patient care and HCP health. Investments in HCP education on IP concepts to reduce harms that can inadvertently arise from overuse of precautions are needed.
This study had several limitations. The survey design captured anecdotal experience from a convenience sample of US hospital IP leaders. We did not assess the persistence of these early pandemic experiences, and emotional drivers of such experiences were inferred.
In summary, we found multiple examples of HCP modifying PPE and clinical practices with detrimental effects on patients and HCP across many hospitals, likely driven by excessive caution to avoid exposures. These findings have important implications for pandemic planning and response, including the need to emphasize balanced approaches to precautions, to prioritize HCP educational campaigns to manage safety concerns, and to generate an evidence base that can guide appropriate IP practices.
Supplementary material
To view supplementary material for this article, please visit https://doi.org/10.1017/ice.2023.89
Acknowledgments
The findings, conclusions, and views expressed in this presentation are those of the author(s) and do not necessarily represent the official position of the Centers for Disease Control and Prevention (CDC), the University of California Health System, HCA Healthcare and/or HCA Healthcare–affiliated entities, Washington University School of Medicine, Cedars Sinai Medical Center, or Sharp Memorial Hospital.
Financial support
This research was funded by the Centers for Disease Control and Prevention (CDC) Epicenters Program, which did not participate in the preparation, submission, and review of the manuscript. This research was supported in kind by HCA Healthcare (and/or HCA Healthcare–affiliated entities), whose representatives have been included as authors who participated in the preparation, submission, and review of the manuscript.
Competing interest
All authors report no conflicts of interest relevant to this article.
Open access
