Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-22T10:22:59.411Z Has data issue: false hasContentIssue false

Practices to prevent central line-associated bloodstream infection: A 2021 survey of infection preventionists in US hospitals

Published online by Cambridge University Press:  24 April 2024

Larissa Pisney
Affiliation:
The Division of Infectious Diseases, Department of Medicine, University of Colorado Anschutz, Aurora, CO, USA University of Colorado Health System, Aurora, CO, USA
Lisa Camplese
Affiliation:
University of Colorado Health System, Aurora, CO, USA
M. Todd Greene
Affiliation:
VA/UM Patient Safety Enhancement Program, Ann Arbor, MI, USA Center for Clinical Management Research, Veterans Affairs Ann Arbor Healthcare System, Ann Arbor, MI, USA Division of Hospital Medicine, Department of Internal Medicine, University of Michigan, Ann Arbor, MI, USA
Sanjay Saint
Affiliation:
VA/UM Patient Safety Enhancement Program, Ann Arbor, MI, USA Center for Clinical Management Research, Veterans Affairs Ann Arbor Healthcare System, Ann Arbor, MI, USA Division of Hospital Medicine, Department of Internal Medicine, University of Michigan, Ann Arbor, MI, USA
Karen E. Fowler
Affiliation:
VA/UM Patient Safety Enhancement Program, Ann Arbor, MI, USA Center for Clinical Management Research, Veterans Affairs Ann Arbor Healthcare System, Ann Arbor, MI, USA
Vineet Chopra*
Affiliation:
Division of Hospital Medicine, Department of Medicine, University of Colorado Anschutz, Aurora, CO, USA
*
Corresponding author: Vineet Chopra; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

To determine prevalence of technical and behavioral interventions aimed at preventing central line-associated bloodstream infection (CLABSI) following the COVID19 pandemic.

Design:

Cross-sectional survey.

Setting:

US acute care hospitals.

Participants:

Infection preventionists at participating hospitals.

Methods:

Surveys were sent to infection preventionists from a national random sample of 881 US acute care hospitals. Questions covered use of technical interventions to prevent CLABSI (eg, alcohol-containing chlorhexidine gluconate [CHG] for skin antisepsis, use of coated catheters), socio-adaptive interventions (eg, feedback of CLABSI rates, use of appropriateness criteria), and leadership support for CLABSI prevention.

Results:

Survey response rate was 47% (415/881). Technical interventions such as maximal sterile barriers (99%) or CHG-impregnated dressings (92%) were highly prevalent, but routine use of CHG bathing was less common (68% indicated regular use in intensive care unit [ICU] vs 18% in non-ICU settings). Although 97% of respondents indicated use of systems to monitor CLABSI, feedback to providers on CLABSI events was reported by 89%. Only 53% of respondents indicated regular use of tools to determine appropriateness of central venous catheters (CVC). Three-quarters of respondents indicated their hospital assessed CVC necessity daily, but only 23% reported strategies to reduce routine blood cultures. CLABSI prevention was extremely important to hospital leadership at 82% of responding hospitals.

Conclusions:

Most US hospitals continue to use evidence-based methods to prevent CLABSI as recommended by leading organizations. Opportunities to focus on socio-adaptive interventions such as feedback of infection rates, use of appropriateness criteria for CVC placement, and improving the “culture of pan-culturing” remain.

Type
Original Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

Introduction

Despite reductions in the incidence of central line-associated bloodstream infection (CLABSI), an estimated 31,000 CLABSIs continue to occur in US hospitals annually. 1 Success in reducing CLABSI may be attributed to implementing technical interventions, including practices at the time of central venous catheter (CVC) insertion (eg, use of alcohol-containing chlorhexidine for skin antisepsis) and advances in ensuring optimal maintenance of the device (eg, antiseptic-impregnated dressings). Reference Shekelle, Wachter and Pronovost2,Reference Buetti, Marschall and Drees3 Additionally, several newer innovations such as advanced dressings for the catheter site and implementation of chlorhexidine bathing among high-risk patients have been shown to contribute to reductions in CLABSI events. Reference Buetti, Marschall and Drees3

Much of the success and many of the practices core to preventing CLABSI were interrupted during the COVID-19 pandemic, which corresponded with an increase in CLABSI rates. Reference Weiner-Lastinger, Pattabiraman and Konnor4,Reference Evans, Simbartl and Kralovic5 Although there are many explanations for the increased rates during this period, a key reason is that CLABSI prevention is not solely about technical aspects or use of technology-based innovations. Rather, behavioral or socio-adaptive aspects such as feedback of infection rates to providers, removing CVCs when they are no longer clinically indicated and more recently use of appropriateness criteria prior to placing a CVC are also relevant. Reference Buetti, Marschall and Drees3,Reference Chopra, Flanders and Saint6 As we emerge from the pandemic, understanding current practices for CLABSI prevention and practices related to behavioral initiatives remains important.

In this study, we examine reported rates of adherence to CLABSI prevention tactics as recommended by practice recommendations published by Society for Healthcare Epidemiology of America (SHEA), the Infectious Diseases Society of America and the Association for Professionals in Infection Control and Epidemiology using national surveys of lead infection preventionists at US hospitals. Reference Buetti, Marschall and Drees3 We specifically sought to understand the use of technical, behavioral and leadership practices in preventing CLABSI.

Methods

Study design and data collection

In 2021, we performed a comprehensive survey aiming to understand practices used by infection preventionists in US hospitals to prevent hospital acquired infections. Reference Saint, Kowalski and Kaufman7Reference Saint, Greene and Fowler10 We used data from the American Hospital Association to identify a national random sample of 900 hospitals from all 2,655 non-federal, general medical and surgical hospitals, each of which had an intensive care unit (ICU). Hospitals that were identified as closed or ineligible by a pre-survey Internet search or returned mail were removed from the sample. A total of 881 hospitals were identified as eligible and included in the 2021 survey.

The survey followed a modified Dillman approach. Reference Dillman11 A pre-survey letter was sent to the “Infection Control Coordinator” at all hospitals, notifying them to expect the survey mailing in the next week. The initial surveys were mailed in mid-April 2021 and included $10 as an incentive to complete the survey. Two weeks after the initial mailing, a reminder letter was sent to all non-respondents. To increase participation, additional reminder surveys were mailed to non-respondents approximately 1, 2, and 3 months after the initial mailing. Respondents were given the option of completing the survey on paper and returning in a postage-paid envelope or completing the survey electronically using REDCap electronic data capture tools. Reference Harris, Taylor and Minor12 At hospitals that employ more than one infection preventionist, we asked that the lead infection preventionist serve as the primary respondent, although we encouraged consulting with others as needed to complete the questionnaire. Similarly, if infection preventionists worked in a healthcare system with more than one facility, they were asked to respond to questions with respect to their primary site. Respondents were told that there were no right or wrong answers to the infection control practices; rather, our interest was to understand strategies being used for infection prevention.

Study measures

The survey instrument included questions about general hospital characteristics and characteristics of the infection prevention and control (IPC) program (eg, number of acute vs ICU beds, affiliation with medical schools, presence of a hospital epidemiologist). With respect to technical elements related to preventing CLABSI, questions regarding use of CLABSI insertion bundle elements (eg, maximum sterile barriers, alcohol-containing chlorhexidine gluconate [CHG] for skin antisepsis), technology-based interventions (eg, advanced securement devices, antimicrobial coated catheters, antiseptic-impregnated dressings) were posed. With respect to behavioral/socio-adaptive aspects related to CLABSI prevention, questions regarding whether reporting of infection rates to providers, use of evidenced-based indications/appropriateness criteria for CVC placement were asked. To understand the role of leadership in a post-COVID era, we asked respondents to provide feedback on perceived support from leadership as it related to CLABSI prevention efforts.

The survey assessed many practices on a 5-point Likert scale (1 = “never use” through 5 = “always use”). Binary variables for each practice were generated with regular use defined as a rating of 4 (almost always) or 5 (always) coded as 1 and 0 otherwise. Other questions had yes/no responses, such as reporting of infection rates and use of appropriateness criteria for CVC selection. Our survey instrument is provided as a Supplementary Appendix.

Statistical analysis

Descriptive statistics—N (%) for categorical variables, and median and range for continuous variables—were calculated for hospital characteristics and use of specific CLABSI prevention practices. Missing values for each of the variables presented were excluded from denominators in the generation of all descriptive statistics.

Ethical and regulatory oversight

This study was reviewed by the institutional review board at the University of Michigan and received an “exempt” status.

Results

General characteristics of respondents

Of 881 hospitals who received the survey invitation, lead infection preventionists from a total of 415 acute care hospitals responded and completed the survey (response rate: 47%). Technical and behavioral/socio-adaptive elements on the survey and associated responses are shown in the table (Table 1). Respondents represented sites that had an average of 214 acute care beds (SD = 218, median = 150, range = 11–1506) and 24 intensive care unit beds (SD = 33, median = 14, range = 0–222). A total of 34% (141/412) of hospitals were affiliated with a medical school. On average, 80% of hospital beds were reported as private. A total of 40% (161/399) of hospitals had a hospital epidemiologist on staff. When asked about the level of support they received from hospital leadership for the IPC program, 64% (266/413) rated their level of support as very good or excellent.

Table 1. Survey item descriptions and raw responses (see Figure 1)

Note. CLABSI, central line-associated bloodstream infection; CVC, central vascular catheter; ICU, intensive care unit; PICC, peripherally inserted central catheter.

a Numerator/Denominator for percent calculations in Figure 1. Numerator indicates number of respondents answering affirmatively to the given survey item. Denominator indicates total number of surveys received with an answer to the given survey item.

b These survey items do not appear in the guidelines.

A total of 34% (133/395) of respondents indicated that critical care physicians were responsible for placing the majority of acute non-peripherally inserted CVCs. Conversely, 67% (266/395) of respondents reported that the majority of peripherally inserted central catheters (PICCs) were placed by designated nurse-led vascular access teams at their sites.

Use of technical practices to prevent CLABSI

Respondents from hospitals almost universally reported that inserters of non-peripherally inserted CVCs and PICCs routinely used maximal sterile barriers and alcohol-containing chlorhexidine gluconate (CHG) for skin antisepsis at the time of device placement (99% for both practices, 390/395 and 388/392, respectively). Notably, a high percentage of respondents (92%, 355/388) also reported the use of chlorhexidine-containing dressings (eg, BIOPATCH™) at the catheter insertion site as part of their CLABSI prevention strategies. The use of advanced securement devices (eg, Tegaderm™ IV Advanced, SecurAcath®) was also highly prevalent, with 91% (357/392) of respondents indicating that they used such a device. However, only 5% (18/360) of hospitals reported use of cyanoacrylate glue to seal the catheter exit site for reducing CLABSI, a practice with mixed evidence. Additionally, slightly less than half of respondents (47%, 178/376) reported using antibiotic impregnated or antiseptic coated catheters as part of their CLABSI prevention strategy. Reference Wang, Tong and Liu13,Reference Chong, Lai, Apisarnthanarak and Chaiyakunapruk14

Chlorhexidine bathing to prevent hospital-acquired infections including CLABSI was reported as being performed daily for ICU patients by 68% (264/388) of respondents. In the non-ICU setting, CHG bathing was reported as being performed daily only by 18% (72/399) of respondents.

Use of behavioral and socio-adaptive practices to prevent CLABSI

Slightly over half of all respondents (53%, 211/395) reported that they employed an established process (checklist, guideline, computer-system based decision tool) to determine the appropriateness of a non-peripherally inserted CVC prior to placement of the device. Interestingly, a greater proportion of respondents (70%, 274/394) indicated that device appropriateness was evaluated prior to placement of PICCs. A little over half (55%, 211/386) of infection preventionists reported that appropriateness was operationalized via a restricted list of clinical indications for central access, whereas 48% (189/391) indicated they used guidelines such as the Michigan Appropriateness Guidelines for Intravenous Catheters to determine appropriateness of PICC use. Reference Chopra, Flanders and Saint6 Almost all respondents (97%, 388/399) indicated having an established surveillance system to monitor CLABSI, and 89% (356/399) reported sharing this data back to direct care providers.

A total of 23% (97/415) of respondents stated that strategies to reduce the collection of unnecessary blood cultures as a measure to reduce CLABSI were in place at their sites. When asked about practices to remove unnecessary devices to prevent CLABSI, 75% (301/404) of respondents indicated that their hospital conducted daily rounds to assess ongoing necessity of central access.

Leadership practices

Respondents were queried across a host of practices to understand how important infection prevention was to hospital leadership following COVID-19. When asked whether hand hygiene is very or extremely important at their hospital, 81% (326/401) indicated this was the case and 96% (385/402) reported that this was being audited by direct observation. Most respondents (82%, 334/408) indicated that they felt it was very/extremely important to hospital leadership to prevent CLABSIs. When queried as to whether their hospitals experienced staff shortages due to absences or illnesses during the COVID-19 pandemic, 88% (355/403) of respondents indicated this was the case. Almost all respondents indicated that they experienced a shortage of basic equipment for preventing CLABSI such as gowns, gloves, face shields and masks.

The reported regular use of various CLABSI prevention practices is illustrated in Figure 1.

Figure 1. Proportion of respondents reporting regular use of infection prevention practices.

Discussion

In this nationally representative survey of infection preventionists performed following the delta wave of COVID-19, several insights emerged. First, we observed that many of the technical practices known to reduce rates of CLABSI remained in high use at most hospitals. Reference Saint, Greene and Krein15 In view of the pandemic and disruption to healthcare delivery, infection prevention and patient safety—this is good news. However, gaps in some evidence-based practices which are known to reduce the risk of CLABSI—such as chlorhexidine bathing—were observed. Second, when querying behavioral aspects aimed to prevent CLABSI, we found several additional gaps including lack of routine feedback of infection rates to inserters of devices. Even fewer respondents indicated that appropriateness criteria or decision aids were in use before placing central access. Finally, although the perceived importance of CLABSI to leadership was rated as high by respondents, gaps in the form of staff shortages and lack of basic equipment emerged as opportunities for improvement. Collectively, these findings suggest that use of several behavioral practices for preventing this important infection remained suboptimal during the COVID-19 pandemic.

In 2022, the recommendations for strategies used to prevent CLABSI in the acute care hospital setting were updated. Reference Buetti, Marschall and Drees3 The literature search supporting the recommendation update spanned from January 2012 through August 2021. As such, the evidence supporting the specific CLABSI prevention practices was temporally aligned with when our infection prevention surveys were distributed in 2021. A key change to the update was reclassifying various practices from “basic” to “essential” (practices which should be adopted by all hospitals) and “special” to “additional” (practices to be considered when CLABSI is not controlled after implementing essential practices). Our findings suggest that nearly all hospitals are implementing practices classified as essential with high strength of evidence supporting their use. For example, we found high reported use of antiseptic dressings with chlorhexidine—a practice previously listed as a special approach that became an essential practice in the 2022 update. Cross-sectional data from Saint et al. suggest that use of BIOPATCH® has steadily increased from approximately 78% in 2013 to nearly 92% in 2021. Reference Saint, Greene and Krein15

Technical innovations to prevent CLABSI such as use of alcohol-containing CHG offer relatively easy solutions to prevent these types of infections. Indeed, some have argued that they may be the most important component in reducing infection rates. Reference Chopra and Shojania16 Results of this survey suggest that these practices remained in use across most of the sites surveyed. Despite the high utilization of dressings containing CHG, the practice of daily CHG bathing in critically ill patients is less prevalent, even though it is an essential practice supported by strong evidence showing its effectiveness and efficacy in reducing CLABSI. Reference Frost, Alogso and Metcalfe17 In addition, use of some technical practices with mixed evidence (eg, advanced securement devices and cyanoacrylate glue) were reported. Reference Timsit, Baleine and Bernard18,Reference Machin, Liu, Coupland, Davies and Thapar19 One way to consolidate these findings in the context of COVID-19 is to consider the diffusion of these practices through the lens of provider burden. Chlorhexidine bathing, while effective, requires substantial nursing time and patient cooperation. Reference Destine, Capes and Reynolds20,Reference Reynolds, Woltz and Keating21 Even in times where staffing shortages were not a concern, compliance has remained suboptimal. Reference Reynolds, Granger and Hatch22 In contrast, technical interventions such as use of antibiotic impregnated or antiseptic coated catheters or using more advanced securement may be associated with a higher cost but are less time-intensive than behavioral strategies. Another essential practice that requires a behavioral intervention is the use of standard processes to determine the appropriateness of central line placement prior to insertion. However, only half of the respondents reported implementing this practice. It is therefore conceivable that there is a trend toward a pragmatic, albeit misguided over-reliance on technical aspects to prevent CLABSI.

Signals supporting the assertion that technical aspects may have overshadowed what is needed from harder to achieve behavioral changes are also present when examining use of appropriateness criteria or feedback of infection rates to providers. Although these elements are known to be effective at reducing rates of infectious and non-infectious complications from catheters, they require active engagement and human interaction to be successful. The best example of this paradigm is demonstrated by the fact that only a quarter of all respondents indicated that they had implemented practices to limit collection of routine blood cultures. The practice of “pan-culturing” that is heavily ingrained in many providers is known to contribute to high rates of CLABSI, Reference Fakih and Khatib23,Reference Vaughn and Chopra24 yet is among the hardest to eliminate when it comes to behavioral change. In an era where staff and supply shortages were experienced, one can understand why these behavioral changes were even more challenging to adhere to or implement.

Although this survey-based study sheds light on contemporary CLABSI prevention practices, our findings do have limitations. First, although we surveyed about one-third of all non-federal, medical/surgical US hospitals with ICU beds, employed a sampling strategy to obtain a nationally representative sample, and achieved a reasonable response rate (particularly during a pandemic), the hospitals choosing to participate may differ from those choosing not to participate, as highlighted by the high proportion of respondents who work at a facility associated with a medical school (34%). Additionally, the exclusion of acute care medical/surgical hospitals without an ICU, federally funded hospitals, and other hospital types (eg, psychiatric, OB/GYN, rehabilitation, orthopedics, various types of pediatric facilities, and acute long-term care facilities) from our sample impacts generalizability. Second, as with any survey-based study, bias in responses (eg, recall, social-desirability) may have occurred as we relied on a single respondent to report practices for their sites. We have no reason to believe that lead infection preventionists would be systematically unaware of practices to prevent CLABSI at their sites, but we cannot ascertain intra-facility differences. Third, while we asked about leadership practices, the extent these may have influenced CLABSI practices directly or indirectly is unclear. Our findings therefore should be viewed as hypothesis-generating in this respect.

Despite these limitations, our study has several strengths. First, we surveyed a large group of US infection preventionists during the COVID-19 pandemic to understand how CLABSI prevention practices were impacted. Insights from this study can help inform infection prevention policy and practice for US hospitals. For example, our findings related to promulgation of technical innovations perhaps at the expense of behavioral changes is important for sites struggling to reduce CLABSI. Second, we found that use of appropriateness criteria remains low and could represent an area for quality improvement, as has been shown by large scale studies. Reference Chopra, Flanders and Saint6

In conclusion, the results of our recent survey demonstrated high use of evidence-based technical interventions to prevent CLABSI, even during the COVID-19 pandemic when supply chains and staffing were strained. Moving forward, emphasis on behavioral interventions represents an area of opportunity for both practice and policy as human capital and leadership efforts can focus on quality initiatives.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/ice.2024.53.

Acknowledgements

None.

Financial support

This study was supported by US Department of Veterans Affairs (VA) via the VA National Center for Patient Safety-funded Patient Safety Center of Inquiry.

Competing interests

All authors report no conflicts of interest relevant to this article.

References

Current HAI progress report. Centers for Disease Control and Prevention website. https://www.cdc.gov/hai/data/portal/progress-report.html. Published 2022. Accessed January 18, 2024.Google Scholar
Shekelle, P, Wachter, R, Pronovost, P, et al. Making health care safer II: an updated critical analysis of the evidence for patient safety practices. National Library of Medicine website. https://www.ncbi.nlm.nih.gov/books/NBK133363/. Published 2013. Accessed January 18, 2024.Google Scholar
Buetti, N, Marschall, J, Drees, M, et al. Strategies to prevent central line-associated bloodstream infections in acute-care hospitals: 2022 update. Infect Control Hosp Epidemiol 2022;43:553569.CrossRefGoogle ScholarPubMed
Weiner-Lastinger, LM, Pattabiraman, V, Konnor, RY, et al. The impact of coronavirus disease 2019 (COVID-19) on healthcare-associated infections in 2020: a summary of data reported to the National Healthcare Safety Network. Infect Control Hosp Epidemiol 2021;43:1225.CrossRefGoogle Scholar
Evans, ME, Simbartl, LA, Kralovic, SM, et al. Healthcare-associated infections in Veterans Affairs acute-care and long-term healthcare facilities during the coronavirus disease 2019 (COVID-19) pandemic. Infect Control Hosp Epidemiol 2023;44:420426.CrossRefGoogle ScholarPubMed
Chopra, V, Flanders, SA, Saint, S, et al. The Michigan appropriateness guide for intravenous catheters (MAGIC): results from a multispecialty panel using the RAND/UCLA appropriateness method. Ann Intern Med 2015;163:S1S40.CrossRefGoogle ScholarPubMed
Saint, S, Kowalski, CP, Kaufman, SR, et al. Preventing hospital-acquired urinary tract infection in the United States: a national study. Clin Infect Dis 2008;46:243250.CrossRefGoogle ScholarPubMed
Krein, SL, Kowalski, CP, Hofer, TP, Saint, S. Preventing hospital-acquired infections: a national survey of practices reported by U.S. hospitals in 2005 and 2009. J Gen Intern Med 2012;27:773779.CrossRefGoogle ScholarPubMed
Krein, SL, Fowler, KE, Ratz, D, Meddings, J, Saint, S. Preventing device-associated infections in US hospitals: national surveys from 2005 to 2013. BMJ Qual Safety 2015;24:385392.CrossRefGoogle ScholarPubMed
Saint, S, Greene, MT, Fowler, KE, et al. What US hospitals are currently doing to prevent common device-associated infections: results from a national survey. BMJ Qual Saf 2019;28:741749.CrossRefGoogle ScholarPubMed
Dillman, DA. Mail and internet surveys: the tailored design method. 2nd ed. New York, NY: Wiley; 2007.Google Scholar
Harris, PA, Taylor, R, Minor, BL, et al. The REDCap consortium: building an international community of software platform partners. J Biomed Inform 2019;95:103208.CrossRefGoogle ScholarPubMed
Wang, H, Tong, H, Liu, H, et al. Effectiveness of antimicrobial-coated central venous catheters for preventing catheter-related blood-stream infections with the implementation of bundles: a systematic review and network meta-analysis. Ann Intensive Care 2018;8:71.CrossRefGoogle ScholarPubMed
Chong, HY, Lai, NM, Apisarnthanarak, A, Chaiyakunapruk, N. Comparative efficacy of antimicrobial central venous catheters in reducing catheter-related bloodstream infections in adults: abridged cochrane systematic review and network meta-analysis. Clin Infect Dis 2017;64:S131S140.CrossRefGoogle ScholarPubMed
Saint, S, Greene, MT, Krein, SL, et al. What US hospitals are doing to prevent common device-associated infections during the coronavirus disease 2019 (COVID-19) pandemic: Results from a national survey in the United States. Infect Control Hosp Epidemiol 2023;44:19131919.CrossRefGoogle ScholarPubMed
Chopra, V, Shojania, KG. Recipes for checklists and bundles: one part active ingredient, two parts measurement. BMJ Qual Saf 2012;22:9396.CrossRefGoogle ScholarPubMed
Frost, SA, Alogso, M-C, Metcalfe, L, et al. Chlorhexidine bathing and health care-associated infections among adult intensive care patients: a systematic review and meta-analysis. Crit Care 2016;20:379.CrossRefGoogle ScholarPubMed
Timsit, J-F, Baleine, J, Bernard, L, et al. Expert consensus-based clinical practice guidelines management of intravascular catheters in the intensive care unit. Ann Intensive Care 2020;10:118.CrossRefGoogle ScholarPubMed
Machin, M, Liu, C, Coupland, A, Davies, AH, Thapar, A. Systematic review of the use of cyanoacrylate glue in addition to standard wound closure in the prevention of surgical site infection. Int Wound J 2019;16:387393.CrossRefGoogle ScholarPubMed
Destine, Y, Capes, K, Reynolds, SS. Reduction in patient refusal of CHG bathing. Am J Infect Control 2023;51:10341037.CrossRefGoogle ScholarPubMed
Reynolds, SS, Woltz, P, Keating, E, et al. Results of the CHlorhexidine Gluconate Bathing implementation intervention to improve evidence-based nursing practices for prevention of central line associated bloodstream infections Study (CHanGing BathS): a stepped wedge cluster randomized trial. Implement Sci 2021;16:45.CrossRefGoogle ScholarPubMed
Reynolds, SS, Granger, BB, Hatch, D. Self-Reported versus observed audit: Measuring CHG bathing compliance. Am J Infect Control 2021;49:15751577.CrossRefGoogle ScholarPubMed
Fakih, MG, Khatib, R. Improving the culture of culturing: critical asset to antimicrobial stewardship. Infect Control Hosp Epidemiol 2016;38:377379.CrossRefGoogle ScholarPubMed
Vaughn, VM, Chopra, V. Revisiting the panculture. BMJ Qual Saf 2016;26:236239.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Survey item descriptions and raw responses (see Figure 1)

Figure 1

Figure 1. Proportion of respondents reporting regular use of infection prevention practices.

Supplementary material: File

Pisney et al. supplementary material

Pisney et al. supplementary material
Download Pisney et al. supplementary material(File)
File 438.4 KB