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Fluoroquinolone stewardship at a community health system: A decade in review

Published online by Cambridge University Press:  16 November 2022

Elena A. Swingler*
Affiliation:
Norton Infectious Diseases Institute, Norton Healthcare, Louisville, Kentucky
Matthew Song
Affiliation:
Norton Infectious Diseases Institute, Norton Healthcare, Louisville, Kentucky
Sarah E. Moore
Affiliation:
Norton Infectious Diseases Institute, Norton Healthcare, Louisville, Kentucky
Brian C. Bohn
Affiliation:
Department of Pharmacy, Barnes-Jewish Hospital, St. Louis, Missouri
Paul S. Schulz
Affiliation:
Norton Infectious Diseases Institute, Norton Healthcare, Louisville, Kentucky
Alan D. Junkins
Affiliation:
Department of Microbiology, Norton Healthcare, Louisville, Kentucky
Ashley M. Wilde
Affiliation:
Norton Infectious Diseases Institute, Norton Healthcare, Louisville, Kentucky
*
Author for correspondence: Elena A. Swingler, PharmD, MBA, BCIDP, Norton Infectious Diseases Institute, 4950 Norton Healthcare Blvd, Plaza 1, Suite 303, Louisville, KY40241. E-mail: [email protected]

Abstract

Objective:

To describe inpatient fluoroquinolone use and susceptibility data over a 10-year period after the implementation of an antimicrobial stewardship program (ASP) led by an infectious diseases pharmacist starting in 2011.

Design:

Retrospective surveillance study.

Setting:

Large community health system.

Methods:

Fluoroquinolone use was quantified by days of therapy (DOT) per 1,000 patient days (PD) and reported quarterly. Use data are reported for inpatients from 2016 to 2020. Levofloxacin susceptibility is reported for Pseudomonas aeruginosa and Escherichia coli for inpatients from 2011 to 2020 at a 4 adult-hospital health system.

Results:

Inpatient fluoroquinolone use decreased by 74% over a 5-year period, with an average decrease of 3.45 DOT per 1,000 PD per quarter (P < .001). Over a 10-year period, inpatient levofloxacin susceptibility increased by 57% for P. aeruginosa and by 15% for E. coli. P. aeruginosa susceptibility to levofloxacin increased by an average of 2.73% per year (P < .001) and had a strong negative correlation with fluoroquinolone use, r = −0.99 (P = .002). E. coli susceptibility to levofloxacin increased by an average of 1.33% per year (P < .001) and had a strong negative correlation with fluoroquinolone use, r = −0.95 (P = .015).

Conclusions:

A substantial decrease in fluoroquinolone use and increase in P. aeruginosa and E. coli levofloxacin susceptibility was observed after implementation of an antimicrobial stewardship program. These results demonstrate the value of stewardship services and highlight the effectiveness of an infectious diseases pharmacist led antimicrobial stewardship program.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

Antimicrobial resistance is a global public health threat mainly driven by the misuse of antimicrobials. 1 Fluoroquinolone antibiotics have historically been prescribed for a wide variety of infections, including mild, uncomplicated infections for which alternatives may be preferred. Reference Linder, Huang, Steinman, Gonzales and Stafford2 Consequently, increasing antimicrobial resistance has been reported, particularly among Enterobacterales and Pseudomonas spp. Reference Lautenbach, Strom and Nachamkin3Reference Sanchez, Master, Karlowsky and Bordon5 Antimicrobial resistance greatly limits empiric and definitive treatment options for potentially serious infections. For example, for Pseudomonas spp infections, fluoroquinolones are the only antibiotic class currently available for enteral administration. Fluoroquinolone exposure has not only been associated with fluoroquinolone-resistant strains but also with methicillin-resistant Staphylococcus aureus and extended-spectrum β-lactamase–producing organisms. Reference Parienti, Cattoir and Thibon6Reference Rodríguez-Baño, Navarro and Romero8

In addition to driving resistance, fluoroquinolones have been associated with serious and potentially permanent musculoskeletal and central nervous system adverse events resulting in regulatory action by the Food and Drug Administration. 9 Their use also carries a moderate to high risk of Clostridioides difficile infection compared with other antibiotic classes, and fluoroquinolones have been linked to the emergence and spread of the hypervirulent 027/BI/NAP1 strain. Reference Deshpande, Pasupuleti and Thota10Reference He, Miyajima and Roberts12

In response to the concerns outlined above, many health systems have employed antimicrobial stewardship interventions to reduce fluoroquinolone use, antimicrobial resistance, and C. difficile infections. Interventions usually consist of formulary restriction and prospective audit and feedback, sometimes in conjunction with education and guidelines for optimal antibiotic use. Reference Pitiriga, Vrioni, Saroglou and Tsakris13 Evidence to support fluoroquinolone-targeted interventions is heterogeneous regarding intervention types, duration, and outcomes measured. Reference Pitiriga, Vrioni, Saroglou and Tsakris13 Overall, stewardship interventions are supported by favorable outcomes of reductions in fluoroquinolone use, resistance, and C. difficile infection rates. Reference Pitiriga, Vrioni, Saroglou and Tsakris13

In this report, we describe fluoroquinolone use and susceptibility data over a 10-year period at a large community health system with an antimicrobial stewardship program (ASP).

Methods

This retrospective surveillance study was conducted at Norton Healthcare, a large, integrated health system of 4 adult hospitals licensed for ∼1,600 beds in Kentucky. Inpatient fluoroquinolone use and susceptibility data were analyzed in the context of a growing ASP.

Antimicrobial stewardship program

The current ASP at our health system started in 2011 with 1 full-time infectious diseases pharmacist and 1 part-time infectious diseases physician. Initially, the ASP focused on formulary optimization, guidelines for optimal antimicrobial use, order-set updates, and provider and pharmacist education. Fluoroquinolone use was addressed primarily through order-set revisions to discourage routine use. After maximizing the antimicrobial stewardship benefit that could be achieved at the system level, the infectious diseases pharmacist in charge of the ASP focused on providing prospective audit and feedback for patients on broad-spectrum antimicrobials, including fluoroquinolones. In 2017, the ASP expanded to include 4 full-time infectious diseases pharmacists (1 at each hospital within the health system) and was able to consistently provide prospective audit and feedback for a larger number of patients. Reference Song and Wilde14 The ASP continues to be supported by a part-time infectious diseases physician leader, but prospective audit and feedback is performed by the pharmacists. Formulary restriction of fluoroquinolones was not utilized at our health system.

Antibiotic use

Inpatient levofloxacin and ciprofloxacin antibiotic use is expressed as days of therapy (DOT) per 1,000 patient days (PD) and is reported quarterly. DOT was calculated using administration records obtained from the electronic health record. Inpatient fluoroquinolone use data are reported for 2016 to 2020. Data were not readily retrievable for inpatient use before 2016.

Microbiology

Levofloxacin susceptibility data for P. aeruginosa and E. coli were obtained from the health system’s antibiograms, which were collated annually for each hospital. Antibiograms were created using only the first isolate of a given species per patient per year and included nonsurveillance samples from inpatient and emergency department patients. Antibiotic susceptibility testing was performed on the MicroScan WalkAway system (Beckman Coulter, Brea, CA). Susceptibility was reported using the Clinical and Laboratory Standards Institute (CLSI) breakpoints established prior to 2019. Adult hospital susceptibility rates were aggregated and weighted according to the number of isolates per hospital per year. The results were reported as the proportion of fluoroquinolone-susceptible isolates among all clinical isolates for each species. Microbiologic data were reported for the period of 2010 to 2020 for inpatients.

Statistical analysis

Line graphs were produced to show changes in fluoroquinolone DOT per 1,000 PD and changes in susceptibility to levofloxacin in E. coli and P. aeruginosa over time. Linear regression was used to produce trend lines and to describe changes over time. Beta coefficients, 95% confidence intervals, and P values were reported.

Scatter plots were produced to plot fluoroquinolone DOT per 1,000 PD versus susceptibility to levofloxacin in E. coli and P. aeruginosa. Pearson correlation coefficients were produced to assess ecological associations between DOT per 1,000 PD and susceptibilities. The Pearson correlation coefficient, r, and P values were reported. All statistical analyses were performed in R version 4.1.2 software (R Foundation for Statistical Computing, Vienna, Austria). P values < .05 were deemed statistically significant.

Results

Antibiotic use

Inpatient fluoroquinolone use decreased from 83.5 DOT per 1,000 PD in quarter 1 of 2016 to 21.4 DOT per 1,000 PD in quarter 4 of 2020, representing a 74% decrease over a 5-year period. Fluoroquinolone use decreased over time by an average of 3.45 DOT per 1,000 PD per quarter, β = −3.45 (95% CI, −3.80 to −3.09; P < .001) (Fig. 1).

Fig. 1. Fluoroquinolone use in adult inpatients from 2016 to 2020.

Microbiology

Inpatient levofloxacin susceptibility increased for P. aeruginosa by 57% (absolute increase of 30%) and for E. coli by 15% (absolute increase of 10%) from 2010 to 2020. P. aeruginosa susceptibility to levofloxacin increased by an average of 2.73% per year, β = 2.73 (95% CI, 1.94–3.51; P < .001) (Fig. 2). We detected a strong negative association between fluoroquinolone use and P. aeruginosa susceptibility to levofloxacin, r = −0.99 (P = .002). E. coli susceptibility to levofloxacin increased by an average of 1.33% per year, β = 1.33 (95% CI, 0.91–1.75; P < .001) (Fig. 3). We also detected a strong negative association between fluoroquinolone use and E. coli susceptibility to levofloxacin, r = −0.95 (P = .015).

Fig. 2. P. aeruginosa levofloxacin susceptibility in adult inpatients from 2010 to 2020.

Fig. 3. E. coli levofloxacin susceptibility in adult inpatients from 2010 to 2020.

Discussion

The ASP efforts at our health system appear to be successful at reducing inpatient fluoroquinolone use and antimicrobial resistance among P. aeruginosa and E. coli isolates.

The results of this study add to the growing body of evidence that demonstrates the importance of persistent and well-resourced hospital-based ASPs. Several meta-analyses have summarized favorable outcomes for individual stewardship interventions as well as full programs on antibiotic use and resistance, clinical outcomes, adverse events, C. difficile infections, and costs. Reference Baur, Primrose Gladstone and Burkert15Reference Schuts, Boyd, Muller, Mouton and Prins19 For these reasons, the ASP at our health system is valued and has expanded to provide comprehensive services across the health system. The desirable trends in fluoroquinolone use and susceptibility reported here provide further justification for our program.

We detected a 74% decrease in fluoroquinolone use over 5 years and an absolute increase of 30% and 10% in levofloxacin-susceptible P. aeruginosa and E. coli isolates, respectively, over 10 years. ASP implementation is typically accompanied by an ∼20% decrease in total antimicrobial use, which is consistent with studies reporting on fluoroquinolone use specifically. Reference Karanika, Paudel, Grigoras, Kalbasi and Mylonakis17,Reference Chin, Green and McKamey20,Reference Jones, Onwubiko and Kubes21 Resistance reduction rates vary widely between studies. Reference Boel, Andreasen and Jarløv22Reference Wu, Liu, Lin, Hsueh and Lee25 We detected a greater reduction in use and resistance than has typically been reported. Although it is difficult to compare results between studies with heterogeneous methods, one possible explanation may be the longer observation period in our study compared with shorter 1–2-year intervention periods in most reports. In fact, a greater magnitude of resistance reduction is observed when fluoroquinolone use and resistance is assessed over a longer period. Reference Cook and Gooch23,Reference Lewis, Fang, Gooch and Cook26 Interestingly, we saw a numerically greater improvement in P. aeruginosa susceptibility than in E. coli. These results are consistent with other studies that describe either no impact on E. coli susceptibility in contrast to P. aeruginosa Reference Hecker, Son and Murphy24,Reference Falagas, Bliziotis and Michalopoulos27 or only marginal improvement. Reference Boel, Andreasen and Jarløv22,Reference Wu, Liu, Lin, Hsueh and Lee25,Reference Gottesman, Carmeli, Shitrit and Chowers28

Our results provide support for non–restriction-focused ASP services. Most current evidence for ASP impact on gram-negative fluoroquinolone resistance includes formulary restriction as the main intervention. Reference Pitiriga, Vrioni, Saroglou and Tsakris13 However, 2 studies have described interventions that included prospective audit and feedback without a restriction component. Reference Hecker, Son and Murphy24,Reference Lafaurie, Porcher, Donay, Touratier and Molina29 The interventions were successful in both studies, demonstrating a significant decrease in fluoroquinolone use and absolute increase of 9%–16% in fluoroquinolone-susceptible P. aeruginosa isolates over an ∼5-year period, which is in line with our results. Our study is unique because it not only provides fluoroquinolone susceptibility trends over 10 years but also has a longer stewardship intervention period than the 2 studies.

Another strength of our study is the utilization of order-set optimization and prospective audit and feedback as the core stewardship intervention, which can be adopted in virtually any hospital setting without the need for around-the-clock staff support, as might be required by some formulary restriction models. We might have observed even greater benefits if our system employed formulary restriction in addition to prospective audit and feedback and order-set optimization. When considering longitudinal antimicrobial stewardship activities, ASPs should periodically re-evaluate their approaches and adapt their activities based on needs and resources.

Antimicrobial stewardship activities at our health systems are primarily pharmacist driven, which is similar to other stewardship programs. Reference Barlam, Childs and Zieminski30 Pharmacists, particularly those with infectious diseases expertise, are uniquely qualified to provide robust antimicrobial stewardship and therapeutic optimization. Reference Garau and Bassetti31,Reference Bessesen, Ma, Clegg, Fugit, Pepe and Goetz32 Leveraging pharmacists’ drug expertise appears to have been successful in reducing both antimicrobial use and antimicrobial resistance at our health system. In addition to empowering pharmacists to perform stewardship activities and promoting their expertise within our health system, investment in staffing likely contributes to the successes described. Various recommendations of ratios of antimicrobial stewardship staff to hospital beds exist, but our ratio of 1 full-time infectious diseases pharmacist to 400 beds may allow for more robust prospective audit and feedback and higher impact relative to ASPs with fewer staff members. Reference Pulcini, Morel and Tacconelli33

This study had several limitations. Fluoroquinolone use data were not available for inpatients before 2016. How use correlated with susceptibility before this time remains uncertain, but other than the stewardship activities described, there were no other clinical interventions, operational changes, or changes in infection prevention practices that could have significantly influenced susceptibility. Based on first-hand knowledge of stewardship activities and prescribing patters prior to 2016, we know the use of fluoroquinolones was substantially higher in 2011 and decreased over time. We could not assess the impact of our program in a quasi-experimental study design due to lack of data prior to the intervention period. We also did not report use and antimicrobial resistance trends for other antibiotic classes, which may have inadvertently increased. However, this is unlikely given that our program did not focus solely on fluoroquinolone use but addressed other broad-spectrum antibiotics in parallel. Susceptibility interpretations for fluoroquinolones were designated based on CLSI breakpoints before the change in 2019. 34 Application of updated breakpoints likely would have resulted in decreased susceptibility rates; however, this would have been a major confounding factor, and for the purposes of this review, utilizing a consistent breakpoint likely more accurately reflects trends over time.

In our health system, fluoroquinolone use substantially decreased and P. aeruginosa and E. coli levofloxacin susceptibility increased after the implementation of an ASP. These results demonstrate the value of stewardship services and highlight the effectiveness of an infectious diseases pharmacist–led ASP.

Acknowledgments

The authors thank Stephen Furmanek, MPH, MS, for his assistance with the statistical analysis of this study.

Financial support

No financial support was provided relevant to this article.

Conflicts of interest

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

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Figure 0

Fig. 1. Fluoroquinolone use in adult inpatients from 2016 to 2020.

Figure 1

Fig. 2. P. aeruginosa levofloxacin susceptibility in adult inpatients from 2010 to 2020.

Figure 2

Fig. 3. E. coli levofloxacin susceptibility in adult inpatients from 2010 to 2020.