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. 2017 Oct 19;6(4):497–505. doi: 10.1007/s40121-017-0175-9

Assessments of Opportunities to Improve Antibiotic Prescribing in an Emergency Department: A Period Prevalence Survey

Tristan T Timbrook 1,2, Aisling R Caffrey 1,2,3, Anais Ovalle 1, Maya Beganovic 1,2, William Curioso 1, Melissa Gaitanis 1, Kerry L LaPlante 1,2,4,
PMCID: PMC5700895  PMID: 29052109

Abstract

Introduction

Approximately 30% of all outpatient antimicrobials are inappropriately prescribed. Currently, antimicrobial prescribing patterns in emergency departments (ED) are not well described. Determining inappropriate antimicrobial prescribing patterns and opportunities for interventions by antimicrobial stewardship programs (ASP) are needed.

Methods

A retrospective chart review was performed among a random sample of non-admitted, adult patients who received an antimicrobial prescription in the ED from January 1 to December 31, 2015. Appropriateness was measured using the Medication Appropriateness Index, and was based on provider adherence to local guidelines. Additional information collected included patient characteristics, initial diagnoses, and other chronic medication use.

Results

Of 1579 ED antibiotic prescriptions in 2015, we reviewed a total of 159 (10.1%) prescription records. The most frequently prescribed antimicrobial classes included penicillins (22.6%), macrolides (20.8%), cephalosporins (17.6%), and fluoroquinolones (17.0%). The most common indications for antibiotics were bronchitis or upper respiratory tract infection (URTI) (35.1%), followed by skin and soft tissue infection (SSTI) (25.0%), both of which were the most common reason for unnecessary prescribing (28.9% of bronchitis/URTIs, 25.6% of SSTIs). Of the antimicrobial prescriptions reviewed, 39% met criteria for inappropriateness. Among 78 prescriptions with a consensus on appropriate indications, 13.8% had inappropriate dosing, duration, or expense.

Conclusion

Consistent with national outpatient prescribing, inappropriate antibiotic prescribing in the ED occurred in 39% of cases with the highest rates observed among patients with bronchitis, URTI, and SSTI. Antimicrobial stewardship programs may benefit by focusing on initiatives for these conditions among ED patients. Moreover, creation of local guideline pocketbooks for these and other conditions may serve to improve prescribing practices and meet the Core Elements of Outpatient Stewardship recommended by the Centers for Disease Control and Prevention.

Keywords: Antimicrobial, Antimicrobial stewardship, Emergency department

Introduction

Overuse of antimicrobials is a major driver of antimicrobial resistance which threatens the health of people all over the world [1, 2]. On May 20, 2017, antimicrobial resistance was recognized and discussed at the Group of Twenty (G20) Summit by leaders from around the world. Together with the World Health Organization, World Organization for Animal Health, and Food and Agriculture Organization of the United Nations, the G20 is preparing a global report with three recommendations: promote conservation of antimicrobials, optimize utilization, as underuse, like overuse, can contribute to antimicrobial resistance, and invest in innovations that can help bring new antimicrobials, vaccines, and diagnostics to market [3]. Consistent with the first two recommendations, antimicrobial stewardship programs (ASPs) have improved antimicrobial use in hospitals through those interventions [4]. However, nearly two-thirds of antibiotic expenditures occur in the outpatient setting, indicating an important area of need for antimicrobial stewardship (AMS) [5, 6].

To improve antimicrobial use in outpatient settings, the Centers for Disease Control and Prevention (CDC) recently released the Core Elements of Outpatient Stewardship [6]. These recommendations include four elements: commitment to improving antibiotic prescribing and patient safety, implementation of at least one policy or practice, tracking and reporting antimicrobial prescribing practices, and providing education and expertise to clinicians and patients on antimicrobial prescribing. These core elements are timely as calls to action for AMS targeting emergency departments (ED) as part of the outpatient setting have gained interest [7, 8]. Prior to addressing the Core Elements of Outpatient Stewardship individually, the CDC recommends identifying high-priority indications (e.g., respiratory infections) for targeted intervention. Overall, 1/3 of antibiotics in the outpatient setting, including EDs and outpatient clinics, are inappropriately prescribed with respiratory tract infections attributing to the majority of inappropriate prescriptions, yielding a significant area of opportunity for AMS [9, 10]. However, overall rates of inappropriate prescribing specific to ED settings are lacking in the US. Therefore, the objective of this study was to determine rates of inappropriate antimicrobial use and define specific areas of opportunity for AMS interventions in the ED.

Methods

Setting and Patients

The Providence Veterans Affairs Medical Center (PVAMC) is a 119-bed teaching hospital located in Providence, Rhode Island, USA. Patients included in this period prevalence study were a randomly selected 10% sample of non-admitted patients 18 years of age or older, who were prescribed an antimicrobial medication in the PVAMC ED and filled at the PVAMC pharmacy from January 1 to December 31, 2015. In 2012, the PVAMC implemented an ASP, in which the infectious diseases pharmacy fellows provide prospective audit and feedback for admitted patients [11]. However, ED patients were not routinely monitored by the ASP during this study period. Moreover, the ASP distributed an antimicrobial guidebook, but no specific interventions or education had been provided to the emergency department on the use of the local guidelines before or during this period.

Data Collection and Assessment

Data collection was performed by a clinical pharmacist and an internal medicine physician. Both clinicians had complete access to the electronic medical records of the included patients. Specific data collected included: patient demographics, encounter infectious diagnosis, temperature, white blood cell count, antimicrobial prescribed (dose, route, duration), concomitant chronic medications, and appropriateness of antibiotic prescribing based on chart assessment. Both the clinical pharmacist and physician retrospectively assessed the appropriateness of antibiotic therapy prescribed based on the documented diagnosis received in the ED for each patient.

Appropriateness was measured using the Medication Appropriateness Index (MAI) [12]. The MAI is a validated tool that assesses the appropriateness of 10 different areas of medication prescribing: indication, effectiveness, dosage (based on indication and renal function), directions, practicality, drug–drug interactions, drug–disease interactions, duplication, duration, and expense [13, 14]. For every prescribed medication, the reviewers answered each of the 10 questions in the MAI with either A (appropriate), B (not clearly appropriate), or C (inappropriate). Assessments on the appropriateness of therapy were made according to local antibiotic use guidelines summarized in a guidebook tool (http://web.uri.edu/antimicrobial-stewardship/) which was derived from national practice guidelines endorsed by the Infectious Diseases Society of America (IDSA) and/or CDC. Study data were collected and managed using REDCap electronic data capture tools hosted within the VA [15].

Compliance with Ethics Guidelines

This study was reviewed and approved by the Institutional Review Board and Research and Development Committee of the Providence Veterans Affairs Medical Center. This article does not contain any new studies with human or animal subjects performed by any of the authors.

Data Analysis

Descriptive statistics were used for patient characteristics, clinical presentation including infectious diagnosis, characteristics of prescribed antibiotic (dose, duration, etc.), and MAI results. MAI responses were categorized as appropriate (appropriate) and inappropriate (inappropriate or not clearly appropriate) [16]. In calculating inappropriate prescribing rates, for a prescription to be defined as inappropriate, it had to be categorized as such by consensus between the clinical pharmacist and internal medicine physician. Kappa statistics for interrater reliability were calculated for the overall MAI, each MAI category, and by infection type [17, 18].

Results

Of 1579 ED-associated antibiotic prescriptions in 2015, we reviewed a total of 159 (10.1%) prescription records for 148 patients, excluding 2 patients who were subsequently admitted during the same visit. Patient characteristics and prescribing indications can be found in Table 1. The median age was 60 and most patients were male (91.2%). Concomitant chronic medication use was common (median 8, interquartile range 3–13). The most common indications for antibiotics were bronchitis or upper respiratory tract infection (URTI, 35.1%), followed by skin and soft tissue infection (SSTI, 25.0%). As reflected in Table 2, frequently prescribed antibiotics included penicillins (22.6%), macrolides (20.8%), cephalosporins (17.6%), and fluoroquinolones (17.0%).

Table 1.

Patient characteristics

Characteristics n = 148
Age (years), median (IQR) 60 (44–69)
Male 135 (91.2%)
White 125 (84.5%)
Temperature (°C), median (IQR) 36.7 (36.5–37.0)
White blood cells (measurement), median (IQR) (n = 64) 8.4 (6.5–11.2)
Concomitant medications, median (IQR) 8 (3–13)
Indication
 Bronchitis or URTI 52 (35.1%)
 CAP 8 (5.4%)
 COPD 5 (3.4%)
 Flu 1 (0.7%)
 Intra-abdominal 12 (8.1%)
 Other 14 (9.5%)
 Prophylaxis 7 (4.7%)
 SSTI 37 (25.0%)
 UTI 8 (5.4%)
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CAP Community-acquired pneumonia, COPD chronic obstructive pulmonary disease, IQR interquartile range, SSTI skin and soft tissue infection, URTI upper respiratory tract infection, UTI urinary tract infection

Table 2.

Antimicrobials prescribed

Drug class n = 159
Antiviral 8 (5.0%)
Clindamycin 4 (2.5%)
Cephalosporin 28 (17.6%)
Fluoroquinolone 27 (17.0%)
Macrolide 33 (20.8%)
Metronidazole 8 (5.0%)
Penicillins 36 (22.6%)
Sulfonamide 4 (2.5%)
Other 11 (6.9%)
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A summary of inappropriate prescribing based on MAI criteria is shown in Table 3. Thirty-nine percent of antimicrobial prescriptions were classified as inappropriate. Inappropriate prescribing varied by indication: bronchitis/URTI (15/52, 28.9%), SSTI (10/39, 25.6%), intra-abdominal infections (15.0%; 3/20), community-acquired pneumonia (CAP; 3/9, 33.3%), urinary tract infection (UTI; 2/8, 25.0%), and other conditions (4/14, 28.6%). Of the 79 (49.7.8%) prescriptions with a consensus on appropriate indication, inappropriate prescribing was noted among 13.8% of prescriptions with regards to dose, duration, or expense, while the other MAI categories reflected no inappropriate prescribing based on reviewer consensus. CAP and UTI dosing were found to be inappropriate in 11.1% and 12.5% of cases, respectively. Inappropriate durations were found in 6.0% of bronchitis/URTI, 7.7% of SSTI, and 5.0% of intra-abdominal infections. Excessive expense was noted in 11.1% of CAP, and only 2% of bronchitis/URTI.

Table 3.

Inappropriate prescriptions by MAI category

MAI category n (%)
Indication 40 (25.2)
Effectiveness 0 (0)
Dosage 2 (1.3)
Correct directions 0 (0)
Drug–drug interaction 0 (0)
Drug–disease interaction 0 (0)
Practical directions 0 (0)
Expense 12 (7.5)
Duplication 0 (0)
Duration 8 (5.0)
Total 62 (39.0)
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MAI Medication Appropriateness Index

Overall, interrater reliability of the MAI was high (k = 0.90). The kappa statistics for indication, dose, and duration were 0.46, 0.47, and 0.26, respectively. Though other MAI categories had high positive agreement for appropriateness (median 85, IQR 79–98), kappa statistics could not be calculated for these MAI categories due to the lack of negative agreement (determined as inappropriate by both reviewers). Kappa scores by indication were also high, with a median of 0.82 (IQR 0.58–0.91).

Discussion

The present study reflects the first ED inappropriate prescribing assessment reported in the US, with 39% of prescribing found to be inappropriate as defined by the MAI and local guidelines. The two most common indications, SSTI and bronchitis/URTI, also had the highest rates of inappropriate prescribing (25.6% and 28.9%) aside from CAP where ~ 1/3 of antibiotics were not indicated based on diagnostic criteria from a chart review. These results are consistent CDC data which found ~ 1/3 of antibiotic prescriptions in the outpatient setting, including outpatient clinics and EDs, as being inappropriate [9].

Similar to studies from outpatient clinic settings, we found an opportunity for AMS among patients with a diagnosis of bronchitis or URTI patients with 28.9% of prescribing being inappropriate based on indication [9, 10]. In our older population of Veterans, the prevalence of chronic obstructive pulmonary disease (COPD) is more than double that of the general US population [19, 20]. Therefore, many of these patients may have had a history of COPD, and thus components of COPD exacerbation requiring antibiotics. Our local guidance, concordant with national guidelines for bronchitis and URTIs, infrequently recommends antibiotics since > 90% of patients presenting with a new onset cough for outpatient treatment have a virus [21].

To assist in diagnostic uncertainty for respiratory indications, rapid diagnostic testing, both procalcitonin and respiratory viral panels, have been shown to help in decreasing inappropriate antibiotic use among patients presenting with respiratory illnesses with possible infectious etiologies [22, 23]. However, these technologies may be suboptimal in decreasing inappropriate antibiotic use unless there is education and AMS guidance along with audit and feedback [24]. Future efforts should focus on how to optimize implementation of diagnostic testing within the ED to increase appropriate use of antibiotics in patients with respiratory tract infections. Clinician education has also been shown to be an effective intervention modality for decreasing antimicrobial use in adults with acute respiratory infections treated in EDs [25].

Another important area of opportunity identified for improved prescribing was with SSTIs. We found 25.6% of prescribing for SSTIs was inappropriate based on indication. Current national guidelines recommend against the use of antibiotics for uncomplicated skin abscesses which have undergone incision and drainage, yet this practice remains common [26, 27]. A study of the National Hospital Ambulatory Medical Care Survey (NHAMCS) from 2007 to 2010 found that 87% of visits for abscesses which had incision and drainage were still prescribed antibiotics [27]. Adaptation of and education on ED-specific national guidelines may encourage ED providers to execute more judicious use [28].

While comprehensive assessments of inappropriate antibiotic prescriptions in the ED have not been previously reported in the US, a recent study in France found that 59.9% (455/760) of prescriptions in the ED were inappropriate [29]. This was higher than our observed 39% which may be due to differences in patient populations, as well as national and local treatment guidelines. Similar to our study, however, they found high rates of inappropriate prescribing for respiratory tract infections (46.5%), SSTIs (71.2%), and UTIs (38.4%). We also observed high inappropriate prescribing for UTIs (37.5%). Education on optimal empiric treatments given high resistance to therapies like fluoroquinolones has been shown to improve empiric prescribing [30, 31].

To date, there has been a single study reporting on a comprehensive AMS initiative in the ED [32]. This was a single center study at a 497-bed tertiary university hospital in France with about 35,000 ED visits per year. An intervention bundle was employed consisting of a 0.2 infectious diseases (ID) physician full-time equivalent for advising during business hours, educating staff every 6 months on stewardship principles, creating a treatment guideline pocketbook, appointing an ED antimicrobial champion to attend daily staff meetings and promote optimal antimicrobial use, and reviewing ED antibiotic prescribing and culture results twice weekly by the ID physician. Antimicrobials were prescribed in 769 visits during the pre-implementation period and 580 visits in the post-implementation period. Prescriptions were not compliant with guidelines in 62.9% of the pre- and 46.7% of the post-implementation visits (p < 0.001). Non-indicated prescriptions decreased by 8.2% (< 0.001), while prescriptions with excessive duration decreased by 2.2% (non-significant). The bundled intervention in this study consisted of various stewardship activities which would be useful to address inappropriate antimicrobial prescribing in an ED. These activities are also supported by a systematic review of AMS in outpatient settings [33].

Measuring inappropriate rates of antimicrobial prescribing is important, yet challenging [34]. A recent study evaluating antimicrobial appropriateness with computerized case vignettes, as reviewed by two infectious diseases physicians, demonstrated a kappa of 0.01 after initial independent review, 0.34 after discussion of case disagreements, and 0.72 after uniform application of institutional guideline criteria. In our initial pilot study, 50 randomly selected patients were evaluated using national guidelines without a summary tool or local guidelines and resulted in a lower overall interrater reliability (k = 0.30), hence the use of local guidelines substantially improved our interrater reliability (k = 0.90). The importance of assessing antibiotic appropriateness using local guidelines to decrease subjectivity and increase reproducibility of assessments has been suggested elsewhere [35]. In fact, this is part of the CDC core elements for outpatient stewardship’s initial steps: establishing standards for antibiotic prescribing [6]. They recommend to consider adapting national guidelines to establish clear expectations for appropriate antibiotic prescribing.

There are several limitations to this study. Our study was a single center in a VA ED. Moreover, given our sample size, outcomes of inappropriate prescribing were not assessed. Future comprehensive assessments of inappropriate antibiotic prescribing in the ED should be evaluated in community hospital settings to assess differences among non-Veteran populations and should attempt to evaluate outcomes of inappropriate prescribing. Due to data collection limitations, this study did not capture patients who did not fill their prescriptions at the PVAMC pharmacy. Additionally, we only evaluated patients who were prescribed an antibiotic, indicating a potential selection bias. The use of the kappa statistic limited our ability to calculate interrater reliability for some MAI categories due to a lack of negative agreement (determined as inappropriate by both reviewers), especially when there were high rates of appropriateness. We evaluated only empiric prescribing and did not evaluate culture results; therefore, our inappropriate rates of antibiotic use are likely conservative. However, extensive literature on the value of AMS in culture result follow-up reflects both the need and the benefit of AMS in optimizing definitive therapy and the discontinuation of therapy in the absence of organism growth [3640]. While our local guidelines provided objective assessment criteria for many indications, they were not exhaustive, and, therefore, decisions on certain indications relied more heavily on clinical judgment.

Conclusion

Consistent with national outpatient prescribing, inappropriate prescribing was identified in 39% of antibiotic prescriptions in the ED with the highest rates among patients with bronchitis, URTI, and SSTI. ASPs may benefit by focusing on initiatives for these conditions in the ED setting. Moreover, creation of local guideline pocketbooks may improve prescribing practices, with these activities together meeting the CDC recommended Core Elements of Outpatient Stewardship.

Acknowledgements

No funding or sponsorship was received for this study or publication of this article. This material is based upon work supported, in part, by the Office of Research and Development, Department of Veterans Affairs. All named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this manuscript, take responsibility for the integrity of the work as a whole, and have given final approval to the version to be published. T.T.T. and A.R.C. had full access to all data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.

Disclosures

Tristan T. Timbrook has received honorarium as a speaker and/or advisor for BioFire Diagnostics and GenMark Diagnostics. Aisling R. Caffrey has received research funding from Pfizer, Cubist (Merck), The Medicines Company. Kerry L. LaPlante has received research funding or honorarium as an advisor for Cubist (Merck), BARD/Davol, Biomerieux, Forest (Allergan), Ocean Spray, The Medicines Company, Cempra, and Pfizer. Anais Ovalle, Maya Beganovic, William Curioso, and Melissa Gaitanis have no disclosures to declare.

Compliance with Ethics Guidelines

This study was approved by the Institutional Review Board and Research and Development Committee of the Providence Veterans Affairs Medical Center. This article does not contain any new studies with human or animal subjects performed by any of the authors.

Disclaimer

The views expressed are those of the authors and do not necessarily reflect the position or policy of the United States Department of Veterans Affairs.

Data Availability

The datasets generated and analyzed during the current study are available from the corresponding author on reasonable request.

Open Access

This article is distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 International License (http://creativecommons.org/licenses/by-nc/4.0/), which permits any noncommercial use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Footnotes

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The datasets generated and analyzed during the current study are available from the corresponding author on reasonable request.

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