Reducing Antibiotic Use in Children: A Randomized Trial in 12 Practices

Design

In this prospective trial, practices were randomly assigned to intervention or control groups. Data from automated claims were analyzed retrospectively for the baseline (preintervention) year (December 1, 1996–November 30, 1997) and intervention year (December 1, 1997–November 20, 1998). The primary outcome measure was the rate of antibiotic courses dispensed to children (antibiotics per person-year) in intervention and control practices. The study was designed to detect a 10% decrease in the rate of antibiotic dispensing attributable to the intervention with 80% power and 2-sided type 1 error of 5%.

Setting

Twelve practices affiliated with 2 MCOs—Harvard Pilgrim Health Care (HPHC) in eastern Massachusetts and Group Health Cooperative (GHC) in northwest Washington State—were studied. The HPHC sites were suburban group practices contracting with the MCO, whereas the GHC sites were multispecialty clinics of an integrated group-model health system. Of the 6 GHC practices, 2 were urban and 4 were suburban or in small towns; no rural practices were included. At HPHC, pharmacy claims for Medicaid enrollees were paid directly by Medicaid and unavailable; HPHC Medicaid members were, therefore, excluded from analysis. Medicaid enrollees at GHC were included; a previous study documented that 11.6% of 2-year-old GHC members were Medicaid enrollees.²³Although there may have been attention to antibiotic prescribing at some of the practices before the initiation of the randomized trial, there were no relevant plan-wide initiatives at either MCO.

Randomization

Sites were stratified by size (<500 vs >500 person-years of observation for children 3 to <72 months of age), separately for HPHC and GHC. They were then ranked in decreasing order of antibiotic courses prescribed using available data from 1994 to 1996 (before the baseline study year). Practice pairs with the most similar baseline prescribing rates were randomized to intervention or experimental groups.

Subjects

We included in our analysis children 3 months to <72 months of age enrolled in the health plans and receiving pharmacy benefits for at least 3 months during the study period December 1, 1996 to November 30, 1998. We excluded children enrolled in the health plan according to membership data, but who had no record of any ambulatory visits (including well-child care) and no antimicrobial dispensing during the study period. We specified 2 age groups before the analysis: 3 to <36 and 36 to <72 months, because the incidence of otitis media,²⁴ patterns of antibiotic prescribing⁸and the approach to testing and treatment of febrile illness^25–27 differ in older and younger preschool children.

Educational Intervention

The 1-year targeted educational intervention, begun in the fall of 1997, was designed to change both physician and parental behavior to decrease unnecessary antimicrobial use. Six 1-page evidence-based summaries corresponding to the diagnoses targeted by the CDC's initiative to promote judicious antibiotic prescribing¹³were created in the format of “academic detailing” summaries¹⁹ (available from the CDC). Endorsement by both CDC and local MCOs was designed to increase the credibility of key messages. In October or November of the intervention year, a practicing pediatrician “peer leader,” trained at a CDC workshop, led an initial 90-minute small group educational session with members of the practice. Topics included a discussion of the general problem of antibiotic resistance and potential ways to prevent overuse of antibiotics. Peer leaders focused particularly on differentiating acute otitis media from otitis media with effusion, because prescribing for otitis media is particularly frequent, and on the benefit of clinicians in a practice using similar diagnostic criteria for respiratory tract infections. At approximately the same time, each family receiving care at intervention practices was mailed a copy of the CDC-produced pamphlet entitled “Your Child and Antibiotics,” with a cover letter signed by their pediatricians. Key messages to parents were reinforced by educational materials (additional CDC pamphlets and posters) in the waiting and examination rooms of the intervention practices. Study coordinators restocked the experimental sites with educational materials throughout the intervention year. Approximately 4 months after the initial session, the peer leaders visited the intervention sites again to reinforce the recommendations for judicious antibiotic use and to present feedback (bar graphs of practitioner and practice-level antibiotic prescribing rates) from the previous year. No feedback was given to physicians of control practices.

Data Sources

Antibiotic courses dispensed for each child were extracted from automated pharmacy claims data, which include records of both original prescriptions and refills. These claims are submitted by pharmacies for payment when a medication is actually dispensed and include the drug dispensed and the date. We excluded antituberculosis drugs, antihelminthics, topical antimicrobials, and other antimicrobial agents rarely used in ambulatory pediatric care.

Each agent dispensed was linked, when possible, to the most recent ambulatory encounter, ascertained from automated ambulatory claims records.⁸ Encounter diagnoses were grouped according to the following International Classification of Diseases-Ninth Revision codes and their subcodes: otitis media, pharyngitis (including tonsillitis and scarlet fever), sinusitis, bronchitis, pneumonia, upper respiratory infection/common cold, other viral, and a composite group (nonrespiratory bacterial) including other focal bacterial, skin/soft tissue, and urinary tract infections. Remaining diagnoses, including well-child care visits, were categorized as “other.” Encounters for which >1 diagnosis was recorded were assigned a primary diagnosis giving priority to a respiratory tract illness and, when present, to a potential bacterial source (eg, if both common cold and otitis media were coded, the latter was designated primary). For this analysis we use the general category “otitis media” to include both acute otitis media and otitis media with effusion, because these conditions are not reliably separable in retrospective, claims-based analyses.

Analysis

The primary goal was to compare the rates of antibiotic courses dispensed per person-year in experimental and control practices. Eligible observation time (in person-years) was determined for each child as the period of membership, in the age group of interest, during the baseline and intervention years. Because some children entered or left the practice, or “aged out” of the cohort in the middle of a year, person-time may have been <1 year for any individual. Unadjusted dispensing rates in control and intervention groups were compared using negative binomial regression, which accounts for the observed overdispersion of rates compared with the Poisson distribution.

In our primary analysis, we assessed the adjusted intervention effect for children enrolled during both years of observation. Because some children crossed the boundary between age groups during the study period, we assigned each child to the 3 to <36 month or 36 to <72 month age group based on their age at the start of the intervention year (December 1, 1997). We used generalized estimating equations²⁸ to predict the antibiotic prescription rate for each individual child in the intervention year, adjusting for each patient's antibiotic use in the baseline year, age, and MCO. Usual regression techniques assume that each observation (in this case, the rate of antibiotic use by each child) is independent. Generalized estimating equations is a regression technique that can account for nonindependence, or clustering, of individuals. Our model accounted for the fact that the prescription rates of children in each practice site are correlated. This model also assumed the relationship between the mean and the variance of the outcome variable was the same as that of a negative binomial distribution.

We also performed a practice-level (N = 12) analysis using linear regression to predict the antibiotic prescription rate in the intervention year, adjusting for the baseline prescription rate in each practice. Because this practice-level analysis did not adjust for clustering or patient level covariates, it was expected to provide a conservative estimate of the intervention effect. All analyses usedSAS Software, Version 8 (SAS Institute, Inc, Cary, NC). Results were declared significant if 2-tailed Pvalues were <.05.