Impact of an Evidence-Based Computerized Decision Support System on Primary Care Prescription Costs

INTRODUCTION

For some physicians, representatives from pharmaceutical companies have become the most frequently used source of new medical information. In a study of 108 primary care physicians, information about the last new drug prescribed was derived more often from pharmaceutical company representatives than from the primary literature (42% vs 9%, respectively).¹ Unfortunately, reliance on promotional information from pharmaceutical representatives has been associated with higher rates of inappropriate prescribing, higher medication costs, and more frequent use of heavily promoted products.^2–,⁴

Computerized decision support systems (CDSSs) that provide unbiased, evidence-based information about the relative efficacy, safety, and cost of different therapeutic options might help physicians practice more fiscally responsible care. Two systematic reviews found that a CDSS could improve other aspects of physician performance, such as medical error rates, drug dosing, diagnosis, laboratory test usage, and adherence to clinical guidelines.^5,6 Because most of these trials assessed internally developed, proprietary systems in hospital settings, there has been a call for research evaluating commercially available CDSSs and their impact in primary care.^6,7

This study was designed to evaluate the impact of a commercially available CDSS on the cost of medications prescribed by primary care clinicians in a community-based, ambulatory setting. The CDSS provides diagnosis-specific, evidence-based messages during the electronic prescribing process. Most messages focus on the comparative efficacy, safety, and cost of different treatment options.

METHODS

RESULTS

Of the 50 clinicians who wrote prescriptions in the CDSS between June 1, 2002, and November 30, 2002, 19 were included in the intervention group. The other users were excluded because they did not start using the system until after the study period began (24), were not primary care clinicians (6), or did not provide patient care under the Network Health Plan for each of the 12 months (1).

As displayed in Table 1⇑, the intervention and control groups were well matched at baseline. Each group consisted of 16 physicians, 2 nurse-practitioners, and 1 physician’s assistant. During the 6-month baseline period, these clinicians accounted for a total of 183,636 member months, and 11,840 new prescriptions were written for 6,612 different patients. These new prescriptions generated an additional 15,040 refills within 6 months of the original prescription date. The total billed amount, number of patients treated, and number of prescriptions filled by patients in each group were nearly identical during the baseline period.

During the study period, the intervention and control groups continued to account for a similar number of member months (92,558 and 88,685, respectively) and write a similar number of new prescriptions (5,667 and 5,202, respectively) for a similar number of patients (3,250 and 3,004, respectively). Overall, 17,115 diagnosis-specific messages were displayed to clinicians in the intervention group during this period; 12,618 (74%) of these messages were for diagnoses associated with medications in the 10 high-cost drug categories. In addition, 88 (70%) of the daily messages sent to clinicians during the study period pertained to one of the drugs in the top 10 categories.

Table 2⇓ summarizes the prescription costs for the intervention and control groups. After implementation of the CDSS, the mean cost per new prescription was $4.16 lower (95% CI, $0.84-$7.49, P = .02) in the intervention group. These new prescriptions were refilled an average of 1.3 times during 6 months of follow-up, producing an additional 7,470 claims in the intervention group and 6,900 claims in the control group. Including refills, the cost per prescription was $4.99 lower (95% CI, $1.49-$8.48, P = .01) in the intervention group. The 6-month savings from new prescriptions and their refills are estimated to be $65,554 (95% CI, $19,574-$111,402) or $3,450 (95% CI, $1,030-$5,863) per clinician. Overall, compared with baseline, prescription costs tended to increase in the control group, whereas they decreased in the intervention group.

Table 3⇓ summarizes the changes in prescription costs for the 10 high-cost drug categories. Mean prescription costs during the study period were consistently lower in the intervention group compared with those in the control group, with significant between-group differences observed for all categories combined (P = .03) and within the categories of antide-pressants (P = .02), gastroesophageal reflux disease medications (P = .01), and antihypertension medications (P = .01). Significant decreases from baseline costs were observed in the intervention group overall (P = .01) and within the categories of antidepressants (P = .002), asthma medications (P = .04), antihypertension medications (P = .001), and headache medications (P = .03). There was a significant net intervention effect within the category of headache medications ($47.49 [95% CI, $11.51-$83.47], P = .01) and clinically meaningful trends within the category of antidepressants ($7.96 [95% CI, −$0.29–$6.20], P = .06) and all categories combined ($4.43 [95% CI, −$0.18–$9.04], P = .06).

DISCUSSION

Providing information about the relative efficacy, safety, and cost of different therapeutic options during the electronic prescribing process had a significant impact on prescription costs. Prescription costs continued to increase in the control group, which is consistent with national drug expenditure trends. At the same time, prescription costs decreased in the intervention group. Overall, drug costs were decreased by approximately 11% in the group using the CDSS.

The CDSS used in this study displayed concise, credible information that was relevant to the clinical condition being treated, and it provided this information within the clinician’s workflow. After a diagnosis was selected, prewritten prescriptions and evidence-based messages relevant to the chosen diagnosis were automatically displayed. We believe these attributes were critical to the success of the system. In other studies, computerized delivery of evidence-based guidelines had no impact when the information was not timely, relevant, and easy to access.^9,10 Likewise, a computerized system with preventive care reminders was not effective when it required clinicians to choose to see the recommendations, but succeeded when the same system displayed prewritten orders that were easily implemented.^11,12

A number of unique aspects of the study environment warrant discussion. The Affinity Health System is an integrated network with its own health plan and group of primary care and specialty physicians. Although the health system paid for the cost of the CDSS, these clinicians received no financial incentives to use the system or to modify their prescribing behavior. For logistical reasons, the intervention group consisted of clinicians from office sites where the system was first implemented. The sites were determined based on expressed clinician interest and convenience. It was not possible to randomize clinicians to intervention or control status.

Although the prescribing behavior was nearly identical between groups at baseline, it is possible that unobserved differences between groups could have introduced selection bias. Bias also could have been introduced by limiting the baseline analyses to new prescriptions only; however, a separate analysis of all prescription claims confirmed that the groups had remarkably similar prescribing behavior before implementation of the CDSS (n = 74,200 prescriptions; mean cost per prescription was $46.29 and $46.24 in the intervention and control groups, respectively). The use of a control group that was closely matched at baseline and observed during the same period helped reduce the possibility that a changing patient mix, availability of new generic medications, or a change in the pharmacy benefit would influence the outcome.

Our results would be strengthened with longer follow-up; however, the study period had to be limited to 6 months to avoid cross-contamination of groups. New clinicians were being added to the system throughout the study period. By the end of the study period, clinicians in the control group were scheduled to begin using the system.

In conclusion, providing context-specific messages to clinicians in their workflow can shift prescribing decisions toward more evidence-based care and lower prescription costs. In this study, the savings associated with improved prescribing behavior easily offset the cost of the system.