Do Medical Scribes Help Primary Care Providers Respond More Quickly to Out-of-Visit Tasks?

Design

This observational study compared the change in outcomes before and after scribe implementation between scribed providers and nonscribed providers. We compare visits during the year before scribe implementation (July 2017 to June 2018) with the year after implementation (July 2018 to June 2019).

Setting

This study was conducted at a safety net community academic health system, which uses an EMR (EPIC, Verona, WI). The EMR integrates inpatient, emergency, and outpatient care, including primary care, specialty, laboratory, pharmacy, and imaging data. In addition, the electronic inbox receives messages that patients send via a secure portal Web site, MyChart. PCPs can access their inboxes on both computers and mobile devices (via EPIC Haiku). Once a provider has addressed a task, the task is either automatically removed from their inbox or it is removed when the provider indicates they have completed the task by clicking a “done” button.

Outcomes

We defined “time to completion” as the time from when a task arrives in the provider’s inbox to the time a task is cleared from a provider’s inbox. We examined time to completion for prescription requests, results, and electronic portal patient messages. We selected these tasks because responses to these tasks are generally dependent on the provider. In contrast, other inbox messages such as telephone calls and staff messages often result in back and forth with other staff; thus, time to completion is dependent on other staff and would not be expected to be impacted by scribes.

Intervention

Scribes were recent college graduates who were interested in careers as health care professionals. Scribes received 3 days of training on how to function effectively in their role and 1 day of training in EMR functionality. Scribes continued learning through feedback from supervising PCPs. Scribes documented patient encounters, recording medical and social histories and physical examination findings, and transcribing discussions of treatment plans and PCPs’ instructions to patients. PCP participation was voluntary. PCPs received no compensation for participating in the scribe program, and PCPs were not required to increase clinical care (ie, add patients to their panels or see more patients) to work with a scribe. PCPs that worked with scribes were not statistically different from those who declined scribes, in gender, race, provider type (physician vs nurse practitioner), tenure at the institution and proportion of time working clinically (Appendix Table 1).

Inclusion/Exclusion Criteria

Because the first year at an institution is a learning period for PCPs during which inbox management skills are increased, we excluded 12 PCPs who worked at the institution for less than 1 year before the scribe program. We excluded 1 provider who was in the postintervention period for less than a month. To focus on providers who received the intervention most of the time, we excluded an additional 12 scribed providers who had less than 66% of their visits scribed during the post period. This resulted in our final sample of 5 scribed providers and 74 nonscribed providers.

We started with 528,742 tasks. Based on 1 PCP’s (WA) extensive clinical experience with scribes, we excluded tasks that occurred in the first 6 weeks of working with a scribe to account for an initial learning period (n = 2943; 0.6%). We removed extreme outliers through a 2-step process. First, we examined the median difference in time to completion by task type pre to post for each provider among scribed and nonscribed providers. Extreme changes in time to task response could indicate random variation; we therefore removed tasks for providers if the difference in time to completion for that task was an extreme outlier (defined as 3 × IQR) (n = 44,501; 8.4%).²³ Finally, because providers can keep uncompleted tasks in their inboxes intentionally (eg, as a reminder to follow up at a future date), we removed those with values greater than the 99th percentile (n = 4767; 0.9%).

Analysis

We compared demographic characteristics for patients and providers using fisher’s exact or the c² test for categorical variables and t-test for continuous variables. Because the outcome of time-to-completion was right skewed, we used a natural log transformation. We first conducted bivariate analyses, comparing outcomes pre to post separately for scribed and nonscribed providers using t-tests. Next, we compared the change in outcomes from before scribe implementation to after scribe implementation among scribed providers, compared with nonscribed providers using generalized estimating equations with robust standard errors to account for repeated measures (ie, multiple visits by the same patients) and the hierarchical nature of the data (patients nested within providers). Finally, we controlled for provider characteristics (gender, race, panel size, percent full-time equivalent in outpatient clinical care), patient demographics (age, gender, race/ethnicity), and patient complexity (complex care management program enrollment and at least 1 inpatient admission). We were unable to control for provider type (MD vs NP) due to the small number of NPs in the sample. Although we were able to include many covariates in the model, sample size limitations did not allow us to control for all covariates; thus, we were unable to include provider tenure in the models.

The Cambridge Health Alliance Institutional Review Board considered this study exempt from review.