Abstract
Purpose: An. understanding of primary care provider (PCP) workload is an important consideration in establishing optimal PCP panel size. However, no widely acceptable measure of PCP workload exists that incorporates the effort involved with both non–face-to-face patient care activities and face-to-face encounters. Accounting for this gap is critical given the increase in non–face-to-face PCP activities that has accompanied electronic health records (EHRs) (eg, electronic messaging). Our goal was to provide a comprehensive assessment of perceived PCP workload, accounting for aspects of both face-to-face and non–face-to-face encounters.
Methods: Internal medicine, family medicine, and pediatric PCPs completed a self-administered survey about the perceived workload involved with face-to-face and non–face-to-face panel management activities as well as the perceived challenge associated with caring for patients with particular biomedical, demographic, and psychosocial characteristics (n = 185). Survey results were combined with EHR data at the individual patient and PCP service levels to assess PCP panel workload, accounting for face-to-face and non–face-to-face utilization.
Results: Of the multiple face-to-face and non–face-to-face activities associated with routine primary care, PCPs considered hospital admissions, obstetric care, hospital discharges, and new patient preventive health visits to be greater workload than non–face-to-face activities such as telephone calls, electronic communication, generating letters, and medication refills. Total workload within PCP panels at the individual patient level varied by overall health status, and the total workload of non–face-to-face panel management activities associated with routine primary care was greater than the total workload associated with face-to-face encounters regardless of health status.
Conclusions: We used PCP survey results coupled with EHR data to assess PCP workload associated with both face-to-face as well as non–face-to-face panel management activities in primary care. The non–face-to-face workload was an important contributor to overall PCP workload for all patients regardless of overall health status. This is an important consideration for PCP workload assessment given the changing nature of primary care that requires more non–face-to-face effort, resulting in an overall increase in PCP workload.
Case mix among primary care provider (PCP) panels can vary substantially. Accordingly, the effort required of a PCP for routine management of a particular group of patients varies depending on the characteristics of the patients in the panel and the utilization patterns in terms of both the volume and type of activities the panel demands. The face-to-face PCP workload associated with managing a panel, as measured by work relative value units (wRVUs) (Centers for Medicare and Medicaid Services Resource–based Relative Value Scale), is captured well by age- and sex-based weighting for children, but other weighting methods are necessary for adults.1 According to Chung and colleagues,1 panel weights vary 1.9- to 2.6-fold depending on whether age- and sex-based or condition-based weighting is used, respectively. However, non–face-to-face work in primary care, such as electronic communication, telephone calls, and communication of results through letters and other means, is an increasing demand on PCPs. These non–face-to-face activities historically have not generated RVUs and therefore generally are not reflected in total workload analyses at the PCP service level.
There have been other efforts to assess workload in primary care. In a recent study of Ontario's community health centers,2 a consistent association was noted between smaller PCP panel sizes, greater proportions of patients living in poor neighborhoods, and multimorbidity. The authors inferred that patients who live in low socioeconomic areas on average generate greater workload, indicating the importance of considering measures of personal and neighborhood poverty when assessing workload in primary care and panel size targets. Katerndal and colleagues3 proposed a method for estimating the complexity of face-to-face encounters in ambulatory care using elements of history, physical examination, testing, diagnoses, patient demographics, medications and other therapies, procedures performed, and disposition, but non–face-to-face effort was not considered in this analysis.
There are multiple comorbidity indices available that use data from insurance claims and electronic health record (EHR) systems to predict future use, costs, mortality, or quality of life, including the Chronic Disease Score,4,5 Adjusted Clinical Groups System,6 Charlson Index,7 Cumulative Index Illness Rating Scale,8,9 Duke Severity of Illness Checklist,10⇓–12 and others.13 However, these indices do not account for the non-RVU-generating activities of non–face-to-face panel management routinely performed in primary care, nor do they account for other important patient characteristics, including demographics or certain social characteristics such as poverty or under- or uninsured status, that may be associated with more non–face-to-face patient management in primary care.
A better understanding of non–face-to-face panel management activities affecting primary care workload is critical. For example, a systematic review of electronic communication between patients and clinicians concluded there is mutual benefit to both patients and providers, but the workload implications for clinicians are substantial.14 The Centers for Medicare and Medicaid Services recently announced reimbursement for some (though not all) non–face-to-face services,15 an explicit acknowledgment of the increased workload and implied value of these services in primary care. A comprehensive assessment of both face-to-face and non–face-to face activities could identify PCPs with a higher workload relative to their peers, which may help to predict, and therefore prevent, clinician burnout. Panel-based primary care compensation could be more fairly distributed based on total work performed, not just work producing RVUs. Quality measures could be reconsidered by accounting for the effort put forth by a PCP rather than assessing specific outcome measures that do not consider the process involved to achieve the outcome. Clinic schedulers could allocate PCP schedules and nursing support differently to accommodate time for non–face-to-face panel management activities.
This study describes the assessment of PCP estimates of workload associated with both routine face-to-face and non–face-to-face activities common in primary care as well as the relative rankings of various challenging patient characteristics. Total workload at the PCP level is calculated by coupling resource use from EHR data at the patient encounter level with clinician estimates of both face-to-face and non–face-to-face workload associated with multiple primary care activities.
Methods
Setting and Patient Sample
This research was conducted in the primary care departments of family medicine, internal medicine, and pediatrics at University of Wisconsin (UW) Medical Foundation, which is one of the largest multispecialty medical groups in Wisconsin and includes more than 1200 faculty physicians who provide care at approximately 45 UW Health clinical practice locations and 62 clinical outreach locations throughout Wisconsin. Patients included in the study (n = 105,288) had at least one primary care encounter during a 3-year period between July 1, 2010, and June 30, 2013 and their PCP was located at one of the UW Health clinics in Dane County in south-central Wisconsin. A 3-year period was selected because it is used by the participating system and corresponds to the time frame during which patients are considered to be currently managed if they have one or more visits to primary care. Patients' EHRs, demographics, and billing data were extracted from the participating system's enterprise data warehouse for analysis. This research was determined to be exempt by the UW Health Sciences Institutional Review Board.
Clinician Survey
A 2-question survey was sent to the 271 UW Health PCPs to better understand PCP workload. The survey incorporated concepts of the National Aeronautics and Space Administration Task Load Index (NASA-TLX), which is a validated tool that has been used in the primary care clinical setting as a measure of workload by assessing perceived intensity and stress experienced by clinicians while providing medical services.16,17 This index also served as a framework for human factors research involving physician estimates of the mental demands of their work in other specialties.18,19
In one survey question, clinicians assessed the perceived workload associated with various face-to-face and non–face-to-face encounters considering the 6 NASA-TLX domains of mental demand, physical demand, temporal demand, performance, effort, and frustration. Respondents were asked to assign a value to 16 different patient care activities, assuming the workload associated with an office visit for level 3 evaluation and management of an established patient (code 99213) had a relative weight of 1.0. For example, an encounter with a weight of 0.5 means the task requires half (50%) of the overall workload compared with a 99213 office visit, whereas an encounter that has a weight of 2.0 would represent twice (200%) the overall workload of a 99213 office visit. Face-to-face encounters in the survey included new and established patient office visits, preventive health visits, and, if applicable to the survey respondent, maternity care, emergency and urgent care, hospital care, and skilled nursing facility visits. Non–face-to-face encounters included electronic and written patient communication, telephone calls, medication refills, placing orders, and supervising nurse-only visits.
In the other survey question, clinicians assessed the challenge associated with various biomedical, demographic, and psychosocial patient characteristics considering the same 6 NASA-TLX domains. Clinicians could rate each condition from 0 (not challenging) to 100 (very challenging). For reference, clinicians were asked to consider a healthy child or adult to whom only routine uncomplicated preventive care was provided as “not challenging.” The patient characteristics included in the survey were influenced by a framework proposed by Rosen and colleagues20 that includes health status, demographics, health behavior, psychosocial issues, and social environment. Before distributing the survey, faculty members in a focus group format were asked to review these biomedical, demographic, and psychosocial characteristics associated with challenging patients. As a result, a total of 31 patient characteristics were assessed in the survey.
Assessing Total System-based wRVUs and PCP Site-based Workload
wRVUs were accounted for at the UW Health system level, which included both ambulatory and all available inpatient data for all patients with a PCP located at one of the UW Health clinics in Dane County in south-central Wisconsin. An assessment of workload at the PCP site was calculated for both face-to-face and non–face-to-face activities. This was done to identify what proportion of PCP workload comprised non–face-to-face compared with face-to-face activities. The PCP site-based workload scores were derived from the individual workload value associated with each activity type in the clinician survey and was multiplied by the number of each of those activities that occurred over the 3-year study period. The distribution of workload scores was assessed among the 9 health status levels assigned by 3M's Clinical Risk Group (CRG) software (3M Health Information Systems, Salt Lake City, UT) to compare the workload results generated from the clinician survey against a validated diagnosis-based risk adjustment system. The software assigns each patient to 1 of 9 mutually exclusive hierarchical health statuses, ranging from healthy to catastrophic, based on patient demographic information and diagnostic and procedure codes in the EHR.
Data Analysis
Initial analysis consisted of descriptive characteristics of the PCP survey respondents. Individual encounter-level workload weights representing the average overall workload score for each encounter type were generated. Accompanying standard deviations for these weights also were computed. A patient's overall workload score during the study period then was acquired by summing workload weights from all encounters or visits rendered during the study period. Survey-generated workload scores were compared with average wRVUs where applicable (for face-to-face encounters).
To validate the workload results generated from the survey against a validated diagnosis-based risk adjustment system, we compared the distribution of the average overall, face-to-face, and non–face-to-face workload scores by the 9 health status levels assigned by 3M's CRG software. Average PCP survey-generated workload scores then were compared with system-wide clinician wRVUs for each CRG-generated level of patient health status. Finally, average scores for “challenging characteristics” with accompanying standard deviations were calculated. Statistical analyses were performed using SAS/Base software version 9.3 (SAS, Inc., Cary, NC).
Results
Of the 271 PCPs surveyed, 185 completed the survey, including 120 family medicine clinicians (65% of respondents), 42 general internal medicine clinicians (23% of respondents), and 23 general pediatrics clinicians (12% of respondents), for an overall response rate of 68% (Table 1). The majority of PCP respondents had been practicing for ≥10 years, were on average ≥0.6 clinical full-time equivalents, and had a panel size of >1000 patients. Most UW Health patients are insured (66% commercial, 12% Medicare, and 11% Medicaid coverage), 58% are female, 24% are younger than age 18, and 88% are younger than age 65.
Encounter Workload
Table 2 provides the summary of PCP-determined workload values by encounter type. Hospital admissions received the highest PCP survey-generated workload score (3.20), indicating the highest perceived overall workload, whereas the non–face-to-face activity of supervising a nurse-only visit had the lowest rating (0.32). For comparison, the wRVU (or range) according to the resource-based relative value scale for each face-to-face encounter is listed. For example, the wRVU range for a hospital admission is 1.92 to 3.86, depending on the level of service, and the mean PCP survey-generated workload score for a hospital admission is 3.20. The majority of survey-generated scores were within 0.5 of the associated wRVU value or range, with the exception of obstetric care (wRVU, 14.37; survey-generated workload, 2.86), hospital discharge (wRVU, 1.28–1.90; survey-generated workload, 2.80), and level 3 new patient to practice office visit (wRVU, 1.42; survey-generated workload, 2.08).
System-based and PCP Site-based Work Assessment
The average workload created by all primary care panel patients categorized by each CRG health status was calculated and is summarized in Table 3. Total workload within PCP panels at the individual patient level varied by overall health status; higher average wRVU and/or PCP survey-generated workload scores were associated with increased severity of health status. Although each individual face-to-face encounter type is associated with higher workload compared with each individual non–face-to-face activity according to PCP survey results (Table 2), the total survey-generated workload of non–face-to-face panel management activities associated with routine primary care was greater than the average survey-generated workload associated with face-to-face encounters across all levels of CRG health status.
Patient Characteristic Assessment
Table 4 shows the 31 patient characteristics ranked by primary care clinicians as the most challenging (ranked number 1), to the least challenging (ranked number 31). Chronic pain/fibromyalgia/myofascial pain was ranked as the most challenging, with an average score of 79.3, whereas hypertension was ranked as the least challenging patient characteristic, with an average score of 36.8.
Discussion
We were able to combine PCP perception of workload associated with non–face-to-face encounters with the wRVUs associated with face-to-face encounters to calculate a total workload score at the primary care service level for each primary care panel member. Our PCPs indicated the workload required for non–face-to-face activities ranges from 32% to 63% of an office visit for level 3 evaluation and management of an established patient (code 99213). In addition, there was high agreement between wRVUs and PCP survey-generated workload scores where available, suggesting PCPs are able to objectively assess workload. The total PCP site-based non–face-to-face workload was higher than the total PCP site-based face-to-face workload at all CRG health status levels. This is a particularly critical finding given that the scope and frequency of non–face-to-face encounters will likely continue to increase with the proposed Centers for Medicare and Medicaid Services recommendation that complex care management include provider availability 24 hours a day, 7 days a week,21 which may result in tremendous strain on primary care clinicians. As a result, we believe it is important to include non–face-to-face activities in addition to face-to-face activities when assessing workload in primary care because primary care clinicians engage in significant non–face-to-face work that adds value (eg, communicating medication information, medical information exchange)14 to patients, clinicians, and the broader health care system.
There are many similarities between the workload results from the PCP survey compared with established wRVUs for many encounter types. However, the workload associated with hospital discharge, for example, was rated by clinicians as 2.80 compared with the range of wRVUs of 1.28 to 1.90 for hospital discharge. This may reflect increased effort clinicians are putting into hospital discharges as pressure increases to reduce the risk of readmissions. There seems to be a trend toward more patient education, care coordination, and other administrative work associated with the day of discharge. In addition, the survey response to this question likely depends on the scope of a clinician's practice. For example, the discharge of a healthy term newborn by a pediatrician is likely less complicated than the discharge of an elderly adult with multiple comorbidities. The hospital discharge workload ratings were 2.90 compared with 2.58 for family medicine and pediatrics, respectively.
This workload assessment method may be an appropriate tool to identify “high users” at the PCP service level who may not be identified through other means. Identifying individual patients who use significant non-RVU-producing health care resources at the primary care site could allow for different management strategies. For example, this method could be used to identify groups of patients, such as those who have frequent contacts with the PCP office, who could be candidates for more proactive care. One patient in our practice who had 173 telephone encounters during the 3-year study period could be contacted during a planned weekly telephone call to reduce the number to 156 telephone calls. With respect to resident training, this workload assessment method could be used to create fair workload balance for clinicians, in contrast to simple panel calculations.
As shifts continue toward compensating PCPs for managing patient panels appropriately versus fee-for-service or productivity-based compensation models, it is becoming increasingly important to understand all aspects of primary care panel management. For example, this workload assessment method could contribute to a more complete picture when negotiating bundled payments or capitation for certain primary care populations that could be used as financial support for primary care compensation. Similarly, it might justify the need for additional staff or clinicians better than the usual wRVU-generating billing data that is frequently used in assessments of workload at the primary care level.
Although we assessed PCPs regarding the challenge associated with caring for certain biomedical, demographic, and psychosocial patient characteristics, we did not use these survey results to assess the effect of these characteristics on workload at the PCP service level. Since there are associations with workload and overall health status, however, we presume that once these characteristics are taken into consideration when assigning an overall health status, as incorporated in risk adjustment programs such as CRG, the effect on workload may be even greater. We plan to study differences in workload by individual PCP and clinic site by incorporating the challenging patient characteristic scores our PCPs described in Table 4. This is an important next step as we consider the effect of challenging patient characteristics on total PCP workload and how it may affect PCP panel size targets.
Limitations
We used EHR data to assess PCP workload by accounting for both face-to-face and non–face-to-face encounters routinely performed in primary care. However, some of our patients are hospitalized in local hospitals that are not connected to our enterprise reporting database. As a result, our workload score may represent an underestimate of the all-system utilization portion for patients who visit hospitals or providers outside our system. One of the important points of this workload assessment method is accounting for non–face-to-face activities. These generally occur at the PCP site, and therefore the PCP service level, so they would be captured by our enterprise reporting database.
With a 68% survey response rate, we would have liked increased participation to help inform our PCP workload assessment method. However, there was a balanced survey response rate among all primary care specialties including family medicine (120 of 174, 69%), general internal medicine (42 of 61, 69%), and pediatrics (23 of 36, 64%). As a result, the PCP assessment of workload is likely applicable across primary care specialties. However, if unique patient characteristics are to be considered in addition to PCP workload for panel size adjustments in the future, as suggested by Chung and colleagues,1 it would be necessary to consider the results from each primary care specialty separately since the results of the mostly adult specialties of family medicine and internal medicine were more similar than those from pediatrics. Unfortunately, some of these patient characteristics are difficult to obtain from the EHR since they often are not entered in discrete data fields. Future EHR system developments should create discrete data entry fields to capture these characteristics. In addition, this study took place in a single large group practice in Wisconsin and requires replication and validation in other settings.
Conclusions
We used PCP survey results coupled with EHR data to assess PCP workload associated with both face-to-face as well as non–face-to-face panel management activities in primary care. The non–face-to-face workload was significant for all patients regardless of overall health status. This is an important consideration for PCP workload assessment given the changing nature of primary care, which requires more non–face-to-face activities that may account for an overall increase in PCP workload.
Notes
This article was externally peer reviewed.
Funding: none.
Conflict of interest: none declared.
- Received for publication August 14, 2013.
- Revision received January 21, 2014.
- Accepted for publication March 20, 2014.