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Abstract Objective To develop expeditiously a pragmatic, modular, and extensible software framework for understanding and improving healthcare value (costs relative to outcomes). Materials and methods In 2012, a multidisciplinary team was assembled by the leadership of the University of Utah Health Sciences Center and charged with rapidly developing a pragmatic and actionable analytics framework for understanding and enhancing healthcare value. Based on an analysis of relevant prior work, a value analytics framework known as Value Driven Outcomes (VDO) was developed using an agile methodology. Evaluation consisted of measurement against project objectives, including implementation timeliness, system performance, completeness, accuracy, extensibility, adoption, satisfaction, and the ability to support value improvement. Results A modular, extensible framework was developed to allocate clinical care costs to individual patient encounters. For example, labor costs in a hospital unit are allocated to patients based on the hours they spent in the unit; actual medication acquisition costs are allocated to patients based on utilization; and radiology costs are allocated based on the minutes required for study performance. Relevant process and outcome measures are also available.
A visualization layer facilitates the identification of value improvement opportunities, such as high-volume, high-cost case types with high variability in costs across providers. Initial implementation was completed within 6 months, and all project objectives were fulfilled. The framework has been improved iteratively and is now a foundational tool for delivering high-value care. Conclusions The framework described can be expeditiously implemented to provide a pragmatic, modular, and extensible approach to understanding and improving healthcare value.
, Background and significance Improving healthcare value—defined as the health outcomes achieved per dollar spent—is a central challenge for the US healthcare system. The USA spends approximately $9000 per capita on health care annually, accounting for approximately 18% of the gross domestic product.
This per capita expenditure is the highest in the world and roughly 2.5 times the average expenditure among industrialized nations. Despite these expenditures, health outcomes are relatively poor. An estimated 440 000 Americans die prematurely each year due to preventable medical harm.
Moreover, US adults receive only about half of recommended care, and life expectancy in the US is below most developed nations and some developing nations. The lack of correlation between spending and outcomes is fueling a national focus on value. Under traditional fee-for-service payment models, US healthcare systems have had little financial incentive to improve value. Increasingly, however, healthcare payors are adopting payment models that provide strong financial incentives for the delivery of high-value care. Payment models may offer a fixed fee for managing a population or episode of care rather than a variable fee that increases as more services are provided. Employers are also driving change. Large corporations such as Walmart have begun to steer high-cost, high-margin care such as cardiac and spine surgery to a small number of hospitals with demonstrated high value.
Consequently, healthcare systems are faced with major financial and existential imperatives to understand and improve care value. In seeking to improve care value, a central challenge most healthcare delivery organizations face is their limited capacity to measure and analyze healthcare value, particularly around costs. Understanding care costs is challenging due to the highly complex, fragmented, and variable nature of healthcare delivery. As noted by Porter and Lee, while measuring medical outcomes has become a national priority, there is a “near complete absence of data on the true costs of care for a patient with a particular condition over the full care cycle, crippling efforts to improve value.” Billing charges are often confused with the costs of delivering care. However, charges are an inaccurate estimate of the actual costs incurred. True costing numbers are critical to developing and monitoring strategies to reduce costs, supporting the adoption of value-based reimbursement systems, and encouraging innovation. Cost accounting has high relevance for informatics as well.
According to Ohno-Machado, “an important but often underpublished area of biomedical informatics (is) the cost-effectiveness of informatics interventions in healthcare,” which requires accurate healthcare cost data for proper evaluation. The prior literature on healthcare cost accounting includes analyses of the relative strengths and weaknesses of different approaches, as well as high-level descriptions of specific cost accounting systems. Several commercial entities also provide software and consulting services in this area. Overview of system architecture. Letters refer to system components. Opportunity Identification = reports to identify potential opportunities for improving value.
Variance Analysis = reports to analyze variance in care costs among care providers. Performance Tracking = reports to track performance over time with regard to both costs and outcomes. Identification of direct clinical care costs For facility costs, the identification of direct clinical costs is generally straightforward, as a healthcare facility has one primary mission—clinical care. For professional costs in the context of an academic healthcare system, the identification of direct clinical costs can be more challenging because physicians and their support staff may also engage in research and education.
In the initial phase of VDO, direct professional clinical costs were identified by leveraging an existing annual faculty survey on effort allocation and an additional survey of clinical department administrators to identify expenses in the general ledger attributable to direct patient care. Business rules were then applied to identify direct professional costs (eg, direct clinical cost of physician = (salary + benefits) × (estimated% effort dedicated to clinical care)).
Costing methods for allocating costs to encounters provides an overview of the categories of costing methods that have been implemented for allocating identified direct care costs to encounters. Each method category can have multiple associated methods. For example, within the ‘actual cost’ method category, the pharmacy and supply costing methods are implemented as separate methods, as they use different algorithms to identify acquisition costs and encounter-level resource utilization. Costing method category Example Current use% of total facility direct costs using costing method Pre-VDO, fiscal year 2011 Post-VDO, fiscal year 2013 Actual cost The cost of a surgical implant is determined from the supply management system and assigned to a given encounter based on actual use Supplies Most medications Labs by external entity 12.3 30.5 Time-based allocation The cost of operating the medical intensive care unit is identified by adding up all costs involved in running the unit, including labor, office supplies, equipment, etc. The per-hour cost is calculated by dividing the total cost by the total number of patient hours in the unit, and then costs are allocated to encounters based on actual hours spent in the unit. As another example, radiology technician cost is allocated according to the number of minutes an exam is estimated to take in the radiology scheduling system Facility utilization (emergency department, inpatient units and operating room) Radiology 13.5 32.6 Work RVU-based allocation A physician's clinical costs are compared to his or her total work RVUs in a given period to identify a cost per work RVU, where the work RVU is an estimate of the relative level of time, skill, training and intensity required by a clinician to provide a given clinical service. This per-RVU cost is multiplied by the work RVUs associated with a given patient encounter to allocate physician costs to an encounter Professional costs 0 0.
Quantity-based allocation The cost of operating a procedural unit is identified by adding up all costs involved in running the unit. The per-procedure cost is calculated by dividing the total costs by the total number of procedures performed by the unit.
The cost is then estimated by multiplying the number of procedures performed by the per-unit cost. Respiratory therapy Counseling programs 8.9 1.6 Cost-to-cost ratio The fee for laboratory management by a third party is allocated to individual labs in proportion to the item-level payments made to the third party for those labs Laboratory management fee 0 1.8 Cost-to-charge ratio The total cost for operating the cardiac catheterization unit is compared to the total charges billed by that unit.
Costing method category Example Current use% of total facility direct costs using costing method Pre-VDO, fiscal year 2011 Post-VDO, fiscal year 2013 Actual cost The cost of a surgical implant is determined from the supply management system and assigned to a given encounter based on actual use Supplies Most medications Labs by external entity 12.3 30.5 Time-based allocation The cost of operating the medical intensive care unit is identified by adding up all costs involved in running the unit, including labor, office supplies, equipment, etc. The per-hour cost is calculated by dividing the total cost by the total number of patient hours in the unit, and then costs are allocated to encounters based on actual hours spent in the unit. As another example, radiology technician cost is allocated according to the number of minutes an exam is estimated to take in the radiology scheduling system Facility utilization (emergency department, inpatient units and operating room) Radiology 13.5 32.6 Work RVU-based allocation A physician's clinical costs are compared to his or her total work RVUs in a given period to identify a cost per work RVU, where the work RVU is an estimate of the relative level of time, skill, training and intensity required by a clinician to provide a given clinical service. This per-RVU cost is multiplied by the work RVUs associated with a given patient encounter to allocate physician costs to an encounter Professional costs 0 0. Quantity-based allocation The cost of operating a procedural unit is identified by adding up all costs involved in running the unit. The per-procedure cost is calculated by dividing the total costs by the total number of procedures performed by the unit. The cost is then estimated by multiplying the number of procedures performed by the per-unit cost.
Respiratory therapy Counseling programs 8.9 1.6 Cost-to-cost ratio The fee for laboratory management by a third party is allocated to individual labs in proportion to the item-level payments made to the third party for those labs Laboratory management fee 0 1.8 Cost-to-charge ratio The total cost for operating the cardiac catheterization unit is compared to the total charges billed by that unit. Costing method category Example Current use% of total facility direct costs using costing method Pre-VDO, fiscal year 2011 Post-VDO, fiscal year 2013 Actual cost The cost of a surgical implant is determined from the supply management system and assigned to a given encounter based on actual use Supplies Most medications Labs by external entity 12.3 30.5 Time-based allocation The cost of operating the medical intensive care unit is identified by adding up all costs involved in running the unit, including labor, office supplies, equipment, etc. The per-hour cost is calculated by dividing the total cost by the total number of patient hours in the unit, and then costs are allocated to encounters based on actual hours spent in the unit. As another example, radiology technician cost is allocated according to the number of minutes an exam is estimated to take in the radiology scheduling system Facility utilization (emergency department, inpatient units and operating room) Radiology 13.5 32.6 Work RVU-based allocation A physician's clinical costs are compared to his or her total work RVUs in a given period to identify a cost per work RVU, where the work RVU is an estimate of the relative level of time, skill, training and intensity required by a clinician to provide a given clinical service. This per-RVU cost is multiplied by the work RVUs associated with a given patient encounter to allocate physician costs to an encounter Professional costs 0 0. Quantity-based allocation The cost of operating a procedural unit is identified by adding up all costs involved in running the unit. The per-procedure cost is calculated by dividing the total costs by the total number of procedures performed by the unit.
The cost is then estimated by multiplying the number of procedures performed by the per-unit cost. Respiratory therapy Counseling programs 8.9 1.6 Cost-to-cost ratio The fee for laboratory management by a third party is allocated to individual labs in proportion to the item-level payments made to the third party for those labs Laboratory management fee 0 1.8 Cost-to-charge ratio The total cost for operating the cardiac catheterization unit is compared to the total charges billed by that unit. Costing method category Example Current use% of total facility direct costs using costing method Pre-VDO, fiscal year 2011 Post-VDO, fiscal year 2013 Actual cost The cost of a surgical implant is determined from the supply management system and assigned to a given encounter based on actual use Supplies Most medications Labs by external entity 12.3 30.5 Time-based allocation The cost of operating the medical intensive care unit is identified by adding up all costs involved in running the unit, including labor, office supplies, equipment, etc. The per-hour cost is calculated by dividing the total cost by the total number of patient hours in the unit, and then costs are allocated to encounters based on actual hours spent in the unit. As another example, radiology technician cost is allocated according to the number of minutes an exam is estimated to take in the radiology scheduling system Facility utilization (emergency department, inpatient units and operating room) Radiology 13.5 32.6 Work RVU-based allocation A physician's clinical costs are compared to his or her total work RVUs in a given period to identify a cost per work RVU, where the work RVU is an estimate of the relative level of time, skill, training and intensity required by a clinician to provide a given clinical service.
This per-RVU cost is multiplied by the work RVUs associated with a given patient encounter to allocate physician costs to an encounter Professional costs 0 0. Quantity-based allocation The cost of operating a procedural unit is identified by adding up all costs involved in running the unit. The per-procedure cost is calculated by dividing the total costs by the total number of procedures performed by the unit. The cost is then estimated by multiplying the number of procedures performed by the per-unit cost. Respiratory therapy Counseling programs 8.9 1.6 Cost-to-cost ratio The fee for laboratory management by a third party is allocated to individual labs in proportion to the item-level payments made to the third party for those labs Laboratory management fee 0 1.8 Cost-to-charge ratio The total cost for operating the cardiac catheterization unit is compared to the total charges billed by that unit.
For each method category, outlines its current use and the proportion of total direct facility costs allocated using the approach before and after implementing VDO. VDO currently allocates all professional costs according to work relative value units (RVUs), whereas professional costing was not available before VDO. Facility costs allocated using actual costs and time-based methods increased from 25.8% pre-implementation to 63.0% post-implementation. We prioritized the application of true costs and time-based methods to high-cost areas where required data were already being captured.
We are currently pursuing the application of these cost methods to additional facility costs and to professional costs. VDO enables the co-existence and incremental evolution of varying costing methods. For example, VDO currently considers the per-minute utilization cost for a given operating room to be the same across all surgeries. This method could be enhanced to account for differential resource utilization. For example, surgeries requiring more nurses could be allocated a higher per-minute cost than surgeries requiring fewer nurses, and surgeries involving the use of robotics systems could be allocated a higher per-minute cost than surgeries which do not.
Such enhancements are iteratively implemented based on available resources and prioritization. Technical details of implementation approach provides detailed information on the VDO implementation approach.
These technical details include the software and informatics approaches used in VDO, the software and data needed for replicating the VDO approach at other institutions, an entity-relationship diagram of the core VDO database tables, and detailed explanations of how source data are transformed into encounter-level costs using two representative VDO costing methodologies. Also describes how data are organized to support drill-down capabilities in reports. Costing timeframe and process VDO provides cost analyses from fiscal year 2012 onward. The costing process is fully automated, takes approximately 4 h to execute, and is repeated monthly and at the end of each fiscal year. Following processing, financial professionals validate the results.
Any identified issues, such as unexpected cost variance due to changes in the general ledger structure, are corrected before release of the data. Quality, outcome, and value measurement In addition to cost accounting, which is the focus of this manuscript, VDO supports the measurement and analysis of quality, outcome, and value. An overview of VDO's approach in this area is provided in.
Reporting and analytics Web-based reports enable end-users to efficiently engage with and analyze VDO data, which encompass the entire healthcare system and over 100 million rows of data based on over a million annual encounters. The reports are designed to be intuitive, with dropdown menus and filters that enable users to ‘slice and dice’ the data in real-time. Hover-over and drill-down capabilities are also heavily leveraged, and department-specific reports provide a customized experience while optimizing performance by limiting the dataset. The default, user-adjustable timeframe for most reports is a fiscal year.
Provide samples of core VDO reports. The Opportunity Identification Report enables the identification of case types (by Diagnosis-Related Group (DRG) or International Classification of Diseases, 9th revision (ICD-9) diagnosis or procedure category) that are the most common, have the highest total costs, and/or have the largest coefficient of variation (SD/mean) for costs across attending physicians. In the example shown, among cardiothoracic surgery procedures with a common ICD-9 code, the insertion of an implantable heart assist system demonstrated the highest ‘relative rank,’ computed as the coefficient of variation multiplied by total costs. A related Opportunity Visualization Report provides this information more graphically. The hover-enabled bubbles represent case types, with bubble sizes reflecting the magnitude of the opportunity.
Cost trending report. The Value Dashboard provides outcome metrics on the y-axis, average cost per visit on the x-axis, and bubbles to represent individual attending providers, with bubble sizes corresponding to case volumes. The example shown delineates the relationship between cost and 30-day readmission rates for patients hospitalized for sepsis. The Physician Care Cost Dashboard compares average costs for specified case types stratified by attending provider and grouped into cost categories.
Cost categories can be drilled down to individual orderables, enabling real-time investigation of the sources of intra-institutional cost variation. For the example shown, the average hip replacement cost was almost 70% higher for the highest-cost provider (leftmost bar) compared to the lowest-cost provider (rightmost bar), with the costs of the implant and facility utilization being the greatest drivers.
Finally, the Cost Trend Report provides costs for selected encounter types (intracranial injury in this case) over time. Additional reports are also available, with new reports being added iteratively based on need. Evaluation Implementation timeliness A functioning prototype, including most core reports, was available 3 months into the project, and institutional leaders decided VDO was ready for production use as the institutional costing system 6 months into the project. Thus, the aggressive goals for implementation timeliness were fulfilled.
System performance Thirty representative requests for the reports in averaged 1.8 s (SD 0.8 s), with all requests taking less than the targeted 5 s. Completeness Total direct costs accounted for in VDO are generally within 0.5% of general ledger costs, and well under the target of 2%. Discrepancies may occur, for example, if a new clinic has been established and is incurring costs but has not yet begun to see patients. In such cases, because there are no encounters against which to allocate costs, costs appear in the general ledger but not in VDO. Accuracy As noted in, facility direct costs allocated using actual costs and time-based methods have increased from 25.8% pre-VDO to 63.0% post-VDO implementation. System extensibility System extensibility has been validated through multiple iterative enhancements to the initial system. Major completed and in-progress enhancements include: a major hardware upgrade; the addition of multiple new reports; the enhancement of data interfaces; the development and incorporation of outcome metrics; and various enhancements to our costing methodologies.
End-user adoption VDO data and reports are made available primarily to institutional decision makers such as service line directors, department chairs, and division chiefs. As of June 2014, there are 53 registered report users, and reports were accessed an average of 185 times per month during the first 6 months of 2014. Furthermore, many institutional stakeholders, including VDO team members, directly access VDO data through the data warehouse for custom analyses and reports. Institutional leaders now use VDO to determine the profitability of individual clinical areas, which is then used to guide investment decisions. Also, VDO serves as the source of truth for a program that incentivizes physician-led value improvement efforts by transferring 50% of efficiency gains to those physicians’ clinical units.
Furthermore, multiple value improvement initiatives use VDO to identify opportunities for process improvement and for assessing the impact of interventions and return on investment. We are also exploring the use of VDO for contract negotiations.
Ability to support value improvement To date, in tandem with a health system-wide Lean management initiative, and in collaboration with the School of Business, over 50 value improvement initiatives have been initiated or evaluated using the VDO value analysis framework. These initiatives include bottom-up efforts conceived by frontline clinicians, as well as top-down efforts prioritized by service line directors and the Chief Medical Quality Officer using VDO. User satisfaction Of 79 invited survey participants, 47 (59%) responded, of whom 37 identified themselves as VDO users and were included in the analysis. As noted in, users expressed satisfaction with VDO, in particular with regard to accuracy. Further details, including a summary of free-text comments, are available in.
Category Question Sample size. Median (IQR)% positive responses (4 or 5) Questions from Doll and Torkzadeh's validated survey instrument for end-user computing satisfaction Scale: 1—almost never, 2—some of the time, 3—about half of the time, 4—most of the time, 5—almost always Content Overall responses for content-related questions below 147 4 (4, 5) 88 Does VDO data provide the precise information you need? 37 4 (4, 5) 92 Does the VDO information content meet your needs?
37 4 (4, 5) 87 Does VDO provide data or reports that seem to be just about exactly what you need? 37 4 (4, 5) 84 Does VDO data provide sufficient information to support your work? 36 4 (4, 5) 89 Accuracy Overall responses for accuracy-related questions below 74 5 (4, 5) 95 Is VDO data accurate? 37 5 (4, 5) 95 Are you satisfied with the accuracy of VDO data? 37 5 (4, 5) 95 Format Overall responses for format-related questions below 72 4 (4, 5) 93 Do you think the VDO output is presented in a useful format?
35 4 (4, 5) 94 Is the VDO information clear? 37 4 (4, 5) 92 Ease of use Overall responses for ease of use-related questions below 72 4 (4, 5) 81 Are VDO data and reports user friendly? 37 4 (4, 5) 81 Are VDO data and reports easy to use?
35 4 (4, 5) 80 Timeliness Overall responses for timeliness-related questions below 67 4 (4, 5) 90 Do you get the information you need in time? 31 4 (4, 5) 87 Does VDO data provide up-to-date information? 36 4 (4, 5) 92 Additional questions Scale: 1—strongly disagree, 2—disagree, 3—neither agree nor disagree, 4—agree, 5—strongly agree Overall Overall responses for overall satisfaction questions below 74 5 (4, 5) 93% Overall, I am satisfied with VDO. 37 5 (4, 5) 95% Overall, VDO is successful in enabling University of Utah Health Care to measure and improve care value. 37 5 (4, 5) 92%.
Category Question Sample size. Median (IQR)% positive responses (4 or 5) Questions from Doll and Torkzadeh's validated survey instrument for end-user computing satisfaction Scale: 1—almost never, 2—some of the time, 3—about half of the time, 4—most of the time, 5—almost always Content Overall responses for content-related questions below 147 4 (4, 5) 88 Does VDO data provide the precise information you need?
37 4 (4, 5) 92 Does the VDO information content meet your needs? 37 4 (4, 5) 87 Does VDO provide data or reports that seem to be just about exactly what you need?
37 4 (4, 5) 84 Does VDO data provide sufficient information to support your work? 36 4 (4, 5) 89 Accuracy Overall responses for accuracy-related questions below 74 5 (4, 5) 95 Is VDO data accurate? 37 5 (4, 5) 95 Are you satisfied with the accuracy of VDO data?
37 5 (4, 5) 95 Format Overall responses for format-related questions below 72 4 (4, 5) 93 Do you think the VDO output is presented in a useful format? 35 4 (4, 5) 94 Is the VDO information clear?
37 4 (4, 5) 92 Ease of use Overall responses for ease of use-related questions below 72 4 (4, 5) 81 Are VDO data and reports user friendly? 37 4 (4, 5) 81 Are VDO data and reports easy to use? 35 4 (4, 5) 80 Timeliness Overall responses for timeliness-related questions below 67 4 (4, 5) 90 Do you get the information you need in time? 31 4 (4, 5) 87 Does VDO data provide up-to-date information? 36 4 (4, 5) 92 Additional questions Scale: 1—strongly disagree, 2—disagree, 3—neither agree nor disagree, 4—agree, 5—strongly agree Overall Overall responses for overall satisfaction questions below 74 5 (4, 5) 93% Overall, I am satisfied with VDO. 37 5 (4, 5) 95% Overall, VDO is successful in enabling University of Utah Health Care to measure and improve care value.
37 5 (4, 5) 92%. Category Question Sample size.
Median (IQR)% positive responses (4 or 5) Questions from Doll and Torkzadeh's validated survey instrument for end-user computing satisfaction Scale: 1—almost never, 2—some of the time, 3—about half of the time, 4—most of the time, 5—almost always Content Overall responses for content-related questions below 147 4 (4, 5) 88 Does VDO data provide the precise information you need? 37 4 (4, 5) 92 Does the VDO information content meet your needs? 37 4 (4, 5) 87 Does VDO provide data or reports that seem to be just about exactly what you need? 37 4 (4, 5) 84 Does VDO data provide sufficient information to support your work? 36 4 (4, 5) 89 Accuracy Overall responses for accuracy-related questions below 74 5 (4, 5) 95 Is VDO data accurate? 37 5 (4, 5) 95 Are you satisfied with the accuracy of VDO data? 37 5 (4, 5) 95 Format Overall responses for format-related questions below 72 4 (4, 5) 93 Do you think the VDO output is presented in a useful format?
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35 4 (4, 5) 94 Is the VDO information clear? 37 4 (4, 5) 92 Ease of use Overall responses for ease of use-related questions below 72 4 (4, 5) 81 Are VDO data and reports user friendly? 37 4 (4, 5) 81 Are VDO data and reports easy to use? 35 4 (4, 5) 80 Timeliness Overall responses for timeliness-related questions below 67 4 (4, 5) 90 Do you get the information you need in time? 31 4 (4, 5) 87 Does VDO data provide up-to-date information?
36 4 (4, 5) 92 Additional questions Scale: 1—strongly disagree, 2—disagree, 3—neither agree nor disagree, 4—agree, 5—strongly agree Overall Overall responses for overall satisfaction questions below 74 5 (4, 5) 93% Overall, I am satisfied with VDO. 37 5 (4, 5) 95% Overall, VDO is successful in enabling University of Utah Health Care to measure and improve care value. 37 5 (4, 5) 92%. Category Question Sample size. Median (IQR)% positive responses (4 or 5) Questions from Doll and Torkzadeh's validated survey instrument for end-user computing satisfaction Scale: 1—almost never, 2—some of the time, 3—about half of the time, 4—most of the time, 5—almost always Content Overall responses for content-related questions below 147 4 (4, 5) 88 Does VDO data provide the precise information you need? 37 4 (4, 5) 92 Does the VDO information content meet your needs?
37 4 (4, 5) 87 Does VDO provide data or reports that seem to be just about exactly what you need? 37 4 (4, 5) 84 Does VDO data provide sufficient information to support your work? 36 4 (4, 5) 89 Accuracy Overall responses for accuracy-related questions below 74 5 (4, 5) 95 Is VDO data accurate? 37 5 (4, 5) 95 Are you satisfied with the accuracy of VDO data?
37 5 (4, 5) 95 Format Overall responses for format-related questions below 72 4 (4, 5) 93 Do you think the VDO output is presented in a useful format? 35 4 (4, 5) 94 Is the VDO information clear? 37 4 (4, 5) 92 Ease of use Overall responses for ease of use-related questions below 72 4 (4, 5) 81 Are VDO data and reports user friendly?
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37 4 (4, 5) 81 Are VDO data and reports easy to use? 35 4 (4, 5) 80 Timeliness Overall responses for timeliness-related questions below 67 4 (4, 5) 90 Do you get the information you need in time? 31 4 (4, 5) 87 Does VDO data provide up-to-date information? 36 4 (4, 5) 92 Additional questions Scale: 1—strongly disagree, 2—disagree, 3—neither agree nor disagree, 4—agree, 5—strongly agree Overall Overall responses for overall satisfaction questions below 74 5 (4, 5) 93% Overall, I am satisfied with VDO.
37 5 (4, 5) 95% Overall, VDO is successful in enabling University of Utah Health Care to measure and improve care value. 37 5 (4, 5) 92%.
Key challenges and solutions We encountered several key challenges when implementing VDO. Summarizes challenges we had anticipated and corresponding solutions we implemented or are considering for future implementation. These challenges included: changes in underlying data sources; the need to integrate information from multiple data sources; system performance; availability of required data; and the aggressive timeline. Of note, many of these anticipated issues, as well as the solutions devised, were related to core issues pertaining to the management and use of healthcare data warehouses in general., Furthermore, summarizes those challenges we had not anticipated, as well as potential solutions for those challenges. Challenge Example Solutions Comments Identification of expenses attributable to clinical care within a school of medicine A physician-scientist faculty member may conduct research, teach, and provide clinical care. Challenge Example Solutions Comments Identification of expenses attributable to clinical care within a school of medicine A physician-scientist faculty member may conduct research, teach, and provide clinical care. Challenge Example Solutions Comments Identification of expenses attributable to clinical care within a school of medicine A physician-scientist faculty member may conduct research, teach, and provide clinical care.
Challenge Example Solutions Comments Identification of expenses attributable to clinical care within a school of medicine A physician-scientist faculty member may conduct research, teach, and provide clinical care. Discussion Understanding and improving care value is a key challenge facing healthcare delivery organizations as well as society. Here, we provide guidance on the design and implementation of a pragmatic, modular, and extensible technical platform for measuring and visualizing healthcare costs relative to outcomes. Critical role of biomedical informatics Traditionally, biomedical informatics has focused on the quality and outcomes component of the healthcare value equation.
Today, as value becomes a central driving force for health care, it will be imperative for clinical informaticists to gain expertise in healthcare costing. Indeed, many of the challenges of healthcare costing—such as the need to integrate disparate data sources and to derive actionable information from data—are already core focal areas of biomedical informatics. Furthermore, accurate healthcare costs are required for properly evaluating the cost-effectiveness of informatics interventions. The increased use of cost data in health care also poses a myriad of operational and research questions directly relevant to clinical informatics, such as how best to attribute costs and profits to individual clinicians, as well as how to leverage cost-based incentives most effectively. Thus, it will be critical for value measurement and improvement to be integrated into the research and practice agenda of clinical informatics.
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Importance of accuracy Cost and related profitability data are used to inform significant decisions, including clinician compensation and the allocation of institutional resources. As a result, new ways of costing will inevitably lead to ‘winners and losers’. In our experience, it is critical that cost data are accurate and understandable, so as to avoid situations where stakeholders can simply claim that ‘the data are no good’. Key aspects of accuracy include the use of robust and transparent costing methodologies, as well as risk adjustment to account for the higher expected costs of more complicated cases. In our survey, VDO users reported being highly satisfied with data accuracy. Limitations and strengths of approach One limitation of VDO is that it has not been replicated elsewhere. Thus, while we believe the approach is generalizable, we lack empirical evidence to that effect.
Also, VDO can support the analysis of indirect costs, but such costing has thus far been mostly out of the project scope. Finally, our approach requires electronic data sources and a data warehouse to function optimally, and these resources may not always be available.
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However, adoption of key health IT systems such as EHR systems is increasing rapidly in the USA, and our approach is specifically designed for incremental enhancement based on available capabilities. A key advantage of VDO is its modularity and flexibility. Furthermore, the approach can be implemented relatively quickly, without the need for global adoption of highly resource-intensive activities such as time and motion studies. VDO also provides a variety of actionable reports and dashboards to identify top priorities for improvement, rapidly investigate potentially unwarranted variation in care, and monitor progress as care improvement interventions are instituted. Finally, the approach is designed to be transferable to other institutions. Future directions We are currently implementing major system enhancements, including the incorporation of various outcome metrics and the implementation of an improved approach to professional costing. Moreover, we are developing and refining systematic processes for leveraging VDO to improve care value, and we are exploring its use for contract negotiation and management.
We are also actively investigating potential improvements to the underlying costing methodologies, such as through a collaboration with Professor Robert Kaplan of the Harvard Business School to incorporate time-driven activity-based costing methods that can enable better assessment of unused capacity. We also are exploring opportunities to enable other healthcare institutions to leverage our approach. Conclusion The measurement and improvement of care value is a critical imperative facing the US healthcare system.
We speculate that the technical approach described in this manuscript will help guide other institutions’ efforts to address this challenge and improve both the efficiency and effectiveness of health care.