Developing Enterprise-wide Provider Analytics

James P. McGlothlin, Hari Srinivasan and Ilija Stojic

Fusion Consulting Inc, Irving, TX, U.S.A.

Keywords: Business Intelligence, Data Warehousing, Analytics, Patient Quality, Patient Safety, Patient Outcomes.

Abstract: In recent years, the growth of electronic medical records for hospitals has exponentially increased the quantity

of healthcare data available for analysis and performance improvement. However, the general consumption

of this data by providers has still been limited to analysts and power users. Most data is delivered via static

reports which serve only a single purpose. This paper describes a project to deliver a vast quantity of data in

a simple and secure manner to all hospital physicians and administrative leaders. This includes clinical,

operational and cost information. The delivery is with versatile and intuitive interactive dashboards which are

integrated into the EMR yet come from many different sources. This allows physicians to look at their

performance and compare it to their peers. Executives are able to identify improvement opportunities across

the system and directors are able to identify improvement opportunities within their service. Quality and

performance improvement specialists can perform data analysis without having to generate report requests

and wait for delivery. This allows them to target specific initiatives and patient populations, and to tailor

improvement programs to the needs of the organization. These analytics and dashboards are designed to

facilitate quality improvement, efficiency, treatment standardization and cost reduction.

1 INTRODUCTION

Hospitals are under constant pressure to reduce cost

of care and improve outcomes. This includes

reducing length of stay, readmissions, resource

utilization, complications, hospital-acquired

infections, and mortality while increasing patient

experience and satisfaction. Generally, the methods

to improve these key performance indicators (KPIs)

involve changing provider behaviour or changing

hospital processes. However, it is not readily apparent

to most providers where the opportunities for

improvement are and often providers do not think

they have any issues. Furthermore, holding providers

accountable is difficult.

The use of advanced electronic medical records

(EMRs) for hospitals has grown exponentially in the

past decade. Many hospitals have developed

enterprise data warehouses specifically designed to

support advanced reporting and analytics.

Technologies to integrate data from auxiliary systems

have become common. At this hospital, auxiliary

systems exist for the catherization lab, imaging,

interventional radiology, laboratory, pathology, risk

management, infection control, cost accounting,

supply chain, human resources, time and attendance,

decision support, pharmacy acquisition, and more. As

we continue to bring in these outside sources and

continuously optimize and advance our EMR and

data warehouse, the amount of data available

continues to grow at an astronomical pace.

There are many challenges to delivering this

information to a provider in a meaningful way.

Physicians are trained in medicine not in computer

science and are extremely busy, so it is unrealistic to

ask them to learn new, complex technology. Also,

there is so much data available, it is challenging to

determine which information to deliver to a specific

provider. This is further exacerbated by strict privacy

laws that make it essential that providers do not get

access to patient information for patients they do not

treat. Additionally, there are laws limiting the

financial, referral and utilization information users

can see in order to prevent collusion or market

interference. (Office of Inspector General, 2018)

Currently, we have thousands of reports but they

are each directed towards a limited scope and

audience. Most of our reports are primarily static

where they look at specific orders or diseases or

medications, but do not allow you to change these

parameters. They are created in response to user

requests, so the requirements were generated by users

McGlothlin, J., Srinivasan, H. and Stojic, I.

Developing Enterprise-wide Provider Analytics.

DOI: 10.5220/0007568601350146

In Proceedings of the 12th International Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2019), pages 135-146

ISBN: 978-989-758-353-7

135

who already had an idea what they wanted to analyse

or change and how.

We have also had great success in the past with

targeted initiatives to optimize specific type of

utilization such as red blood cells (McGlothlin at al.,

2017), imaging (Wyatt et al., 2018), broad spectrum

anti-biotics, opioids and metabolic panels (Wyatt et

al., 2018). However these were specific programs

targeting particular types of utilization and made

available to specific users in relevant situations.

Furthermore, development of each of these projects

incurred significant level of effort. The goal of this

project is to provide general analytics that can be

utilized to evaluate all types of encounters, diseases

and resources, and will be available to the large

audience of all hospital physicians and leadership.

One of the most effective ways to drive

performance improvement is to target quality

initiatives and clinical decision support to specific

acute diseases. Our own experience (McGlothlin,

2016) and previous research (Kitchiner et al., 1996)

demonstrates the effectiveness of these programs.

The Joint Commission has established clinical

pathways as a fundamental approach to improving

healthcare performance (Joint Commission on

Accreditation of Healthcare Organizations 1996).

Studies have consistently shown that clinical

pathways reduce length of stay and cost (Stephen et

al., 2003) (Pearson et al., 2001) (Wazeka et al., 2001).

The care path can encourage providers to use specific

medications, images and labs and to utilize them at

specific times. This not only gives the opportunity to

choose the lower cost option when there are multiple

equally appropriate alternatives, it also gives the

hospital an opportunity to make treatment and

utilization more predictable. This can be very

important. If we can predict how many images will be

ordered, we can optimize our equipment, resources

and schedules. If we can predict utilization of

medications, then we can better manage inventory

and negotiate acquisition costs. If we can predict

length of stay, then we can improve bed assignment

and staff scheduling.” However, each disease

program requires 12-20 weeks of effort to build

(McGlothlin, 2018). Also, it can be challenging to

evaluate the effectiveness of each program in a

standardized manner. A common set of metrics and

shared analytics tool can provide this evaluation.

Analytics are needed for hospitals to intelligently

choose which diseases to target. Furthermore, it is not

realistic to build pathways for every disease. There

are over a thousand diagnosis related groups (DRGs),

68,000 ICD-10 disease codes and more than 10,000

research papers proposing specific care paths

(Vanhaecht et al., 2006) (Rotter et al., 2007).

Therefore, the goal of this project is to both provide

leadership insight into which disease programs can

provide the most benefit, and to provide some

meaningful information for every disease treated at

the hospital.

For the remainder of this paper we will describe

our challenges, how we overcame each, and our

solution and results.

2 ATTRIBUTION AND SECURITY

As previously discussed, one of the most important

aspects of our project is to only show users data

related to them and to secure our system so no user

sees patient data unless they are authorized.

We achieve this by attributing metrics to the

correct provider, attributing the provider to the

correct service, and then applying security using the

provider and service information.

2.1 Provider Attribution

We allocate providers differently depending on the

role that is responsible for the metrics in the chart. So

far we have identified five roles:

 Discharge provider

 Admitting provider

 Emergency department provider

 Authorizing provider

 Surgeon

The discharge provider is assigned at the grain of the

hospital visit- i.e. each hospital visit has exactly one

discharge provider. The discharge provider is

attributed to the hospital visit based on who signed

the discharge summary. Discharge provider is used

for readmission and mortality metrics and for metrics

related to discharge efficiency.

The admitting provider is assigned also at the

grain of the hospital visit based on the provider who

authorized the admitting order. The admitting

provider is used primarily for metrics around

admissions efficiency.

The emergency department (ED) provider is

assigned also at the grain of hospital visit based on the

provider who chose the emergency department

disposition. The ED provider is primarily used for the

metrics around ED efficiency.

The authorizing provider is assigned at the grain

of an order. The authorizing provider is the provider

HEALTHINF 2019 - 12th International Conference on Health Informatics

136

who authorized the order. This provider is used for

metrics around order utilization and cost.

The surgeon is assigned at the grain of surgery.

The surgeon is currently used only for surgical site

infections.

2.2 Service Attribution

Service attribution was one of our greatest challenges.

Our data warehouse assigns service at all points

during the patient stay in a patient movement table.

However, extensive data profiling and validation

determined this value was often incorrect due to the

current workflow and the large number of users who

have the ability to change this value in the EMR.

For this reason, we chose to attribute the service

based on the provider we already attributed in the last

section. In other words, the discharge metrics are

attributed to a service because the provider who

discharged the patients was in that service. However,

we determined that our provider records were

insufficient to accurately assign the service. As an

example, we have providers credentialed in

anesthesiology yet performing the role of surgical

intensivist (service of SICU) or neurosurgery

attending provider. This provider role information is

not available in any system we have available.

Therefore, we determined to assign the providers

manually. This problem was further exacerbated

because many of the providers perform multiple

roles. Some examples are providers who serve

internal medicine in the adult hospital and also act as

pediatrics providers in the children’s hospital,

providers who work in obstetrics and gynecology,

provider who work in the SICU and acute care

surgery, providers who work in the NICU and the

emergency department. Therefore, we had to develop

options that allow the service to vary based on:

 The patient’s hospital

 The patient’s level of care

 Whether the event happened during a

surgical episode

 Whether the event happened in an outpatient

setting

 The patient’s unit

 The patient’s service in patient movement

Which values we use for the identifiers depends again

on the type of metrics. For discharge metrics we use

last value, for admission metrics we use first value

and for cost and order utilization metrics we use

values based on the time of the order. Figure 1 shows

our methodology for service attribution of orders and

costs based on authorizing provider and patient

location at the time of the order. Provider attribution

for discharges and admits is similar but simpler since

anesthesiologists and gastroenterologists do not

discharge patient.

Additionally, there are some metrics where we

want to attribute service but not provider. For census,

we use the service at the time according to our patient

movement table. For hospital-acquired infections, we

manually attribute the service during our infection

control process. For patient experience data, we

assign service based on the discharge provider but we

then aggregate the data only at the service level.

2.3 Service Attribution and Security

Forms

There are over 800 providers in our hospital who have

discharged patients in the last three years, and over

1800 who have authorized orders. Certainly, the

analytics team cannot accurately assign the service(s)

for each of these providers. In our initial attempt, we

allowed the quality department leadership to fill these

values in an Excel spreadsheet. However, we found

that not only was this very time consuming, it also

was prone to errors and inconsistencies which then

had to be manually resolved by the analytics team. It

also presented challenges for incremental updates.

For this reason, we have now developed a set of

custom secured forms for the operation. There are

five forms that drive our security. All of the person

columns in these forms (provider, director, executive,

support team) allow the user to search and select the

person using their name based on the network

security data and our software finds their identifying

information.

1. Service Form

We want to group some of our services together. For

example the set of providers for liver transplant and

kidney transplant are the same, so we want these

services to rollup to the service of “transplant”. Our

service form simply gives the user the opportunity to

specify the “service rollup” from a drop down list for

each service in the system. The services are

prepopulated from two sources. We acquire all the

services from the EMR in our patient movement

table. Additionally, because some of our critical care

services are not assigned in patient movement, we

have a set of inferred ICU services based on unit,

level of care and service. We populate this table with

those services as well.

Developing Enterprise-wide Provider Analytics

137

Figure 1: Service attribution for orders and cost.

HEALTHINF 2019 - 12th International Conference on Health Informatics

138

2. Service Rollup Form

We assign our attribution at the grain of service

rollup. The user can create new “service rollups”

which will then be available in drop-down lists within

the service form and the provider and director forms.

They can also specify the abbreviation the dashboard

will use for this category. The key fields they

populate for each service rollup is a set of yes/no

fields:

a. Adult? Is this an adult service?

b. Children’s Hospital? Is this service in the

children’s hospital?

c. Surgical? Is this a surgical service?

d. ICU? Is this a critical care service?

e. Other? For each of dashboards should this

service be shown on the dashboard or

bucketed in “other”.

These values are used both to determine what

executives are allowed to see, and to populate drop

down boxes for the provider form. Figure 2 shows the

entry form for service rollups.

Figure 2: Entry form.

3. Provider Form

We allow the user to add a provider based on a look

up into the system. Then they can attribute the

patient’s service based on the diagram in Figure 1.

They can choose any service rollup from the drop

down as the provider’s single service, or they can

choose any adult service rollup (from the service

rollup form) as their service when the patient is in an

adult hospital, or any ICU service rollup as their

service when the patient is in the ICU level of care,

etc. The form insures they choose only valid services

and rules which are not contradictory.

Additionally, our provider service attribution

form has four check boxes specific to service

attribution for orders and cost. There is an

anesthiology check box which says this provider

should be attributed to anesthesiology only for orders

which they place during a surgical episode and there

are ED and urgent care flags and gastroenterology

which say this provider should be attributed to that

service only for orders placed while the patient is in

that unt.

4. Director Form

This form allows the user to assign one or more users

as “directors” for specific services.

5. Executive Form

This form allows the users to assign executives. The

executive are grouped based on the options in the

service rollup form. So an executive can be assigned

as an executive only for surgical services or

children’s services, as examples.

All of our forms are secured. The director and

executive forms can only be updated by analytics or

leadership within the Patient Safety and Reliability

department. However, directors can add providers

who are attributed to their service. In this way, we

have distributed the maintenance effort for the service

attribution without reducing the security.

2.4 Security

We have three different types of dashboards:

executive, director and provider. In this section, we

will describe the security for each type of dashboard.

2.4.1 Executive Dashboards

Executive dashboards include charts which compare

performance across different services. This is only

true for executive dashboards. Each user is limited to

services which they have access to based on the

executive form described in the last section.

Executive users can see patient data for all encounters

in the services they can access. Executive dashboards

can drill down into director dashboards.

2.4.2 Director Dashboards

Director dashboards show metrics and performance

within a service but cannot compare services. They

can however compare providers within their service.

If a user has access to multiple director service

dashboards, they can still only look at one service at

a time. All data will be limited to that service. All

patient information is available.

Developing Enterprise-wide Provider Analytics

139

2.4.3 Provider Dashboards

Provider dashboards are our most important

dashboards for mass consumption and user adoption.

Within a provider dashboard, the provider sees

performance for himself compared only to his

service. He can see patient information for his

encounters but not for the other encounters in his

service. He can compare himself with his peers but

the other provider names are redacted and replaced

with numbers. Figure 3 shows an example of length

of stay (LOS) provider comparison chart with redact

names. It shows this provider has the second highest

LOS in his service. The provider’s metrics are

calculated using the provider attribution described

earlier. When the user opens the dashboard we

acquire their system login and use this to

automatically filter to their encounters and the

redacted information for other encounters only in this

service.

Figure 3: LOS by provider.

2.5 Support Users

We frequently find the need to emulate other users for

support and testing purposes. For example, to test that

the dashboard correctly works for a provider with

both adult and pediatric services, we need to emulate

such a provider. Additionally, a provider may call us

with questions and we want to reproduce what he

sees. Our visualization tool does not have this feature

built in. Since none of our analytics developers or

quality analysts actually treat patients, we would

never be able to see data in the provider dashboard.

To solve this problem we created one more form,

the support users form. This form allows any user on

the support team, whether from analytics or from

business departments such as the Patient Safety and

Reliability department or the finance department, to

Our visualization tool, Tableau, does support

“live” data providers versus extracted data. We have

set just this one query as live. What this means is that

we can alias ourselves, press save on the form, refresh

the dashboard in the browser and immediately see the

dashboard as though we were that provider.

3 IMPLEMENTATION

Our solution is developed in our enterprise data

warehouse. This primarily sources from our EMR

data warehouse. We have created more than 70

extension facts from previous projects and we have

created a set of data warehouse foundation tables

which model the business and our rules rather than

showing the specific implementation details of the

EMR. For example, our EMR sets the inpatient

admission time based on the planned admission time

for planned post-op admits, but we have calculated

the true inpatient admission time. Our EMR defines

discharge provider based on the discharge order, but

we are instead using the hospital bill as the source for

discharge provider who signed the discharge

summary. This gives us a single version of the truth.

Our solution requires several outside sources to

acquire cost data, hospital acquired infection data and

patient experience data. We integrate these sources

into our data warehouse using data virtualization

techniques as described in (McGlothlin et al., 2017).

Our visualizations are written in Tableau and user

row level security based on the user() function. They

are secured and published to the provider via

Microsoft Sharepoint and integrated into the EMR via

the EMR’s integration techniques. The users do not

have database access to data warehouse, only access

to the Tableau dashboards.

4 METRICS AND DASHBOARDS

4.1 Common Features

All of our dashboards have the features below which

have reduced the learning curve for users and allowed

us to achieve user adoption.

4.1.1 Filters

All of our dashboards include standard filters such as

date range, primary diagnosis, diagnosis-related

group (DRG), payor, benefit plan, admitting and

discharging departments, location and services, and

HEALTHINF 2019 - 12th International Conference on Health Informatics

140

admission type (elective vs urgent). This allows a user

to choose any disease based on diagnosis or DRG and

see how they are performing for that specific patient

cohort. This allows us to target disease populations

globally rather than only through specific custom

analytics dashboards. All of our filters are dynamic

and cascading. As an example, this means if you filter

to a specific DRG, the discharge service filter will

now only show those services which discharged

patients with that DRG.

4.1.2 Drill Down

When the user has access to the patient information,

all relevant data is available for the drill down include

encounter, patient, and order information. Even when

the user does not have access to the patient

information, all information used in the metric

calculations and filters is available in drill down. This

increases the user’s trust in our data. This has also

enabled the users to look at specific events and

encounters in order to do root cause analysis and learn

how to improve.

4.1.3 Outlier Rulers

A small number of encounters can drastically

influence some calculations such as averages. We

provide rulers for user’s to filter out outliers. Figure 4

shows an outlier ruler for the length of stay chart. As

an example, the user could move the ruler to 2 and 30

to only look at patients who were in the hospital at

least 2 days and less than 30 days. Alternatively, the

same ruler can be used to investigate outliers, perhaps

by looking only at those encounters under 1 day or

over 30 days.

Figure 4: LOS outlier ruler.

4.1.4 Hover Information

Throughout our dashboards you can hover over any

point in a chart to get additional information. This is

especially useful to tell the user the volume of

encounters. Many of our hovers even include

additional charts specific to the portion of data that is

being selected. Figure 5 shows an example of

utilization information available by hovering over

one specific procedure.

Figure 5: Hover information.

4.1.5 Interactive Charts

All of our charts are clickable and interactive.

Clicking a specific bar in bar graph will filter all other

charts to that value. For example, if the dashboard is

displaying cost by service and by procedure, clicking

on the service will show what procedures cost the

most in that service, or clicking on the procedure will

show what services use that procedure the most.

4.1.6 Dashboard Companions

We have created dashboard companions in PDF for

each dashboard. On every tab of every dashboard we

have added a question mark icon that opens that

section of the dashboard companion. These

documents explain how to use the dashboard, what

the charts represent and how the data points are

calculated. We also are developing a searchable data

dictionary.

4.2 Length of Stay

One of the most important metrics is how long the

patient stayed in the hospital. Length of stay is one of

the most important outcomes and can be used as a

valid surrogate for hospital cost (Kitchiner et al.,

1996). Unlike government LOS measures, we count

length of stay for every hour and present it as a real

number instead of a whole number of days. Every

hour a patient remains at the hospital requires nursing

support, occupies a bed another patient could utilize

and decreases patient experience.

Developing Enterprise-wide Provider Analytics

141

At the provider level we show both length of stay

and CMI (case mix index) adjusted length of stay for

the provider. Adjusting length of stay using CMI

allows us to adjust for when the provider simply

treated sicker or less sick patients. We compare the

provider to benchmark length of stay information

from CMS, our state public health insurance, the

Children’s Hospital Association and benchmark

vendors. We also compare the provider to their

service and rank them against their peers as shown in

Figure 3

At the executive level, we compare length of stay

across services and we look for length of stay

opportunity: (length of stay – benchmark) * volume.

The diseases with the greatest length of stay

opportunity represent patient cohorts and workflows

we want to target with performance improvement

initiatives. Figure 6 shows LOS opportunities.

Figure 6: LOS opportunity by DRG.

4.3 Outcomes

In this category we focus on the metrics of

readmissions, mortality and discharge disposition.

Our metrics are as follows:

1. Encounter Disposition

2. Inpatient unplanned readmissions

a. 7 day

b. 14 day

c. 30 day

3. ED readmissions

a. 7 day

b. 14 day

c. 30 day

4. In-hospital mortality

We additionally stratify readmissions by disposition.

The goal is to maximize discharges to home and to

reduce readmissions and mortality.

At the provider level, the provider sees metrics for

encounters they discharged compared to their service

and their redacted peers. Readmissions and mortality

are also stratified over time based on discharge date

and compared to their service over the same time

frame. At the director level, the director sees the

metrics for their service and comparisons for each

metric by discharging provider. At the executive

level, all metrics are shown for the system and then

stratified both by service and DRG. When it is

stratified by DRG it is sorted both by highest % (who

readmitted the highest % of patients) and by highest

volume (who readmitted the most patients even if the

percentage was lower).

Literature shows that providers have the greatest

impact on seven day readmissions. Therefore we

focus on opportunities to improve seven day

readmission rates. Unlike CMS specifications, we

allow readmissions to also be indexes. We also

include the DRG and diagnosis of the readmit

encounter. This allows us to filter on any disease and

see how often they are coming back and why.

Figure 7 shows an example of charts analyzing

readmission by days. Figure 8 shows an example

readmission chart stratified by index DRG.

Figure 7: Readmission by readmit days example.

Figure 8: Readmission by index DRG.

4.4 Discharge Efficiency

For discharge efficiency, the goal is to discharge the

patients as early as possible. This saves resources and,

as we are a very full institution, allows us to put

another patient in that bed. We look at when the

discharge order was written and when the patient

departed. We measure both percentage of discharge

orders written by 10am and noon. Providers have

more control over when the discharge order is written

than when the discharge occurs so this is the primary

provider and service-based metric.

Additionally, we have a goal of departure by noon

and discharge order to departure in under two hours

HEALTHINF 2019 - 12th International Conference on Health Informatics

142

so we track both of these metrics. These metrics are

tracked primarily by unit as the unit staff has more

influence over this measure than the discharging

provider. On the provider dashboard, these values

are still shown only for patient’s the provider

discharged.

Finally we stratify both metrics by time and day

of the week to look for opportunities for

improvement. Figure 9 shows this chart. This is an

example of a metric than can improve length of stay

and cost without requiring us to target specific

diseases.

Figure 9: Discharge efficiency by day of week.

4.5 ED and Admissions Efficiency

For these metrics, we track ED length of stay, time

from decision to admit to admit order and time from

admit order to the patient departing the ED. The

attributed provider is the admitting provider though

stratification for the director and executive

dashboards includes the ED providers for ED length

of stay. The provider is compared against their service

for decision to admit to admit order. The time from

admit order to ED departure is stratified by the

inpatient unit the patient was moved to.

4.6 Patient Experience

We have a third party vendor who surveys the patient

experience of our hospital patients. The set of

questions is different for adults and children. We have

set up a secure FTP location to receive and import

these results monthly. We are attributing them to the

encounter information so that filters by hospital,

discharging service and DRG can still be supported.

However, we do not attribute them to providers as the

sample size is too small and we do not allow any users

to see the actual patient name or encounter number.

Provider and directors both see the responses to each

set of questions, and the percentile compared to other

hospitals. The executives are also able to compare the

patient experience scores across the services. The

results are benchmarked based on percentiles from

other hospitals through our vendor. We are bringing

this data in from the vendor through secure FTP.

Figure 10 shows an example of patient experience

information.

Figure 10: Patient experience by service.

4.7 Bed Blocks and Room Turnaround

Time

There are many reasons a bed can be blocked.

Because our hospital doesn’t have private rooms, it

can be because the other patient in the room has an

infectious disease, is a VIP or is considered

dangerous. It can also be from mechanical or staffing

issues. We have created metrics and dashboards

which allow the user to see volume of bed blocks by

day, stratified by type of block, unit or time. This

allows us to analyse issues effecting occupancy,

patient movement efficiency and timeliness of care.

Room turnaround time shows the average or

median time from when a patient leaves a bed until it

is cleaned and the average or median time from when

it is cleaned until when it is occupied.

Developing Enterprise-wide Provider Analytics

143

These metrics allows the user to analyse issues

effecting occupancy, patient movement efficiency

and timeliness of care.

Neither of these metrics is directly influenced by

services so they are both stratified by unit, and all

users can see this data. There is no patient

information.

4.8 Orders Utilization

For orders utilization, we calculate how many

procedure or medications are ordered, stratified by

authorizing provider, service and what was ordered.

We also show what % of the orders used an orderset.

These metrics are calculated four ways: total (for the

time period), per encounter, per patient day (for each

day the patient was in hospital), per service day (for

each day the provider ordered anything for that

patient). For the provider they can only see patient

information for patients they wrote an order on, and

they can only see any information for patients a

provider in their service wrote an order on. They

cannot see orders outside of their service even for the

patients they wrote orders for.

For a provider, this is primarily useful for them to

see what they are ordering most for different diseases

and how their utilization compares to their peers. For

a director, they can look across their providers and see

who are utilizing more orders per patient day than

others for the same disease and attempt to adjust

practice.

At the executive level, the executive can look at

order sets and see which items are being used most,

and they can look at diseases and see which orders

outside of the orderset are being ordered. This allows

for orderset optimization. They can also compare

orders across services or providers to drive

performance improvement.

4.9 Cost

For all cost besides medications, we integrated data

from our hospital’s decision support system to

acquire cost per unit and location based on revenue

code and used that to calculate cost for every single

hospital billing transaction including fixed direct,

variable direct, and indirect cost. We added an extra

calculation that applies current cost to past

transactions. As an example if a chest x-ray’s cost

increased 10% but we were able to decrease

utilization 5%, this allows us to apply today’s cost to

the old transactions and thus demonstrate the savings

created by the 5% reduction, rather than losing the

ability to quantify this return on investment (ROI) due

to price fluctuations.

The finance department was unable to give us

accurate unit cost for medications. This becomes

challenging because some medications are single use.

For example, if a patient only has albuterol once from

an inhaler, the entire inhaler is still utilized. For now,

the best surrogate we were able to do was to reverse

the markup applies to the pharmaceutical charge as a

surrogate for cost. We did special logic to adjust this

for 340-B medications (Health Resources and

Services Administration, 2018). This is an accurate

surrogate for cost with a consistent bias, but it does

not allow us to provide current costing to past

transactions.

78% of our costs are associated with an order. If

the order is attached, we attribute the cost to the

provider and the provider’s service attribution. In the

event the provider is not attributed or is a resident, we

utilize the service at the time of the order using our

patient movement data. Similarly, if there is no

associated order, we use the first service on that

service date. In these instances, the provider is

unassigned but the service is still assigned.

Similar to orders, we calculate cost in our

dashboards in total, per encounter, per patient day and

per service day. For the provider dashboard a

provider is allowed to see their direct costs over time

compared to their service. The greatest opportunity

for provider improvement is in labs, images, and

medications. Therefore we break these three

categories out and bucket all remaining costs into one

category. The provider dashboard does not show

indirect costs as the provider cannot affect these

values. Within lab, imaging, medication and other the

provider can see their cost and their services cost by

the procedure or medication that was ordered.

At the director level, the director can compare

providers in their service by their cost in each

category. At the executive level they can look at all

revenue groups, compare cost by service and look at

indirect costs as well. Moreover, the executive can

compare analyse total cost by disease in each

category. At the executive level we have also created

separate charts for room and board cost and ICU cost.

Executives can also look across the entire system for

the highest cost medications and procedures and

investigate opportunities to use a more economical

option. Additionally, quality experts can look at the

cost related to specific disease cohorts, ordersets and

care paths to optimize the ordersets to minimize cost.

Furthermore, this cost data provides valuable

feedback to know which quality and performance

HEALTHINF 2019 - 12th International Conference on Health Informatics

144

initiatives are delivering financial return on

investment.

Figures 11, 12 and 13 show some examples of

cost charts.

Figure 11: Imaging cost by procedure.

Figure 12: Direct cost per encounter by category.

Figure 13: Total lab costs by DRG.

4.10 Complications

For hospital-acquired infections such as catheter-

associated urinary tract infection (CAUTI), central

line-associated blood stream infection (CLABSI) and

methicillin-resistant Staphylococcus aureus (MRSA),

the hospital documents and attributes the infection in

an Excel spreadsheet. We import this spreadsheet

daily using a shared drive and checking for updates.

For complications such as falls, the incidents are

reported in the risk management software. We import

this data programmatically. For surgical site

infections (SSI), we acquire this data from the web

registry used to report it.

All of these metrics are associated to services and

sometimes departments. We show the volumes with

the ability to drill down to the details to enable

performance improvement. Additionally, we adjust

and standardize the rate and compare it to

benchmarks. All of this is done with outside reporting

registry and risk management software, and then

integrated into our data warehouse.

5 RESULTS

We have delivered 14 dashboards with 46 tabs for this

project. We currently have over 500 users, over 300

who have viewed dashboards in the last month, and

over 10,000 distinct views. All of this is accessed

from a single location with a common look and feel.

Since going live 5 months ago, we have been able

to reduce length of stay by 4.3% and the number of

days over benchmark (length of stay – benchmark) by

12%. Readmissions have been reduced by 6.4%.

Room turnaround time has been reduced by 51%. Our

cost phase went live only this month so we do not

have sufficient data to analyse results yet.

We used the information from the executive

dashboard to choose disease to design programs

around. So far, we have developed care paths for

sickle cell anemia, heart failure, pediatric sepsis and

acute coronary syndrome (ACS). We are currently

developing solutions for pre-eclampsia, adult sepsis

and asthma. All of these show in the top 5 for either

volume, length of stay opportunity, cost or

readmissions. Early results for heart failure show a

savings of over 1.5 days in the length of stay when the

care path was utilized. Additionally, we were able to

identify high cost unnecessary orders (compound

narcotics urinary analysis was second highest cost)

and variations in care (two providers averaged almost

two chest x-rays per visit while most averaged only

one). For ACS, we have demonstrated statistically

Developing Enterprise-wide Provider Analytics

145

significant and consistent reduction of 51.6% in

emergency department length of stay since

development of the care path.

6 FUTURE WORK

We plan to analyse our results more after we have

been in production for a full year. Our infection and

complications phase is still in final development. We

have planned future phases including productivity,

additional complications, surgical efficiency, boarder

time in ICU and PACU, supply cost details, waste,

and appropriate utilization. Additionally, we plan to

develop many more care paths for specific diseases

with high opportunity. We plan to evaluate cost

savings from each of these care paths. Finally, we

plan to integrate additional benchmarks to measure

hospital performance versus our peers.

7 CONCLUSIONS

We have developed a set of simple, meaningful, easy

to use and secure dashboards for enterprise-wide

consumption by providers and service lines across

multiple types of devices. We have demonstrated the

ability to create performance improvement utilizing

these dashboards. Early user adoption has been good.

We have a framework for continued expansion and a

set of secure configuration and attribution forms for

simplified maintenance. We can continue to develop

care paths based on these analytics, and create

meaningful changes, outcome improvement and cost

reduction.

ACKNOWLEDGEMENTS

The project was implemented at Loma Linda

University Health System. We would like to thank the

Loma Linda team for their leadership, work effort and

insights which made this project successful. We

would like to especially thank Dr. Ihab Dorotta and

Brenda Bruneau for their leadership and direction.

REFERENCES

Office of the Inspector General, 2018. A Roadmap for New

Physicians: Fraud & Abuse Laws. Viewed November

2018. https://oig.hhs.gov/compliance/physician-educa

tion/01laws.asp.

Kitchiner, D., Davidson, C and Bundred, P., 1996.

Integrated Care Pathways: effective tools for

continuous evaluation of clinical practice. Journal of

Evaluation in Clinical Practice, vol. 2, no. 1, pp. 65–

69, 1996.

Joint Commission on Accreditation of Healthcare

Organizations, 1996. An Integrated Approach to

Medical Staff Performance Improvement.

Stephen, A.E. and Berger, D.L., 2003. Shortened length of

stay and hospital cost reduction with implementation of

an accelerated clinical care pathway after elective colon

resection. In Surgery, vol. 133, no. 3, pp. 277–282.

Pearson, S., Kleefield, S., Soukop, J., Cook, E., Lee, T.,

2001. Critical pathways intervention to reduce length of

hospital stay. In American Journal of Medicine.

Wazeka,A., Valacer, D., Cooper, M., Caplan, D.W., and

Dimaio, M., 2001. Impact of a pediatric asthma clinical

pathway on hospital cost and length of stay. In Pediatric

Pulmonology, vol. 32, no. 3, pp. 211–216.

Rotter, T., Koch, R., Kugler, J., Gothe, H.,Kinsman, L. and

James, E., 2007.Clinical pathways: effects on

professional practice, patient outcomes, length of stay

and hospital costs. In Cochrane Database of Systematic

Reviews.

Vanhaecht, K., Bollmann, M., Bower, K., Gallagher,C.

Gardini, A., Guezo, J., Jansen, U., Massoud, R.,

Moody, K., Sermeus, W., Zelm, R.V., Whittle, C.,

Yazbeck, A.-M., Zander, K. and Panella, M., 2006.

Prevalence and use of clinical pathways in 23 countries

- an international survey by the European Pathway

Association. In International Journal of Care

Pathways, vol. 10, no. 1, pp. 28–34, Jan. 2006.

McGlothlin, J. P. Madugula, A., and Stojic, I., 2017. The

Virtual Enterprise Data Warehouse for Healthcare. In

Proceedings of the 10th International Joint Conference

on Biomedical Engineering Systems and Technologies.

Health Resources and Services Administration, 2018. 340B

Pricing Program. Viewed November 2018.

https://www.hrsa.gov/opa/index.html.

McGlothlin, J.P., Crawford, E., Srinivasan, H., Cianci, C.,

and Dorotta, I, 2017. Reducing Red Blood Cell

Transfusions. In ITBAM.

Wyatt, J., Vaks, Y., Moretti, A., Pappas, J., Wilson, M.,

Samayoa, C., McGlothlin, J., Lopez, M., 2018. The

Future of Healthcare: Avoiding Pain, Unnecessary

Interventions and Reducing Cost in the PICU. In

Critical Care Medicine, vol 46, issue 1.

McGlothlin, J..P., Vedire, S., Crawford, E, Pappas, J.,

Bruneau, B., and Obregon, L., 2016. Improving Patient

Care Through Analytics. In ISCBI.

McGlothlin, J.P., 2018. Accelerating Analytics for Clinical

Pathways to Drive Cost Reduction and Quality

Improvement. In IEEE International Conference on

Information Reuse and Integration.

HEALTHINF 2019 - 12th International Conference on Health Informatics

146