Strengthening Partnerships Along the Informatics Innovation Stages and Spaces: Research and Practice 
Collaboration in Utah 

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Online Journal of Public Health Informatics * ISSN 1947-2579 * http://ojphi.org * Vol.3, No. 3, 2011 

Strengthening Partnerships along the 
Informatics Innovation Stages and Spaces: 

Research and Practice Collaboration in Utah 
 

Wu Xu, PhD
1,2

, Warren Pettey, MPH, CPH
2,3

, Yarden Livnat, PhD
2
, Per Gesteland, MD

2,4
, 

Deepthi Rajeev, MS, MSc
2
, Jonathan Reid, MBA

1
, Matthew Samore, MD

2,3
, R. Scott 

Evans, MS, PhD 
2,4

, Robert T. Rolfs,  MPH, MD
 1,2

, Catherine Staes, BSN, MPH, PhD
2
 

1
Utah Department of Health,  

2
University of Utah, 

3
VA Salt Lake City Health Care System, 

4
Intermountain Healthcare 

 

 

Abstract 

 
Collaborate, translate, and impact are key concepts describing the roles and purposes of the 

research Centers of Excellence (COE) in Public Health Informatics (PHI). Rocky Mountain 

COE integrated these concepts into a framework of PHI Innovation Space and Stage to guide 

their collaboration between the University of Utah, Intermountain Healthcare, and Utah 

Department of Health. Seven research projects are introduced that illustrate the framework 

and demonstrate how to effectively manage multiple innovations among multiple 

organizations over a five-year period.  A COE is more than an aggregation of distinct research 

projects over a short time period.  The people, partnership, shared vision, and mutual 

understanding and appreciation developed over a long period of time form the core and 

foundation for ongoing collaborative innovations and its successes.  

 

Key Words: Public health partnership, innovation stage, space, and management  

 

Introduction 
 

Public health informatics (PHI) is an action-oriented science and innovation-driven practice. 

Partnership between academic informatics researchers and public health practitioners is crucial 

for successful translations of informatics research findings into practice. Building sustainable 

partnerships over various innovation journeys and efficiently translating a product from a 

research laboratory into public health operations are challenges for the academic Centers of 

Excellence (COE) in Public Health Informatics. In this manuscript, we describe the Rocky 

Mountain Center of Excellence in Public Health Informatics (RMC) and put it forward as an 

illustrative example of a framework for successful innovation partnership between public health 

and academia in Utah. 

  

We built the RMC upon ongoing collaborations from three related domains: Informatics 

research, epidemiology and population sciences research, and public health practice (see Figure 



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1). The research institutions include the University of Utah Departments of Medicine, Pediatrics, 

and Biomedical Informatics, and Intermountain Healthcare. The practice organizations include 

Utah Department of Health, Salt Lake Valley Health Department, Davis County Health 

Department, Denver Health, and Intermountain Healthcare. Regardless of a member’s 

background, all the collaborators had a shared vision of the RMC as a “Center of Excellence to 

rapidly translate public health informatics research results into practice, to broaden collaboration 

between innovative researchers and practitioners, and significantly impact and improve 

epidemiology and surveillance.” The RMC’s innovation priorities include informatics tools to 

support disease surveillance and investigation (especially food safety, pandemic influenza), 

public health case reporting, and secured communication.   

 

 
 

Shared vision does not naturally lead to smooth partnership among different disciplinary 

professionals. Thomas J. Allen pointed out that to treat both professions (engineers and 

scientists) as one and then to search for consistencies in behavior and outlook is almost certain to 

produce error and confusion of results (1).
 
An epidemiologist’s priority, in general, is to conduct 

disease surveillance, investigate outbreaks, and operate a public health system under the public 

health legal authority. A researcher’s priority is to conduct studies and disseminate novel 

discoveries directed by funding sources with time limits. Aside from the disciplinary factors, 

collaborative informatics research among academic and public health parties often involves 

members of one party performing in the workspace of the other. Workspace crossover may lead 

to tension among partners. Furthermore, content of partnerships and interactions across 

workspace at different innovation stages are interdependent but not consequential as well (1). 

 

Framework for Public Health Informatics Innovations’ Spaces and Stages (PHI-ISS) 

 

In order to translate our innovation experiences into a framework to better coordinate the 

research projects across research and practice spaces and project lifecycles, we used inductive 

reasoning methods and theorized our own experiences during the past five years. Specifically, 

we first collected information from one project such as project deliverables, tasks, timelines, 

responsible parties and locations. We analyzed the information within the context of our own 

recalls and reflections on the partnership situations for each of project deliverables and tasks. For 

example, the concept of the “innovation space” was first used by a public health investigator 

during a heated discussion on how to balance resource commitments between research project 

timeline and public health practice priorities. When we summarized our research activities and 

Epidemiology 
/population 

Research

Informatics

Research

Public 
Health 

Practice

Figure 1: Interactive domains of public health informatics



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evidences of partnership development into a structured framework, the concepts of innovation 

“space” and “stage” emerged. 

     

Public health informatics is a relative new sub-field of the health informatics domain, which also 

includes clinical informatics and has recently seen an explosion of interest in funding and 

conducting translational research. The paradigm of clinical translational research has a four-

phase conceptual model describing clinical research progressing “from bench to bedside.” We 

adapted and applied this phase concept to public health informatics research arguing that the 

corollary is to transition public health informatics research and innovation “from campus to 

field.” 

  

Clinical and translational research has four distinct but interdependent phases (T1-T4): 

 T1: research seeks to move a basic discovery into a candidate health application 

 T2: research assesses the value of T1 application for health practice leading to the 
development of evidence-based guidelines 

 T3: research attempts to move evidence-based guidelines into health practice, through 
delivery, dissemination, and diffusion research.  

 T4: research seeks to evaluate the "real world" health outcomes of a T1 application in 
practice (2). 

 

Out Public Health Informatics Innovation Stage and Space (PHI-ISS) also include four stages. 

We also add a new dimension of “space” in each stage as follows:  

 ISS1 - Research initiates to move new discoveries into candidate public health 
applications with practitioners’ input (Space=University mainly.  Finished during the 

grant writing period.) 

 ISS2 - Research and practice collaborate to assess the value of ISS1 discovery for public 
health practice leading to evidence-guided innovation (Space=University and public 

health) 

 ISS3 – Research translates and practice implements fully-tested ISS2 innovation into 
public health practice through researchers’ delivery, dissemination, and diffusion efforts 

(Space=Public health and university) 

 ISS4 - Research evaluates the "real world" impact of public health outcomes of ISS3 
implementation in practice (Space=University) (3).

 
 

Figure 2 outlines the four innovation stages where research space is highlighted in light color and 

public health space in dark color. The direction and color of an arrow indicate an action initiator, 

role impact and location of workspace. For example, at the Initiate Stage I, public health is 

needed to identify what the problem, issue or desired outcome is. Informatics researchers 

determines the “how.” Researchers mainly work on campus and make impact on public health’s 

participation in the Collaborate Stage II. Public health makes active input on research designs in 

Stage II where workspace crossover begins. At the Translate Stage III, researchers deliver 

prototypes, pilot products, and modify public health informatics infrastructure. When a research 

product is implemented in a public health practice, research impact will go beyond the original 

practicing collaborators being diffused widely. Over the four stages, research activities 



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highlighted in light color gradually penatrate into public health practice indicated by the 

incressed dark-color areas. 

 
         Figure 2. Innovation Stage and Space for public health informatics 

 

During the past five years, the RMC has performed research and development resulting in 

projects that, as of 2011, are at various points along the spectrum of Public Health Informatics 

Innovation Stage and Space. We now provide several examples below to illustrate the PHI-ISS 

framework.  

 

Epinome: an example of transition through the continuum of Innovation Stage and Space 

 We describe the Innovation Stages and Space framework using our work with a new 

software innovation called Epinome (4, 5).
 
 Epinome is a user centric visual analytics system that 

empowers users to visualize, explore and analyze public health data. Epinome features a 

dynamic environment that seamlessly evolves and adapts to user tasks and focus change. 

Translation of Epinome into a public heath setting can significantly enhance the analytical 

capacity and usability of the reportable disease data collected using Utah’s surveillance computer 

system (UT-NEDSS implemented with TriSano software). 

 

= Public Health Space= Research Space

II III IVI

IMPACT
Evaluation

Outreach

COLLABORATE
Public health evidence-
based design and 
development

TRANSLATE
Operationalize research 
product

Transform practice

INITIATE
Idea prototype
with limited 
public health 
input



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Figure 3. Epinome interface 

 

ISS1 – Initiate to move new discoveries into candidate public health applications 

(Space=University): 2007-2009 

 

Started in 2007, the University of Utah’s researchers conducted interviews with state and local 

epidemiologists on the topic of pertussis outbreak investigation, and collected input from experts 

in cognitive psychology, infectious disease epidemiology, and mathematical modeling of 

infectious disease and visual analytics. Based on the identified public health needs, COE 

investigators developed a software prototype of the Epinome novel technology. The researchers 

then demonstrated the prototype of Epinome to public health practitioners using large scale high-

fidelity simulations of pertussis outbreaks. In 2009, the researchers and public health personnel 

jointly wrote the RMC grant application for further development of Epinome system and seek to 

generalize and adapt the pertussis investigation model to food-borne illness and influenza.  

During this initial stage, activities mainly occurred on campus; public health had minimal 

participation and less commitment to the research project. The minimal interactions between the 

teams did not lead to a noticeable tension within the partnership. 

  

We applied the PHI-ISS framework to analyze collaborative activities and identified 15 

deliverables from the Epinome research team as candidates for public health adaptation and 

implementation. Of the 15 deliverables of Epinome components, nine were in the ISS2 stage, 

four in the ISS3 stage, and two in the ISS4. 

  

ISS2 – Collaborate to assess the value leading to evidence-guided innovation 

(Space=University and public health):2009 – 2011 

 

At the ISS2 stage, researchers and practitioners jointly assessed the practical and potential added 

value of Epinome. We conducted contextual inquiries and observations of public health practice, 



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processes, procedures, and policy to elucidate design objectives, restrictions and requirements 

that may be imposed at a public health practical setting.  Public health was actively involved in 

evidence collection in this stage. The researchers conducted multiple on-site 

demonstrations/explorations with different groups of potential public health users of Epinome to 

assure that Epinome would meet practitioners’ needs. This effort has led to the reengineering of 

Epinome’s functionality and IT infrastructure. Researchers worked with two groups of 

practitioners, namely epidemiologists and information technologists, on the nine deliverables for 

this phase of the project:  

1. State epidemiologists, informaticists, and campus researchers conducted contextual inquiries 
on (a) food-borne disease investigation workflow at state and local health departments and 

(b) unmet needs from the users of the Indicator-based Information System for Public Health 

(IBIS-PH) 

2. Conducted an “Affinity Walk” to organize and categorize similar user needs collected 
through contextual inquiries (an affinity diagram) 

3. Developed use cases based on affinity diagrams 
4. Develop Epinome’s ontology for processing the UT-NEDSS data 
5. Integrate Epinome with the state of Utah’s GIS service  
6. Develop Web services for Epinome 
7. Ensure interoperability of Epinome with the  UDOH IT environment (Authentication, 

application/database servers) 

8. Mirror the UDOH implementation environment (UT-NEDSS functionality, export schema, 
Apache/Spring server respond to user’s requests) at the University of Utah’s IT laboratory 

9. Create visualizations of diagnostic Pulsed Field Gel Electrophoresis (PFGE) patterns (an 
alphanumeric result) that assist epidemiologists in understanding both the pathogens 

circulating in populations (surveillance) and for investigating the similarities and differences 

between the PFGE patterns of cases and candidate exposures (outbreak investigation) 

The ISS2 deliverables were workspace crossovers without significant tensions among partners as 

the efforts focused on information collection and knowledge exchange and were less invasive in 

other party’s business processes. This stage requires increased resource commitment by the 

public health side (e.g., face to face meeting time) to provide additional information, artifacts and 

consultation to researchers.  At time, the research agenda and time commitments had to compete 

with public health operational priorities.   

 

ISS3 – Translate innovation into practice (Space=Public health and university): 2010-2011 

 

Researchers worked with Utah Department of Health personnel on the following ISS3 

deliverables: 

1. Exported UT-NEDSS data according to the Epinome ontology schema 
2. Established access to the UDOH’s Laboratory Information Management System 
3. Develop UT-NEDSS mirror functioning at UDOH 
4. Establish Apache/Spring server responds to calls  

The ISS3 is a success- or fail-stage for translating Epinome from campus to the public health 

field. To prepare for a smooth implementation in the ISS3, researchers spent considerable time 

and resources to replicate the UT-NEDSS IT environment and data structure in the University 



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research environment. With the Institutional Review Board’s permission, the research team 

obtained access to de-identified data from the UT-NEDSS system, and then, to sustain a realistic 

dataset, matched the remaining identifiers to an in silico population to provide fictional details 

where identifiable details had been scrubbed. Utah Department of Health successfully exported 

the UT-NEDSS data according to the Epinome’s ontology schema. The researchers and 

practitioners began to integrate Epinome into the state IT system - Establishing operational 

communication between Epinome and Laboratory Information Management System (LIMS) and 

UT-NEDSS.  

 

Success in the ISS3 stage requires special attention to be paid to maintaining an effective and 

active partnership. This stage involves translation of research innovation from university 

workspace into public health workspace: this workspace crossover is a potential tension point. 

To address this concern we developed a protocol and shared vocabulary to facilitate 

communication, provide contextual information, and assure correct and efficient utilization of all 

resources. Shared identification and articulation of the ISS3 deliverables helped to maintain a 

mutual understanding assuring successful collaborative innovations across workspaces. 

The Epinome partners jointly developed a plan for agile delivery and training, usability testing, 

and deployment strategies. The researchers also planned to transfer knowledge necessary (e.g. 

software documents, etc.) to maintain Epinome in practice. Public health was in process of 

developing a sustainability plan.  

 

At this stage, public health began to realize that the Epinome research product possibly would 

become an operational resource for their practice and gradually developed a stewardship attitude 

towards the Epinome. The ISS3 had disproportionate effects on public health practice due to 

required changes in public health’s workflow, data access, and adjustment to unfamiliar visual 

analytical methods and data displays. The tasks in the ISS3 are more interdependent across 

workspaces than those in other stages. Investigators at the university depended upon 

collaborators at practice to accept, understand, and complete certain tasks before moving forward 

with next research tasks. However, for public health collaborator, these research tasks were low 

priorities for their practice and competed with their day-to-day job demands.  Key personnel 

functioned as liaisons were indispensable in overcoming these challenges. The liaisons who 

understand or have previous experiences in both research and practice, served as information 

pipelines between the campus and the field. We have avoided pitfalls and tension points due to 

the liaisons’ constant coordination of competing demands on personnel, communication channels 

and appropriate assignments for public health personnel.    

 

ISS4 - Evaluate the impact in the “Real World” (Space=University and public health): 2011 

 

There were four ISS4 deliverables which comprised the following: 

1. Collect and analyze Epinome server records (click stream analysis) to assess and describe 
patterns of usage  

2. Created and evaluated mockups for Epinome special application for foodborne disease 
outbreak investigation  

The ISS4 is an impact stage. The UDOH Institutional Review Board approved “opening the 

public health space” for researchers to evaluate the impact of adopting Epinome. The partners 



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planned to jointly develop an evaluation plan and metrics by analyzing web log files to identify 

patterns of use and problems experienced while using the software. Additionally, the team can 

create plans to disseminate the novel discovery, physical product, and its evaluation to research 

and practice communities.  

 

In summary, the PHI-ISS framework provides a) a priority tool for planning and administrating 

various tasks and deliverables, b) a new perspective to consider how to allocate resources across 

organizations at appropriate time, c) a communication facilitator to identify and mitigate 

unnecessary tension or conflict among partners, and d) a road map to measure the status of a 

public health informatics research project.   

 

Status of other projects in 2011 relative to Innovation Stage and Space 

 

Figure 4 presents the status of other six research projects conducted by the RMC investigators or 

informatics graduate students mentored by the RMC faculty from 2007 to 2011. As of the end of 

2011, these projects are at various points along the spectrum of Public Health Informatics 

Innovation Stage and Space.  Projects that were the focus of research during the first three years 

of funding are further along in the spectrum.  The two projects currently in Innovation Stage IV 

were developed and deployed in a single environment allowing other users to access the system 

using the Web: GermWatch, a pathogen-specific surveillance system, was developed and 

deployed in the Intermountain Healthcare environment while PHAccess, a secure 

communication and project management network, was developed and deployed at the Utah 

Department of Health.  In contrast, the two projects currently in Innovation Stage III have 

required more than one environment to successfully develop and deploy the research output. 

Epinome has been developed in the research environment but requires integration with data and 

systems at the Utah Department of Health before it can become operational and impact public 

health.  Similarly, RTCEND, a project transmitting case reports electronically from healthcare to 

public health, requires implementation in both the clinical and public health environment to 

realize the exchange of information between the two settings. To complicate the situation further, 

the public health disease surveillance system (Utah-NEDSS) to which these applications must be 

linked was developed and deployed during the past few years. The knowledge management 

project in Innovation Stage II was initiated more recently in 2010 and is currently focused on 

collaboration to design and develop systems that meet evidence-based public health needs. 

Finally, while Innovation Stage I for the funded projects occurred during the grant writing 

period, the ongoing collaborations between public health practitioners and researchers and 

students in the academic setting have spawned new ideas and prototypes that have the potential 

to further advance the science and practice of public health informatics. These additional projects 

are described below. 

 



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Figure 4.  Status in 2011 of RMC-related projects along the Innovation Stage and Space 

spectrum 

 

GermWatch in the Operation/Impact Stage 

 

GermWatch (http://www.germwatch.org) is a pathogen-specific surveillance system that was 

initiated in 2001 by researchers in the Department of Pediatrics at the University of Utah and 

supported by a Utah Department of Health’s grant, then further developed with partial support 

for junior investigators with the RMC. GermWatch is an information resource that provides 

timely (~24 hour delay) surveillance information about regional microbiological activity 

including viral respiratory surveillance, viral and bacterial gastrointestinal infections and 

antimicrobial resistance (See Figure 5).  The system is based on microbiological testing 

performed in Intermountain Healthcare’s large integrated healthcare delivery network that 

provides a majority of the healthcare for the state of Utah, which affords the potential to 

approximate population-based rates.  Intermountain Healthcare operates the GermWatch system 

in partnership with the University of Utah Departments of Pediatrics and Biomedical informatics 

on behalf of Utah clinicians and state and local health departments.  The system is currently 

being modified to provide information more suitable for consumption by the public. 

  

GermWatch greatly enhances the breadth Utah’s surveillance system by adding pathogen-

specific data based on microbiologic testing in Utah’s largest integrated healthcare delivery 

system to syndromes based on Emergency Department chief complaints and notifiable diseases 

reported under State law (6). The system is also novel in the sense that the information provided 

is specifically geared towards meeting the information needs of healthcare providers and 

healthcare system administrators, as well as providing information to public health about 

common outbreaks that are not part of the reportable disease profile (e.g., RSV, adenovirus, 

enterovirus, human Metapneumovirus) (7). GermWatch data has been used by COE researchers 

to conduct cutting edge infectious disease modeling research including forecasting RSV 

epidemics using meteorological variables (8) and modeling seasonal variation of RSV (9). The 

data on antibiotic resistance is available for the entire system and can be partitioned by 

IMPACT
Evaluation

Outreach

COLLABORATE
Public health evidence-
based design and 
development

TRANSLATE
Operationalize research 
product

Transform practice

= Public Health Space= Research Space

INITIATE
Idea prototype
with limited 
public health 
input

Logic analyzer*
Knowledge 

management

Epinome

PHAccess

GermWatch

RTCEND

II III IVI
Mortality 

surveillance*

*student projects spawned by RMC collaborations



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conditions and various populations (e.g., ambulatory pediatric urinary tract infections). Ongoing 

research is addressing how to optimally present and provide access to this data to front line 

clinicians. 

 

Surveys and anecdotal reports have documented substantial and sustained interest on the part of 

clinicians in having access to this information because they believe the data to be useful in 

clinical practice for improving diagnostic accuracy, improving clinical decision making (e.g., 

antibiotics prescribing, testing for viruses), improving communication with patients/parents 

about pathogens circulating in their regions(6-8, 10).  Administrators charged with managing 

healthcare resources and systems find the data valuable for making decisions about human 

resources (e.g., knowing when they will need to call in extra staff), implementing visitor 

restrictions to reduce nosocomial infections and planning and implementing RSV 

immunoprohylaxis for high-risk patients [Personal communication PHG]. Public health officials 

report that the system is a valuable addition to their surveillance arsenal because it provides 

ready access to information about conditions they are not resourced to track [Personal 

communication PHG]. 

 

 

 
 

Figure 5. GermWatch interface providing a portal to pathogen-specific surveillance and brief 

messages to guide clinical and public health decision making 

 

PHAccess in the Operation/Impact Stage 

 

During the first three years of COE funding, the research and collaboration efforts due to the 

“Interact” project resulted in a shared and improved understanding of the problems in 

communication between clinical and public health settings. For example, we documented 

problems among urgent care providers with understanding public health reporting requirements 

and their role in population health (10).Urgent care providers are highly likely to be first line 



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responder during an outbreak. We also identified communication barriers between public health 

settings.  Between the various clinical and public health settings, secure transmission of 

information was limited to phone calls and faxed paper reports. 

 

   

 
 

 

Figure 6: Screenshot of the PHAccess interface allowing secure access to multiple applications 

 

In 2008, the development of PHAccess was initiated by a RMC research informaticist who was 

involved in informatics research and training but stationed in the public health environment.  

Initially, the purpose of the application was to share information about public health issues with 

all 12 local health departments in Utah.  PHAccess expanded through user input about their 

needs and has value for public health practitioners and agencies.  It allows secure communication 

about current issues/outbreaks between state and local public health departments and clinical 

partners.  There is an easy single sign-on to access secure applications, such as Epi-issue tracker, 

ILI surveillance reporting, UT-NEDSS and secure messaging. PHAccess has a simple 

framework that allows for the ability to create and publish new applications with little 

development effort.  PHAccess allows secure communication between researchers and public 

health practitioners.  Finally, PHAccess has the ability to easily bring on new users.   

The value of PHAccess can be measured by usage.  As of August 2011, there were a total of 898 

Registered Users, including public health practitioners affiliated with the Utah Department of 

Health (n=470), local and county health departments (n=114), as well as physicians and infection 

preventionists from hospitals in Utah (n= 138), and other users from state, national or 

commercial entities (n= 175).  As many as 339 epidemiologic issues have been collaboratively 

addressed with local health departments. Finally, 57,174 secure emails have been sent using 

PHAccess. PHAccess rapidly transitioned through the stages of the ISS framework and is 

currently available for adoption by other public health entities. 

 



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RTCEND in the Translating Stage 

Starting in 2007, RMC investigators from informatics, clinical, and public health settings 

collaborated to design a system to implement real-time communication of electronic notifiable 

(aka reportable) diseases (RTCEND). The team was not addressing detection of reportable 

events, but rather addressing the content and structure of electronic messages for a clinical 

setting to report diseases such as hepatitis A or salmonella to public health.  Investigators 

collaborated (in Stage 2) to understand the public health workflow and information needs, and 

evaluated existing HL7 and CDC messaging standards (11, 12). Based on evidence derived from 

the investigations and the existing messaging infrastructures, a proposed Health Level 7 (HL7) 

version 2.5.1 message format was defined that was extendable to accommodate any reportable 

condition and allowed for the inclusion of both laboratory and clinical information in a message 

(see Figure 7).  In addition to local collaboration efforts, RMC investigators collaborated with 

the CSTE/CDC case report standardization workgroup (CRSWg) to provide input and be 

informed by the CSTE policy concerning the recommended core content of a case report.  

 

 

 
 

 

Figure 7. RTCEND Reporting Process 

 

Currently, RTCEND is in Innovation Stage 3 and becoming operational by Intermountain 

Healthcare and the Utah Department of Health. Prior to implementing the system, researchers 

evaluated the quality of electronic reporting using RTCEND compared with traditional manual 

reporting methods, and focused on the timeliness, completeness of information content in the 

initial report, and completeness of transmitting case reports for recognized reportable 

events.(13)The prospective evaluation (performed in July 2010) and the retrospective evaluation 

(performed on messages sent from October 2010 to February 2011) found that electronic 

messages were more timely than paper reports sent from other healthcare facilities (p<0.0001) 

(13). The HL7 messages also included more complete information when compared to the content 

of paper reports from other facilities, particularly concerning hospitalization status, and the 

reporting contact’s name and phone number (13). 



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RTCEND illustrates the challenges of implementing new informatics innovations in the 

operational public health environment.  During the time of this project, several important 

changes occurred in the public health environment that required modifications to the 

implementation plans.  To complete the research and evaluate impact on public health practice, 

the Utah Department of Health must be able to receive and integrate messages into their 

surveillance system.  During the course of this research, UDOH has developed and implemented 

a new Utah-NEDSS system with an outside contractor (TriSano) and the reporting standards 

have changed. The RTCEND message format is currently being modified to meet the intent of 

RTCEND to send clinical information while fulfilling the recent Meaningful Use requirements 

defined by the HITECH Act to send electronic laboratory messages (14). Electronic messages 

are currently being sent from 22 Intermountain Healthcare facilities to a test environment at 

UDOH. The messages will need to be integrated into the Utah-NEDSS before their impact on 

public health work flow and disease control can be assessed.  Once integration has been 

completed, Intermountain Healthcare will explore enhancing the messages to include other 

clinical data requested by public health.  

 

Knowledge Management in the Collaborative Stage 

 

In the fall of 2009, research was initiated to address the management of public health knowledge 

required to improve communication between public health agencies and their clinical and 

laboratory partners. The research is focused on the following three use cases:  

 Public health reporting from laboratory and clinical settings,  

 Public health notifications about alerts and “what’s going around”, and  

 Request and response for information to support a public health investigation, particularly 
using structured reports (e.g. based on the HL7 clinical document architecture). 

 

The goal is to demonstrate a new model for managing public health knowledge using service-

oriented architecture (SOA) and standard terminologies that a) allow public health authorities to 

author, store, and ‘publish’ computer-interpretable knowledge, and b) allow users to access the 

knowledge using context-aware information retrieval strategies, view human-readable content, 

download structured content using web services for execution within their own systems, and 

subscribe or query for updates.  This project is a reference implementation to assess the 

feasibility and value of the proposed system. 

 

Currently, we are focused on the public health reporting use case in Innovation Stage II. 

Researchers and practitioners are jointly assessing the problems and defining requirements in the 

public health practice Space to ensure that design and development efforts underway in the 

research Space are guided by evidence. To determine content and functional requirements, 

researchers reviewed existing knowledge resources and analyzed business process (15). We 

surveyed hospital and commercial laboratories to describe current processes, estimate their 

burden to comply with public health reporting, and to evaluate the business need and readiness 

for a service using SOA to deliver standardized reporting specifications. We are using 

ethnographic methods to get feedback from public health, clinical, and laboratory users on 

design and workflow issues. 

  



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To develop the system, we are using the infrastructure developed for the University of Utah’s 

Federated Utah Research and Translational Health electronic Repository (FURTHeR). The 

system uses Web services developed in JAVA for intersystem communication and requires no 

proprietary tools by laboratory or hospital personnel/systems. The knowledge is stored in XML 

files located in a metadata repository. The terminology services are handled by Apelon’s 

Distributed Terminology System (DTS) (http://apelon-dts.sourceforge.net/) which supports 

national data standards.  We are using Altova’s XML Spy and StyleVision to create data models 

and data entry forms, but these tools are not needed by system users. The knowledge is accessed 

through a query interface that allows a user to specify a condition, jurisdiction and role (e.g., 

laboratory or clinician). The query results are returned by a service and displayed. 

   

To develop the system, we are using the infrastructure developed for the University of Utah’s 

Federated Utah Research and Translational Health electronic Repository (FURTHeR). The 

system is Web-based, using Web services and developed in JAVA, and requires no proprietary 

tools by laboratory or hospital personnel/systems. The knowledge is stored in XML files located 

in a metadata repository. The terminology services are handled by Apelon’s Distributed 

Terminology System (DTS) (http://apelon-dts.sourceforge.net/) which supports national data 

standards.  We are using Altova’s XML Spy and StyleVision to create data models and data 

entry forms, but these tools are not needed by system users. The knowledge is accessed through a 

query interface that allows a user to specify a condition, jurisdiction and role (e.g., laboratory or 

clinician). The query results are returned by a service and displayed. 

   

We will test system usability and evaluate functionality during Innovation Stage 2 by exporting 

the reporting specifications for Utah and using the knowledge to inform public health reporting 

from the University Healthcare enterprise data warehouse. Further development is limited by 

reduced support for the RMC.  

 

Pilot Projects in the Initial Stage 

 

A center of excellence in public health informatics requires the ongoing infusion of new ideas 

and new investigators to address emerging and future public health informatics needs. 

Collaborations forged by the RMC environment have spawned a variety of new research pilots 

conducted by students and other investigators interested in public health informatics related 

problems. Two illustrative examples currently underway are shown in Figure 4. As public health 

practitioners and researchers engage in discussions about problems they face and research in 

progress, students and investigators identify a) new and interesting research questions, and b) 

opportunities to apply informatics methods used in other domains to the public health practice 

space. For example, in the Spring of 2010, a graduate informatics student with a background in 

engineering identified a solution for automating the analysis of reporting logic defined in CSTE 

position statements (16). The student developed a JAVA-based tool with a user-friendly excel 

file for input to test reporting logic for hepatitis (17). To lay down a solid base for this research 

initiative, the RMC research faculty guided the student to solicit input from three public health 

epidemiologists that authored the hepatitis-related position statements.  The epidemiologists 

provided feedback about the tool and received follow-up reports about the logic being revised for 

re-balloting in 2011. However, more input from public health and research resources would be 

required to move it from the Innovation Stage I to Innovation Stage II.  



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Similarly, another graduate informatics student is developing a grid-based tool to improve the 

processing of cause of death narratives to enable real-time monitoring of deaths due to 

pneumonia and influenza and other events with public health implications (18). While this 

research is not funded by the RMC, its innovation journey and impact are highly relevant to the 

RMC’s innovation research and integral to the mission of developing sustainable partnerships 

and researchers that understand public health practice. 

 

Other impacts of partnerships fostered by public health informatics innovations 

  

The sustained collaboration between partners resulted in other benefits that may not be obvious 

to outside observers. The collaborations resulted in “floating everyone’s boat”, being a force 

magnifier for training, engaging partners in the national standards development efforts, and 

improving the analysis of problems in the public health and clinical environment.  For example, 

first, the collaboration between public health practice, research and academics resulted in 

a)knowledge transfer in both directions, b) integration of practitioners into the national efforts 

(ELR), c) creating a ‘safe environment’ for public health practitioners to get up to speed in a 

faster way; and d) developing a model for informatics students to participate in “Infoaids” during 

public health crisis situations. 

   

Second, the COE was a force magnifier for training the public health workforce, informatics 

graduate students, and junior investigators. For example, public health collaborators had access 

to continuing education and in turn contributed as faculty for the AMIA 10x10 course. Graduate 

informatics students became engaged in research leading to careers in public health informatics 

and had the opportunity to interact closely with public health practitioners, evaluate surveillance 

systems and CSTE Position Statements, and make significant contributions to the CDC/CSTE 

Case Report Standardization Workgroup (19). Five junior faculty investigators in University of 

Utah jump-started careers built on the grants opportunities and collaborations fostered through 

the RMC. 

  

Third, improved problem analysis was demonstrated during theH1N1 outbreak in 2009.  Prior to 

establishing the RMC, many of the key players who would need  to respond to this type of  

public health events did not know one another.  As the H1N1 outbreak evolved, researchers from 

the center were able to rapidly and systematically evaluate real communication in the field and 

identify problems with duplication of effort and communication overload (20). After the first 

wave of the outbreak, a new communication strategy was developed in large part due to the 

ongoing partnership among the major stakeholders, many of whom were represented in the RMC 

partnership (Figure 7). The revised organizational communication strategy included a taskforce 

to coordinate messaging and deliver a unified public health messages through chief medical 

officers with health care entities, and requirements were identified for future message delivery to 

improve response to public health threats.  



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Figure 7. Timeline of response to the H1N1 outbreak illustrating integration of research and 

impact on practice 

 

Finally, there are other tangible and intangible impacts resulting from the collaborations fostered 

by the RMC.  Practitioners and researchers from the RMC jointly participated in national 

standards development efforts to increase their understanding of standards and speed up the 

innovation process at the home organziation.Sharing of ideas were also fostered through the 

RMC weekly virtual meetings to discuss new research, issues, and outside innovations.  There 

was a total of 164 papers, posters, abstracts, presentations, and white papers published during the 

past 5 years. The collaborations reached outside of our own RMC to establish the Community of 

Innovators in Epidemiology and Public Health Informatics (coi-EPHI). 

 

Conclusion and Discussion 
 

The Rocky Mountain Center of Excellence (COE) in Public Health Informatics’ collaborative 

trajectory provides live examples of our innovation processes within the past five years. 

Respecting each other’s working space is crucial for successful collaboration between 

researchers and practitioners.  Understanding the innovation stage advances the innovation 

management across the spaces. Acting indifferently to needs and expectations across workspaces 

may hamper or even dissolve the collaboration. Sometimes, workspace crossover may cause 

miscommunication and friction among collaborators. Applying the Public Health Informtics 

Innovation Stage and Space framework to collaborative activities can help reveal potential 

challenges early. With mutual understanding of a common framework, we developed strategies 

to help project managers to anticipate potential points of difficulty and proactively reduce and 

mitigate potential risks for partnerships. Understanding the boundary and process of practitioner-

participated research significantly improved efficiency of public health informatics innovations 

in Utah. 



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The seven informatics researches described above also demonstrate that COE is not just a 

one-time collaboration of distinct research projects within one grant.  The people, partnership, 

shared vision, and mutual understanding and appreciation developed over a long period of time 

are the core and base for ongoing effective innovations and its successes.  

Acknowledgment 

Research supported by CDC Grants COE1: 5P01HK000030 and 5P01HK000069.  P.I. Matthew 

Samore, MD, University of Utah. 

Corresponding Author 

Wu Xu, PhD 

Deputy Director, Center for Health Data 

Director, Office of Public Health Informatics 

Utah Department of Health 

Salt Lake City, Utah 84114-1019 

wxu@utah.gov 

801-538-7072 (o) 

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