ISDS Annual Conference Proceedings 2017. This is an Open Access article distributed under the terms of the Creative Commons Attribution-
Noncommercial 3.0 Unported License (http://creativecommons.org/licenses/by-nc/3.0/), permitting all non-commercial use, distribution,  
and reproduction in any medium, provided the original work is properly cited.

ISDS 2016 Conference Abstracts

Facilitating the Use of Epidemiological Models for 
Infectious Disease Surveillance
Alina Deshpande* and Kristen Margevicius
Analytics Intelligence and Technology, Los Alamos National Laboratory, Los Alamos, NM, USA

Objective
1. To develop a comprehensive model characterization framework

to describe epidemiological models in an operational context.
2. To apply the framework to characterize “operational” models

for specific infectious diseases and provide a web-based directory, 
the biosurveillance analytics resource directory (BARD) to the global 
infectious disease surveillance community.

Introduction
Epidemiological modeling for infectious disease is useful for 

disease management and routine implementation needs to be 
facilitated through better description of models in an operational 
context. A standardized model characterization process that allows 
selection or making manual comparisons of available models and 
their results is currently lacking. Los Alamos National Laboratory 
(LANL) has developed a comprehensive framework that can be used 
to characterize an infectious disease model in an operational context. 
We offer this framework and an associated database to stakeholders of 
the infectious disease modeling field as a tool for standardizing model 
description and facilitating the use of epidemiological models. Such a 
framework could help the understanding of diverse models by various 
stakeholders with different preconceptions, backgrounds, expertise, 
and needs, and can foster greater use of epidemiological models as 
tools in infectious disease surveillance.

Methods
We define, “operational” as the application of an epidemiological 

model to a real-world event for decision support and can be used by 
experts and non-experts alike. The term “model” covers three major 
types, risk mapping, disease dynamics and anomaly detection.

To develop a framework for characterizing epidemiological models 
we collected information via a three-step process: a literature search 
of model characteristics, a review of current operational infectious 
disease epidemiological models, and subject matter expert (SME) 
panel consultation. We limited selection of operational models to 
five infectious diseases: influenza, malaria, dengue, cholera and 
foot-and-mouth disease (FMD). These diseases capture a variety 
of transmission modes, represent high or potentially high epidemic 
or endemic burden, and are well represented in the literature. We 
also developed working criteria for what attributes can be used to 
comprehensively describe an operational model including a model’s 
documentation, accessibility, and sustainability.

To apply the model characterization framework, we built the 
BARD, which is publicly available (http://brd.bsvgateway.org).  
A document was also developed to describe the usability requirements 
for the BARD; potential users (and non-users) and use cases are 
formally described to explain the scope of use.

Results
1. Framework for model characterization
The framework is divided into six major components (Figure 1): 

Model Purpose, Model Objective, Model Scope, Biosurveillance 
(BSV) goals, Conceptual Model and Model Utility; each of which 
has several sub-categories for characterizing each aspect of a model.

2. Application to model characterization
Models for five infectious diseases—cholera, malaria, influenza, 

FMD and dengue were characterized
using the framework and are included in the BARD database. Our 

framework characterized disparate models in a streamlined fashion. 
Model information could be binned into the same categories, allowing 
easy manual comparison and understanding of the models.

3. Development of the BARD
Our model characterization framework was implemented into an 

actionable tool which provides specific information about a model 
that has been systematically categorized. It allows manual category-
to-category comparison of multiple models for a single disease and 
while the tool does not rank models it provides model information in 
a format that allows a user to make a ranking or an assessment of the 
utility of the model.

Conclusions
With the model characterization framework we hope to encourage 

model developers to start describing the many features of their models 
using a common format. We illustrate the application of the framework 
through the development of the BARD which is a scientific and 
non-biased tool for selecting an appropriate epidemiological model 
for infectious disease surveillance. Epidemiological models are not 
necessarily being developed with decision makers in mind. This gap 
between model developers and decision makers needs to be narrowed 
before modeling becomes routinely implemented in decision making. 
The characterization framework and the tool developed (BARD) are 
a first step towards addressing this gap.

Keywords
epidemiological models; database; decision support

Online Journal of Public Health Informatics * ISSN 1947-2579 * http://ojphi.org * 9(1):e3, 2017 



ISDS Annual Conference Proceedings 2017. This is an Open Access article distributed under the terms of the Creative Commons Attribution-
Noncommercial 3.0 Unported License (http://creativecommons.org/licenses/by-nc/3.0/), permitting all non-commercial use, distribution,  
and reproduction in any medium, provided the original work is properly cited.

ISDS 2016 Conference Abstracts

Acknowledgments
Thanks to Dr. Madhav Marathe, Dr. Bryan Lewis, Dr. Steven Eubank 
(Virginia Bioinformatics Institute) and Dr. Reid Priedhorsky (LANL)  
for their advice and providing information for the characterization of the 
Epi-Simdemics model.

References
1. Hoshen MB, Morse AP. A weather-driven model of malaria

transmission. Malaria J. 2004; 3: 32.
2. Kulldorrf M, Nagarwalla N. Spacial disease clusters: detection and

inference. Stat Med. 1995; 14: 799–810. PMID: 7644860
3. Barrett CL, Bisset KR, Eubank SG, Feng X, Marathe MV.

EpiSimdemics: an efficient algorithm for simulating the spread of
infectious disease over large realistic social networks. International
Conference for High Performance Computing, Networking, Storage
and Analysis. 2008. SC 2008; Available: http://ieeexplore.ieee.org/
xpls/abs_all.jsp?arnumber=5214892&tag=1.

*Alina Deshpande
E-mail: deshpande_a@lanl.gov

Online Journal of Public Health Informatics * ISSN 1947-2579 * http://ojphi.org * 9(1):e3, 2017 


	ISDS16_Abstracts-Final 55
	ISDS16_Abstracts-Final 56