Bryan Demianyk scite author profile

Bryan Demianyk

4Publications

40Citation Statements Received

15Citation Statements Given

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Affiliations

University of Manitoba, Orthopaedic Innovation Centre

Publications

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Agent-Based Modeling of the Spread of Influenza-Like Illness in an Emergency Department: A Simulation Study

Laskowski

Demianyk

Witt

et al. 2011

IEEE Trans. Inform. Technol. Biomed.

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The objective of this paper was to develop an agent-based modeling framework in order to simulate the spread of influenza virus infection on a layout based on a representative hospital emergency department in Winnipeg, Canada. In doing so, the study complements mathematical modeling techniques for disease spread, as well as modeling applications focused on the spread of antibiotic-resistant nosocomial infections in hospitals. Twenty different emergency department scenarios were simulated, with further simulation of four infection control strategies. The agent-based modeling approach represents systems modeling, in which the emergency department was modeled as a collection of agents (patients and healthcare workers) and their individual characteristics, behaviors, and interactions. The framework was coded in C++ using Qt4 libraries running under the Linux operating system. A simple ordinary least squares (OLS) regression was used to analyze the data, in which the percentage of patients that became infected in one day within the simulation was the dependent variable. The results suggest that within the given instance context, patient-oriented infection control policies (alternate treatment streams, masking symptomatic patients) tend to have a larger effect than policies that target healthcare workers. The agent-based modeling framework is a flexible tool that can be made to reflect any given environment; it is also a decision support tool for practitioners and policymakers to assess the relative impact of infection control strategies. The framework illuminates scenarios worthy of further investigation, as well as counterintuitive findings.

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Improving Agent Based Models and Validation through Data Fusion

Laskowski

Demianyk

Friesen

et al. 2011

OJPHI

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This work is contextualized in research in modeling and simulation of infection spread within a community or population, with the objective to provide a public health and policy tool in assessing the dynamics of infection spread and the qualitative impacts of public health interventions. This work uses the integration of real data sources into an Agent Based Model (ABM) to simulate respiratory infection spread within a small municipality. Novelty is derived in that the data sources are not necessarily obvious within ABM infection spread models. The ABM is a spatial-temporal model inclusive of behavioral and interaction patterns between individual agents on a real topography. The agent behaviours (movements and interactions) are fed by census / demographic data, integrated with real data from a telecommunication service provider (cellular records) and person-person contact data obtained via a custom 3G Smartphone application that logs Bluetooth connectivity between devices. Each source provides data of varying type and granularity, thereby enhancing the robustness of the model. The work demonstrates opportunities in data mining and fusion that can be used by policy and decision makers. The data become real-world inputs into individual SIR disease spread models and variants, thereby building credible and non-intrusive models to qualitatively simulate and assess public health interventions at the population level.

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Uncertainties inherent in RFID tracking systems in an emergency department

Laskowski

Demianyk

Friesen

et al. 2010

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3G Smartphone Technologies for Generating Personal Social Network Contact Distributions and Graphs

Benavides

Demianyk

McLeod

et al. 2011

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This paper presents a novel means of collecting and analyzing data related to personal social contact networks. The work developed a custom application for Smartphones that support Bluetooth connectivity, as representative of the ensemble of many consumer electronic products and can be used to infer users' proximity, contact duration, and GPSbased information. In many cases this is augmented by device meta identity. The 3G application, data storage and retrieval is discussed in detail. Preliminary data were collected (devicedevice proximity, duration, and location) gathered in pilot testing on the Blackberry Storm and HTC Hero (Android). Data are presented as distributions and visualization tools for evolving contact graphs, including Pareto distributions and power law exponents generated representative of face to face contacts. Finally, data are then demonstrated to be useful in estimating the potential of infection spread (e.g. respiratory illness), where a key transmission vector is person-person contact. A variant of the standard SIR agent based model is developed, with agent contacts guided by contact distributions extracted from the data.

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Bryan Demianyk

Agent-Based Modeling of the Spread of Influenza-Like Illness in an Emergency Department: A Simulation Study

Improving Agent Based Models and Validation through Data Fusion

Uncertainties inherent in RFID tracking systems in an emergency department

3G Smartphone Technologies for Generating Personal Social Network Contact Distributions and Graphs

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