Transcript Slide 1

GIS for Public Health
Eddie Oldfield
Director, New Brunswick Lung Association
1918
What can we learn from SARS?
The National Advisory Committee on SARS and Public Health identified many systemic
deficiencies in responding to SARS in Canada. Among these were:
1.
absence of protocols for sharing data,
2.
poor coordination among health authorities at national, provincial, and local levels,
3.
delays in identification of unknown virus,
4.
poor understanding of disease etiology and transmission vectors.
The CGDI and Public Health
GIS applications have become a staple in European health policy:
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health data management tools in Italy,
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a national public health atlas in The Netherlands,
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healthcare planning tools in Switzerland, and
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modular GIS applications in the United Kingdom.
The expansion of the Canadian Geospatial Data Infrastructure and
other national SDIs into the public health discipline is deemed
critical
for
addressing
shortcomings
in
population
health
monitoring, developing effective intervention strategies for chronic
and infectious disease, improving healthcare services, and
responding to health and safety emergencies.
SDI: Spatial Data Infrastructure
Potential for Applications in
Canada and the US
•
All respiratory diseases
•
Monitor chronic diseases
•
Monitor epidemic outbreaks (influenza), communicable disease clusters, and
disease vectors (e.g. migratory bird routes, zoonotic vectors)
•
Joint health and safety emergency management (e.g. bioterrorism)
•
Monitor water (including well-water) and food quality
•
Aboriginal health status (Tuberculosis, Diabetes etc)
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Ambulance vehicle routing
•
Public Health Resource management
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Population demographics (for assessing population vulnerabilities)
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Global Warming: predictive health impacts modeling
•
Cross-disciplinary research (linking air quality, climate change and human
health)
Example of a thematic map showing the different insecticide treatments
and the localization of bird reports and mosquito pools, in 2003. This
thematic map shows the different insecticide treatments (shaded areas)
and the localization of bird reports (colored dots) and mosquito pools
(colored triangles) along with their status, in 2003.
Example of a thematic map showing the status of reported dead Corvidae
around the Montreal Island, in 2005. This thematic map shows the status
(represented by different colors) of reported dead Corvidae for different
territorial subdivisions around the Montreal Island, in 2005.
Reference: “The Integrated System for Public Health Monitoring of West Nile Virus
(ISPHM-WNV): a real-time GIS for surveillance and decision-making.”
Pierre Gosselin, Germain Lebel1, Sonia Rivest and Monique Douville-Fradet
Modeling Health Impacts from a
Changing Climate
These health issues call for the application of ecological and systems-based
approaches. The classical toxicological model applied in environmental
epidemiology, where defined exposure to a specific agent causes an adverse health
effect to identifiable exposed populations, is generally not adequate for assessing
indirect or multi-causal impacts of climate change on human health.*
* World Health Organization – Climate Change and
Adaptation Strategies for Human Health
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Extreme Weather Events
Heat Waves
Flooding / floodplain management
Vector & Rodent borne diseases
Water-borne diseases
Drought / water supply
Food-borne diseases / food supply
Predictive Modeling
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Add slide showing graph / map, air quality
+ health in a community
Gaps in GIS for Public Health
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Lack of infrastructure (protocols for distributed access)
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Uneven capacity among health authorities (i.e. resource
constraints)
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Concerns over data privacy / poor access to data
•
Barriers to integration of health data within CGDI (i.e. lack
of health data standards / inconsistencies)
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Inconsistent ‘patchwork’ approach to development of
applications (technology does not currently satisfy public
health requirements)
Gaps in GIS for Public Health
•
Lack of training among public health professionals and
traditional IT support
•
Lack of engagement of provincial epidemiologists in GIS-
based modeling of health determinants and for population
health monitoring
•
Lack of Canadian methodologies / research
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Inadequate research agenda / cross-jurisdictional
•
Inadequate promotion of benefits to decision-makers
?
Planning for One Scenario? Not likely.
Virulence, Progression, Peak, Rate of Mortality
Multiple Health Responses to Escalating Threats (WHO Protocols)
Understanding Spatial Disease
Epidemiology
electron microscope image of the Avian Flu Virus
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Baseline Influenza vs Pandemic Indicators
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Transmissibility / Vectors
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Progression Rate / Death Rate
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Vulnerable Populations
From Micro
To Macro
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Access to Health Care
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Vaccine Distribution
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Capacity / Demand Surge
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Affected Health Care Workers
Mapping Public Health Data
Community Health Maps
Kilometers
0
25 50
100
Access to Health Care
Asthma Admission /
10,000 Population – 2001
Admission / 10,000 Population
0
0.1 - 7.1
7.1 - 9.7
9.7 - 15.7
15.7 - 110.3
Mapping
Influenza Cases
Mapping Public Health Data
New Brunswick Lung Association
American Lung Association of Maine
University of New Brunswick
Kilometers
0
25 50
100
University of Southern Maine
Maine Health Authority / CDC
NB Department of Health
Public Health Agency of Canada
Emergency Measures Organization (NB)
Service New Brunswick
WHO-PAHO / University of Laval
Cox-Hanson O’Reilly Matheson Law Firm
0
0.1 - 7.1
7.1 - 9.7
9.7 - 15.7
15.7 - 110.3
CARIS Ltd
Chief Medical Officer
Physician / Nurse
Data Technician
Lab / Verification of Suspected Cases
Identification of disease strain / etiology
Vaccine Distribution
Must be easy to use
Ambulatory Response
Notification
Public Access
CARIS Spatial Fusion Enterprise
Configuration Manager
http://www.caris.com/products/
Wireless and Remote Applications
Porting an existing desktop web application
Layered
windows
Prototype Thin Client in Action
Map
View
Data
Entry
Integrating Data
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Quality Checking (errors, omissions)
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Vertical and Horizontal Alignment
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Scale Matching / Representation
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Matching Health Codes / Identifiers
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Multi-Dimensional DB Design
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Spatial and Temporal Stamps / Querying
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Statistical Modules (average / total, normalized by population,
etc)
User Collaboration
Incident Management and Spatial
Analysis Tools
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Public Participation GIS – municipal
model, University of New Brunswick
Existing Incident Management / Tracking
and Spatial Tools are Independent
Geo-Conferencing, TGIS
CARIS Spatial Fusion Enterprise with
Incident Management Suite
OGC Standards Development, CGDI
Services, WMS/WFS compliance