Geographic information systems
(GISs) and geographic information science (GIScience) combine computer-mapping
capabilities with additional database management and data analysis tools.
Commercial GIS systems are very powerful and have touched many applications and
industries, including environmental science, urban planning, agricultural
applications, and others.
Public health is another focus
area that has made increasing use of GIS techniques. A strict definition of
public health is difficult to pin down, as it is used in different ways by
different groups. In general, public health differs from personal health in
that it is (1) focused on the health of populations rather than of individuals,
(2) focused more on prevention than on treatment, and (3) operates in a mainly
governmental (rather than private) context. These efforts fall naturally within
the domain of problems requiring use of spatial analysis as part of the
solution, and GIS and other spatial analysis tools are therefore recognized as
providing potentially transformational capabilities for public health efforts.
This article presents some
history of use of geographic information and geographic information systems in
public health application areas, provides some examples showing the utilization
of GIS techniques in solving specific public health problems, and finally
addresses several potential issues arising from increased use of these GIS
techniques in the public health arena.
Public health efforts have been
based on analysis and use of spatial data for many years. Dr. John Snow
(physician), often credited as the father of epidemiology, is arguably the most
famous of those examples. Dr. Snow used a hand-drawn map to analyze the
geographic locations of deaths related to cholera in London in the mid-1850s.
His map, which superimposed the locations of cholera deaths with those of
public water supplies, pinpointed the Broad Street pump as the most likely
source of the cholera outbreak. Removal of the pump handle led to a rapid
decline in the incidence of cholera, helping the medical community to
eventually conclude that cholera was a water-borne disease.
Dr. Snow's work provides an
indication of how a GIS could benefit public health investigations and other
research. He continued to analyze his data, eventually showing that the
incidence rate of cholera was also related to local elevation as well as soil
type and alkalinity. Low-lying areas, particularly those with poorly draining
soil, were found to have higher incidence rates for cholera, which Dr. Snow
attributed to the pools of water that tended to collect there, again showing
evidence that cholera was in fact a water-borne disease (rather than one borne
by 'miasma' as was commonly believed at the time.
This is an early example of what
has come to be known as disease diffusion mapping, an area of study based on
the idea that a disease starts from some source or central point and then
spreads throughout the local area according to patterns and conditions there.
This is another area of research where the capabilities of a GIS have been
shown to be of help to practitioners.
Today’s public health problems are
much larger in scope than those Dr. Snow faced, and researchers today depend on
modern GIS and other computer mapping applications to assist in their analyses.
For example, see the map to the right depicting death rates from heart disease
among white males above age 35 in the US between 2000 and 2004.
Public health informatics (PHI)
is an emerging specialty which focuses on the application of information
science and technology to public health practice and research. As part of that
effort, a GIS – or more generally a spatial decision support system (SDSS) –
offers improved geographic visualization techniques, leading to faster, better,
and more robust understanding and decision-making capabilities in the public
health arena.
For example, GIS displays have
been used to show a clear relationship between clusters of emergent Hepatitis C
cases and those of known intravenous drug users in Connecticut. Causality is
difficult to prove conclusively – collocation does not establish causation –
but confirmation of previously established causal relationships (like
intravenous drug use and Hepatitis C) can strengthen acceptance of those
relationships, as well as help to demonstrate the utility and reliability of
GIS-related solution techniques. Conversely, showing the coincidence of
potential causal factors with the ultimate effect can help suggest a potential
causal relationship, thereby driving further investigation and analysis (source
needed?).
Alternately, GIS techniques have
been used to show a lack of correlation between causes and effects or between
different effects. For example, the distributions of both birth defects and
infant mortality in Iowa were studied, and the researchers found no
relationship in those data. This led to the conclusion that birth defects and
infant mortality are likely unrelated, and are likely due to different causes
and risk factors.
GIS can support public health in
different ways as well. First and foremost, GIS displays can help inform proper
understanding and drive better decisions. For example, elimination of health
disparities is one of two primary goals of Healthy People 2010, one of the
preeminent public health programs in existence today in the US. GIS can play a
significant role in that effort, helping public health practitioners identify
areas of disparities or inequities, and ideally helping them identify and
develop solutions to address those shortcomings. GIS can also help researchers
integrate disparate data from a wide variety of sources, and can even be used
to enforce quality control measures on those data. Much public health data is
still manually generated, and is therefore subject to human-generated mistakes
and miscoding. For example, geographic analysis of health care data from North
Carolina showed that just over 40% of the records contained errors of some sort
in the geographic information (city, county, or zip code), errors that would
have gone undetected without the visual displays provided by GIS. Correction of
these errors led not only to more correct GIS displays, but also improved ALL
analyses using those data.
There are also concerns or issues
with use of GIS tools for public health efforts. Chief among those is a concern
for privacy and confidentiality of individuals. Public health is concerned
about the health of the population as a whole, but must use data on the health
of individuals to make many of those assessments, and protecting the privacy
and confidentiality of those individuals is of paramount importance. Use of GIS
displays and related databases raises the potential of compromising those
privacy standards, so some precautions are necessary to avoid pinpointing
individuals based on spatial data. For example, data may need to be aggregated
to cover larger areas such as a zip code or county, helping to mask individual
identities. Maps can also be constructed at smaller scales so that less detail
is revealed. Alternately, key identifying features (such as the road and street
network) can be left off the maps to mask exact location, or it may even be
advisable to intentionally offset the location markers by some random amount if
deemed necessary.
It is well established in the
literature that statistical inference based on aggregated data can lead
researchers to erroneous conclusions, suggesting relationships that in fact do
not exist or obscuring relationships that do in fact exist. This issue is known
as the modifiable areal unit problem. For example, New York public health
officials worried that cancer clusters and causes would be misidentified after
they were forced to post maps showing cancer cases by ZIP code on the internet.
Their assertion was that ZIP codes were designed for a purpose unrelated to
public health issues, and so use of these arbitrary boundaries might lead to
inappropriate groupings and then to incorrect conclusions.

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