Jurnal Internasional SIG dalam bidang kesehatan
International
Journal of Health Geographics
Review
Open Access
The
application of geographical information systems to important public health
problems in Africa
Frank
C Tanser*1,2 and David
le Sueur1
Address:
1The National Malaria Programme, Medical Research Council, PO Box 70380,
Overport 4067, Durban, South Africa and 2The Africa Centre for Health and
Population Studies, PO Box 198, Mtubatuba, 3935, South Africa
Email:
Frank C Tanser* - tanserf@mrc.ac.za; David le Sueur
*
Corresponding author
Published: 9 December 2002
International
Journal of Health Geographics 2002, 1:4
Received:
8 November 2002
Accepted:
9 December 2002
This
article is available from: http://www.ij-healthgeographics.com/content/1/1/4
©
2002 Tanser and le Sueur; licensee BioMed Central Ltd. This is an Open Access
article: verbatim copying and redistribution of this article are permitted in
all media for any purpose, provided this notice is preserved along with the
article's original URL.
Abstract
Africa is generally
held to be in crisis, and the quality of life for the majority of the
continent's inhabitants has been declining in both relative and absolute terms.
In addition, the majority of the world's disease burden is realised in Africa.
Geographical information systems (GIS) technology, therefore, is a tool of
great inherent potential for health research and management in Africa. The spatial
modelling capacity offered by GIS is directly applicable to understanding the
spatial variation of disease, and its relationship to environmental factors and
the health care system. Whilst there have been numerous critiques of the
application of GIS technology to developed world health problems it has been
less clear whether the technology is both applicable and sustainable in an African
setting. If the potential for GIS to contribute to health research and planning
in Africa is to be properly evaluated then the technology must be applicable to
the most pressing health problems in the continent. We briefly outline the work
undertaken in HIV, malaria and tuberculosis (diseases of significant public
health impact and contrasting modes of transmission), outline GIS trends relevant
to Africa and describe some of the obstacles to the sustainable implementation
of GIS. We discuss types of viable GIS applications and conclude with a
discussion of the types of African health problems of particular relevance to
the application of GIS.
Background
The physical and ecological structure of Africa is as varied as
its social, political and demographic characteristics [1].Major biomes in the
continent include tropical rainforest, montane forest, moist and dry savanna,
semi-desert and desert and temperate grasslands [2]. The political environment,
poverty and generally low levels of well-being for the majority of the people
in the continent combine with the varied climatic conditions, vegetation and
biogeography to explain the prevalence of disease-causing organisms, or
pathogens such as bacteria, viruses and worms [3].
The applications of geographical information systems (GIS) to
health and epidemiology have been critiqued by numerous authors [4–13] and
although found to be under- utilised it has been concluded that GIS has much to
contribute to the health sciences. However, it has been less clear whether GIS
technology is both applicable and sustainable in an African setting. GIS is a
tool of great inherent potential for health in Africa as health is largely
determined by environmental factors (including the sociocultural and physical
environment) which vary greatly in space. The spatial modelling capacity
offered by GIS is directly applicable to understanding the spatial variation of
disease, and its relationship to environmental factors and the
health care system [14]. Public health practice needs
timely information on the course of disease and other
health events to implement appropriate actions and GIS
are an innovative technology for generating this type
of information. Unfortunately, the importance of the spatial distribution of disease has been too often
overlooked [8].
Africa
is generally held to be in crisis and the quality of life for the majority of
the continent's inhabitants has been declining in both relative and absolute
terms[15]. The health problems are different to those in the developed world
and if GIS is to be used for the health challenges facing Africa, then it must
respond to these realities and priorities. Due to infrastructural and cost
constraints, there is a lack of reliable statistics and disease reporting in
Africa. Where data do exist, they tend to be clinically (as opposed to
diagnostically) based. Disease estimates in Africa can therefore range between
'educated guesses and wild speculation' [16]. GIS can help significantly in
this area by filling the gaps through empirical disease modelling techniques.
If the potential for GIS to contribute to health research and planning in
Africa is to be properly evaluated then the technology must be applicable to
the most pressing health problems in the continent. In this article we focus on
the human immunodeficiency virus (HIV), malaria and tuberculosis as some of the
most important public health threats in Africa [17,18]as well as having diverse
modes of transmission. Furthermore we review work done in the spatial analysis
of health systems (that must assist in the attenuation and control of these
diseases).
Review
Africa's
health priorities
HIV/AIDS
is the leading cause of mortality and morbidity in Africa [18]. Since its
appearance more than two decades ago the virus has spread to almost every
country in the world affecting an estimated 34 million people [19]. Nearly 24
million people in Africa currently live with HIV/AIDS and the epidemic
continues to ravage the development prospects for millions of Africans
throughout the continent. In 1999, about 3.8 million Africans were infected
with HIV during that year, and a total of 10.7 million children were estimated
to be orphaned by it[15]. The 21 countries with the highest HIV prevalence are
in Africa. In South Africa, Botswana and Zimbabwe, one in four adults is
infected. A child born in Zambia or Zimbabwe today is more likely than not to
die of AIDS. In many other African countries, the lifetime risk of dying of
AIDS is greater than one in three [15]. While prevalence in many west and central
African countries has remained relatively low and stable, eastern and southern
Africa have experienced explosive epidemics with HIV prevalence exceeding 40%
among pregnant women in some regions. Around 5 million
new infections
are currently occurring annually worldwide, over 90% in developing
countries[19].
One
of the reasons for the severity of Africa's HIV/AIDS epidemic is the high
prevalence of other sexually transmitted infections (STIs) and the inadequacy
of STI services. Another reason for the recent rise in HIV in Africa is the
gradual adaptation to new environments, for example, as people migrate from
rural to urban areas in search of
work. However,
the spread of sexually transmitted diseases can also be sharply intensified by
crises such as natural
disasters,
social disintegration, armed conflict and mass population movements[20]. HIV is
especially burdensome as the infection and resultant disease primarily affects
young and mature adults in their most productive years (15–25) when older and
younger family members are dependent on them. The global HIV pandemic is
composed of a series of several smaller epidemics. Even within Africa, where
levels of infection are the highest in the world, there is substantial
heterogeneity of levels of infection.
Tuberculosis
is the leading infectious cause of death worldwide, killing more people aged
over 5 years of age than AIDS, malaria, diarrhoea and all other tropical
diseases combined. The World Bank estimate that the disease
accounts for 26%
of all avoidable adult deaths in less-developed countries[21]. So serious is
the threat of tuberculosis
that in 1993,
the World Health Organisation took the unprecedented step of declaring this
disease a global emergency[22]. HIV infection renders a person infected by Mycobacterium
tuberculosis much more likely to develop overt tuberculosis, and the
evolution of the disease is considerably accelerated. About 20% of tuberculosis
cases in
Africa are
believed to be related to HIV infection[23]. WHO has calculated that, unless urgent
action is taken the annual global number of deaths could rise from 3 million to
4 million by the year 2004. The need for effective intervention is compelling
because tuberculosis treatment is one of the most cost-effective of all health
interventions. In response to this re-emerging epidemic, the World Health
Organisation is promoting the DOTS control strategy
(directly
observed therapy, short course) with community based treatment at its core[24].
In the last
decade, in Africa, the incidence of malaria has been escalating at an alarming
rate. Cases in Africa account for 90% of malaria cases in the world [25]. Until
recently, malaria was ranked as the leading disease in terms of disease
burden[21]. It is now estimated that only HIV has a larger impact on the health
of the African population than that of malaria[18]. Malaria is estimated to cause
disease in 400 million individuals in Africa and is responsible for 20–50% of
all hospital admissions. Mortality associated with cerebral malaria has not improved
in the past 30 years [26]and severe malaria anaemia is on the increase[27]. One
study has estimated (using empirical methods) that during 1995, 0.75 to 1.3
million deaths resulted from malaria in Africa and that approximately 80% of
these occurred in children < 5 years of age[16].
The
development of drug-resistant strains of the malaria parasite Plasmodium
falciparum has been one of the greatest obstacles to controlling the
disease [28]. Drugs such as chloroquine, which were once highly effective, are
now almost useless for treating malaria in many parts of the world [29].
Frequent armed conflicts, migration of nonimmune populations, changing climatic
patterns, adverse socioeconomic patterns (e.g. gross inadequacies of funds for
drugs), high birth rates and changes in the behaviour of the vectors are also
responsible for the upsurge[30]. The
upsurge has also
been attributed in part to the declining nutritional status of individuals in
both urban and rural areas[2]. Malaria and underdevelopment are closely
intertwined. The disease causes widespread premature death and suffering,
imposes financial hardship on poor households, and holds back economic growth
and improvements in living standards. Malaria flourishes in situations of
social and environmental crisis, weak health systems and disadvantaged
communities[18].
Health
systems in Africa face increasingly diverse and complex health problems,
rapidly growing populations, and severe resource constraints. Improving the
performance of health systems has been identified as a major global health
priority[18]. Health systems' performance makes a profound difference to the
quality, as well as the length of the lives of the billions of people they
serve. If health systems are poorly constituted and managed, lifeenhancing
interventions cannot be delivered effectively to those in need. Malaria and
tuberculosis are examples of
diseases that
thrive in the absence of well constituted, effective health systems. This is
particularly pertinent for Africa where health systems often perform poorly and
are unreliable.
GIS
research in health in Africa
Much
remains to be understood about the relationship between space and disease. The
spatial dynamics of tuberculosis, HIV and malaria are different because of the
different modes of transmission and differing relationships
to the
environment. For example, tuberculosis (transmitted by respiratory droplets)
and HIV (transmitted largely through sexual contact) rely on close human
contact for transmission. Malaria however is transmitted by mosquito and is
constrained only by the flight distance of mosquitoes. This has been measured
in one vector species at a maximum distance of 1.8 km [31]. Climatic factors
play a large part in determining the distribution of malaria, whereas HIV and
tuberculosis are affected more by the social environment. These differences
will necessarily affect the types of GIS methodologies used to understand the
various spatial components of these diseases.
GIS
has been widely applied to the understanding and management of malaria in
Africa. For example GIS has been used to generate models of malaria occurrence
[32,33], seasonality [34,35] and transmission intensity [36–41] using climatic
and remotely sensed data. The outputs of such models have been combined with
population data [16,42] to estimate population exposure, mortality and
morbidity [16,42] and to analyse [43] and project [44,34] the effects of
climate change on malaria. GIS has been used to map malaria vectors [45–47],
vector habitats [48] and infection [49]. It has also been used in the
management and control of malaria [50–52], to measure the effects of access to
malaria treatment [53] and to evaluate the effects of intervention strategies
[39]. The above studies were undertaken at scales ranging from micro to
continental.
We
were only able to locate a handful of published studies using GIS to study
tuberculosis in Africa, all of which were undertaken in South Africa. GIS has
been used to map tuberculosis cases in an Urban area in the Western Cape of
South Africa [54] and analyse childhood tuberculosis in two urban communities
of Cape Town [55]. In a rural area of KwaZulu-Natal, GIS has been used to
analyse the distribution of treatment points and the effect of communitybased
(as opposed to facility-based) treatment on increased access to nearest
treatment supervision point [56,57].
GIS
could have an important role to play in tuberculosis control programme
management, service development, and research. In terms of planning and
managing the service, GIS can assist in the planning of the number and
distribution of the supervision points as proximity of treatment is one
important factor in promoting adherence to treatment. Much remains to be
understood about tuberculosis transmission dynamics in developing countries[58]
and GIS will be a useful addition to molecular techniques and conventional
epidemiology, in elucidating transmission pathways, and clusters of multi-drug
resistant cases for example.
Although several
studies analysing geographic variations in HIV in Africa have been conducted
[59–63], and the importance of place in targeting areas for priority intervention[
64] has been emphasised, only one published study could be located that applied
GIS to the analysis of HIV [65]. The study provided some evidence for an
ecological relationship between transport accessibility (distance to roads) and
HIV prevalence. This was believed to be related to the amount of sex work
taking place along the major routes as well as the higher mobility of persons
living near transport routes. However, this relationship needs to be tested at
an individual as well as at an ecological level. Though studies have documented
heterogeneity in the geographical distribution of the HI virus [66–68], much
remains to be learnt about the causes and nature of this heterogeneity. Most
research has focussed on temporal analysis ignoring the spatial dimensions of
the HIV/AIDS epidemic. Yet, spatial analysis may be an important tool to
monitor the epidemic, predict future treatment demands and to target areas for
public health interventions. Work in Europe and North America [e.g. [69,70]]
has focused largely on the distribution and diffusion of the disease [71]. In
addition, the delimitation of high-risk areas (based on the distribution of
co-factors) using standard risk analysis techniques could prove invaluable in
Africa. Furthermore, the technology could also assist in the optimal spatial
organisation of health care delivery including home-based care. The difficulty
of obtaining HIV data and the stigma associated with disclosure however, is a
major obstacle to the use of GIS in HIV research in Africa.
Surprisingly,
there were few published examples of the use of GIS in health systems research
in Africa but there is an encouraging amount of work in progress. One group
used GIS to study inequalities in population per bed ratios and the
implications of open access to the private and the formerly white hospital
services in the province of KwaZulu-Natal, South Africa [72]. One study used
GIS to equitably distribute fieldworker workload in a large health
survey. The
methodology predicted average inter-homestead walking time and divided the
heterogeneous study area into units of equal workload [73]. The author suggests
that an extension of the same methodology can be used to optimally distribute
community health workers and tuberculosis DOT supervisors, for example. Another
study analysed modal patterns of fixed and mobile clinic attendance across an
integrated rural health district [74] and developed indices to analyse the
relative attraction and repulsion by the various clinics in the district. The
most important outcome of the research was the development of a composite
measure of clinic usage and interclinic interaction based on the ratio of total
actual versus predicted distance travelled to attend clinic. The same data set
has been used to validate a model of travel time to the various clinics based
on a network analysis of a road network. Relative clinic attraction and
inter-clinic interaction were again studied using travel time as the
denominator in the index (F.C. Tanser & K. Herbst, In prep., 2002). A study
using a similar methodology is underway in the Rufiji district of Tanzania to
investigate the relationship of wealth quintiles and health outcomes to travel
time to nearest health facility (D. de Savigny et al., In prep.,
2002).Researchers are using GIS to investigate the relationship between clinic
access and maternal and child health indicators in rural Kwa-Zulu Natal South
Africa (J. Tsoka et al., In prep., 2002) In four districts of Kenya, GIS
is being used to capture and model both population's access and utilisation of
health services with a view to increasing the effectiveness of malaria
treatment coverage (A. Noor et al., In prep., 2002).
Limited
physical access to primary health care is a major factor contributing to the
poor health of populations in developing countries[75]. The world health report
of 2000 [18] was dedicated to improving the performance of health systems.
Health systems performance make a profound difference to the quality, as well
as the length of the lives of the billions of people they serve. However, an
important omission from the report was the spatial aspect of health systems
research. GIS can be used to effectively spatially analyse health systems
coverage and identify deficiencies. The potential exists for GIS to play a key
role in rational and more cost-effective health service planning and resource
allocation in Africa.
GIS
trends relevant to Africa
GIS
is largely technologically (as opposed to research) driven. Some of these
global technological trends are irrelevant to health research in Africa at the
present time. However, some global trends (both technological and
non-technological) are of significant relevance to Africa's health crisis.
It is becoming clear that although GIS started
out as a technological tool, it is rapidly evolving into a science in its own
right[76], albeit in embryonic form. At present it lies somewhere along the
continuum between the two. As software becomes increasingly powerful and new
datasets become available and GIS is increasingly used to understand and forecast
the dynamics of (particularly environmental) disease, this evolution is likely
to continue. A
parallel exists
between GIS and epidemiology. In the same way that epidemiology evolved into a
science in its own right in the 1970s [77], GIS is beginning to be recognised
as a science. Like epidemiology its tenets have been established piecemeal [77]
with contributions coming from a number of different disciplines, in particular
the earth sciences. It is now time to draw the different facets of GIS together
under the umbrella of geographic information science.
Computer
hardware is becoming increasingly cheaper and more powerful, so that even
complex analyses of GIS and image data can be carried out on a desktop
computer. At the same time, commercial software has been developed into
stand-alone solutions capable of performing increasingly complex tasks through
increasingly userfriendly interfaces. Whilst there is an increasing amount of
free software, the commercially available comprehensive packages remain expensive
[11].
Since
the 1st May 2000 the accuracy of off-the-shelf global positioning systems (GPS)
has improved by an order of magnitude. Low cost units can now perform tasks
that they previously weren't suitable for. This development is likely to result
in a sharp increase in the number of georeferenced health projects making use
of GPS technology in the near future.
Obstacles
to the advancement of GIS in health in Africa
The
paucity of qualified staff, which has prevented manyGIS projects from surviving
the donor involvement phase, is a major problem in Africa [78]. GIS
applications in Africa are often found to be initiatives funded or supported by
international aid agencies and many are pilot or research projects as opposed
to operational systems. They also tend to be controlled by outsiders, not by
African scientists[79]. If GIS are to be useful and effective, then they must
be introduced by local scientists who understand both the technological and the
socio-economic context in
which the
systems are to operate. Training creates capacity and leads to an increase in
terms of data needs. It however
also provides
the capacity to fulfil these needs and the new products that result are often
of value to many other sectors. Capacity development of African staff should
therefore be prioritised.
In
addition to lack of capacity, a lack of suitable GIS data sets is a major
impediment to the growth of GIS in Africa. The access to spatial data (which
are fundamental to any GIS application) continues to be difficult and
expensive[10]. This is not specific to health but to all sectors that utilise
GIS. There are similarities in the field requirements for using GIS between
forestry, ecology, archaeology and epidemiology that could provide substantial
benefits by the sharing of experiences and the pooling of resources[11].
However, much of the spatial data collection efforts within Africa have been
conducted in a decentralised and uncoordinated manner. Inter-sectoral
collaboration
initiatives
should therefore be encouraged and receive funding priority. Africa could
usefully build projects such
as the Global
Spatial Data Infrastructure[80] (embedded within which is the SDI – Africa
project) and the EIS – Africa [81] projects which aim to support ready access
to geographic information to support decision making at all scales for multiple
purposes. Geographic datasets are being developed for some countries in Africa
through these initiatives, but a systematic programme is required to make
geographic data readily available for the continent as a whole. A major
programme (funded by an international body) is needed to take up this
challenge. Priorities include, for example, the digitalisation of 1:250 000 and
1: 50 000 cartographic maps for countries that have them.
Similarly,
national geo-referenced health facility databases should be established.
Inexpensive African data sets include the African data sampler (topographic,
boundary and place data)[82], long-term rainfall and temperature
data [83] and
raster population data [84]. Development of such data sets are of paramount
importance to ensure
the growth of
all sectors of GIS in Africa.
Widespread availability of small scale digital
data (< 1: 50.000) for many countries within Africa is unlikely to ever
become a reality. The most cost-effective answer to the data deficit and poor
vital registration and health statistics problem in Africa is the establishment
of sentinel geo-referenced demographic and health surveillance systems[85].
This will enable the elucidation of small-scale disease patterns (e.g.
diffusion dynamics) that could be modelled using coarser resolution data and
the coverage extended. The INDEPTH network is a network of these sentinel
surveillance sites, 23 of which are in Africa[86]. The sites follow up a designated
population intensively over time collecting highly accurate demographic, vital
event (e.g. births, deaths, migrations) and health data on a routine basis. So
far only a small proportion of the sites are fully geo-referenced but this is
likely increase with the increase in GPS accuracy, falling prices and the
obvious operational and research advantages of fully geo-referenced data. These
sites can especially contribute (and have already contributed) to our
understanding diseases with ill-defined relationships to the environment due to
the detailed longitudinal collection of disease covariates. A recent spatial
initiative in health is the West African Spatial Analysis Prototype (WASAP)
that used geo-coded demographic and health survey (DHS) data to study the
effects of climate on children's nutritional status, and the relationship
between economic diversity and reproductive behaviour, as well as study the
subnational geographic variation in health indicators at a regional
level[87,88]. Following the success of WASAP, more DHS sites have began to
geo-code their survey data in an effort to facilitate cross-disciplinary
analyses. The increasing availability of regional geo-referenced DHS data will
facilitate a more comprehensive understanding of the patterns and processes of
demographic and health changes and will lead to an increasing amount of
GIS-based analyses of this important data in the near future.
In addition to
the geo-coded household datasets outlined above, a large number of remotely
sensed data sets, which have been already used extensively in health are
available free of charge or at nominal cost. With the emergence of new
technologies and techniques within remote sensing, there is likely to be a
great improvement in the quality of such data sets and parallel improvement of
GIS and related research products[89]. Nevertheless, it is also true to say
that so far, our ability to extract meaning and make useful decisions from
remotely-sensed data has not kept pace with the developments in this field.
The
issue of scale is one that is poorly understood in the disease arena. Disease
patterns and processes evident at one scale are not necessarily evident at
another. Moreover, correlations between explanatory variables and outcomes may
even be (seemingly) reversed at different scales. This has led to a significant
amount of confusion when hypotheses are rejected at one scale and not at
another. Sometimes it is advisable to use coarser resolution data to mask out
small scale heterogeneity. For example, the malaria modelling at a continental
level used climatic data at a resolution of 0.05° [32,34]. Higher resolution
satellite data (sub kilometre) may obscure continental malaria patterns by
exposing unnecessary small area variation. Ideally the resolution of the data
should be driven by the application. However, given Africa's geographic data
deficits, future research is needed to establish how applicable coarse
resolution data sets are to modelling high resolution disease-specific dynamics
and vice-versa. The above issues are as applicable to temporal resolution as
they are to spatial resolution.
Another
obstacle remaining to the growth of GIS in health in Africa is to convince role
players (often from cashstrapped organisations) of the proven
cost-effectiveness of GIS in the health arena[90]. Even amongst the
international scientific community, significant scepticism still exists
surrounding the use of GIS technology in health. This problem will diminish in
size as GIS continues to evolve. The parallel with epidemiology again warrants
mentioning: In the same way that scepticism greeted epidemiologists who
hypothesised that a relationship existed
between smoking
and lung cancer in the 1950s [77], so to will scepticism continue to plague GIS
until it is firmly established as a science.
It
is encouraging to note that several of the issues cited as obstacles to the
growth of GIS in Africa a decade ago [91] have been overcome to some degree.
These included the incompatibility of different software formats (data conversion
problems), the non user-friendly interfaces of many systems and the lack of
good inexpensive/free GIS software. Other obstacles such as the prohibitive
costs of hardware have also become less of an issue. Perhaps a review in a
decade's time will describe the increasing availability of inexpensive spatial
data sets for Africa?
The 'mapping
malaria risk in Africa' (MARA) research collaboration is an African research
endeavour that makes extensive use of GIS technology. The collaboration has
been highly successful in collating malaria data from around the continent, and
producing a large number of scientific publications on a limited budget. The
outputs of the research were then disseminated to countries throughout Africa
in the form of digital (via the stand-alone MARA lite software) and hard copy
maps. The collaboration overcame significant data deficits by creating its own
base data sets and created a significant amount of GIS capacity in its five
regional centres throughout the continent. During the setting up of the
collaboration, significant scepticism was expressed by influential malaria
scientists as to the ultimate value of a GIS approach, its logistical
feasibility and cost-effectiveness[33]. The collaboration is a testament to the
fact that successful GIS initiatives can be undertaken in Africa.
Viable
GIS health applications in Africa
The
current software and hardware trends in combination with the realities faced in
Africa have given rise to essentially, two broad categories of long-term
feasible GIS health applications in Africa. The outputs of the categories
will inform one
another and are not mutually exclusive and may overlap. The first category
involves the use of GIS
as a research
tool. These applications should seek to provide new insights into the spatial
dimensions of disease and new methodologies to more cost-effectively allocate resources
to health services. These types of applications will normally use high-end systems
with significant analytical functionality and will usually involve a
significant amount of additional data collection.
The
second category of long-term viable GIS application concerns the use of GIS as
a health planning and management tool and for exploratory data analysis.
Generally speaking this kind of system will involve a low-end GIS. The primary
goal of such a system will be to simply display and overlay basic health data
concerning both health
care facilities
and disease patterns. These systems (normally vector-based) permit rapid
manipulations of spatial data and display of the results so that the decision
makers can use them for policy decisions. A further step could involve limited
spatial queries and analysis such as buffering.
The
outputs of the different categories of application will inform one another. As
the data is geographically displayed using a management GIS and research
questions are derived, collaborations can be initiated with institutions
undertaking GIS research
to test hypotheses and model disease distributions. Similarly, research GIS
applications will inform GIS management applications to plan optimal resource
allocation and intervention strategies, for example. The MARA collaboration is
a successful example of this type of approach and is embedding several of its
research outputs in the freely available GIS software HealthMapper (developed
by WHO) for intervention planning in Africa at a district level.
Conclusions
A
review of the health literature in Africa reveals the GIS bias towards so
called 'environmental' diseases. In certain diseases, such as the vector-borne
diseases (e.g. malaria, schistosomiasis, human helminth infections and
trypanosomiasis) the environmental component in the determination of factors
such as transmission intensity is
extremely high.
In other diseases, especially in the noncommunicable category (e.g. multiple
sclerosis) links to
the environment
are weak or non-existent. Some infectious diseases such as HIV and tuberculosis
have moderately
strong links to
the environment. Thus there exists a continuum of diseases, on the one end
there are those diseases in which GIS has limited research application and on
the other there are those in which GIS is highly applicable. This continuum
does not relate to the availability of ancillary data sets but rather to the
inherent nature of the disease itself.
Not
only does Africa have the highest burden of disease of all the continents[18],
but it is the continent in which the greatest component of the burden is
contributed by so called 'environmentally dependent' diseases. In addition, the
phenomenon of climate change is likely to hit hardest in Africa [15] on account
of its greater rainfall variability and the proportion of 'ecothermic
infectious diseases'. This makes the potential applications of GIS in health
particularly relevant to Africa, i.e. GIS in health has greater relevance and
inherent potential in Africa than it does in the United States or Europe for
example. Unfortunately, this reality is not reflected in the literature or in
practice. Thus, we concur with authors [92,93] who have concluded that GIS is
an appropriate technology for developing countries (despite the fact that in
some ways GIS appears to contradict the principles of appropriate technology
because of its sometimes high cost and often high levels of expertise required)
since many issues of poverty relate to large scale problems requiring
integration of large spatial datasets. Furthermore, the success of
participatory approaches for the transfer of GIS technology by the MARA project
and in other developing country settings [94] could serve as a useful framework
for future projects.
The
ability to map spatial and temporal variation in disease risk is more important
than ever given the ever-increasing disease burden in Africa. GIS allows the
planning of control strategies and the delivering of interventions
where the need
is greatest, and sustainable success is most likely. Despite some obstacles,
GIS holds considerable promise for health research and development in Africa.
The global trend towards faster, more powerful computers, user-friendly
software and falling prices combined with the magnitude and nature of Africa's
disease burden and lack of reliable disease statistics makes it a viable,
relevant and powerful technology for health research and management in Africa.
List of
abbreviations
DHS –
Demographic and Health Survey
DOT – Directly
observed treatment
EIS –
Environmental Information Systems
GPS – Global
Positioning System
HIV – Human
Immunodeficiency Virus
MARA – Mapping
Malaria Risk in Africa
SDI – Spatial
Development Initiative
WASAP – West
African Spatial Analysis Prototype
WHO – World
Health Organisation
Authors'
contributions
The authors
contributed equally to the conceptualisation and writing of the manuscript.
Acknowledgements
David le Sueur
died unexpectedly during the advanced stages of manuscript preparation. Frank
Tanser wishes to acknowledge him for conceiving and driving the Mapping Malaria
Risk in Africa (MARA) initiative and for his unsurpassed lifetime contribution
to the field of malaria mapping and modelling and to GIS in health in general.
This research was jointly funded by the South African Medical Research Council
and the Wellcome Trust.
dical Research
Council dan Wellcome Trust.
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