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Spatial exclusion, and its gender dimensions, is an important component of social marginalization and vulnerability. Transport infrastructure and services play a critical role in supporting mobility and access to basic services vital to achieving poverty reduction, gender equality, and sustainable development objectives. This paper explores how Geographic Information Systems (GIS) technology can support integrated evaluations of the gender dimensions of transport using an innovative combination of community participatory mapping, new gender-disaggregated household-level Demographic and Health Surveys (DHS), and transport sector GIS data. The pilot study focuses on three countries, Lesotho, Ethiopia, and Ghana, and reveals new opportunities for cross-scale evaluation.

Spatial exclusion, and its gender dimensions, is an important component of social marginalization and vulnerability. Transport infrastructure and services play a critical role in supporting mobility and access to basic services that are vital to achieving poverty reduction, gender equality, and sustainable development objectives, such as the Millennium Development Goals. However, one of the principal challenges facing the transport sector lies in measuring the social benefits and impacts of its investments, especially as they emerge over time and for particular segments of the population served by specific infrastructure and/or services.

To bridge this measurement gap, international targets, such as the Millennium Development Goals, are being employed by countries to evaluate overall development progress, to serve as key indicators for national Poverty Reduction Strategies (PRS), and to guide planning and prioritization of investments and programs. Three specific health-related MDGs—reduce child mortality (Goal 4); improve maternal health (Goal 5); and combat HIV/AIDS, malaria, and other diseases (Goal 6)—are particularly relevant for transport investment and evaluation, since the sector plays a key role in meeting all three goals. Transport sector contributions include support for routine medical visits, provision of emergency services, health care provider access, and mobile health service delivery to isolated communities and populations. Transport networks and services also play a vital role in assuring the distribution of drugs and supplies.

Although these linkages have been clearly articulated and agreed upon by transport sector government officials in many countries, in reality there is very little explicit monitoring of transport impacts on MDGs within national programs and projects (SSATP, 2005). Failure to do so ensures that traditional cost-benefit analyses of planned projects continue to drive investment prioritization and decisionmaking. The lack of a systematic approach to social cost and benefit accounting for transport investments limits decisionmakers’ abilities to weigh their options for investment based on a broader framework that includes the anticipated social impacts of investments (Greene et al., 1986; Button, 1995; Howe, 2003).

This paper explores how Geographic Information Systems (GIS) technology can support evaluations of the gender dimensions of transport using an innovative combination of participatory mapping with communities, gender disaggregated household-level Demographic and Health Survey (DHS) data, and transport sector GIS data. Maps can be important tools for illuminating the direct and indirect social impacts of transport investments and highlighting the gender dimensions of spatial exclusion. However, mapping technologies have only recently begun to make links to gender-based analyses. Innovations in participatory mapping methods and improvements to existing data sources, such as spatial referencing of household and community surveys, now allow these analysis to be done at a multiple scales–from the community to national level–and to capture changes over time. This paper presents a pilot study focused on three countries: Lesotho, Ethiopia, and Ghana. The rationale for choice of these countries is based on the availability of data for both DHS and road networks and differences in physical size, social context, and existing evidence on gender differences in access and mobility.

The integrated analysis developed here explores how the combination of existing DHS data and transport GIS data sources can be used to support national-level monitoring and evaluation of the social impacts of transport programs. The results of this type of integrated analysis can further help to address:

The resulting approach and analysis has the potential to address common goals in health and transport, such as mapping the synergies in mobility and access between the sectors and evaluating and assessing available services. As transport ministries increasingly invest in GIS for decision support, geo-reference their road networks, and continue to expand their spatial data infrastructure (SDI), the opportunities for combining data sets and devising new ways to meet monitoring challenges across scales, timeframes, and forms of investments will continue to emerge. This paper explores some of the critical issues associated with integration of new transport and health databases, and outlines a spatial analytic approach to rigorous data integration and evaluation from the community to the national level.

Direct social benefits and impacts of the transport sector include employment creation and reductions in travel costs and travel time. These indicators can be captured through 1) regular monitoring of infrastructure and road construction activities, 2) detailed questioning during key social assessments and surveys, 3) targeted follow-up evaluations, and 4) data collection from related agencies, such as government departments responsible for regulating public transport. Changes in mobility, access to key services or destinations, and greater frequency and/or ease of travel are the principal aims of many transport programs and national growth agendas. Yet these outcomes are harder to systematically capture on a large scale. The challenges of measuring these often indirect, but long term and durable, impacts of a national program of linear investments are numerous.

Evaluation of cross-sectoral interactions can help identify indirect transport sector contributions to improving health or education outcomes. The health sector in particular offers data that capture underlying relationships with mobility and access to services. Demographic and Health Surveys (DHS) are routinely carried out in many countries around the world. These surveys focus primarily on characterizing health-seeking behaviors, but they also include valuable information for the transport sector on access to healthcare and availability of transport services. Unlike many other sources of transport survey data, the DHS is nationally representative, capable of being disaggregated by gender, age, administrative boundaries or eco-zones, and increasingly geo-referenced using GPS technology to mark the locations of survey enumeration areas (EA) or clusters.

These recent technological innovations allow DHS demographic and health data to be integrated into transport GIS. This integration through spatial analysis provides opportunities for both technical planners and managers to better understand specific transport related challenges in access to healthcare, such as the role of transport costs, differential mobility time burdens, availability of transport infrastructure and services as barriers, and how these rank with other obstacles including availability of healthcare facilities/personnel or cultural restrictions. DHS surveys have a particular emphasis on elucidating gender differences in access and use of health services and therefore can help to better understand gendered differences in access and mobility as well. The resulting spatial information can further serve as an important tool for analysts and managers to monitor the impact of transport plans on national development indicators such as the MDGs and assist in targeting future community development and infrastructure investments.

This paper and pilot study focus on data from three countries: Lesotho, Ethiopia and Ghana. The rationale for choice of these countries is based on the availability of both recent national DHS data and road network spatial data, in addition to differences in physical size, social context, and existing evidence on access and mobility.

Lesotho: The major emphasis in this pilot is on Lesotho, due in part to the importance that the Ministry of Public Works and Transport (MoPWT) has placed on georeferencing the transport network and building a GIS system that integrates many layers of transport, and other spatial data. In 2005, Oddsson, Walker, Bergveinsson carried out an in-depth multisectoral needs assessment of spatial data availability and updated the MoPWT GIS with extensive data layers in searchable formats.

Figure 1. This image illustrates the analytical and decision support potential of the MoPWT GIS. The map was developed based on a query to show only those health clinics within a 5 km radius of the road network. This type of spatial analysis has the potential to support the placement of new clinics, the evaluation of access criteria, and characterizations of underserved populations.

In addition, the MoPWT has engaged in complementary participatory mapping processes with communities and local government (Walker et al., 2005). As a relatively small country with low population densities in the rural highlands and multiple barriers to mobility and access, participatory mapping approaches have the potential to play a major role in linking community-level transport information to national data and monitoring. This community-centered spatial approach for eliciting local priorities and relevant indicators, now form a key methodology used by MoPWT for social assessments and prioritization of investments with local governments (see Vajjhala, 2005 for more on general participatory mapping approaches).

Representatives of the MoPWT were able to participate in early DHS survey tool development meetings and this collaboration resulted in the addition of several extra transport-related questions to the nationwide survey instrument. These questions greatly enhance the ability to perform transport specific spatial analysis on the 2004 DHS, which is the first one that has ever been done for the country.

Figure 2. This image captures local information on the costs of access to healthcare facilities for rural communities in Lesotho during normal everyday travel (yellow line on the right) and for emergency access (red line on the left). Emergency travel, in this example, can cost up to 47 times the costs for everyday access.

Ethiopia: With one of the lowest density road networks in Africa, a population of over 70 million and great difficulties in access, especially for rural communities, investment in the transport sector has been and continues to be a major priority in Ethiopia. The Ethiopian Roads Authority (ERA) has created a GIS of the network and is including new layers of spatial data. At the same time, major efforts in the 2006 census laid the groundwork for georeferencing of village locations and mapping of administrative boundaries. DHSs have been carried out in the country several times and the ability to analyze results over time is an important opportunity in the integration of these national survey data.

Ghana: Although the road network for Ghana has been georeferenced, the pilot team did not have access to the data or to data on village locations. This country was included to show what can be done with extremely limited data and serves as a counter example to the transport and social contexts of Lesotho and Ethiopia. In between the total land areas of Lesotho and Ethiopia, with a higher density road network, established urban centers, and better MDG achievements, Ghana illustrates very different access and mobility issues.

Access and mobility are addressed in several questions in all national DHS. For example, the frequency of access to health providers for prenatal care and during pregnancies is extensively probed. There are questions on time to access water, and ownership of various modes of transportation, including country specific intermediate means of transport (IMTs) and animal transport. In the women’s questionnaire all DHS include a question on barriers to health care access for self. Among the five barriers included in the survey, two are transport specific: distance to health facility and having to take transport.

For the Lesotho 2004 DHS, the MoPWT was able to insert three extra transport-related questions onto the survey. These include: time to access health clinics, mode of access to health clinics, main health center accessed. In addition, MoPWT verified that relevant intermediate means of transport (IMT) options such as scotch carts and horses were included in the question on ownership of transport. One important question on transport costs for access to healthcare facilities suggested by MoPWT was not included in the 2004 questionnaire. In the future, transport cost questions could help to deconstruct and identify any underlying transport issues in an existing barrier to access: cost of treatment.

Disaggregation and analysis of differential impacts of mobility: All DHS have specific survey questions for women, men, and children. Unfortunately, there are very few instances where the same question is asked to members of each group. This limits opportunities for analyzing gender differences and impacts across particular populations. However, disaggregation of the survey data can be done by age, enumeration area, district and ecozone. Georeferencing of the enumeration clusters, a technique added to many DHS relatively recently, can facilitate further spatial analysis across other relevant boundaries such as Health Service Areas (HSA) and local administrative boundaries beneath the level of districts. The use of GPS to locate enumeration clusters also allows for impact monitoring of specific project areas using different boundary definitions and impact identification of national transport programs at macro scales.

Integrating transport and health data requires a careful, systematic approach. This section outlines the five-step methodology for integrated analysis of DHS transport and health data for broader comparative spatial analysis using GIS road network, health service, and administrative data used by the study team. The steps outlined here are intended to serve as a replicable and adaptable framework for application of geo-referenced DHS data to the evaluation of a wide-variety of cross-sectoral health and transport issues.

First, we selected key DHS questions relevant for transport analysis. For the Lesotho DHS, several new transport related questions were specifically added to the 2004 survey. This set included questions on transport ownership, location of primary health facility, mode of travel to health service provider(s), time to access health services, and major transport barriers to health service provision. Figure 3 is an excerpt from the 2004 Lesotho DHS questionnaire illustrating the different types (multiple choice, yes/no, rating, ranking, open-ended) of responses collected. By examining DHS questionnaires across countries, we defined a set of relevant research questions and possible statistical and spatial analyses, comparing within- and between-country metrics, given available data.

Figure 3. Excerpt of 2004 Lesotho DHS Questionnaire showing key transport question formats.

Second, building on the research questions motivated by available DHS data and the georeferenced survey clusters, we compiled relevant spatial data from different sources corresponding to selected DHS health and transport questions. For the purposes of this study, we gathered existing GIS information from a variety of health and transport databases, including the Transport and Health Ministries, and various other departments and organizations across all three countries (see references). All selected data were national level with full-coverage corresponding to the DHS ^¹

Fourth, one of the important challenges in integrating this work was finding valid ways in which to measure and then visualize access. We calculated three different measures of transport access based on available GIS data on the road network for comparison to relevant DHS results. Multiple measures were used to overcome biases and limitations of each individual metric. For example, the first and most commonly used measure of transport access is the World Bank Rural Access Indicator (RAI), which is based on an estimate of percent of the total population living within 2km of an all-weather road. The strength of this measure is that it brings together population and transport statistics in a widely-comparable definition of access. The weakness of this measure is that the RAI varies significantly depending on the spatial scale selected for analysis (country, region, district, etc.) and the reliability of road and population (size and location) data. In many cases, up-to-date geo-referenced population estimates are unavailable or inaccurate. To overcome this issue, we calculated a second measure of access which was district-level road density (km. of road length per sq. km. area). This measure is also highly-scale dependent, but it provides a population independent measure of road network availability.

Finally, to generate a jurisdiction-independent measure of access we plotted 2km, 5km, and 10km radius buffers around each survey enumeration area and calculated the total road length (km) within each buffer. This last measure allows for comparisons of road density by buffer at the cluster-level, and also comparisons of buffer averages at the district and country levels. The RAI and road density measures are illustrated in Figure 4. These multiple definitions of access allowed us to 1) overcome important data gaps among countries and 2) find ways of probing issues of access in relation to both the road network and the enumeration clusters that allowed us to look at different scales.

Finally, the fifth step in this study was the integrated evaluation of DHS cluster results, separately calculated measures of access, and related health, demographic, and socioeconomic statistics, including measures of social inclusion such as religion/ethnicity, education, wealth. Comparative analyses included tests of pairwise correlations of distance to the primary health clinic (number of household who identified a clinic as the primary clinic in the DHS), time to access, and women’s perception of distance as a “big problem” in accessing health services. These comparisons allow both visualization of key transport indicators and issues across countries and regions, and also identification of area “hotspots” of limited transport access and/or poor health service outcomes.

The five-step approach outlined here brings together elements of separate DHS, transport, and health analyses into a single integrated spatial analysis. The value of this approach is that it supports the identification of significant cross-sectoral issues and influences. The next section illustrates the results of the analyses described here for selected transport and health DHS questions.

Although the integration of DHS and GIS health and transport data provides many new opportunities for analysis and evaluation, these two types of databases have never traditionally been linked. As a result, there are several key data gaps. Below is a list of the most important caveats for interpreting the methods outlined in this paper and the results of this particular pilot study. These caveats are listed up front to place the analysis to follow in context and also to highlight future barriers to integration, while still demonstrating the value of integration and the robustness of our approach.

One of the most critical barriers to effective use of DHS GPS data in transport-health analyses is a consequence of the DHS method of ensuring survey participant privacy. During the compilation of all survey results, actual GPS point data collected for each enumeration area are taken at what researchers believe to be the center of the area and then randomly “shifted” to ensure that villages or individuals cannot be identified. Individual points are moved randomly by +/- 5km for all rural clusters and +/-2km for all urban clusters in any direction. This decision, while important for maintaining participant anonymity, makes it impossible to estimate, measure, or analyze point-to-point distances between populations and key services, such as roads or health clinics. Importantly, for this pilot, the shifting of the GPS points makes it impossible to layer the exact location of cluster sites over the road network and subsequently directly analyze access and mobility issues.

The methodology section describes our approach to addressing this spatial ambiguity by using buffers over multiple distances to capture some of the basic relationships between populations, transport infrastructure, and health services without relying on actual measured distances. Using this approach we believe our results are robust for the general level of aggregation at which they are presented; however, it is important to note that the potential for comparative analysis is significantly limited by the imprecision deliberately introduced into all DHS GPS data. We believe that there are other means of addressing privacy concerns that could allow for the full release of accurate survey GPS points.

A second caveat concerning both DHS and GIS data in different countries is data quality. Any analysis is only as good as the data it uses, and in cases where multiple datasets are being integrated, the least robust data has the potential to constrain an entire study. Issues of particular importance for this pilot include the accuracy, reliability, and/or completeness of the following variables or layers: village and health service locations, road network coverage, road classification (type), and time to access estimates, among others.

Without complete and robust data in each of these fields it is difficult to assess and interpret the results of any comparative analysis. For example, incomplete health service provider data (e.g. GIS layers that are missing certain geographic areas or provider types) could result in inaccurate spatial analyses that show a lack of health service provision in areas where services are present or vice versa. Having reliable and up-to-date metadata for all GIS layers is essential. The results of this study highlighted in Section 5 are largely based on analyses of transport and health in Lesotho, primarily because of the high quality of both DHS and GIS data for the country relative to data on Ethiopia and Ghana.

In all three countries, it is important to note that the coverage of the DHS–the extent to which survey clusters and responses are 1) regionally representative of populations and groups, 2) uncorrelated with the road network and representative of inaccessible areas or communities, 3) comparable between countries and over time–is critical. These issues are related to basic survey design and implementation decisions. Coverage issues are addressed here through statistical tests comparing key variables within and between regions and close examination of unusual results or outliers. Although this process can help identify some data gaps, applying this approach to other countries or sectors requires careful consideration of possible inconsistencies or incompatibilities that may occur as a result of data collection practices (e.g., whether or not survey teams really go to remote areas or tend to choose enumeration areas that are readily accessible to the road network); thereby affecting the interpretation of key results and their social development implications.

Building on this point, a final caveat for this analysis is that many of the relationships between transport and health evaluated and identified here have multiple underlying explanations. For example, distance to health clinics could be positively correlated with higher incidence of maternal or infant mortality in some countries; however, there are many other explanatory variables also correlated (co-linear) with distance that could influence maternal or infant mortality rates, including income, education, and a host of related demographic, spatial, cultural or socio-economic characteristics. As a result, this study does not attempt to make any causal links between transport barriers and health outcomes. Instead the focus of this effort is to illustrate key spatial relationships between transport and health, and highlight opportunities for improved evaluation and planning with new DHS and GIS databases in many countries. Obviously, it is very important to complement this kind of monitoring effort with other monitoring techniques including in-depth qualitative analysis with focus groups, key informant and individual interviews.

Taken together, these caveats illustrate both the importance and the complexity of cross-sectoral spatial analysis. We see many of the data limitations described here as problems that can be overcome with better coordination of transport and health data collection. To this end, this section is intended to outline a roadmap for improvement both in how DHS data is collected and compiled and how GIS layers are generated in different countries and sectors.

Based on DHS and GIS transport and health data for Lesotho, Ethiopia and Ghana, there are several key national level analyses possible with available data. This section highlights four main categories of illustrative analyses and major results.

It is important to underline that none of these categories focus on causal links between health and transport, instead these analyses and the results presented in the sub sections to follow are intended to illustrate the variety of cross-sectoral assessments possible with improved data integration in the future and further investigation of correlations substantiated by in-depth investigation on the ground. Currently, the limited GIS data for both Ethiopia and Ghana constrains the possible spatial and statistical comparative analyses. Moreover, the dramatically different contexts for transport and health services and the MDGs make it difficult to establish a clear baseline for comparison across all three countries examined here. Table 2 shows selected descriptive statistics (country averages across all survey clusters) to illustrate these variations in transport ownership options, distances to basic services (water), and socioeconomic characteristics across countries.

Table 2. Country level averages of basic DHS descriptive questions for Ghana, Lesotho, and Ethiopia.

Overall, the four categories of analyses discussed below are only a few of the comparisons possible using geo-referenced DHS data in tandem with GIS data.

As discussed in Section 3, several basic transport questions were added to the 2004 Lesotho DHS survey. These questions focused on household transport ownership, location of primary health facility, individual mode of transport to health facility, and time to reach health facility. Responses were aggregated for each of these questions (averages by survey cluster) and overlaid on related GIS transport data including total constituency road lengths and road density. The three maps in this sub-section highlight the tremendous spatial variation in transport availability, mode, and access. Together, they illustrate the implications of these variations for effective transport planning and improved health service delivery to diverse populations.

Figure 5. Map with overlay of DHS transport ownership by survey cluster and road density by constituency area for Lesotho.

Figure 5 highlights the relationship between DHS transport ownership and road density by administrative constituency. The darker areas on the map background are those with higher total kilometers of roads per unit area. The pie charts indicate transport ownership by DHS cluster. Overlaying these results reveals significant variations in the dominant type of transport owned by cluster where a large majority of households own no transport and horses/ mules are the next largest category of transport ownership. Ownership of motorized vehicles (car, truck, motorcycle, scooter) is largely limited to urban areas and there is a weak positive correlation between aggregate ownership (all forms of transport) and road density.

5.1.2 Health Clinic Access

Figure 6. Primary mode of transport to health facility as a percent of cluster total overlaid on total district road lengths (km).

A MoPWT added Lesotho DHS question focuses on primary mode of transport used to access health services. As Figure 6 shows, across Lesotho, the primary mode of access to health clinics is walking (orange) for the majority of clusters. Interestingly, the next most dominant mode of access is by car/truck and not horse or mule. This is in sharp contrast to the high levels of horse/mule household ownership across the country and limited motorized transport ownership highlighted in Figure 5. However, it may also highlight a key gender issue: that women do not own or have access to horse or mule transport. When overlaid on total kilometers of road by district, clusters in and around urban areas and those along the main road network are associated with the greatest use of motorized transport for health facility access.

Figure 7. Weighted average time of travel to health clinic (hours) by cluster relative to health facility locations and use patterns.

The previous maps reveal the complex relationships between transport ownership and mode of health facility access. Figure 7 illustrates even greater challenges associated with considering time to access and distribution of health facility users. This map overlays the average time respondents from different survey clusters said it took to go to the nearest health clinic and total use by health facility summed across all clusters. Results of this comparison reveal that survey clusters with very high travel times are in many cases located in close proximity to facilities with high numbers of users. This suggests that the primary health facility respondents’ identified in the survey may not be the nearest health facilities to their villages.

In fact, some of the EAs located closest to the health facilities with the highest numbers of self-identified users (largest health facility symbols) are also those where DHS survey respondents identified travel times of four or more hours to reach the nearest clinic. There are many possible reasons for this incongruity including underlying issues such as availability and quality of services at any given health facility, adequacy of staffing and supplies, and key geographical barriers such as rivers or mountains that could make short straight line distances on the map entirely inaccessible. This analysis points to opportunities for linking data from this DHS to Ministry of Health data on clinic staffing, client base, satisfaction of service delivery surveys, etc. in the future which would help to further understand the relationships between access to and use of basic services across sectors. Such analysis would foster integrated planning and development, and prioritize lower-cost measures such as mobile clinics and footpath rehabilitation which, to date, have received relatively little attention as important community level contributions to improving rural access, particularly for women, to existing services.

Evaluating the types of spatial relationships and constraints in the previous sections is even more important when considering investments to address barriers to transport and health service delivery. Based on a full set of DHS questions on all three (Ghana, Ethiopia, and Lesotho) DHS questionaires, Table 3 and the maps in this section illustrate the extent to which transport barriers on average across all clusters are identified by a majority of women as being “big problem” relative to other barriers to health service access. Because these barriers were each evaluated separately by survey participants and not ranked in order of difficulty or priority, the data does not allow for direct comparison of barriers to one another. Instead, each barrier is highlighted separately in the maps of Lesotho to follow to show the spatial variation.

Table 3. Summary table of country averages percent of women by cluster who identified each barrier as a “big problem” to accessing health services instead of as a “small problem.”

Figure 8. Average % of women by cluster who said “distance to health facility” was a big problem in access to health services.

As summarized in Table 3, both transport barriers in the set of DHS surveyed issues were identified by a large majority of women as being a “big problem” and not a “small problem” in comparison to other constraints on health service access. The map to the right shows that womens’ perceptions of distance as a barrier is further correlated with the location of their villages (clusters) relative to both roads and proximate health facilities. Comparing the average percentage of women by cluster who identify distance as a big problem with constituency road density reveals that clusters in constituencies with higher road densities have lower percentages of women who say distance is a big problem.

Figure 9. Average % of women by cluster who said “having to take transport” was a big problem to health service access.

Unlike the very clear pattern linking perceptions of distance to health facilities as a barrier with low road density, the barrier of having to take transport is a more diffuse problem. Figure 9 shows the distribution of the average percentage of women by cluster who identified “taking transport” as a big problem. In this case, a large percentage identified this issue as a big problem; however, the results do not appear to be correlated with existing transport or health infrastructure availability. A possible reason for this lack of obvious spatial correlations could be that cost, access to money within the household (or another non-spatial variable) are the primary drivers associated with this barrier instead of possible spatial determinants, such as availability of roads or services.

5.2.3 Barrier: All Barriers

Figure 10. Cluster percentages of all barriers to health service access and constituency road density in SW Lesotho.

Evaluating all of the barriers included in the DHS health service access questions reveals that for Lesotho, transport barriers dominate all others. Figure 10 is a zoom in to a particular area of Lesotho with poor access and limited road density. This zoom covers the project area for the World Bank supported Senqu-Senqunyane bridge project, and serves as a preliminary snapshot of access issues for the social assessment and baseline monitoring (Walker et al. 2005). In almost all cluster areas surveyed, distance and having to take transport account for at least 50% of barriers. Likewise, several of the health facilities located in the area are not utilized by respondents even though they may be located in close proximity to communities.

5.3 Distance, Mobility and Road Networks: What are the impacts of poor access?

What are the impacts of distance, mobility and size of road networks on access to health services? All of the issues raised above can be further analyzed and quantified by looking at the correlations between distance to a health facility, mobility of the population and density of the road networks. In this case, we calculated the distance of each cluster to the health facilities and divided them between those that were less than five kilometers and those that were further than five kilometers.

In reference to the questions on barriers to access, the role of distance and mobility is greatly affected by being further or closer to a health facility. Cost of treatment² paramount among the variables for women within 5km of a health facility and is twice as much as distance as a barrier. Over 5km from a health facility distance and mobility barriers rank equal to the cost of treatment. This suggests that while cost of treatment remains relatively constant regardless of distance from a facility, specific transport related barriers (distance and access to services) inhibit access to health facilities for populations located more than 5km from the sites.

Table 4 Lesotho: Barriers to Health Facilities and distance (less than and more than 5km)

Figure 11. Density of road network surrounding clusters greater and less than 5 km from a health facility

Analysis of DHS survey data on HIV/AIDS can also be enhanced when combined with transport network and other spatial data. In this case, several of the questions about HIV/AIDS are exactly the same in both the men’s and women’s questionnaires. This allows for sex disaggregation of results and illuminates the differential impacts of access to health services, public health information and the impact of HIV/AIDS on each group.

Table 5 disaggregates the data by country and sex. Table 6 looks at several of these same variables and adds the issue of distance to a health center. While there is little difference in men’s knowledge on HIV/AIDS depending on distance, there is a significant drop in women’s knowledge with greater distance. This underlines the importance of understanding gender mobility issues and barriers and the impact they can have on access to information and specifically public health information. It also underscores the role that poor transport (distance, services and road networks) can potentially have on health knowledge and eventual health outcomes.

Figure 12 is a zoomed-in view of the southwestern regions of Ethiopia. This map illustrates the variations in the percent of women who have heard of HIV/AIDS across Ethiopia and begins to highlight particular hotspots of poor knowledge in relation to distance to health services. It is clear that access to knowledge is not solely dependent on distance – in many cases there is poor knowledge in areas close to health services, and this may reflect the quality of services being offered. However, this kind of analysis gives a quick snapshot of the state of awareness and can help identify areas for HIV/AIDS outreach and, future transport investment aimed at facilitating access. Table 6 provides a summary of these same results dissaggregated spatially for survey clusters that contain a health center within a 5km buffer and those that do not.

The final analysis in this study focuses on the correlations between transport measures (road density by EA buffer) and general socio-economic population data. This analysis in general and the specific results for women’s education below are intended to highlight the importance of transport to achieving and evaluating the MDGs in different countries. As the graphs in Figures 13 and 14 highlight for Lesotho and Ethiopia, there is a strong positive correlation between availability of roads and women’s education levels. Although these results do not suggest a causal relationship between transport and education, they illustrate an important link worth further investigation.

Figure 13 Lesotho: Correlation of Road Density with Women’s Education Levels

Figure 14 Ethiopia: Correlation of Road Density with Women’s Education Levels

This study illustrates some of the basic links between transport and health, and highlights their implications for understanding the underlying dynamics of spatial exclusion across scales. There are many other possible applications of this approach and methodology. Carefully combining the types of data analyzed in this paper with other relevant metrics, such as transport cost, can help to further elucidate the social dimensions of transport programs. Most DHS include sections on education and wealth ranking. Both of these topics, if complemented by a few transport specific questions, could provide valuable inter-sectoral knowledge on barriers to access to education and correlations between wealth and mobility. Several (but not all) DHS also include information on social inclusion issues such as religion and ethnicity. These indicators, when combined with transport and other data layers, could support valuable initial analysis of the impact of mobility and access on inclusion, vulnerability, and isolation at a national level.

Overall, this pilot spatial analytic approach and cross-scale evaluation illustrate opportunities to improve:

Taken as a whole, the major results of this study reveal how opportunities for cross-sectoral analysis have improved as new information technologies, such as GIS, and cost-effective local data collection methodologies, such as geo-referencing, have emerged. As the transport sector increases its investments in Africa and moves from a project to a programmatic focus at a national level, the importance of identifying supporting technologies and approaches to monitoring the social impacts of investments and providing relevant information for decision support of planners and policy makers are paramount. The findings of the pilot analysis point to new opportunities for linking gender, transport, and health data across scales using spatial information technologies.

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Walker, W., S. Vajjhala, T. Phomane, N. Zaly, S. Moonyane, and M. Mokhoro, (2005). Ground Truthing: Mapping Mobility and Access in Rural Lesotho. The World Bank, Washington, D.C.

1 In the case of Ethiopia, the Southeastern district was missing from all major databases and there were no DHS enumeration area, road, or health center data available for this region.

2 The DHS survey does not define cost of treatment and it is possible that respondents include in this answer the cost of transport to access treatment. Adding a specific question on cost of transport to access healthcare (as the MoPWT in Lesotho had suggested), would help to eliminate this confusion and help to understand where the barriers are most pronounced (i.e., transport or healthcare costs) and what kinds of measures would be best to address them.