Over the period of the Millennium Development Goals (2000-15), it became clear that there was a pressing need and an increasing capacity for a ‘data revolution’ to inform the global health development agenda. In most developing countries, data on key indicators were collected through laborious and retrospective surveys that were as much as five years out-of-date, or through passive reporting systems that relied on routinely generated health facility data. Gaps in the primary data were filled by modelled estimates, which often relied on inadequate assumptions.

Recognition of this gap led the United Nations to convene an International Expert Advisory Group on a Data Revolution for Sustainable Development. This group released the ‘A World That Counts: Mobilising the Data Revolution for Sustainable Development’ report which highlighted the need for better data and statistics to help governments track progress.¹ The Sustainable Development Goals have been closely tied to the data revolution from their outset.

In many Low and Middle Income Countries (LMICs), health information and civil and vital statistics systems are underdeveloped. Most events such as births, morbidity and deaths also occur outside the reach of these systems and are as such not officially captured.² Additionally, data collection, when done, is often inconsistent, quality is poor and most data remain unprocessed for use.³ Consequently, governments and healthcare organizations lack reliable systems for data collection, verification and aggregation⁴ as well as capacity for analyses, interpretation and dissemination to address health challenges. In rural and remote geographies that bear a disproportionately higher burden of poor health outcomes, obtaining credible data can be even more difficult due to constraints associated with extreme poverty, illiteracy, insecurity, poor infrastructure and skewed distribution of human and material resources. This lack of health information undermines evidence informed policy-making, program design, implementation, monitoring and service delivery,⁵ further exacerbating inequalities.

The need for surveillance systems and periodic health surveys

In high income settings, data from well-developed public health surveillance systems have been used to determine the burden of disease, identify risk factors and to inform immediate public health action and policy on conditions as diverse as Acute Flaccid Paralyses, childhood overweight and obesity, levels of physical activity, and sporting injuries among others.⁶

To address the problem of poor civil registration systems in LMICs, governments and other stakeholders typically develop localized surveillance programs. These systems capture data from sample populations, which are used centrally to inform policy and programs. For example, some countries that have not achieved universal civil registration have implemented SAVVY (SAmple Vital registration with Verbal autopsY) to improve the quality of vital statistics. SAVVY addresses short- to medium-term needs for critical information on births, deaths, and cause of death at the population level.⁷ Other systems that capture information on both health and vital events on sample populations include Health and Demographic Surveillance Systems (HDSSs) established and operated by national public health institutes or institutions of higher learning. HDSSs also provide platforms for health and population research, generate regular population and health statistics and share data publicly to enhance their utility.⁸

In LMICs, the planning, implementation and evaluation of health programmes at central level is increasingly informed by periodic regional or national population surveys. These include population-level surveys such as the Demographic and Health Surveys, Multiple Cluster Indicator Surveys, AIDS Indicator Surveys and Malaria Indicator Surveys among others. On the other hand, planning for health service delivery is informed by facility based surveys such as the Service Availability and Readiness Assessments, and Service Provision Assessments. These surveys assess the actual service delivery infrastructure, capacity to provide services, and quality and quantity of services provided.⁹

Problems with current data systems in LMICs

Periodic population-level and health facility surveys are costly, usually rely on donor funding and are thus not locally sustainable. Data from these surveys may find utility at macro-level (global and or national) program planning and policy development. However, centralized planning could render these surveys insensitive to nuanced sub-national health system information needs. Implementation over large geographical areas (regional or national) could also mean that their indicator estimates often mask gross local area disparities. Furthermore, these surveys are implemented every three to five years and may be unresponsive to rapidly changing local area priorities. Consequently, these factors imply that these surveys have limited utility to local health systems and communities.

With advancement in technology and changes in systems of governance e.g. devolution of health services to sub-national level in Kenya, there is increased capacity and opportunity for a locally-oriented data revolution in which local health systems and communities generate and use their own data to plan, implement and evaluate their health programs. To contribute to the goal of universal health coverage and the SDG agenda, local health ecosystems must be strengthened to generate health information that addresses their own unique health priorities, that is more up to date, sustainable, readily accessible, easy to interpret and use locally, and which can potentially feed into national data platforms.

The Aga Khan University together with two local health authorities in the coastal area of Kenya developed a strategy to address these issues. This approach consists of a system to capture the demographic and health information of this area, nested on the government’s community health strategy.¹⁰ The system, briefly described below, has dual aims which include (i) strengthening the capacity of the local department of health for collection, processing and use of population-level health and vital events data; and (ii) provide a platform serving the University’s needs for population-level research and academic programming. In this viewpoint, we describe the development and utility of the system within the first aim, while its epidemiological utility in the second aim has been described elsewhere.¹¹

DESCRIPTION OF KALOLENI/RABAI COMMUNITY HEALTH AND DEMOGRAPHIC SURVEILLANCE SYSTEM (KRHDSS)

Briefly, it consists of a biannually updated population and health information registry of approximately 92,000 residents in 18,337 households within 112 villages in the rural Kaloleni and Rabai sub-Counties in the Coastal Area of Kenya. This platform is nested on the Kenya government community health strategy and data are collected by community health volunteers (CHVs) during their routine health promotion and education activities in the households. The project team provides regular refresher training, quality control and supervision of household data collection by CHVs as well as supports the use of the data for community-level planning and mobilization of health activities. Since 2017, seven biannual rounds of electronic data collection have been completed, which capture information on about 40 demographic, health, social determinants of disease and vital events. The indicators and their definitions are based on the Ministry of Health household-level data collection tool,¹⁰ and can be adapted to local needs and priorities.

These data are archived electronically and households and residents are allocated unique IDs through which individual information is linked longitudinally across data collection rounds. These data are also accessible to the local department of health for planning of health interventions.¹¹

The data are analyzed to produce reports of indicator estimates and trends. Aggregate data are shared with the health system management for decision-making and updating the health information system while data disaggregated by village or community health unit are discussed and shared with CHVs and community health officers for community-level feedback and activity planning during community health dialogues. The sequence of activities within a typical KRHDSS surveillance cycle is presented in Figure 1. To allow more in-depth exploration of social determinants of health in the local context, these data can also be linked with those form other sources e.g. geolocation linkage with data on physical infrastructure, climate and physical environment, population density, land use, mobile phone coverage and use among others.

Figure 1.The Kaloleni-Rabai Health and Demographic Surveillance System (KRHDSS) cycle.

Development of community health units, selection and training of CHVs and data collection.

Development of this system involved consultations with community members, village and government administration and public health officials in the target areas. In these meetings, the purpose of the project was explained and the support sought from these stakeholders. Community health units were established and CHVs selected by the community members following the Ministry of Health guidelines.¹⁰ The selected CHVs in each community health unit were then trained on data collection by project and Ministry of Health personnel.

Refresher training is conducted at the beginning of each biannual data collection round. Trained CHVs are allocated between 50 and 100 households for data collection, during which each CHV is visited at least twice for supportive supervision. The estimated per capita cost of one biannual cycle is USD 0.82 and USD 4.12 per household.

Data interpretation, dissemination and use community level

Interpretation of the results of data analyses include discussions between public health personnel, CHVs and the project team at the beginning of each refresher training session. It involves an indicator-by-indicator examination of estimates from the previous round and a review of the trends to the current round. Based on these discussions, the teams identify priority indicators for health promotion and education. They also receive a summary report of findings for community dissemination and to support their efforts to mobilize community health activities.

Data use by the local Department of Health and other stakeholders

The local department of health is using these data in planning mobilization and outreach activities to villages with poor coverage or uptake of interventions. For example, villages with poor WaSH indicators have benefited from intensified mobilization and support for pit latrine construction and installation of handwashing facilities while those with low usage of insecticide treated nets are targeted during mass net distribution campaigns. The demographic and household membership data have also been used in filariasis eradication campaigns, defaulter tracing e.g. for immunizations, planning and budgeting for activities while the local administration has used them to guide planning for relief food distribution during drought. Additionally, the local public health officials have been extracting and synthesizing data summaries to update the community level health information system, thereby contributing to the National Health Management Information System.

What has been the impact?

The engagement of CHVs in this program has enhanced their retention (over 94% retained over the 3 years), increased contact with community and lead to enhancement of efforts in household and community-level health promotion and education and subsequently improvements in community health indicators.

This work demonstrates the feasibility of utilizing existing community health structures to collect locally relevant health information.

What are the challenges?

Challenges to establishing a successful community health surveillance platform relate to building and sustaining local community buy-in, shortage of literate local community resource persons who can be trained on collection and dissemination of health information using digital technologies and syncing with the needs of the local health system to ensure uptake at the official level. These can be mitigated by building relationships and trust with the local community and health system, over a period of time. This would entail ensuring community participation from the onset, for example, in identification of qualified local implementers, fostering local relevance of the program outputs through consultations with the local health system management in the initial phases and providing timely and useful feedback and results of analyses to inform health action.

CONCLUSIONS

The approach of integrated community-oriented health information system can mitigate challenges associated with traditional routine population data collection in underserved populations. Providing regular training opportunities and supportive supervision improves availability of quality data for informed decision making and planning. This model is inexpensive, replicable and scalable, strengthens local community-based health information systems and enhances the utilization of data for decision making at the local level.

Acknowledgements

The Community and Community Health Volunteers whose involvement and work is highlighted in this viewpoint.

Funding

None.

Authorship contributions

AKN and SL conceived the idea presented in this manuscript. The first author developed the first draft and all authors contributed to editing and finalizing the write-up.

Conflicts of interest

The authors completed the ICMJE Unified Competing Interest form on http://www.icmje.org/disclosure-of-interest/ (available upon request from the corresponding author), and declare no conflicts of interest.

Correspondence to:

Anthony K Ngugi (PhD, DLSHTM),

Department of Population Health,

Medical College (East Africa).

Aga Khan University,

Nairobi, Kenya.

[email protected]