Using the power of big data to improve maternal health in Africa

Man standing in McMaster engineering lab with his arms crossed

Engineering professor Tom Wanyama uses his experience in AI and manufacturing to address health challenges in a new way. Photo credit: Jin Lee


Tom Wanyama has lots of ideas about how to improve maternal and infant health in his native Uganda.

He isn’t a medical doctor. He isn’t an international development specialist. And he clearly isn’t a mother (although he does have four children).

He’s an engineer.

More specifically, Wanyama is an assistant professor in McMaster’s W Booth School of Engineering Practice and Technology. His work focuses on using artificial intelligence in manufacturing – and he’s convinced that the technologies used to monitor and optimize those industrial processes can also be used to improve the health of mothers and babies in Uganda and other developing nations.

Wanyama is also now a recipient of a Queen Elizabeth II Diamond Jubilee Scholarship for Advanced Scholars, working on the Waterloo University-led “Water Security as a Foundation for Healthy Communities and Sustainable Livelihoods” project, of which McMaster is a key partner. He will be working with colleagues from McMaster, Waterloo and Uganda Christian University on initiatives aiming to improve maternal health by addressing issues around drinking water, sanitation and hygiene.

Wanyama, who grew up in Uganda’s Busia District, knows this is an uphill struggle. Although lower than those in many countries in Africa, including neighbours Kenya and Tanzania, Uganda’s mortality rates for mothers and babies are still some of the highest in the world. And he’s seen first-hand that external help is often a stop-gap solution.

“My experience has been that some help is more like firefighting – people address specific problems,” he explains. “There’s no water? Create a bore hole. Children are sick? Provide vaccinations. The problem is that the underlying factors and the core of why things are happening are not being addressed.”

That means that initiatives are launched, but don’t necessarily continue long-term. And because of a lack of continuity, Wanyama points out, organizations may duplicate efforts, or repeat initiatives that aren’t effective.

The problem? Lack of data that tells organizations whether what they’re doing actually achieves their objectives, and the artificial intelligence necessary to analyze what data does get collected.

Let’s say there’s a health centre in a rural village. Because sanitation is important, an NGO provides it with detergent and soap. There’s also a water pump on the property that provides clean water. But even with these interventions, mothers may not use the centre, or outcomes may be poor. Why?

That’s where Wanyama – and his experience working in AI and process improvement – comes in.

“In manufacturing, we use data to predict demand, monitor and predict quality, and so forth,” he says. “Why don’t we take the same knowledge and skills and apply it to maternal health? Why don’t we monitor the centre’s waste water for evidence of detergent use? Why don’t we put a sensor on the water pump to let us know if it’s being maintained?”

This kind of monitoring could also be used to improve access to doctors in rural areas. Wanyama explains that many rural health centres don’t have a permanent doctor on staff – instead, a doctor from a city will visit periodically. If the rural centre’s water pump isn’t working that day, or the electricity is down, or supplies have run out, the doctors’ visit is wasted – unless a data collection system could alert them in advance not to make the journey, or let them know that there was a working water pump in the next village.

Wanyama plans to start with water monitoring, but he says this type of approach to data could be used on a much wider scale – working with the wide network of cellphones across many countries in Africa to develop apps for expectant mothers, for example. With permission, these could then collect information about the women using them. And in places where medical record-keeping may be inconsistent, using a cellphone app could help fill in the gaps.

Eventually, the data collected – a mother’s medical history, genetic information, community, family situation and other information – could be used to create personalized health-care solutions, like flagging a mother for increased follow-up visits. Health centres may also be able to use data to predict when demand on their services will be higher. There’s lots of potential, Wanyama points out.

But for now, he’s starting small, working with his colleagues at McMaster and Uganda Christian University and focusing on water. The outcome of his QES-AS scholarship will be a project proposal – which means a lot of work to assess whether what he has in mind is actually possible.

“Many things that we are dealing with in terms of health are symptoms, not the problem itself – symptoms of a lack of income, low education levels, lack of family support, abuse, and so on,” Wanyama says. “When I talked to a Ugandan colleague of mine about this, he said that his big problem was that there were too many problems. Well, I say problem aren’t problems. They’re opportunities to find a solution.”

The Canadian Queen Elizabeth II Diamond Jubilee Scholarships (QES) is managed through a unique partnership of Universities Canada, the Rideau Hall Foundation (RHF), Community Foundations of Canada (CFC) and Canadian universities. The QES-AS is made possible with financial support from IDRC and SSHRC.

McMaster University is a key partner in the  University of Waterloo-led Canadian Queen Elizabeth II Diamond Jubilee Scholarships (QES): Advanced Scholars “Water Security as a Foundation for Healthy Communities and Sustainable Livelihoods” project. 

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