The solutions to today’s water and sanitation development challenges are right in front of us, provided we look for them. We are quietly reminded of this each time our research team visits a field site to assess the newest water treatment system. Arriving at the site, we typically find the new system alongside an old, broken filter, or next to a partially dismantled bicycle-driven water pump that had been touted in the international press as an inexpensive work of genius that would save the world, or near a perfectly functioning pit latrine that no one uses. Few remember who put these devices in place, how to fix them, why to use them, or whether life got better while using them. Meanwhile, as the team begins to evaluate the latest technology to provide clean water, a child shyly eyes us from behind the broken filter. She runs home afterwards to drink pathogen-laden water collected and carried by hand from a stagnant stream, just yards from the village open defecation zone that is discretely concealed in the underbrush. We wonder whether the latest incarnation of water service will give her clean water and begin to collect the evidence.
These filters were installed by a well-intentioned group that did only short term follow up, but removed by villagers after they clogged. Residents had no choice but to drink unfiltered, unsafe water.
Countless well-intentioned projects begin and end at enormous cost and effort globally, but they often leave stakeholders no better off, a grim reality those who work in the water sector know all too well. What works well in a North American or European lab can quickly fail in the humid tropics; when monsoons make dirt roads impassable, supply chain disruptions can cripple operation of small treatment plants. Too many organizations drill a well or distribute some point-of-use water treatment technologies and declare “mission accomplished” without any data collection to see if health has improved, which is the ultimate goal, and without any follow up support beyond the initial year or so.
For example, Small Water Enterprises (SWE) are community-based entrepreneurial water systems that provide the lion’s share of drinking water in many countries, and in a 2009 literature survey that scanned thousands of articles on SWEs, the Schwab research group did not find a single rigorous, evidence-based, peer-reviewed scientific study to show the efficacy of SWEs in providing potable water. Many of these SWEs have failed or will fail. But if we had evidence for approaches that work versus those that do not, we could break the cycle of neglect and failure that plagues the water and sanitation sector. With evidence, we can learn from our mistakes. With evidence, we might even learn how to take the next gizmo promising to save the world and actually save the world.
"The solutions to today’s water and sanitation development challenges are right in front of us, provided we look for them."
A major challenge for the next decade is to identify successful water and sanitation approaches through evidence-based research, which is a core philosophy underlying the mission of the JHU Global Water Program. Funding for research is scarce, however. Donors, both big and small, often say they are not interested in research, that they are interested in implementing solutions, that they want to their dollars to go to helping people directly, implying that research is a diversion. Nothing could be further from the truth. Evidence is what guides us and prevents our repeated follies.
In fact, building a toolbox of appropriate evidence-based solutions will save more in the long term. There are enormous financial and human costs associated with implementing an inappropriate technology or strategy that ultimately fails. The World Bank estimates that it will cost $9 billion per year to run the interventions just to provide basic water and sanitation coverage to meet the Millennium Development Goal targets, and up to $30 billion per year to provide universal coverage. But how many of these interventions have staying power? Research suggests that very few do, so we can expect to spend billions of dollars annually on solutions that are temporary at best.
Water is heavy. Everyday, millions of children all over the world walk for miles to collect water, which often turns out to be highly contaminated.
At the very least, implementing the wrong approach represents a missed opportunity. At most it represents nearly criminal neglect, because the burden of lack of access to clean water is tragically high. Dr. Schwab often tells students that water is heavy, and asks them to try carrying 20 liters of water around for a while, just to see what it is like. Every day, millions of people spend hours carrying water on their heads over many kilometers, sometimes developing neck problems. Asking students to carry water teaches them that water is heavy in the literal sense, but the rest of the course teaches them that water is heavy in the figurative sense. The burden of disease from unsafe water far outweighs the physical heaviness of water. Lack of access to clean water causes health problems like malnourishment and diarrhea, the number two killer of children under 5, and has social consequences, like preventing girls from attending school because they need to fetch water. Sustaining this crushing burden on the poor is the true cost of choosing the wrong water intervention, and this choice is largely sustained by neglect to gather or learn from scientific evidence.
"Through evidence-based research, we can find solutions that work."
At the Johns Hopkins University Global Water Program we are making tools to gather the evidence that will ultimately guide us to approaches with positive impact. We discovered a data gap on SWEs, so we are currently working on a study in Ghana to fill that gap. We are also developing a portable, rapid-response, comprehensive water quality screening “toolkit” which can be used to quantitatively detect key microbial and chemical contaminants. This kit involves user-friendly tools and methods for the intermittent monitoring and evaluation of the quality of water systems. Using this toolkit, our goal is to determine the efficiencies of various water treatment technologies using the selected water quality assessment tools. On a related research thrust, we are developing ways to creatively make use in advances on information technology, including real-time data collection on cell phones with geospatial accuracy, and eventually through wireless sensing networks. And in collaboration with the Center for Communications Programs, we are undertaking research in social science and human behavior to learn how to get the best results from our hygiene, water, and sanitation programs.
The context in which we develop these tools is international, but they have immediate translation to needs at home, especially for disaster relief. In the aftermath of Hurricane Katrina, many Americans found themselves resorting to sources with dubious quality, and fecal contamination in the streets of New Orleans was high. The U.S. was largely unprepared for this scenario. But should another Katrina strike the Atlantic coast, or a major earthquake hit California, the rapid-response toolkit and cell phone technologies that we develop internationally will help us at home. To get to that point, however, to create an arsenal of effective water and sanitation solutions, we need a major commitment from all in the water sector, including donors and implementers, to gather the evidence. Through evidence-based research, we can find solutions that work.
Members of a Global Water Program field survey team in Ghana, who are evaluating the efficacy of a community based water treatment system by collecting household data on health, hygiene, and water use practices.
- Hutton, G. and J. Bartram (2008). Global costs of attaining the Millennium Development Goal for water supply and sanitation. Bulletin of the World Health Organization 86: 13--19.
- Opryszko, M., H. Huang, et al. (2009). Data gaps in evidence-based research on small water enterprises in developing countries. Journal of water and health 7(4): 609.
- Schwab, K., K. Gibson, et al. (2007). Microbial and chemical assessment of regions within New Orleans, LA impacted by Hurricane Katrina. Environmental science & technology 41(7): 2401.