Epistemic status: after researching for more than 80 hours each, we are moderately certain that ceramic filters (CFs) can be more cost-effective than chlorination to prevent waterborne diseases at least in some—and possibly in many—LMICs. We are less certain of the real size of the effects from CFs, and how some factors like household sizes affect the final cost-effectiveness.
At least 1.7 billion people globally used drinking water sources contaminated with feces in 2022, leading to significant health risks from waterborne enteric infections. According to the Global Burden of Disease (GBD) 2019 study, more than 2.5% of total DALYs lost that year were linked to unsafe water consumption—and there is some evidence that this burden can be even bigger.
This makes the improvement of access to clean water a particularly pressing problem in the Global Health and Development area.
As a contribution to target this problem, we have put together areporton ceramic water filters as a potential intervention to improve access to safe water in low and medium income countries. This was written during our time as research fellows at Charity Entrepreneurship’s Research Training Program (Fall 2023).
In this post, we summarize the main findings of the report. Nonetheless, we invite people interested in the subject to check out thefull report, which provides much more detail into each topic we outline here.
Key takeaways:
There are several (controlled, peer-reviewed) studies that link the distribution of ceramic filters to less frequent episodes of diarrhea in LMICs. Those studies have been systematically reviewed and graded low to medium quality.
Existing evidence supports the hypothesis that ceramic filters are even more effective than chlorination to reduce diarrhea episodes. However, percentage reductions here should be taken with a grain of salt due to lack of masking and self-report and publication biases.
Despite limitations in current evidence, we are cautiously optimistic that ceramic filters can be more cost-effective than chlorination, especially in countries where diarrheal diseases are primarily caused by bacteria and protozoa (and not by viruses). Average household sizes can also play a role, but we are less certain on the extent to which this is true.
We provide a Geographic Weighted Factor Model and a country-specific back-of-the envelope analysis of the cost-effectiveness for a hypothetical charity that wants to distribute free ceramic filters in LMICs. Our central scenario for the cost-effectiveness of the intervention in the top prioritized country (Nigeria) is $8.47 U.S. dollars per DALY-averted.
We ultimately recommend that EA donors and meta-organizations should invest at least some resources in the distribution of ceramic filters, either by bringing up new charities in this area, or by supporting existing, non-EA organizations that already have lots of expertise in how to manufacture, distribute and monitor the usage of the filters.
Why ceramic filters?
There are plenty of methods to provide access to safe(r) water in very low-resource settings. Each one of those has some pros and cons, but ceramic filters stand out for being cheap to make, easy to install and operate, effective at improving health, and durable (they are said to last for a minimum of 2 years).
In short, a ceramic filter is a combination of a porous ceramic element and a recipient for the filtered water (usually made of plastic). Water is manually put into the ceramic part and flows through its pores due to gravity. Since pores are very small, they let water pass, but physically block bigger particles—including bacteria, protozoa and sediments—from passing. It is also common for manufacturers to add colloidal silver to the ceramic, which adds another layer of protection by acting as a biocide and preventing growth of bacteria on the surface of the filter.
(a)
(b)
Image of a bucket ceramic filter available for sale in Rwanda and Uganda (a) and a diagram of its internal anatomy (b). Source:Spouts of Water, n.d..
We have briefly investigated multiple point-of-use (POU) treatment methods suggested by UNICEF, and ultimately concluded that the properties of ceramic filters made them a good candidate for distribution in scale in low resource settings, with low unit cost and low instruction and maintenance burdens[1]. At the same time, we take advantage of the fact that GiveWell has already investigated (and funded) chlorination as a water treatment method, and use this as a benchmark to compare ceramic filters with.
How would a charity operate to promote the usage of ceramic filters?
The flowchart below provides a graphical representation of the Theory of Change (ToC) we idealize that a charity could implement to distribute free ceramic water filters to populations with low access to clean water in LMICs.
The proposed charity’s Theory of Change is structured around a series of activities leading to desired outputs, outcomes, and eventual impact. The initial phase consists of four key activities: (1) Identifying areas lacking access to clean water and affordable filtering solutions; (2) manufacturing ceramic filters; (3) distributing these filters at the household level; and (4) providing households with education on the proper use and maintenance of these filters. The successful execution of these activities is expected to yield two primary outputs: (5) Community members knowing how to correctly use the filters, and (6) consistently using them. The ultimate goal of this program, reflected in the outcomes and impacts, is threefold: (7) increasing access to cleaner drinking water, (8) significantly reducing the incidence of diarrhea and other waterborne illnesses, and (9) enhancing the overall health of the community.
In the full report, we discuss all of our assumptions and uncertainties behind this causal chain. But, in short, our current biggest concerns about this ToC are related to the ease of manufacturing filters locally (2); the logistics of distribution, filter lifespans and suitability of free versus paid (subsidized) distribution (3); and the rate of adherence (6).
What evidence is there to indicate ceramic filters can be an effective way of preventing diarrheal diseases in LMICs?
We have analyzed in total three (partially overlapping) systematic reviews that investigate ceramic water filters (among other POU water treatment methods). The more comprehensive of the three is a Cochrane Review by Clasen and colleagues (2015), so our analysis mostly relies on it.
According to this review, the pooled risk ratio for diarrhea episodes in the general population subject to POU ceramic filtration interventions was 0.39 (95% CI: 0.29-0.53, 12 studies—all of them cluster-RCTs -, moderate quality evidence, n=5,763, I²=91%). This means, on average, people in clusters that received ceramic filters reported suffering from 61% less episodes of diarrhea than people in control clusters. This is especially substantial because POU chlorination cluster-RCTs had a pooled effect of only 23% for reducing diarrhea episodes in this same review (RR 0.77, 95%CI 0.65-0.91, 14 studies, low quality evidence, n=30,746, I²=91%).
We performed our own subgroup analysis of the ceramic filtration studies selected by Clasen and his colleagues. In this analysis, we separately considered an intervention that provided Water, Sanitation and Hygiene (WASH) education together with delivering the filters. We also excluded one study conducted only with HIV-positive subjects, and a study that had been misclassified as using ceramic water filters, but actually used a membrane filter.
Our final estimate was that the distribution of ceramic filters with_out_ significant WASH education has a pooled effect of 53% for reducing diarrhea episodes (RR 0.47, 95% CI: 0.41-0.54, 8 studies, n=3,011). We also estimate that adding a WASH education component to the intervention may increase this effect by an additional 12 percentage points (RR 0.35, 95% CI: 0.26-0.47, 1 trial, n=432), but we put low weight on this number because it comes from a single study.
Besides RCTs, there are also some real-world examples that this sort of intervention can be implemented. While researching ceramic filters, we found at least8 organizationswho already work with local manufacturing and distribution of these filters in LMICs for quite a few years. For example, we have interviewed two field experts from Pure Home Water, a nonprofit from Ghana that has been using ceramic filters since 2015 to prevent transmission of water borne tropical diseases. These interviews helped us check on some assumptions from our ToC and polish some numbers from our cost-effectiveness analysis.
Where would this intervention be most cost-effective and likely to succeed?
To answer this question, we developed a Geographic Weighted Factor Model (GWFM) considering four factors:
Therate of DALYs lostdue to diarrheal diseases caused by bacteria and protozoa, attributed to unsafe water consumption per country(50% of the weight). This accounts for the scale of the problem in each country. However, we restrict our analysis to bacteria and protozoa because ceramic filters are not considered effective against viruses, and therefore should not be very cost-effective where disease burden from viruses is comparatively higher.
The Purchase Power Parityconversion factorsfrom the World Bank(25% of the weight). This was used as a proxy for the cost of operating in each country.
The averagehousehold sizefor the country_ (10% of the weight)_. We consider this relevant because, in general, we expect to distribute only one filter per household. Therefore, the more people in a given household, the more people served with the same initial cost. (While we see some theoretical reasons why the filter lifespan should also be reduced with greater usage, we expect this effect to be less than linear, so the cost-effectiveness would still increase in larger households).
The 2023Fragile State Index(15% of the weight). This is used as a way of de-prioritizing highly unstable countries that may be very difficult to work with/in. Besides using it as a weighted criteria, we also apply a hard cutoff on this factor to remove such countries.
The resulting GWFM was built in accordance with Charity Entrepreneurship’s guidelines for Weighted Factor Models. The five top prioritized countries according to the selected criteria and weights were[2]:
The costs considered were based on four organizations who reported prices on the ceramic filters they manufactured (on average, $17.62 per unit), plus a 50% delivery/overhead cost. We also separately consider the cost for delivering a WASH education package together with the filter (estimated at an additional $12.70 per household). These costs were divided by the country’s average household size and by the filter lifespans (conservatively set at 2 years) to get the costs per person served per year.
The effectiveness calculation per country was performed in a separate spreadsheet (with an accompanyingintroduction video). For this, we tried to emulate GiveWell’s analysis of chlorination interventions where possible. However, we diverge from it in that we use odds ratios for all-population diarrhea episodes (from our subgroup analysis of Clasen et al., 2015) and consider it a proxy for reductions in morbidity and mortality—GiveWell, instead, considered reductions in mortality of under-5 years-old children. We also introduce a new external validity adjustment to make reductions in diarrhea cases proportional to the relative burden caused by the relevant pathogen groups (bacteria and protozoa for ceramic filters; bacteria and viruses for chlorination).
The effectiveness calculations considered impacts coming from reductions in morbidity and mortality both for the under-5s and 5-and-over populations, according to GBD (2019) numbers, filtered for relevant etiologies and multiplied by the estimated effects of the interventions. For mortality and morbidity, we considered both direct reductions in enteric diseases and multiplied them by GiveWell’s estimate for the size of the Mills-Reinke phenomenon. We also considered medical costs averted from children under 5 years-old who would counterfactually need treatment; and estimated the developmental effects on the population up to 14 years old.
The following two tables summarize the results of our analysis. The first table compares the cost-effectiveness with and without a bundled WASH education component. The second table compares the cost-effectiveness (in GiveWell’s moral weight units, equivalent to 1 unit increase in log(consumption) for one individual over a year) for chlorination interventions and ceramic filter interventions. Chlorination interventions were evaluated both using GW’s original numbers and by replicating our analysis with the odds ratios for POU chlorination interventions from Clasen et al. (2015).
Table 1. Comparison of methodological differences betweenGiveWell (2022)analysis of chlorination interventions and our analysis of ceramic filters.
GiveWell (2022) on chlorination interventions
Present analysis on ceramic water filters
Primary measure
Primary measure was the risk ratio for all-cause mortality for children under 5 years old and for children and adults 5 years old or older.
Primary measure was the risk ratio for diarrhea episodes among the population of all ages.
Safe water vessels
Considered outside the scope of the intervention and discounted from the effect through an internal validity adjustment.
Considered an integral part of the intervention and accounted for in the unit cost of delivering the intervention.
WASH education
Considered outside the scope of the intervention and discounted from the effect through an internal validity adjustment.
Considered outside the scope of the intervention and discounted from the effect through a subgroup analysis of RCTs.
External validity adjustments
Adjusted by the proportion between mortality observed in control groups in the considered RCTs, versus deaths linked to water quality from GBD 2019.
Adjusted by the proportion of the burden of diarrheal diseases caused by bacteria and protozoa, versus all diarrheal diseases in the countries with RCTs considered, according to GBD 2019.
Table 2. Comparison of CEA results for water treatment interventions in Kenya.
Moral weight units per 100,000 people served per year*
Cost per person served per year (USD)
Moral weight units per USD $10,000 donated*
Country: Kenya
In-line chlorination—GiveWell’s original analysis
4,284
$1.68
255
Dispensers for Safe Water—GiveWell’s original analysis
2,616
$1.68
156
“Generic” chlorination intervention—our analysis
4,538
$1.60
270
“Generic” ceramic filtration intervention without education—our analysis
12,485
$3.44
363
Country: Malawi
Dispensers for Safe Water—GiveWell’s original analysis
6,000
$1.86
342
“Generic” chlorination intervention—our analysis
3,773
$1.60
235
“Generic” ceramic filtration intervention without education—our analysis
11,971
$3.09
387
Country: Uganda
Dispensers for Safe Water—GiveWell’s original analysis
3,125
$1.22
257
“Generic” chlorination intervention—our analysis
3,074
$1.60
192
“Generic” ceramic filtration intervention without education—our analysis
9,570
$2.12
452
_*Before leverage and funging adjustments. ** “Generic” here means we are considering the pooled risk ratios from studies listed in Clasen et al. (2015) (or a subgroup of these studies, for ceramic water filters), instead of a specific implementation (e.g., dispensers for safe water, in-line chlorination etc.). _
So, what is the bottom line?
Ceramic water filters appear to be a promising and cost-effective intervention for preventing waterborne diseases, and probably also all-cause mortality, in low and middle-income countries (LMICs).
Here are the key takeaways:
Cost-effectiveness: We found the cost-effectiveness of our proposed ceramic filter intervention to be $67 dollars per DALY in Kenya, $54 dollars per DALY in Uganda, and $8 dollars per DALY in Nigeria. Further, we found ceramic filters to be 1.3, 2.4, and 3.7 times more cost effective than chlorination in Kenya, Uganda, and Nigeria, respectively.
Ceramic filters compared to chlorination: We believe both ceramic filter and chlorination interventions are cost-effective, and the optimal choice depends on factors like disease prevalence and household size. Ceramic filters are often better suited for areas with more bacteria and protozoa-caused diarrhea cases and larger households, while chlorination may be preferable in regions with more viruses or smaller households. To explore these differences in more detail, we’ve created a CEA spreadsheet where you can input any country and compare the cost-effectiveness of ceramic filters and chlorination side-by-side.
Collaboration: EA donors and organizations should consider partnering with existing non-EA organizations already working with ceramic filters in LMICs. This collaboration can leverage existing expertise, avoid duplication of efforts, and potentially lead to faster, more effective, and culturally sensitive interventions that respect local communities.
Recommendations: Based on the available evidence, the report recommends that EA donors and organizations seriously consider investing in a ceramic filter charity, either by supporting existing charities or launching new ones focused on this intervention.
**Areas for further research: **
Investigating whether funders should allocate money towards existing charities, towards incubating new charities, or both.
Exploring evidence that directly links ceramic water filter usage to reductions in morbidity and mortality (instead of only diarrhea episodes).
Investigating the relationship between household sizes and filter lifespans, and possibly adjusting our CEA accordingly.
Investigating the potential value of comprehensive WASH interventions alongside ceramic filters to enhance overall health outcomes and cost-effectiveness.
Examining behavioral constraints to the adoption of ceramic filters, especially in top prioritized countries.
Using proper uncertainty intervals to model the cost-effectiveness, instead of point estimates of best and worst-case scenarios.
Experimenting with adjustments for biases in self-reported data and publication bias, or further looking for RCTs that are more resilient to these biases.
Overall, ceramic water filters offer a promising avenue for improving water quality and health in LMICs. While further research is needed to refine cost-effectiveness estimates and address implementation challenges, the potential benefits appear significant enough to warrant further investment and exploration.
Acknowledgements and final notes
Both authors contributed equally to this report.
We are extremely grateful to our advisors Leonie Falk and Erik Hausen for their guidance on this report; to Morgan Fairless for the review and suggestions; and to Joel McGuire and Jame Montavon for the informal reviews. We also thank Yvette Neh and Michael Anyekase from Pure Home Water for kindly sharing their time and knowledge with us. And, of course, we are grateful to Karolina Sarek and the whole CE staff who made RTP possible, and to our fellow colleagues from the RTP Fall 2023 cohort, for exchanging ideas with us and giving us support and encouragement.
This is not to say other methods can not be useful in certain scenarios. In particular, we recommend further research on solar disinfection methods, which seem potentially cost-effective in some particular settings.
Chad, Central African Republic, South Sudan, Somalia and Niger were also selected among the top 10 countries, in various positions. Yet, Chad, Central African Republic, South Sudan and Somalia were excluded due to our cutoff based on the Fragile State Index. And Niger was manually excluded because it underwent a hostile regime change in mid-2023, and we believe the latest Fragile State Index available does not reflect the new situation on the ground.
Why EA should (probably) fund ceramic water filters
Epistemic status: after researching for more than 80 hours each, we are moderately certain that ceramic filters (CFs) can be more cost-effective than chlorination to prevent waterborne diseases at least in some—and possibly in many—LMICs. We are less certain of the real size of the effects from CFs, and how some factors like household sizes affect the final cost-effectiveness.
At least 1.7 billion people globally used drinking water sources contaminated with feces in 2022, leading to significant health risks from waterborne enteric infections. According to the Global Burden of Disease (GBD) 2019 study, more than 2.5% of total DALYs lost that year were linked to unsafe water consumption—and there is some evidence that this burden can be even bigger.
This makes the improvement of access to clean water a particularly pressing problem in the Global Health and Development area.
As a contribution to target this problem, we have put together a report on ceramic water filters as a potential intervention to improve access to safe water in low and medium income countries. This was written during our time as research fellows at Charity Entrepreneurship’s Research Training Program (Fall 2023).
In this post, we summarize the main findings of the report. Nonetheless, we invite people interested in the subject to check out the full report, which provides much more detail into each topic we outline here.
Key takeaways:
There are several (controlled, peer-reviewed) studies that link the distribution of ceramic filters to less frequent episodes of diarrhea in LMICs. Those studies have been systematically reviewed and graded low to medium quality.
Existing evidence supports the hypothesis that ceramic filters are even more effective than chlorination to reduce diarrhea episodes. However, percentage reductions here should be taken with a grain of salt due to lack of masking and self-report and publication biases.
Despite limitations in current evidence, we are cautiously optimistic that ceramic filters can be more cost-effective than chlorination, especially in countries where diarrheal diseases are primarily caused by bacteria and protozoa (and not by viruses). Average household sizes can also play a role, but we are less certain on the extent to which this is true.
We provide a Geographic Weighted Factor Model and a country-specific back-of-the envelope analysis of the cost-effectiveness for a hypothetical charity that wants to distribute free ceramic filters in LMICs. Our central scenario for the cost-effectiveness of the intervention in the top prioritized country (Nigeria) is $8.47 U.S. dollars per DALY-averted.
We ultimately recommend that EA donors and meta-organizations should invest at least some resources in the distribution of ceramic filters, either by bringing up new charities in this area, or by supporting existing, non-EA organizations that already have lots of expertise in how to manufacture, distribute and monitor the usage of the filters.
Why ceramic filters?
There are plenty of methods to provide access to safe(r) water in very low-resource settings. Each one of those has some pros and cons, but ceramic filters stand out for being cheap to make, easy to install and operate, effective at improving health, and durable (they are said to last for a minimum of 2 years).
In short, a ceramic filter is a combination of a porous ceramic element and a recipient for the filtered water (usually made of plastic). Water is manually put into the ceramic part and flows through its pores due to gravity. Since pores are very small, they let water pass, but physically block bigger particles—including bacteria, protozoa and sediments—from passing. It is also common for manufacturers to add colloidal silver to the ceramic, which adds another layer of protection by acting as a biocide and preventing growth of bacteria on the surface of the filter.
(a)
(b)
Image of a bucket ceramic filter available for sale in Rwanda and Uganda (a) and a diagram of its internal anatomy (b). Source: Spouts of Water, n.d..
We have briefly investigated multiple point-of-use (POU) treatment methods suggested by UNICEF, and ultimately concluded that the properties of ceramic filters made them a good candidate for distribution in scale in low resource settings, with low unit cost and low instruction and maintenance burdens[1]. At the same time, we take advantage of the fact that GiveWell has already investigated (and funded) chlorination as a water treatment method, and use this as a benchmark to compare ceramic filters with.
How would a charity operate to promote the usage of ceramic filters?
The flowchart below provides a graphical representation of the Theory of Change (ToC) we idealize that a charity could implement to distribute free ceramic water filters to populations with low access to clean water in LMICs.
The proposed charity’s Theory of Change is structured around a series of activities leading to desired outputs, outcomes, and eventual impact. The initial phase consists of four key activities: (1) Identifying areas lacking access to clean water and affordable filtering solutions; (2) manufacturing ceramic filters; (3) distributing these filters at the household level; and (4) providing households with education on the proper use and maintenance of these filters. The successful execution of these activities is expected to yield two primary outputs: (5) Community members knowing how to correctly use the filters, and (6) consistently using them. The ultimate goal of this program, reflected in the outcomes and impacts, is threefold: (7) increasing access to cleaner drinking water, (8) significantly reducing the incidence of diarrhea and other waterborne illnesses, and (9) enhancing the overall health of the community.
In the full report, we discuss all of our assumptions and uncertainties behind this causal chain. But, in short, our current biggest concerns about this ToC are related to the ease of manufacturing filters locally (2); the logistics of distribution, filter lifespans and suitability of free versus paid (subsidized) distribution (3); and the rate of adherence (6).
What evidence is there to indicate ceramic filters can be an effective way of preventing diarrheal diseases in LMICs?
We have analyzed in total three (partially overlapping) systematic reviews that investigate ceramic water filters (among other POU water treatment methods). The more comprehensive of the three is a Cochrane Review by Clasen and colleagues (2015), so our analysis mostly relies on it.
According to this review, the pooled risk ratio for diarrhea episodes in the general population subject to POU ceramic filtration interventions was 0.39 (95% CI: 0.29-0.53, 12 studies—all of them cluster-RCTs -, moderate quality evidence, n=5,763, I²=91%). This means, on average, people in clusters that received ceramic filters reported suffering from 61% less episodes of diarrhea than people in control clusters. This is especially substantial because POU chlorination cluster-RCTs had a pooled effect of only 23% for reducing diarrhea episodes in this same review (RR 0.77, 95%CI 0.65-0.91, 14 studies, low quality evidence, n=30,746, I²=91%).
We performed our own subgroup analysis of the ceramic filtration studies selected by Clasen and his colleagues. In this analysis, we separately considered an intervention that provided Water, Sanitation and Hygiene (WASH) education together with delivering the filters. We also excluded one study conducted only with HIV-positive subjects, and a study that had been misclassified as using ceramic water filters, but actually used a membrane filter.
Our final estimate was that the distribution of ceramic filters with_out_ significant WASH education has a pooled effect of 53% for reducing diarrhea episodes (RR 0.47, 95% CI: 0.41-0.54, 8 studies, n=3,011). We also estimate that adding a WASH education component to the intervention may increase this effect by an additional 12 percentage points (RR 0.35, 95% CI: 0.26-0.47, 1 trial, n=432), but we put low weight on this number because it comes from a single study.
Besides RCTs, there are also some real-world examples that this sort of intervention can be implemented. While researching ceramic filters, we found at least 8 organizations who already work with local manufacturing and distribution of these filters in LMICs for quite a few years. For example, we have interviewed two field experts from Pure Home Water, a nonprofit from Ghana that has been using ceramic filters since 2015 to prevent transmission of water borne tropical diseases. These interviews helped us check on some assumptions from our ToC and polish some numbers from our cost-effectiveness analysis.
Where would this intervention be most cost-effective and likely to succeed?
To answer this question, we developed a Geographic Weighted Factor Model (GWFM) considering four factors:
The rate of DALYs lost due to diarrheal diseases caused by bacteria and protozoa, attributed to unsafe water consumption per country (50% of the weight). This accounts for the scale of the problem in each country. However, we restrict our analysis to bacteria and protozoa because ceramic filters are not considered effective against viruses, and therefore should not be very cost-effective where disease burden from viruses is comparatively higher.
The Purchase Power Parity conversion factors from the World Bank (25% of the weight). This was used as a proxy for the cost of operating in each country.
The average household size for the country_ (10% of the weight)_. We consider this relevant because, in general, we expect to distribute only one filter per household. Therefore, the more people in a given household, the more people served with the same initial cost. (While we see some theoretical reasons why the filter lifespan should also be reduced with greater usage, we expect this effect to be less than linear, so the cost-effectiveness would still increase in larger households).
The 2023 Fragile State Index (15% of the weight). This is used as a way of de-prioritizing highly unstable countries that may be very difficult to work with/in. Besides using it as a weighted criteria, we also apply a hard cutoff on this factor to remove such countries.
The resulting GWFM was built in accordance with Charity Entrepreneurship’s guidelines for Weighted Factor Models. The five top prioritized countries according to the selected criteria and weights were[2]:
Nigeria
Burundi
Cameroon
Eritrea
Mali
How cost-effective can this intervention be?
We have assembled some back-of-the-envelope calculations (see video here) of the cost-effectiveness of this intervention. These can be adapted to any country for which we have found underlying data. In our full report, we provide estimates for Kenya, Malawi and Uganda (because they were the countries considered in GiveWell’s previous cost-effectiveness analysis of chlorination interventions), and for Nigeria (the top prioritized country in our GWFM).
The costs considered were based on four organizations who reported prices on the ceramic filters they manufactured (on average, $17.62 per unit), plus a 50% delivery/overhead cost. We also separately consider the cost for delivering a WASH education package together with the filter (estimated at an additional $12.70 per household). These costs were divided by the country’s average household size and by the filter lifespans (conservatively set at 2 years) to get the costs per person served per year.
The effectiveness calculation per country was performed in a separate spreadsheet (with an accompanying introduction video). For this, we tried to emulate GiveWell’s analysis of chlorination interventions where possible. However, we diverge from it in that we use odds ratios for all-population diarrhea episodes (from our subgroup analysis of Clasen et al., 2015) and consider it a proxy for reductions in morbidity and mortality—GiveWell, instead, considered reductions in mortality of under-5 years-old children. We also introduce a new external validity adjustment to make reductions in diarrhea cases proportional to the relative burden caused by the relevant pathogen groups (bacteria and protozoa for ceramic filters; bacteria and viruses for chlorination).
The effectiveness calculations considered impacts coming from reductions in morbidity and mortality both for the under-5s and 5-and-over populations, according to GBD (2019) numbers, filtered for relevant etiologies and multiplied by the estimated effects of the interventions. For mortality and morbidity, we considered both direct reductions in enteric diseases and multiplied them by GiveWell’s estimate for the size of the Mills-Reinke phenomenon. We also considered medical costs averted from children under 5 years-old who would counterfactually need treatment; and estimated the developmental effects on the population up to 14 years old.
The following two tables summarize the results of our analysis. The first table compares the cost-effectiveness with and without a bundled WASH education component. The second table compares the cost-effectiveness (in GiveWell’s moral weight units, equivalent to 1 unit increase in log(consumption) for one individual over a year) for chlorination interventions and ceramic filter interventions. Chlorination interventions were evaluated both using GW’s original numbers and by replicating our analysis with the odds ratios for POU chlorination interventions from Clasen et al. (2015).
Table 1. Comparison of methodological differences between GiveWell (2022) analysis of chlorination interventions and our analysis of ceramic filters.
Table 2. Comparison of CEA results for water treatment interventions in Kenya.
_*Before leverage and funging adjustments. ** “Generic” here means we are considering the pooled risk ratios from studies listed in Clasen et al. (2015) (or a subgroup of these studies, for ceramic water filters), instead of a specific implementation (e.g., dispensers for safe water, in-line chlorination etc.). _
So, what is the bottom line?
Ceramic water filters appear to be a promising and cost-effective intervention for preventing waterborne diseases, and probably also all-cause mortality, in low and middle-income countries (LMICs).
Here are the key takeaways:
Cost-effectiveness: We found the cost-effectiveness of our proposed ceramic filter intervention to be $67 dollars per DALY in Kenya, $54 dollars per DALY in Uganda, and $8 dollars per DALY in Nigeria. Further, we found ceramic filters to be 1.3, 2.4, and 3.7 times more cost effective than chlorination in Kenya, Uganda, and Nigeria, respectively.
Ceramic filters compared to chlorination: We believe both ceramic filter and chlorination interventions are cost-effective, and the optimal choice depends on factors like disease prevalence and household size. Ceramic filters are often better suited for areas with more bacteria and protozoa-caused diarrhea cases and larger households, while chlorination may be preferable in regions with more viruses or smaller households. To explore these differences in more detail, we’ve created a CEA spreadsheet where you can input any country and compare the cost-effectiveness of ceramic filters and chlorination side-by-side.
Collaboration: EA donors and organizations should consider partnering with existing non-EA organizations already working with ceramic filters in LMICs. This collaboration can leverage existing expertise, avoid duplication of efforts, and potentially lead to faster, more effective, and culturally sensitive interventions that respect local communities.
Recommendations: Based on the available evidence, the report recommends that EA donors and organizations seriously consider investing in a ceramic filter charity, either by supporting existing charities or launching new ones focused on this intervention.
**Areas for further research: **
Investigating whether funders should allocate money towards existing charities, towards incubating new charities, or both.
Exploring evidence that directly links ceramic water filter usage to reductions in morbidity and mortality (instead of only diarrhea episodes).
Investigating the relationship between household sizes and filter lifespans, and possibly adjusting our CEA accordingly.
Investigating the potential value of comprehensive WASH interventions alongside ceramic filters to enhance overall health outcomes and cost-effectiveness.
Examining behavioral constraints to the adoption of ceramic filters, especially in top prioritized countries.
Using proper uncertainty intervals to model the cost-effectiveness, instead of point estimates of best and worst-case scenarios.
Experimenting with adjustments for biases in self-reported data and publication bias, or further looking for RCTs that are more resilient to these biases.
Overall, ceramic water filters offer a promising avenue for improving water quality and health in LMICs. While further research is needed to refine cost-effectiveness estimates and address implementation challenges, the potential benefits appear significant enough to warrant further investment and exploration.
Acknowledgements and final notes
Both authors contributed equally to this report.
We are extremely grateful to our advisors Leonie Falk and Erik Hausen for their guidance on this report; to Morgan Fairless for the review and suggestions; and to Joel McGuire and Jame Montavon for the informal reviews. We also thank Yvette Neh and Michael Anyekase from Pure Home Water for kindly sharing their time and knowledge with us. And, of course, we are grateful to Karolina Sarek and the whole CE staff who made RTP possible, and to our fellow colleagues from the RTP Fall 2023 cohort, for exchanging ideas with us and giving us support and encouragement.
For questions about the content of this research, please contact Bernardo Baron at bc.bernardo@hotmail.com and Juan Benzo at jfbenzo13@gmail.com. For questions about the research process, please contact Leonie Falk at leonie@charityentrepreneurship.com.
Notes
This is not to say other methods can not be useful in certain scenarios. In particular, we recommend further research on solar disinfection methods, which seem potentially cost-effective in some particular settings.
Chad, Central African Republic, South Sudan, Somalia and Niger were also selected among the top 10 countries, in various positions. Yet, Chad, Central African Republic, South Sudan and Somalia were excluded due to our cutoff based on the Fragile State Index. And Niger was manually excluded because it underwent a hostile regime change in mid-2023, and we believe the latest Fragile State Index available does not reflect the new situation on the ground.