For General Release – Summary of: Average Household Size and the Eradication of Malaria
By Lena Huldén, Ross McKitrick and Larry Huldén
Journal of the Royal Statistical Society Series A, October 2013 Online at http://onlinelibrary.wiley.com/doi/10.1111/rssa.12036/abstract Document identifier: DOI: 10.1111/rssa.12036;
Abstract
Malaria has disappeared in some countries but not others, and an explanation for the pattern remains elusive. We show that the probability of malaria eradication jumps sharply when average household size drops below four persons. Part of the effect commonly attributed to income growth is likely due to declining household size. DDT usage plays only a weak role. Warmer temperatures are not associated with increased malaria prevalence. We propose that household size matters because malaria is transmitted indoors at night. We test this hypothesis by contrasting malaria with dengue fever, another mosquito-borne illness spread mainly by daytime outdoor contact.
Background
Malaria is a parasitic disease that is transmitted to humans by infected Anopheles mosquitoes. It infects red blood cells, causing anemia, nausea, fever and sometimes death. There are about 225 million cases annually leading to 800 000 fatalities, of which 90 percent are in Africa, and most of whom are children.
It is a common misconception that malaria is a tropical disease. Although that is where it remains prevalent, it used to occur throughout the world, in all climate zones, from the tropics to the coast of the Arctic Sea (up to 70° N latitude). Malaria was endemic in Europe and North America during the 20th century, but has largely disappeared and has been unable to re-establish itself there in spite of frequent annual importation of cases.
An interesting aspect of this history is that the disease disappeared in many countries that made no special efforts to eradicate it, while remaining prevalent in other countries that tried. Numerous explanations for the global pattern of eradication have been suggested, such as a change in the feeding pattern of the insects, draining of wetlands, or intensive use of the insecticide DDT (dichlorodiphenyltrichloroethane). Despite superficial plausibility, such explanations begin to fail upon close examination. With regard to DDT, for instance, while about 75% of the world used it, with an average application interval of over 15 years, malaria only disappeared in 43% of the world’s countries.
This study looks at the connection between declining average household size and the disappearance of malaria. The ongoing prevalence of malaria in tropical countries suggests a connection with socioeconomic conditions, but explanations have been lacking as to specific mechanisms by which the disease is affected by poverty. Back in the 1930s, Sidney Price James observed that the number of malaria cases was always higher in cottages in which big families slept together in one room, which was especially the case among the poor. This received little attention subsequently and research efforts focused on other factors.
In a 2009 analysis of the malaria trend in Finland over the interval 1750–2006, Lena and Larry Huldén noted that while many standard theories of malaria disappearance had little explanatory power, mean household size appeared to correlate very closely over a long interval with the decline in malaria cases, which led them to ask whether this pattern might hold true globally. Together with economist Ross McKitrick, they have now developed and analyzed a large international data base and found that James’ early conjecture appears to have been correct.
Study details
Data on malaria, insect vectors, demographic factors, sociological factors, and environmental factors for 232 countries or corresponding administrative units were compiled. Data for the year 2000 or the closest year thereto were obtained. Of these 220 countries, malaria was never endemic in 32, remains prevalent in 106 and has been eradicated from 82. Mongolia is the only country with an indigenous vector species but no historical or recent malaria. Thus indigenous malaria vectors (Anopheles species) are known from 188 countries, which is the sample for the analysis.
Explanatory variables include Gross Domestic Product (GDP) per capita, household size, female literacy, urbanization and slums, latitude, mean temperature, forest coverage, Muslim population, national DDT usage, population density and national mean temperature (over the 1980-2008 interval).
The authors used regression analysis to determine which factors affect the probability that malaria will have been eradicated from a country, and, among those countries where it is still present, what affects the disease incidence in the population.
The authors included the Muslim fraction in society as an explanatory variable because households in Muslim countries are characterized by a gender-segregated sleeping arrangements which, in varying degree, divides the household into smaller units depending on how strictly the practice is applied. Hence these are countries that may have relatively large households on average, but effective household sizes below four persons as regards sleeping arrangements.
Note: DDT Usage
The only countries that use DDT for malaria vector control are those that have malaria, so the presence of malaria strongly predicts the use of DDT. Naively putting a DDT usage measure into the model would give results that apparently suggest DDT causes malaria.
The remedy for this problem is to obtain a statistical instrument that measures the the effect of DDT usage on malaria frequency and eradication probability, independent of a country’s decision to use it in response to the presence of malaria. One aspect of the usage decision that was outside the control of most countries was the move by the United States to ban the production and use of DDT in 1971, which marked the start of worldwide efforts to withdraw the product from usage due to environmental concerns.
Figure 1 (below) shows the fraction of countries in our sample with malaria, the fraction using DDT, and the ratio of the two, by year, from 1951 to 2005. In 1951, 81% of the countries in our sample experienced malaria and 63% used DDT, a usage ratio of 0.78. This declined relatively steadily until the 1990s. As of 1971, 55% experienced malaria and 33% were using DDT, yielding a usage ratio of 0.60. In the 1990s the usage ratio began falling more rapidly, such that by 2005, 48% still experience malaria but only 4% use DDT, a ratio of 0.08.
Conditional on a country already having experienced malaria, an aggressive malaria control stance would be indicated by a willingness to use DDT right up to the year in which malaria was eradicated, despite the international pressure not to do so. The authors therefore defined a variable indicating if the year in which a country ceased using DDT was the same as the year malaria disappeared, or one or two years after that. This describes 18% of the sample, and was interpreted as an indication of aggressive DDT usage.
 |
Figure 1. By year: fraction of countries in our sample in which malaria is still present (mal_still, dashed line), DDT is still used (ddt_still, solid line) and the ratio of the two (dotted line). Vertical dash line: 1971, year US banned DDT. |
Results
What increases the probability of malaria eradication?
The table below presents some key results regarding factors affecting the probability of success in malaria eradication.
| Explanatory variable | Effect on the probability of malaria eradication | |
| Higher income | positive | significant |
| Avg household size under 4 persons | positive | significant |
| Higher population density | positive | significant |
| Higher population growth rate | negative | weakly significant |
| % living in urban area | positive | significant |
| % Muslim | positive | significant |
| Mean national temperature | positive | significant |
| DDT used aggressively | positive | insignificant |
| Sample size | 188 | |
| Fraction of variance explained by model | 78.3% |
Household Size Effect
The household size effect shows up strongly when measured as a binary indicator of whether a country’s average household size is below a certain number of persons or not. The largest effects arise when the threshold is set to 4.0 or 4.5 persons: in these cases the threshold effect is larger than that associated with a one-standard deviation increase in real income.
In the Figure, filled circles show the effect when household size drops below the indicated threshold, with 
uncertainty ranges shown. The solid line shows the effect associated with a one standard deviation increase in average income, and the dotted lines show the corresponding ![clip_image006[1]](http://wattsupwiththat.files.wordpress.com/2013/11/clip_image0061.gif "clip_image006[1]"){kind=small}
ranges shown.
 |
TemperatureIf one looks at annual mean temperature in isolation, it could easily yield the mistaken view that higher temperature results in a higher likelihood of malaria occurring in a country. For instance, a simple comparison of histograms showing the fraction of countries by temperature, dividing the sample into places where malaria has been eradicated (top panel) versus where it is still present (bottom panel), could lead to the inference that the higher the mean annual temperature, the greater the number of countries with malaria.
But this is incorrect because it fails to control for the influences of income, household size and other socioeconomic characteristics. The multivariate analysis shows that when these factors are controlled, higher temperatures are actually associated with a small but significant increase in the probability of malaria eradication. |
What factors decrease malaria incidence?
The table below presents some key results regarding factors affecting the number of cases per 100,000 each year in countries where malaria is still present.
| Explanatory Variable | Effect on rates of malaria infection | |
| Higher income | negative | significant |
| Avg household size under 4 persons | negative | significant |
| Higher population density | negative | insignificant |
| Higher population growth rate | negative | insignificant |
| % living in urban area | negative | insignificant |
| % Muslim | negative | significant |
| Mean national temperature | negative | insignificant |
| DDT used aggressively | negative | insignificant |
| Sample Size | 188 | |
| Fraction of variance explained by model | 0.306 |
The regression results show that when household size drops below a four-person threshold, about one-third of the effect that would otherwise be attributed to income disappears and instead is attributable to small household size.
Regarding temperature, the analysis of disease incidence again shows that higher temperatures, if anything, are associated with lower disease incidence, but the effect is statistically insignificant.
An Explanatory Mechanism
The mosquitoes responsible for malaria pick up the parasite from humans. At the local level, practically all Anopheles species feed at night. The female mosquito gets the infection from a human blood meal. After egg laying it returns to the same approximate location for another blood meal. The parasite multiplies sexually in the mosquito. The process takes ~10–16 days and is completed when the infective form of the parasite reaches the salivary glands of the mosquito, which allows it to be transferred to another human through the bite.. Early experiments with Plasmodium vivax showed that an infective mosquito will bite 30–40 times (James 1926). For a new person to be infected, a mosquito carrying the mature parasite back to its feeding location must find a victim who is not already infected. Therefore the more people who are sleeping together in the same room, the higher the probability of spreading the infection to a new person. Reinfection is thus a stochastic process, and below a certain threshold number of persons sleeping together, Plasmodium infection success rates drop below the replacement rate and it begins to disappear from the human population, even without other control measures. This study indicates that the threshold is likely crossed when average household size drops below somewhere between 4.0 and 4.5 persons.
The hypothesis was tested by re-doing the analysis using data on the incidence of dengue fever, which, like malaria, is mosquito-borne and has wide geographic distribution, but is spread by different species that are active during the day in shaded places and only occasionally at night. Thus its transmission mechanism is not expected to be sensitive to household size, but to factors affecting outdoor exposure. In the dengue re-analysis, the household size effect disappeared, as did the Muslim effect, and the income effect became much smaller and less significant. The measure of aggressive DDT usage became marginally significant (p=0.073).
Conclusions
These findings suggest that as average household sizes continue to decline around the world, malaria will also gradually disappear. The authors did not differentiate between adult and children household members. There is evidence that the threshold is not affected by the fraction of children, since the effect has been observed in populations of soldiers where children are not present. The result raise the possibility that in regions with large households (or large populations sharing sleeping quarters, such as lumber camps or military barracks), the eradication of malaria will require segmenting sleeping quarters into smaller units, such as with mosquito nets. The average number of bed nets per person in 35 African countries is 0.21. In Vanuatu (average household size 5.6) a high provision of individual bed nets has, in combination with effective drug distribution and surveillance, been credited with the disappearance of malaria since 1996. Use of individual bed nets emulates a house with several bedrooms, making it more difficult for an infective vector to transmit the parasite to new household members.
Corresponding author contact: Ross McKitrick
Professor of Economics
University of Guelph
Tel 519-824-4120 x52532
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“Naively putting a DDT usage measure into the model would give results that apparently suggest DDT causes malaria.”
We all know that correlation is not causation, but this statement reveals a superlative degree of ignorance.
@ur momisugly tadchem: Not ignorance. Sometimes people must state the obvious, because to some others, the obvious is never obvious. Unfortunately, we seem to have an increasing proportion of people in the world who would have make that linkage.
tadchem says: We all know that correlation is not causation, but this statement reveals a superlative degree of ignorance.
Sorry, we also lnow that !!!
M Courtney says:
November 7, 2013 at 8:00 am
Didn’t actually read the paper did you? Smaller household size also correlates to wealth. More importantly, wealth correlates with how many people you share the bedroom with. Fewer people -> less chance of malaria. Of course, if you are heavily invested in DDT production, the results are not helpful.
highflight56433 says:
November 7, 2013 at 9:04 am
…
1. Don’t share bedroom with more than spouse.
End process
There, it’s fixed.
AFAIK malaria recrudescence relates directly with bad or non-existent public health policy. It’s so much cheaper to do nothing and blame it on something else.
Duster says: Don’t share bedroom with more than spouse. End process . There, it’s fixed.
Exactly !! 10 billion dollars without 100 billion dollars to vaccines will be the result !!
Just think what could be achieved in the world if money spent on trying to avoid cagw was instead spent on mosquito nets, fresh water and clean burning stoves. If only we had the technology.
By the way, did you know Oliver Cromwell died of malaria?
Bloke down the pub says: Just think what could be achieved in the world if money spent on trying to avoid cagw was instead spent on mosquito nets, fresh water and clean burning stoves. If only we had the technology. — By the way, did you know Oliver Cromwell died of malaria?
That is the main point. 10 B Dollars is enough!
Wow, I reread my first comment and boy, was I sarcastic. Not very polite, sorry.
Look the point I was making was that all of these parameters are related and the root cause of the factors is poverty and its alleviation. So the clearest signal comes from household size? Don’t you think household size is related to wealth? All of these parameters are related to wealth.
And do you think household size is the cause of the poverty or the result?
Larry,
Thank You for a very interesting article on malarial epidemiology! I only had a half hour to ‘read and partially digest’ your report on my lunch break but will return to this as more time allows.
MtK
Most of the alternative ”explanations” touted above won’t hold water. Malaria was quite common in Sweden up to c. 1850 and then gradually disappeared and was practically extinct by 1900.
This was long before DDT was invented and mosquito nets have never been used in Sweden
There were certainly never any shortage of mosquitos, and no eradication campaigns. They would be utterly hopeless in any case, Sweden is recently deglaciated land, there is literally hundreds of thousands of lakes and marshes of all sizes, and yes, mosquitos (including Anopheles) are often very bad, particularly in the northern part of the country, but there is no malaria, since about a century or so.
Larry Hulden says: ….
>>>>>>>>>>>>>
Glad you are here to clarify.
Was early testing and treatment of malaria an input? I only ask because as poor people in developing countries get wealthier they tend to have fewer children. They also have the means to send their kids and themselves for lab tests and if positive, take meds the same day. This behavior is less frequent among the poor as I have seen it many times myself.
The Tiwi people of the Bathurst and Melville Islands off the north coast of Australia didn’t know where babies come from half way through the 20th century. One can imagine a bad anthropologist (who disobeys the prime directive) trying to tell them that sex makes babies, while they hoot and holler as they carry him off to the asylum, explaining to him that correlation is not causation, especially if delayed by nine moons.
In non-Tiwi houses the first thing the babies experiment with when they can stand up in their cribs is the light switch. They delude themselves into thinking there is some causal correlation between flipping the switch and the room lighting up. Now maybe the rooster doesn’t make the sun come up, but the correlation does suggest some sort of causation–we only have to sort out the mechanistic trail, like maybe the predawn light wakes the rooster; or the long night makes him hungry and anxious for daylight to feed by.
Of course what the authors are tying to do is control for false causation and get down to the real causes, which of course they are doing admirably. –AGF
M Courtney: ” So the clearest signal comes from household size? Don’t you think household size is related to wealth?”
Depends on the culture, really. But this topic simply reiterates that transmittable issues are a factor of effective human density in general; and time sensitive effective human density in specific. eg. The greater effective density for a given duration, the higher the odds of transmission.
agfosterjr said @ur momisugly November 7, 2013 at 12:22 pm
Oh dear. Missing close blockquote tag after moons. The Git is typing on his Zenbook in a cafe while awaiting repair of his reading glasses…
The Pompous Git says:
November 7, 2013 at 2:12 pm
Ignoring for the moment the well documented widespread ignorance of the procreative mechanism among primitive societies, when do you suppose humans figured it out, and how? –AGF
As a DDT kinda guy I have to say that this paper does make a good point.
On a bit of a sad note I remember around 10 years ago sitting by my daughter’s hospital bedside as she was being treated for cerebral malaria. She made it through – unlike the new born baby next to her bed who passed away in front of my eyes. The doctor and nurses did their best but to no avail. I too had a bad bout of malaria back in 1981. This is why I get so angry when Warmists try to alarm the populace with their horseshit.
Since Larry Hulden is actively responding to this thread. . . I’ve been a DDT fan for a while now, but this study is compelling me to rethink. It sounds like the solution for places where poverty and family size precludes 4 or fewer sleeping in a room is to use sleeping nets to segregate into smaller sleeping units AND make medication available to deal with infections. I know the nets are inexpensive. How costly is the medication? And what to do about dengue fever? Or is that your next study?
Great analysis!
It’ll be nice to have something to point to when someone starts shrieking over increased malaria due to global warming.
Of course, as with any disease transmitted from individual to individual any interruption in the sequence of infection would have similar outcomes. “Herd Immunity” works in a similar way, if a contagion can’t spread from one individual to another it eventually dies out. While I agree with many commenters here that correlation does not prove causation; I think the case as presented for lower household size being a significant if not dominant cause for the decline in malaria is at the very least reasonable to believe, but more importantly reduces the case for causal temperature linkages to malaria to unreasonable to believe.
I liked “Warmer temperatures are not associated with increased malaria prevalence”. So much for the IPCC’s conclusions.
I work in the tropics were malaria is rampant. The main factors appears to be poverty and density of population, as well as the abundance of water for breeding. In the dry season there are no mosquitoes and therefore no malaria.
I also note that many of the areas where there are lots of people and poverty there are also a lot of colds, even though we are in the tropics. I suspect colds (that’s sneezing and coughing etc) are also more prevalent where there are bigger household sizes and poverty. Even though malaria tapers off in the dry season, colds do not. Colds spread more easily amongst bigger households, and amongst markets etc. I wonder if anyone has done a study on this also.
Slightly O/T, but can anyone here clarify how long malaria is infectious (via the mosquito vector)?
My father got malaria in Korea during the war there in the early 1950s. He continued to have sporadic attacks for decades afterwards. Was he a potential source of further infection after the acute phase passed? We had plenty of anopheles, and their bites, in the places that we lived in. Nobody else contracted malaria – in particular my mother, who slept in the same bed every night and got bitten by mozzies (as he did) all the time.
In his case, he wasn’t sleeping in barracks when he contracted it. He was sleeping in a small tent (4 -6 guys) out in the field. From what he tells me, it was a major health problem for the soldiers there. Presumably it was transmitted from the local population to the troops.
Very interesting. It makes intuitive sense that larger families/groups sleeping together should lead increased incidence of mosquito-mediated diseases.
But I am not sure that looking at current data – the text says, “Data for the year 2000 or the closest year thereto were obtained” – tells us much about the historical importance of DDT (or draining of swamps or whatever). If you looked at current data for the U.S., for example, you would conclude that TB and water-borne diseases have little or no impact on life expectancy. And that would be correct today, but it wasn’t always so. In fact, they were among the top killers in the first part of the last century.
For a variety of reasons, death rates from malaria were on the decline in the U.S. since the 1930s, if not earlier (see Fig 13 here). They continued to decline through the 1940s and were virtually zero by 1950. DDT was the coup de grace. I doubt that family sizes increased in the US through the 1930s. And we know there was a baby boom in the post-war years.
Note also that in several countries (in Latin America and Africa, for instance), “malaria has retreated, advanced, and in some places, retreated once again as levels of in-home DDT spraying have been increased, decreased and, occasionally, increased again” (pp. 179-181, Fig 6.19, in the book The Improving State of the World ).