In a two-year community randomised trial involving more than 15,000 children in Tanzania, a long lasting insecticidal net treated with piperonyl butoxide (PBO LLIN) reduced the prevalence of malaria by 44% and 33% in the first and second year respectively, compared to a standard long lasting insecticidal net (LLIN) treated with pyrethroid only.
The study, led by the London School of Hygiene & Tropical Medicine (LSHTM), also showed unprecedented malaria control through indoor residual spraying (IRS) with the insecticide pirimiphos methyl, which after a single spray round reduced malaria infection by 48% for an entire year.
LLINS and IRS are the cornerstones of malaria control in sub-Sahara Africa, and have been estimated to reduce malaria disease by 41% and malaria deaths by 62% between 2000 and 2015 globally. Despite this public health success, malaria still kills nearly half a million people annually, and for the first time in many years the World Health Organization (WHO) reported an increase in malaria cases and no change in the number of malaria deaths in 2017.
There is concurrent evidence that resistance to pyrethroid insecticide is growing in the Anopheline mosquitoes which transmit the disease. Only a limited range of alternative insecticides are available, particularly for LLINs for which pyrethroids are the only class of insecticide fully recommended by the WHO.
Anticipating the possible failure of current control tools due to resistance, WHO and LSHTM have been collaborating with the chemical industry for almost 20 years to develop new types of LLIN and new insecticides for IRS. One of these is a novel LLIN which incorporates piperonyl butoxide (PBO), a chemical which blocks the natural defence mechanisms of insects – the oxidase enzymes that would otherwise metabolise insecticide – which means the pyrethroid on the LLIN remains potent against mosquitoes despite resistance. This chemical synergist stops insects from breaking down the pyrethroid within their bodies, so the insecticide stays toxic to the insect.
Dr Natacha Protopopoff from the London School of Hygiene & Tropical Medicine who led the field research operations in Muleba, Tanzania, said: “It’s imperative we try and remain one step ahead of insecticide resistance which threatens to reverse the great gains made in combating malaria. We must develop an improved strategy based on new classes of LLIN to control malaria transmitted by pyrethroid resistant mosquitoes.”
This new study involved randomly selected children aged six months to 14 years from villages in Muleba district of North West Tanzania, where high levels of resistance to pyrethroids have been reported. In 2015, 48 villages were randomised into four groups with different preventative measures. Altogether 45,000 standard LLINs and 45,000 PBO LLINs were distributed. Children were then tested for malaria at the end of each rainy season.
After nine months, malaria infection was considerably lower in the group that received just the net treated with piperonyl butoxide – PBO LLIN – (31.1%, 275/883) and the group that received indoor residual spraying and standard LLIN (28.7%, 252/877), compared to the group that received standard LLIN alone (55.3%, 515/932). Twelve months later, the PBO LLIN effect was still persisting relative to the standard LLIN.
To strengthen the evidence for the interventions, mosquito traps were placed in each study arm. The number of malaria infected mosquitoes captured in the PBO LLIN villages was reduced by 87% and 67% during the first and second years respectively compared to the standard LLIN villages.
Professor Mark Rowland from LSHTM and Principal Investigator, said: “This project is a game-changer. The trial is the first clear evidence that nets treated with piperonyl butoxide can significantly improve personal and community protection from malaria compared to standard pyrethroid-only nets in areas where there is high pyrethroid resistance. It also demonstrated that pyrethroid resistance is now a significant problem in some areas and standard LLIN are less effective than before, and that the new IRS controlled malaria for an entire year before needing to be re-sprayed.”
As a direct consequence of the trial, WHO revised its reccomendations on LLIN in September 2017, giving an interim policy recommendation to PBO LLIN as a new class of LLIN1.
Dr Jan Kolaczinski, Coordinator for Entomology and Vector Control in the WHO Global Malaria Programme said: “WHO recommends PBO LLINs should be deployed for malaria prevention in areas where mosquitoes are pyrethroid resistant, provided that full coverage is maintained. This would include many endemic areas in Africa where standard LLINs are currently used.”
Professor Rowland said: “We are pleased that the WHO has already revised policy on the basis of this trial. This will ensure insecticide treated nets will remain an effective intervention for malaria control, and justifies the continued investment and research on alternative insecticides for use on nets.”
The authors acknowledge the study does have limitations, including the short buffer distance between villages; however, any spill-over between villages would tend to underestimate the intervention effect rather than increase it.
The authors also stress that it is important to always sleep under a bed net in areas of malaria transmission, and until PBO LLIN are deployed more widely in areas of resistance, standard pyrethroid-only nets will be more protective than non-use of nets and should continue to be used.
How does an insecticide treated bed net actually work?
The Lancet, www.thelancet.com/journals/lan … (18)30427-6/fulltext
via Medical Xpress http://bit.ly/2l6ea5Z
April 11, 2018 at 03:32PM