Experiments on the filarial vector Culex quinquefasciatus revealed that its density was found to be significantly lower (p < 0.05) in the rainy season in comparison to dry seasons (summer and winter) in different endemic areas of the tropics 242526272829303132333435363738 because their breeding places become flooded during the monsoon. On the other hand, the hot months of the rainy season and sometimes summer were found to be the high time for filarial transmission in most of the endemic areas, established by the highest infection and infectivity rates (with filarial parasites) of the vector in nature 313539404142, the shortest developmental period of the parasite in the vector 23 and highest transmission potential 4344 during this period of the year. The rainy season provides optimum conditions to raise the vector efficiency index (VEI) to its peak (VEI is based on rapid parasitic development, proper nursing and low parasitic damage or death) 23.

So, there is a lack of synchronization between two important factors like transmission season and the period of highest vector density, which limits transmission and keeps it at a low level.

When parasite load was examined, a sharp reduction was noticed between the load of microfilariae per infected mosquito and the load of third stage infective larvae (L₃) per infected mosquito (reduction is significant ; p < 0.05) in both urban and rural micro environments 4345. In Fiji, Symes 46 also obtained similar results. It indicates that all the microfilariae that enter into the gastrointestinal tract of mosquito cannot survive to develop into L₃ stage. Bryan et al and McGreevy et al 4748 reported that sometimes microfilariae are damaged by the buccopharyngeal armature of the mosquito during ingestion. Rise or fall of temperature and fall of humidity caused deformity and degeneration of a large number of filarial parasites in the mosquito body 2335

Mosquitoes limit the number of migrating microfilariae by rapidly excreting them. Wharton 49 found an average of more than 100 microfilariae to be ejected in droplet from the anus of An. barbirostris fed on a cat infected with Brugia pahangi. Similar results were obtained with W. bancrofti in Cx. quinquefasciatus 50.

Hu 51 and Chandra et al 23 noted that all the microfilariae failed to escape from the midgut of the infected mosquito due to low temperature in winter in Shanghai, China and West Bengal, India respectively.

Sutherland et al 52, Yamamoto et al 53 and Christensen et al 54 reported on the defence mechanism and defence reaction of mosquito vectors to filarial worms. The growth of a high percentage of parasites is arrested in their sites of development of the vector body due to melanization and encapsulation. The antihemostatic factors present in saliva allow mosquitoes to blood-feed efficiently, but different mosquito species can differ markedly in blood feeding potency 55. Further, the fluid consistency of ingested blood usually varies in different mosquitoes. The coagulation of ingested blood within the mid-gut also inhibits ingested pathogens from migrating out of the gut to reach the final site of development. This potential barrier to pathogen development varies significantly depending on the length of time a pathogen spends within the mid-gut. But evidently the consistency of ingested blood greatly influences both the prevalence and intensity of infection for all mosquito-borne parasites 5657.

Kobayashi et al studied filariasis 58 and analysed the refractory mechanisms of the mosquito Aedes aegypti to the filarial larvae Brugia malayi by means of parabiotic twinning.

The fate of larvae after leaving the proboscis is not known for W. bancrofti, but experimental data for Brugia pahangi 5960 revealed that during a single complete feeding 32% only of the escaping larvae succeeded in penetrating the tissues of experimental hosts. Similar results were obtained when the mosquito had a partial blood meal (31.3%) or made multiple attempts to feed (38,1%), when a single feeding attempt was unsuccessful, 10.2% of the escaping larvae succeeded in penetrating the tissues.

The most important factor in estimating the extent to which accumulation is possible is the rate of survival of immature parasites in the human. Again, data for W. bancrofti are not available, but Edeson & Buckley 61 obtained a survival to maturity of 0.13 for Brugia malayi in experimental animals, assuming a constant death rate during this immature period of 2 1/2 months, the daily mortality can be calculated as

0.13 = e^-75d

When d is the instantaneous death rate per day and e is the base of natural logarithms. From the equation, e = 0.027/day, and W. bancrofti is known from unpublished WHO information to have a minimal prepatent period of 8 month and 4 days. Thus if we apply the calculated death rate, the proportion of the larvae surviving would be 0.00147 6162.

So, a sharp reduction in parasite load during parasitic development in the vector, revealed from the above literature, limits transmission and keeps it at a low level.

Numbers of Cx. quinquefasciatus carrying microfilariae, first stage, second stage and third stage larvae of W. bancrofti in nature gradually decreased in both urban and rural areas 4345. It is an indication that all the mosquitoes (initially infected with microfilariae) cannot survive the period required for the development of microfilariae into third stage infective larvae. Different investigators recorded varied daily mortality rate of Cx. quinquefasciatus from 14% to as much as 47% in different parts of the world 356364656667686970. Almost all the authors, who worked on the vector infection and infectivity of different filarial vectors of different parts of the world 434571 recorded significantly higher (p < 0.05) infection rate than that of infectivity rate of a particular endemic area, which is another indication of substantive vector mortality in a given period.

When presumptive mortality rate 72 of Cx. quinquefasciatus (collected from both urban and rural areas) between two successive gonotrophic cycles was determined, a high percentage of mortality of vector population was observed between two successive gonotrophic cycles. A high mortality between two successive gonotrophic cycles caused considerable reduction of vector as well as parasite population naturally.

Most of the mosquitoes carrying microfilariae were found to be nulliparous (yet to lay first batches of eggs) i.e. took microfilariae during their first blood meal when parity status was determined by Polovodova's method 73. Pentaparous mosquito containing microfilariae proves that they may also be infected during their sixth blood meal but with the increase of age of mosquitoes, new infection with microfilariae decreased 74. So, natural vector mortality during the period required for the development of microfilariae into third stage infective larvae is indicative of reduction in transmission.

Moreover, Wuchereria spp., which causes the major global burden (106.2 million out of 119.1 million), is not a zoonotic parasite i.e. man is the only known definitive host and there is no other reservoir. Except for a mosquito bite, there is no other mode of transmission. Though congenital microfilaremia has been reported 7576, it is of no significance. Microfilariae transmitted by blood transfusion may survive and circulate up to very limited number of days and do not develop into adult worms 17. It can be shown in principle that there are critical densities of host and vector below which the parasite population cannot be maintained and that these critical densities are most important for parasites in which the sexes are separate 77. This is true for all nematodes, as their sexes are separate, and here specifically for Wuchereria and Brugia. Multiple bites by infective mosquitoes are required for effective transmission. The WHO Filariasis Research Unit in Rangoon estimated that an average of around 15,500 bites by infective mosquitoes is necessary to produce 1 case of microfilaremia 62. The major vector of nocturnally periodic Wuchereria (Cx. quinquefasciatus) breeds only in man-made polluted water and Mansonioides, vectors of Brugia breed in water bodies infested with certain preferred weeds (Pistia, Eichornia, Lemna) only 78. At the same time they cannot oviposit in water bodies infested with ferns like Azolla, Salvinia etc 78. So, vast water bodies, which are free of, preferred weeds or infested with Azolla or Salvinia do not favour breeding of Brugia vectors.

According to Dreyer et al factors associated with adult worm longevity are unknown 79. They concluded that survival of adult W. bancrofti is inversely associated with transmission intensity.

Snow and Michael provided clear evidence for the existence of microfilarial density-dependence in the process of transmission for all the three major bancroftian filariasis transmitting mosquito vectors 80. The regulation of mf uptake varied significantly between the vector genera, being weakest in Culex, stronger in Aedes and most severe and occurring at significantly lower human mf loads in Anopheles mosquitoes. It indicates lower intensities of transmission in the vast endemic areas where Culex acts as vector.

Dissanayake showed that development of adenolymphangitis and lymphoedema was strongly associated with amicrofilaraemic infection 81. In contrast, microfilaraemic individuals are more likely to remain microfilaraemic without developing clinical lymphatic disease. It is concluded that asymptomatic microfilaraemia and amicrofilaraemic clinical disease are independent outcomes of W. bancrofti infection and are not sequential events of progressive infection. This indicates that most of the microfilaraemics do not develop symptoms and morbidity. Therefore, all these mechanisms have a natural bearing in limiting transmission.