Abstract
Interest in Cutex qu£nque fa so i atus Say ( = f atigans Wied)
has been increasing with the growth of urban areas in the
tropical zones of the world because this rjmosquito is an
important vector of bancroftian filariasis. When increased
urbanization is accompanied: by inadequate sewage treatment,
conditions are ideal for proliferation of Cm qu'inquefa&ei a t u sm
No other species of mosquito has benefitted rfiore from these
acute sanitary problems than has C• qu£nquefaso'£atus» For
its. egg deposition and larval development, this species finds
optimum conditions in water with a high degree of organic
pollution.
Usually, mosquito larval and pupal surveys are made to
provide guidance for control programmes. They can be designed
for species, geographic and habitat distribution, parasitism
and density.
In Ghana, Macfie and Ingram (1916] working on the seasonal
distribution of the adult and larvae of mosquitoes in the
various districts of Accra and Chris ti an sborg concluded that
Aedes aegif-pt'L and Cutex quinquefaso'Latus are two dominant
species but that Am a&gypti- was more common. Earlier, Graham
(1910) had studied the mosquito larvae found in water -
receptacles at Lagos, Nigeria and found that a seasonal
variation in numbers was shown to occur, but the causes
were obscure. In this study, 2 active natural enemies: of
mosquitoes were found to exist. One natural enemy of
mosquito larvae was Cu lex ti'g ripes* The other was: a small
active surface-feeding fish RapZochtZus- gvaham'Zm This fish
has a great capacity for populating flooded land by leaping
from one pool to another. Catfish, however, preys on these
fish.
In recent years, many basic studies on various aspects
of Cm quznque fasci-atus population biology and disease relationships
ti.e. filariasis) were initiated in Rangoon, Burma.
The results of these studies were reported by de Meillon
et. aZ- (.1 967). More recently, Chinery (.1 965 , 1 968a, 1 968b)
studied the mosquitoes in Accra with emphasis on their breeding
places, in relation to the mosquito control in an urban
environment. He found that proliferation of Cm quCnquefasczatus
( = fatigans) is due mainly to urbanization associated,
with the use of insecticides in preference to conventional
sanitary- measures. The most recent study on pre— adult
population of Cm q u in qu & fa&ciatu s in West Africa was conducted
by Subra (.1 970), Patterson et. aZ-(1 970). They studied the
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seasonal variation of the population. Weidhass et a t •
(1 97 1 , 1 973) also studied C. qu tn q u e fa s s ta tus in an
effort to suppress and eliminate the species using
s; te ri le m a le s •
Referring to the previous studies in Accra, one
observes that life-table studies and other quantitative
studies on the population dynamics are lacking. It is
known that the quantitative ''determination of mosquito
larval abundance is a primary requirement of both mosquito
control and research programmes. Generally, studies on
mosquito dynamics are deficient on two accounts (Anon, 1968)•
1. There are few ‘adequate studies' of total numbers of
eggs, larvae, pupae and adults in any sample.
2. The many effects of the environment on survival and
reproduction have not been fully explored, still
less adequately quantified.
One aim of entomologists is to develop technologies
that will give the required degree of control most effectively,
efficiently and economically. Such an aim implies
that the control of diseases caused by mosquitoes should be
based on the management of total populations rather than
the continual reduction of high density populations at times
when the insect or disease becomes a problem. In most cases,
it is possible to visualize the way in which a control
technique will act on an insect population. However, the
development of the potential of new or integrated approaches
to control is less available.
As a contribution to planning integrated control measures,
scientists have in recent times relied on life-table
construction. The purpose of this is to summarize the
survival and mortality rates of a population. Its application
in recent times is found in agricultural and forest
entomology (Morris 1963 , Southwood 1966, Varley and Gradwell
1 9 7 0 ), and in fisheries biology (Ricker 1944, 1948, Wohlschlag;
1954, Beverton and Holt 1957). Only recently has it been
applied to mosquitoes (Lakhani and Service 1974, Service
1 97 1 , 1 973, Southwood e tm a l , 1 972).
Varley and Gradwell (1970) emphasized that the most
instructive life-table will usually be based on the continuous
and intensive study of a population in a single habitat,
not by sampling different populations in a number of similar
habitats: in different years.
Where sampling is for life-table construction, differences
in sensitivity of larval instars to disturbance
produce biased samples. The 'enclosure method* whereby a
given area is enclosed and all the larvae contained in the
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area removed as practised by Cambournac (1939), Bates
(1941] and Goodwin and Eyles (1 942) are more suited to the
study of extensive areas of shallow water with much vegetation,
where larvae are numerous and evenly distributed.
Zn the types of breeding site indicated^ this method
is difficult to perform, because the larvae accumulate
along the 'shore line* and not in the open area of the
water habitat. The method used by Christie (1954) for
recovery and enumeration of An ophele s g ambiae from pools
is however quite accurate and efficient and it shows that
about 95% of the larvae of all stages except the first are
recovered.
In general, the specimen— collecting devices used in
qualitative and quantitative studies are the same (reviewed
by Bradley and Goodwin, in Boyd 1949) but, where in qualitative
work the specimens collected are most frequently in
themselves the end-goal, the number of organisms taken per
unit of effort or area is important in quantitative studies.
Additionally, quantitative surveys methods differ in that
a sampling design and a mathematical model for data analysis
must be developed. In some cases it is also required that
a method be developed for determining the numerical relationship
between the specimens collected and total population
else.
In connection with quantitative considerations,
Andrewartha (1961a) recognizes two types of population
densities. If it is possible to count or estimate all
the animals in an area, the results are spoken of as the
ab so lu te d e n s i t y of a population. Where the'size of a
population is known only as a ratio to the size of another
population either in time or space, it is said that the
r e l a t iv e d e n s i t y is, known.
In order to understand the factors that determine
mosquito numbers, knowledge of the effects of environment
upon survival, fecundity and dispersal is necessary. The
data required are the total numbers of eggs, larvae^ pupae
and adults, in the area under study at different times,
together with an analysis of environmental factors. Changes
in numbers are then related to changes in environment. The
analysis of such data is the subject of a paper by Hayes
and Hsi (.1 975) ,
The sampling of larval density should aim at roughly
estimating the relative density for quantitative evaluation*
For this reason, the relative abundance of larvae of a
particular species at different places can be determined,
provided that the methods of sampling are standardized^ as
far as possible. Prom experience by WHO, (Anon, 1975a)
ESENA, R (2021). LIFE-TABLE STUDIES IN CULEX SPECIES AND THE SUSCEPTIBILITY OF CULEX QUINQUEFASCIATUS SAY TO INSECTICIDES COMMONLY USED IN ACCRA,. Afribary. Retrieved from https://track.afribary.com/works/life-table-studies-in-culex-species-and-the-susceptibility-of-culex-quinquefasciatus-say-to-insecticides-commonly-used-in-accra
ESENA, REUBEN "LIFE-TABLE STUDIES IN CULEX SPECIES AND THE SUSCEPTIBILITY OF CULEX QUINQUEFASCIATUS SAY TO INSECTICIDES COMMONLY USED IN ACCRA," Afribary. Afribary, 01 Apr. 2021, https://track.afribary.com/works/life-table-studies-in-culex-species-and-the-susceptibility-of-culex-quinquefasciatus-say-to-insecticides-commonly-used-in-accra. Accessed 23 Nov. 2024.
ESENA, REUBEN . "LIFE-TABLE STUDIES IN CULEX SPECIES AND THE SUSCEPTIBILITY OF CULEX QUINQUEFASCIATUS SAY TO INSECTICIDES COMMONLY USED IN ACCRA,". Afribary, Afribary, 01 Apr. 2021. Web. 23 Nov. 2024. < https://track.afribary.com/works/life-table-studies-in-culex-species-and-the-susceptibility-of-culex-quinquefasciatus-say-to-insecticides-commonly-used-in-accra >.
ESENA, REUBEN . "LIFE-TABLE STUDIES IN CULEX SPECIES AND THE SUSCEPTIBILITY OF CULEX QUINQUEFASCIATUS SAY TO INSECTICIDES COMMONLY USED IN ACCRA," Afribary (2021). Accessed November 23, 2024. https://track.afribary.com/works/life-table-studies-in-culex-species-and-the-susceptibility-of-culex-quinquefasciatus-say-to-insecticides-commonly-used-in-accra