How extreme temperature is affecting rabbit production in Nigeria
How extreme temperature can affect your rabbit’s production:
Heat is
one of the most important climatic factors, which may affect rabbit production
in Africa, especially in Nigeria. The rabbit is very largely dependent on
respiratory evaporation for the regulation of its body temperature and this
confers only a limited power of adaption to hot climates. Heat is also
dissipated by radiation and convection, but these are somewhat restricted by
the rabbit's furry covering. Johnson et al..., (1957) reported that short hair
and larger ears helped the cooling process in New Zealand White rabbits. According
to these workers, growth and development were impaired at ambient temperatures
of 28.3°C and above. Generally the higher the ambient temperature the greater
was the disturbance of the rabbit's functions.
The
temperature of a rabbit's body is best measured by recording rectal (Rectum-final section of the large intestine)
temperature. A rectal temperature of 38°C is considered to be within the normal
range. Lee et al., 1944 reported that at ambient temperatures above 29.4°C the
rectal temperature begins to increase in the rabbit. When the rectal
temperature of Angora rabbits reached 39.8°C, the animals became disinclined to
move; at a temperature of 40°C they lay down on their sides; and at 41.7°C the
rabbits suffered obvious distress but were able to carry out ordinary
movements. These rabbits were found to be unable to tolerate ambient
temperatures of 37.8°C to 43.3°C for more than 7 hours, within which time the
critical rectal temperature of 41.7°C was reached.
Reproduction
There is
evidence that high ambient temperatures can impair the reproductive performance
of rabbits. In New Zealand Whites a temperature of 32.8°C reduced fertility in
the male rabbits, a continuous high temperature being more detrimental than
intermittent heat (Oloufa et al., 1951).
In the female, smaller blastocysts and embryos, and an increase in
embryo mortality rates were also observed. El Sheikh and Casida (1955)
concluded that the maximum
temperature
to which rabbits could be exposed (for 1 hour) without impairing health or
sperm motility was 43.3°C at a relative humidity of 30 to 40%. Chou et al.,
(1974) heated the testes of live rabbits to 43°C for 20 min on three successive
days. No spermatozoa were present in the seminiferous tubules up to 30 days
after the treatment. However, recovery was complete at about 10-14 weeks following
the treatment. Hiroe and Tomitzuka, (1965) observed a marked fall in semen
quality in male rabbits subjected to ambient temperature of 30°C for 14 days.
These changes in quality were associated with an increase in the pH of the semen,
a fall in sperm motility, a decrease in sperm concentration, an increase in the
percentage of abnormal spermatozoa and a decline in libido. These workers found
that, with the exception of sperm concentration, the changes could be reversed
by reducing the ambient temperature. Embryo survival was depressed by heat stress
and this was more severe under constant heat stress than under fluctuating heat
stress, and was due largely to post implantation losses.
Embryo
survival at 12 days post fertilization was lower at 32.2°C than 21.1°C. Shah
(1955) reported that severe prenatal losses occur in pregnant does exposed
continuously in the first 6 days of pregnancy to environmental temperatures
sufficiently high to cause a rise in body temperature of 1.2°C to 1.7°C. Such
losses occurred through resorption of embryos following implantation. When
laboratory rabbits were exposed to a Sahel- Sudanean dry climate, breeding was
only successful for 5 months out of 12 (Tacher, 1970).
Heat has become an issue for
breeders, especially in Nigeria as we are recording high temperatures in
different parts of the country.
However, extreme temperatures can be tempered by different measures. Trees around
the building decrease the amount of heat that enters during the day, by
providing shade, and somewhat decrease the amount of heat that escapes during
the night through radiation. They also lessen the impact of wind and rain
(figure 6 and figure 7). Some fast growing legume trees include Leucaena, Gliricidia,
Sesbania, Erythrina, and might even provide some feed for the animals. Besides
trees, the roofing material greatly influences the heat inside. Use your own
judgment:
corrugated
iron is hotter than a straw, grass or tile roof (especially if the roof starts
to become rusty).
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Roof
material and construction in relation with temperature
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