Presentation1.pptx tilapia

PRRESENTED BY:
ASHUTOSH LOWANSHI
MFSc
(DEPT. OF AQUACULTURE)

Grow-out:
Mixed-sex
Culture
Disadvantages:
1. Small harvest weight
2. Mixed sizes at harvest
Advantages:
Technically
easy
Mono-sex
culture
Advantages:
1. Large harvest weight
2. Uniform size at
harvest
Disadvantage:
Technically
difficult

Tropical species Prefers to live in
shallow water.
Lethal temperatures
Lower
11-12 °C,
Upper 42 °C
Preferred temperature
31 to 36 °C.

Omnivorous grazer
Phytoplankton, Periphyton
,aquatic plants small
invertebrates, benthic fauna
detritus and bacterial films
associated with detritus.
Feeding
Filter feeding
Feed by entrapping suspended
particles, including
phytoplankton and bacteria,
on mucous in the buccal
cavity,
Main source of nutrition : surface grazing on periphyton mats.

•Sexual maturity in ponds is reached at an age of 5-6 months.
Spawning begins when the water temperature reaches 24 °C.
• The breeding process starts when the male establishes a territory,
digs a craterlike spawning nest and guards his territory called as lek.
•Nests are prepared by scooping out depressions at pond bottom.
Mature female visits the pond and there is immediate courtship and
mating.

•The ripe female spawns in the nest, and immediately after
fertilization by the male, collects the eggs into her mouth and moves
off.
•The female incubates the eggs in her mouth and broods the fry after
hatching until the yolk sac is absorbed. Incubating and brooding is
accomplished in 1 to 2 weeks, depending on temperature.
•After fry are released, they may swim back into her mouth if danger
threatens. Being a maternal mouth brooder, the number of eggs per
spawn is small in comparison with most other pond fishes.

•Egg number is proportional to the body weight of the female. A 100
g female will produce about 100 eggs per spawn, while a female
weighing 600-1 000 g can produce 1 000 to 1 500 eggs.
• The male remains in his territory, guarding the nest, and is able to
fertilize eggs from a succession of females.
•If there is no cold period, during which spawning is suppressed, the
female may spawn continuously.
•While the female is brooding, she eats little or nothing. Nile tilapia
can live longer than 10 years and reach a weight exceeding 5 kg.

Eggs can be removed from females Yolk-sac tilapia fry
Females incubate eggs
defend the fry

SEED SUPPLY
 Tilapia are asynchronous breeders. Hormones are not used to
induce spawning, which occurs throughout the year in the tropics
and during the warm season in the subtropics.
 Breeding is conducted in ponds, tanks or hapas. The stocking ratio
for females to males is 1-4:1 with 2 or 3:1 being the most common
 The brood fish stocking rate is variable, ranging from 0.3-0.7
kg/m2 in small tanks to 0.2 - 0.3 kg/m2 in ponds.
 The popular hapa-in-pond spawning system in Southeast Asia uses
100 g brood fish stocked at 0.7 kg/m2.

 Spawning ponds are generally 2000 m2 or smaller. In Southeast
Asia, a common hapa size is 120 m2.
 Brood fish are given high quality feed at 0.5-2 percent of body
weight daily. Swim-up fry gather at the edge of a tank or pond and
can be collected with fine-mesh nets
.
 Fry collection can begin 10 to 15 days after stocking. Multiple
harvests (six times per day at 5 day intervals) are conducted up to a
maximum of 8-10 weeks before pond drainage and a complete
harvest is necessary.
 Tanks must be drained and recycled every 1-2 months because
escaped fry are very predaceous on fry from subsequent spawns..

 Alternatively tanks or ponds are harvested completely after a 2-
4 week spawning period. Production of optimum-sized (<14
mm) fry ranges from 1.5 to 2.5 fry/m2/day (20 to 60 fry/kg
female/day).
 In the South East Asian hapa method, fish are examined
individually every 5 days to collect eggs. This system is much
more productive, but it is labour intensive. Brood fish are more
productive if they are separated by sex and rested after
spawning.

Mono-sex male tilapia populations can be produced by:
Visual selection
Hybridization
Sex-reversal
Genetic manipulation

Visual selection
Male Female
Two apertures on ventral side
of belly
Anus and urinogenital.
Three apertures- anus, urinary
And genital aperture.
Urinogenital aperture smaller. Bigger Urinogenital aperture.

Hybridization
Male Hornorum tilapia
(ZZ)
Female Nile tilapia
(XX)
All-male hybrid tilapia
(XZ)

•Commercial tilapia production generally requires the use of male
monosex populations.
•Male tilapia grow approximately twice as fast as females.
•Therefore, mixed-sex populations develop a large size disparity
among harvested fish, which affects marketability.
•Moreover, the presence of female tilapia leads to uncontrolled
reproduction, excessive recruitment of fingerlings, competition for
food, and stunting of the original stock, which may not reach
marketable size.
Sex-reversal

• In mixed-sexed populations, the weight of recruits may
constitute up to 70 percent of the total harvest weight. It is
therefore necessary to reverse the sex of female fry.
• This is possible because tilapia do become sexually
differentiated for several days after yolk sac absorption. If
female tilapia receive a male sex hormone (17 α
methyltestosterone, MT) in their feed, they will develop as
phenotypic males.
• Fry collected from breeding facilities need to be graded
through 3.2 mm mesh material to remove fish that are >14 mm,
which are too old for successful sex reversal.

•Swim-up fry are generally <9 mm. MT is added to a powdered
commercial feed or powdered fish meal, containing >40 percent
protein, by dissolving it in 95-100 percent ethanol, which is mixed
with the feed to create a concentration of 60 mg MT/kg feed after
the alcohol has evaporated.
•The alcohol carrier is usually added at 200 ml/kg feed and mixed
thoroughly until all the feed is moist.
•The moist feed is air dried out of direct sunlight, or stirred in a
mixer until dried, and then stored under dark, dry conditions.
Androgens break down when exposed to sunlight or high
temperatures.
•Fry are stocked at 3 000 to 4 000/m2 in hapas or tanks with water
exchange.

•Stocking densities as high as 20 000/m2 have been used if good
water quality can be maintained.
• An initial feeding rate of 20-30 percent body weight per day is
gradually decreased to 10-20 percent by the end of a 3 to 4 week
sex-reversal period.
• Rations are adjusted daily, and feed is administered four or more
times per day.
•If sex-reversal is conducted in hapas, the feed must be of a
consistency that allows it to float,otherwise a considerable amount
of feed would be lost as it settles through the bottom of the hapa.

•Sex-reversed fry reach an average of 0.2 g after 3 weeks and 0.4 g
after 4 weeks. The average efficacy of sex-reversal ranges from 95 to
100 percent depending on the intensity of management.
•Feminization of genetic male done through estrogen – these
functional females when mated with genotypic males all male
offsprings are produced.

XX “F” + XY “M”
1- XY “F” x XY “F”
2 - XY “ F” x XY “ M”
3-XX “ F ” + 2 XY “ M” + YY “ M”
XX “F” x YY “M”
100 % XY “ M”
Genetic Manipulation
estrogen

•After sex-reversal, fingerlings are generally nursed to an advanced
size before they are stocked into grow-out facilities.
•This procedure increases survival in the grow-out stage and utilizes
growing space more efficiently.
• Sex-reversed fingerlings are stocked at approximately 20-25
fish/m2 in small ponds and cultured for 2-3 months to an average size
of 30-40 g.
•The ponds should be filled immediately before stocking to prevent
the build-up of predaceous aquatic insects. Final biomass at harvest
should not exceed 6000 kg/ha.
Nursery

•A series of small cages (<4 m3) with increasing mesh size can be
used to rear advanced fingerlings.
• Sex-reversed fingerlings can be stocked at a rate of 3 000
fish/m3 and grown for 6 weeks until they average 10 g.
•Fish of this size can be restocked at 2 500 fish/m3 to produce 25-30
g fingerlings in 4 weeks.
• These fish can be stocked at 1 500 fish/m3 to produce 50-60 g
fingerlings in 4 weeks. A recirculation system stocked at 1 000
fish/m3 will produce 50 g fingerlings in 12 weeks. Fingerlings should
be fed 3-4 times daily.
•In ponds, fingerlings are given extruded feed (30 percent protein) at
an initial rate of 8-15 percent of biomass per day, which is gradually
decreased to a final rate of 4-9 percent per day.

Tilapia can be spawned in:
1. Ponds 2. Cages ( hapas )
3. Tanks

POND CULTURE
 Pond culture of tilapia is conducted with a variety of inputs
such as agricultural by-products (brans, oil cakes, vegetation
and manures).
 Chicken manure weekly at 200-250 kg DM (dry matter)/ha and
supplementing it with urea and triple super phosphate (TSP) at
28 kg N/ha/week and 7 kg P/ha/week , inorganic fertilizers and
feed.
 To reduce production costs for domestic markets in developing
countries, two strategies are followed: delayed feeding and
supplementary feeding.
 Tilapia are stocked at 3 fish/m2 and grown to 100-150 g in
about 3 months with fertilizer alone, and then given
supplemental feeding at 50 percent satiation until the fish reach
500 g

Floating cages
 Mesh size has a significant impact on production and should
be 1.9 cm or greater to maintain free circulation of water.
Advantages.
 The breeding cycle of tilapia is disrupted in cages, and
therefore mixed-sex populations can be reared in cages without
the problems of recruitment and stunting. Eggs fall through the
cage bottom or do not develop if they are fertilized
 Use of waterbodies that cannot be drained or seined and would
otherwise not be suitable for aquaculture.
 Flexibility of management with multiple production units.
 Ease and low cost of harvesting.
 Close observation of fish feeding response and health.
 Relatively low capital investment compared to other culture
techniques.

Tanks and raceways
 Tilapia are cultured in tanks and raceways of varying sizes (10-1 000
m3) and shapes (circular, rectangular, square and oval).
 The maximum tilapia density in raceways ranges from 160-185
kg/m3, and maximum loading ranges from 1.2-1.5 kg/litre/min
.
 A common production level in raceways is 10 kg/m3/month, as
water supplies are often insufficient to attain maximum rates.
 Production levels are considerably lower in tanks with limited water
exchange, but water use efficiency is much higher in these systems.

Harvesting techniques
 Complete harvests are necessary in ponds and are
accomplished by seining in combination with draining.
 A complete harvest is not possible by seining alone as tilapia
are adept at escaping seine nets.
 The pond should be dried between production cycles or treated
with pesticides to kill tilapia fry to avoid carryover to the next
production cycle.
 Partial harvests of tanks, raceways and recirculation systems,
which maximize production, are accomplished with grader bars
to remove the largest fish.

•Prepared feeds that provide a complete diet (adequate protein,
lipids, carbohydrates, vitamins and minerals) are readily available
in developed countries and are also manufactured and available in
developing countries with an export market for high quality tilapia
products.
•Some of the main feed ingredients such as soybean meal or
fishmeal may be imported.
• Prepared feeds are often too expensive for the production of
tilapia sold in domestic markets in developing countries; however,
manures and agricultural by-products are used to produce tilapia
cost effectively.
•In developing countries without a tilapia export market, farmers
rely exclusively on manures and agricultural by-products, as
prepared feeds are not available.
Feed

GIFT Tilapia
• A pioneering selective breeding program that began in 1988 to led
to the development of the Genetically Improved Farmed Tilapia
(GIFT) strain by World Fish and partners.
•Selective breeding is the process of choosing the parents of the next
generation in such a way that it will result in improved performance
for certain traits considered to be important during production and
marketing.

Why Tilapia?
•It can be grown in diverse farming systems and is
omnivorous, requiring minimal fish meal in its feed.
• It has a naturally high tolerance to variable water quality and
can grow in both freshwater and marine environments
.
•Because tilapia are hardy and have good disease resistance,
they are inexpensive and easy for small-scale farmers to grow
for food, nutrition and income.
•Tilapia is an affordable source of protein, vitamins, minerals
and essential fatty acids that are vital for good health. GIFT
and other improved strains of Nile tilapia have helped improve
food and nutrition security in the developing world.

Presentation1.pptx tilapia

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