Milkfish are an important aquaculture species in Southeast Asia. They are cultured extensively in brackishwater ponds in the Philippines, Indonesia, and Taiwan, providing food and income. Milkfish culture involves pond preparation, stocking fry or fingerlings, feeding, and monitoring water quality. While milkfish are hardy and support important aquaculture industries, their culture also faces challenges like disease outbreaks, fry supply shortages, and high production costs.
Exotic fish introduction to india and their impact on indigenous speciesAshish sahu
The exotic varieties of fish have been found to encroach the natural water bodies and adversely affect the indigenous fish species. ... Owing to extensive practice of composite culture, three fast growing exotic fishes are introduced along with the three Indian major carps.
Exotic fish introduction to india and their impact on indigenous speciesAshish sahu
The exotic varieties of fish have been found to encroach the natural water bodies and adversely affect the indigenous fish species. ... Owing to extensive practice of composite culture, three fast growing exotic fishes are introduced along with the three Indian major carps.
Any aquatic invertebrate animals having a cutaneous or calcareous shell surrounding there body and belonging to the phylum Mollusca, the class Crustacea (phylum Arthropoda), or phylum Echinodermata is known as shellfish. The term is often used for the edible species of the groups, especially those that are fished or raised commercially. The most commercially important shellfish are:
• Mollusk: Oysters, mussels, scallops and clams
• Crustacean: Shrimp, prawn, lobster, crab and crayfish
• Echinoderm: sea urchins and sea cucumbers
Shellfish hatchery is a place where shellfish seeds are produced in a controlled way. Hatchery management is a branch of science which deals with the activities including from collection of brood shellfish to seed production. Culturing of shellfish has occurred since ancient times. Although controlled rearing of young shell has long existed, hatchery production is a more recent advancement. Producing seed under controlled conditions in a hatchery will disconnect its production from environmental factors and provide a reliable supply of seed. Oysters, mussels and mud crabs are the most important groups of shellfish after shrimp and prawn. These are popular among the western countries and becoming more popular all over the world. So hatchery management of oyster, mussel and crab is crucial.
Introduction
Fish Health Management GOALS
Principles of fish health management
Factors affecting fish health
Common symptoms of diseases
General preventive measures
Proper Health Management through Manipulating the disease triangle
Conclusion
References
Recirculating aquaculture systems (RAS) operate by filtering water from the fish (or shellfish) tanks so it can be reused within the tank. This dramatically reduces the amount of water and space required to intensively produce seafood products.
CAGE CULTURE OF FISH THEIR TREND,STATUS AND PRODUCTION Ashish sahu
Cage culture is an aquaculture production system where fish are held in Cage. Cage culture of fish utilizes existing water resources but encloses the fish in a cage which allows water to pass freely through the enclosures and the surrounding water body. Cages are used to culture several types of shell fish and finfish species in fresh, brackish and marine waters. Cages in freshwaters are used for food fish culture and for fry to fingerling rearing.
In 1950s modern cage culture began with the initiation of production of synthetic materials for cage construction. Fish production in cages became highly popular among the small or limited resource farmers who are looking for alternatives to traditional agricultural crops. The mesh size of the cage is kept smaller than the fish body. In India cage culture have been attempted first for Air breathing fish. Cage mesh netting made from synthetic material that can resist decomposition in water for a long period of time. Cage are used to culture several type of shell fish and fin fishes in fresh , brackish and marine water. Cage in fresh water are used for food fish culture and for fry to fingerling rearing. Cages are generally small, ranging in freshwater reservoirs from 1 square meter (m2) to 500 m2.
Definition –
Cage culture is a system in which the cultured Fish 0r animal are enclosed from all side allowing water to pass freely through the enclosures and the surrounding water body.
HISTORY-
Cage culture seem to have developed around 200 year ago in Cambodia where fisherman used to keep clarias spp. And some other fishes in bamboo made cage. Cage culture is traditional in part of Indonesia also attempted for the first time in air breathing fishes in swamp for raising major carp in running water in the river, Yamuna and Ganga at Allahabad and for raising Common carp , Catla , Silver carp, Rohu , Snakehead and Tilapia in still water body of Karnataka. In India sea cage start in 2007 for culture sea bass at Vishakhapatnam by CMFRI. anchored in streams which are practically open sewers. Common carp , where cage are in the southern USA. Around 80 species are being culture in cage. In India cage culture was initially culture in bamboo cage is practice in west java, since early 1940. Modern cage culture in open water bodies probably originated in Japan in early 1950. According to FAO cage culture is being practiced in more than 62 countries and has a become high tech business in developed countries such as floating and submerged cage culture of Salmonids in Norway, Canada and Scotland, Tuna and Yellowtails in Japan , Chinese carp in China, and catfish.
Modern developments in transport technology are from two levels; one is from an understanding of internal physiological mechanisms of the fish and the optimal requirements, ensuring maximum survival of fish under transport and the other is from a study of the environmental parameters of the medium in which fish are transported. Under anaesthesia fish can be transported without water even, provided the skin and gills are kept moist under low temperature. The cryopreservation of fish sperm for use at any convenient time can be referred to here, though this would concern seed production more directly than live seed transport.
Any aquatic invertebrate animals having a cutaneous or calcareous shell surrounding there body and belonging to the phylum Mollusca, the class Crustacea (phylum Arthropoda), or phylum Echinodermata is known as shellfish. The term is often used for the edible species of the groups, especially those that are fished or raised commercially. The most commercially important shellfish are:
• Mollusk: Oysters, mussels, scallops and clams
• Crustacean: Shrimp, prawn, lobster, crab and crayfish
• Echinoderm: sea urchins and sea cucumbers
Shellfish hatchery is a place where shellfish seeds are produced in a controlled way. Hatchery management is a branch of science which deals with the activities including from collection of brood shellfish to seed production. Culturing of shellfish has occurred since ancient times. Although controlled rearing of young shell has long existed, hatchery production is a more recent advancement. Producing seed under controlled conditions in a hatchery will disconnect its production from environmental factors and provide a reliable supply of seed. Oysters, mussels and mud crabs are the most important groups of shellfish after shrimp and prawn. These are popular among the western countries and becoming more popular all over the world. So hatchery management of oyster, mussel and crab is crucial.
Introduction
Fish Health Management GOALS
Principles of fish health management
Factors affecting fish health
Common symptoms of diseases
General preventive measures
Proper Health Management through Manipulating the disease triangle
Conclusion
References
Recirculating aquaculture systems (RAS) operate by filtering water from the fish (or shellfish) tanks so it can be reused within the tank. This dramatically reduces the amount of water and space required to intensively produce seafood products.
CAGE CULTURE OF FISH THEIR TREND,STATUS AND PRODUCTION Ashish sahu
Cage culture is an aquaculture production system where fish are held in Cage. Cage culture of fish utilizes existing water resources but encloses the fish in a cage which allows water to pass freely through the enclosures and the surrounding water body. Cages are used to culture several types of shell fish and finfish species in fresh, brackish and marine waters. Cages in freshwaters are used for food fish culture and for fry to fingerling rearing.
In 1950s modern cage culture began with the initiation of production of synthetic materials for cage construction. Fish production in cages became highly popular among the small or limited resource farmers who are looking for alternatives to traditional agricultural crops. The mesh size of the cage is kept smaller than the fish body. In India cage culture have been attempted first for Air breathing fish. Cage mesh netting made from synthetic material that can resist decomposition in water for a long period of time. Cage are used to culture several type of shell fish and fin fishes in fresh , brackish and marine water. Cage in fresh water are used for food fish culture and for fry to fingerling rearing. Cages are generally small, ranging in freshwater reservoirs from 1 square meter (m2) to 500 m2.
Definition –
Cage culture is a system in which the cultured Fish 0r animal are enclosed from all side allowing water to pass freely through the enclosures and the surrounding water body.
HISTORY-
Cage culture seem to have developed around 200 year ago in Cambodia where fisherman used to keep clarias spp. And some other fishes in bamboo made cage. Cage culture is traditional in part of Indonesia also attempted for the first time in air breathing fishes in swamp for raising major carp in running water in the river, Yamuna and Ganga at Allahabad and for raising Common carp , Catla , Silver carp, Rohu , Snakehead and Tilapia in still water body of Karnataka. In India sea cage start in 2007 for culture sea bass at Vishakhapatnam by CMFRI. anchored in streams which are practically open sewers. Common carp , where cage are in the southern USA. Around 80 species are being culture in cage. In India cage culture was initially culture in bamboo cage is practice in west java, since early 1940. Modern cage culture in open water bodies probably originated in Japan in early 1950. According to FAO cage culture is being practiced in more than 62 countries and has a become high tech business in developed countries such as floating and submerged cage culture of Salmonids in Norway, Canada and Scotland, Tuna and Yellowtails in Japan , Chinese carp in China, and catfish.
Modern developments in transport technology are from two levels; one is from an understanding of internal physiological mechanisms of the fish and the optimal requirements, ensuring maximum survival of fish under transport and the other is from a study of the environmental parameters of the medium in which fish are transported. Under anaesthesia fish can be transported without water even, provided the skin and gills are kept moist under low temperature. The cryopreservation of fish sperm for use at any convenient time can be referred to here, though this would concern seed production more directly than live seed transport.
Culture Of Cobia- Its Biology, Seed Collection & Culture TechniquesHaladharHembram2
Cobia , Rachycentron canadum also known as Lemon fish or Ling is an oceanodromous , migratory and pelagic fish that lives in brackish and marine waters.
The fish is popular known by the common names-Black kingfish, Black salmon, runner or sergeant fish, crab eater and Sea murrel.
It is a highly priced game fish with high market value both in domestic and international markets.
Cobia known for its excellent meat quality is a famous premium food fish highly preferred by people in Taiwan and Japan. The white meat of the fish is served in restaurants as raw fish called Sashimi.
The fast growth rate, adaptability to captive breeding (attains 6-8 kg/year) are the major attributes which makes cobia as an excellent candidate species for aquaculture.
Cobia is one of the marine finfish species with high aquaculture potential particularly for cage culture in India.
what is fresh water farming introduction,composition,farming strategies,identification and morphology,life cycle of frawns,water quality,ponds construction,food and feeding habits,Harvesting method of frawns, yield of farming ,advantages of prawns farming ,disadvantages of prawns farming.
Le diaporama dédié à la culture du milkfish offrira une exploration approfondie des multiples facettes de cette pratique aquacole. En mettant en avant les conditions environnementales optimales, il abordera les techniques de reproduction, les régimes nutritionnels recommandés, ainsi que les défis et avantages inhérents à l'élevage du milkfish. Des visuels graphiques et des images saisissantes seront incorporés pour illustrer de manière vivante le cycle de vie du poisson et dépeindre les installations d'élevage modernes. En parallèle, des données économiques viendront étayer la présentation, mettant en relief l'impact financier de cette activité. L'aspect culturel du milkfish ne sera pas négligé, mettant en lumière son importance dans diverses régions et soulignant son rôle significatif tant sur le plan économique que social. En somme, ce diaporama vise à offrir une compréhension holistique de la culture du milkfish, alliant informations pratiques et perspectives culturelles.
1. Milkfish Culture
Introduction:
The milk fish is one of the most important food
fish and protein source in the world. It makes up
about 40% of the Philippine‛s total aquaculture
production. Milkfish culture is carried out mainly
in brackish water ponds. production methods
intensified and supplemental is increasingly use to
supply the increasing demand.
2. • People of Indonesia, Philippines and Taiwan use several
hundred thousand of hectares of lands to grow Milkfish.
• This large growing activities use large numbers of young
milkfish fingerlings.
• In the past, these large number of fingerlings were met by
captured wild fingerlings.
• After the wild fingerlings were depleted in many areas in the
past 20years, large milk fish male and females.
• Maintain in ponds or net cages have been used to reproduce
the highly needed finger lings.
4. Common name of Milkfish in many
countries:
• USA: Milkfish
• Japan : Sabahii
• Central taiwan : masaba
• south taiwan : Hi Tsu Hii
• China: Su Mu Yii
• Philippines : Sabalo,Bangus
• Hawaii : Pua Awa,Awa
• Indonesia : Bendeng Bolu
5. Habits of Milkfish:
• Milkfish are herbivores and eat diatoms, blue,
green, algae, and occasionally some animals
such as nematodes and copepods. they feed
throughout the year either at the surface or
on the both pond.
6. Habitat of Milkfish
• Young milkfish migrate from the seas to the
coastal areas and may arc end estuaries, rivers
and lake before migrating back to the sea at
maturity benthopelagic , catadromous, fresh
H2o.depth range 10-13m.
7. Biology of Milkfish:
• Adults occur in small to large schools near the coastal or
around islands where reefs are well developed.
• Eggs and larvae are pelagic up to 2-3 weeks. older larvae
migrate on shore and settle in coastal wetlands during the
juvenile stage or occasionally enter fresh water lakes.
• Juvenile and sub adults return to sea where they mature
sexually. spawns only in fully saline water. larvae eat
zooplankton. juveniles and adults cyanobacteria, soft algae,
small benthic invertebrates and even pelagic fish eggs and
larvae.
• Larvae are collected from rivers and are grown in culture
ponds into juveniles which are marketed fish.
8. Spawning of Milkfish
• Maturation is reached rather week season, april-july and
september-november. Late in life at least age 4 years in
males and 5 or older in females.
• Fertilization in external, the eggs reign released in the open
sea near the shore do float to the surface.
• As many as 7million eggs have been estimated to produce
by a single large female.
• All attempts to obtain from females either by natural
spawning or by stripping in ponds have failed.
• In others milkfish spawn only during summer.
9. Early development stage of young
milkfish:
• Blastula stage
• Eye-cup forming
• Pigmentation forming
• Body elongation
• Lath embryo
• Hatching
• Stage 1:yolk sac larvae(3.2-5.4 mm) 3 days
• Stage 2:pre flexion larvae(5.0-6.3mm)5 days
• Stage 3:flexion larvae(5.4-10.0mm)6 days
• Stage 4:post flexion/fry(6.4-14.9mm)7 days
• Stage 5:transformation(6.4-14.9mm)2-4 weeks
10. Culture of milkfish
• This is extremely important aqua cultural species
wherever it occurs. sexual maturity in reach late
in life and it in difficult to induce mature fish to
spawn in captivity. because large scale artificial
propagation has not been successful, seed fish
are still obtained fro natural reproduction.
• Larval rearing in out color ponds is successful.
• 1.pre culture- benthic algae 10-30 ppt.
• 2.pond culture(brackish water) plankton method
• Cage culture(mariculture)
11. Site selection for Milkfish Culture:
• Naturally or inexpensively, qualify for locating
milkfish culture.
• Ponds should provide water retentive soil base,
exposed by digging of top soil of the site to pond
bottom and embankments.
• The soil should possess basic mineral nutrients
and respond readily to organic and inorganic
fertilizer.
• There should be a dependable source of
perennially available water in adequate quantity
for the size of the culture.
12. .Self draining ponds should be use on sloping sites.
.The physical and chemical properties of the water are
within acceptable limits, such the water quality can be
further manipulated by chemical treatment to suit
aquaculture needs.
.the site is easily accessible by rail and/or road and air.
.there is a market in the vicinity.
.there is no industrial, domestic or pesticide pollution at
the site.
.there are reasonable educational and medical facilities
available in the vicinity of the site.
13. Pond preparation:
• Pre-stoking Management
• Cleaning:
• At first we must clean the pond properly.
• We have to clean aquatic weed and cut down large plants
so that the sunlight directly fall into the pond.
• Maintenance of sanitation and good water quality are the
two most important task in the hatchery.
• For hatcheries in good sites with biologically clean water,
tanks are simply cleaned with detergent solution and
Clorox, or sprayed with hot water and diluted Clorox
applied to sites (Mc Veyand fox 1983), then dried for at
least a day before stocking.
14. • After each run, tanks as well as pipelines and
materials use in the hatchery are disinfected
with 12%Na hypo chlorite at 200 ppm for 24
hrs.
15. Ploughing the pond:
• The ponds are drained completely during low
tides. the bottom is leveled, rake with a
wooden rake or ploughed to bring the sub-
surface soil nutrients to the surface and to
eradicate weeds.
• The pond bottom is leveled in such a way that
it slopes gradually towards the deepest
portion of the pond.
16. Drying ponds:
• The ponds dried and exposed to the sun for
two or three days until the layer of surface soil
cracks.
• In order to get rid of any predatory fish or
predatory pests burrowing in the mud.
• Drying also helps in the mineralization of
organic mailer in the soil.
17. Fertilizing:
• The pond is then treated with chicken manure at the
rate of 2 tons/ha.
• Water is just to cover the pond bottom and 150kg/ha
of 16-20-ONPK fertilizer or half that quantity of 18-46-
ONPK fertilizer per ha, is added after 2or 3 days.in
order to speed up the breakdown of the chicken
manure, urea may be added at the rate of 25kg/ha.
Within a week lablab growth start.
• The water level in the pond is then gradually increased
to 25-30 cm in a period of one and half-month
increasing the level by 3-5cm each time.
18. Watering:
• Watering should be done after 4-7 days of
fertilizing. Watering is done by water pump or
other source. Water is done up to 2-4 feet.
19. Stocking:
• Fry can be stocked directly in the nursery
pond if the salinity of the water in which the
transported is approximately the same as the
salinity of the pond water.
20. Stocking management:
• The density of fry in the nurseries is generally 30-
50 per m². some exchange of water may be
needed it is reported that the growth of Milkfish
fry is retarded at salinity above 45ppt.
• Favorable temperatures for growth are above
23˚c. artificial feeds like rice bream or dried
cumut are provide.
• In about one and half to two, the fry have growth
to a weight of 1-3g and are then either stock in
the rearing ponds or transferred to transition or
stunting ponds.
21. Fry selection
• Fry should be healthy
• Fry must be diseases free
• It can tolerant environmental fluctuation
• The fry captured are between 10-30mm. In
length.
22. Fry collection and transportation:
• This includes fry barriers or fences, sine net and
bulldozer nets.
• The collected milkfish fry placed in well ventilated
containers preferably wooden vats of big earthen
jar filled with clean brackish water.
• The containers must be kept in cool areas.
• Over exposed to sun light should be avoided.
• The fry should also be brought to the
concessionaries buying stations without delay.
23. Stocking density:
• Repeated stocking is done with fingerlings and
fry of different sizes.
• Stocking rates may be as follows:2000 to 2500
fish per ha. For large over wintered
fingerlings:1500to200 fish per ha. For
small:6000 to 7000 fish/ha.
• Some ponds are stocked at a low density for
4000 fry/ha. To ensure faster growth.
24. Species composition:
• In freshwater ponds milk fish can be cultured
with mullet, tilapia and carp with yields
averaging 7,500 kg/ha.
• In brackish water ponds, shrimp, mud crabs
and sea bass most common species combined
with milkfish.
25. Feeding of Milkfish:
• Fish feeds are 2 types, such as natural feeds –
plankton, benthos which is produced in ponds
by minoring.
• The other is supplementary feed such as rich
bran, wheat brand, sesame oil cake, mustard
oil cake, grasses etc.
26. Monitoring:
• Environmental parameters such as water
temperature, salinity and pн should be checked
twice daily.
• MAINTAINING WATER QUALITY:
• Cleanliness must be strictly maintained to ensure
best results. constant vigilance is required to
prevent or control out breaks of disease.
• The wall of the tank should be cleaned with a soft
brush every third day.
27. Health management of milkfish:
• 1:regularly have to control the water quality.
• 2:regularly have to given the supplementary
feed and life food.
• 3:have to observe the growth rate of milkfish.
• 4:have to maintain the pн temp. salinity etc.
• 5:regularly have to observe the fry to free
from discuses and parasites.
28. Suitability of culture of Milkfish:
• Economically friendly
• Highly productivity
• High community acceptance
• Sustainable culture of Milkfish depends on
various factors,
• For sustainable development the following
variables are important.
• Production aspects
• Environmental aspects
• Economics and community aspects
29. Advantages of Milkfish culture:
• Milkfish spawners have a high fecundity, they are
capable of producing an abundant supply of fry.
• The fry are easy identify and are caught in
season.
• Milkfish are hardy, euryhaline and are capable of
enduring a salinity range of 0 to 158 ppt.
• They are basically herbivorous but they can be
also omnivorous.
• Formulated feed for Milkfish can be available at
low costs.
30. Advantages of milkfish culture:
• 1.Milkfish spawners have high fecundity.
• 2.the fry are easy identified and are caught in season.
• 3.Milkfish fry can be obtained in captivity and they are
not difficult to rear.
• 4.Milkfish are hardy, capable of enduring a salinity
range of 0 to 158ppt.
• 5.are basically herbivorous but they can be also a
omnivorous
• 6.formuated feed
• 7.highly potable
31. Disadvantages of Milkfish culture:
• 1.low survival rates for larvae.
• 2.over wintering-sometimes high mortality occurs due to
low temp.
• 3.diseas-as a result of high density.
• 4.coordination of population and marketing.
• 5.high production cost
• 6.occurrence of calamities
• 7.security problems
• 8.inflation
• 9.shortage at fry supply
• 10.lack of infrastructure in many areas
• 11.environmental problems