A fish hatchery is a
"place for artificial breeding, hatching and rearing through the early
life stages of animals, finfish and shellfish in particular". Hatcheries
produce larval
and juvenile
fish (and shellfish and crustaceans) primarily to support the aquaculture
industry where they are transferred to on-growing systems i.e. fish farms to
reach harvest size. Some species that are commonly raised in hatcheries include
Pacific oysters, shrimp,
Indian prawns, salmon, tilapia and scallops. The value of global aquaculture
production is estimated to be US$98.4 billion in 2008 with China significantly
dominating the market, however the value of aquaculture hatchery and nursery production
has yet to be estimated. Additional hatchery production for small-scale
domestic uses, which is particularly prevalent in South-East Asia or for
conservation programmes, has also yet to be quantified.
There is much interest in
supplementing exploited stocks of fish by releasing juveniles that may be wild
caught and reared in nurseries before transplanting, or produced solely within
a hatchery. Culture of finfish larvae has been utilised extensively in the
United States in stock enhancement efforts to replenish natural populations.
The U.S. Fish and Wildlife Service have established a National Fish Hatchery System to
support the conservation of native fish species.
Purpose
Hatcheries produce larval and
juvenile fish and shellfish for transferral to aquaculture facilities where
they are ‘on-grown’ to reach harvest size. Hatchery production confers three
main benefits to the industry;
1. Out of season production
Consistent supply of fish from aquaculture facilities is an important market requirement. Broodstock conditioning can extend the natural spawning season and thus the supply of juveniles to farms. Supply can be further guaranteed by sourcing from hatcheries in the opposite hemisphere i.e. with opposite seasons.
2. Genetic improvement
Genetic modification is conducted in some hatcheries to improve the quality and yield of farmed species. Artificial fertilisation facilitates selective breeding programs which aim to improve production characteristics such as growth rate, disease resistance, survival, colour, increased fecundity and/or lower age of maturation. Genetic improvement can be mediated by selective breeding, via hybridization, or other genetic manipulation techniques.
3. Reduce dependence on wild-caught juveniles
In 2008 aquaculture accounted for 46% of total food fish supply, around 115 million tonnes. Although wild caught juveniles are still utilised in the industry, concerns over sustainability of extracting juveniles, and the variable timing and magnitude of natural spawning events, make hatchery production an attractive alternative to support the growing demands of aquaculture.
1. Out of season production
Consistent supply of fish from aquaculture facilities is an important market requirement. Broodstock conditioning can extend the natural spawning season and thus the supply of juveniles to farms. Supply can be further guaranteed by sourcing from hatcheries in the opposite hemisphere i.e. with opposite seasons.
2. Genetic improvement
Genetic modification is conducted in some hatcheries to improve the quality and yield of farmed species. Artificial fertilisation facilitates selective breeding programs which aim to improve production characteristics such as growth rate, disease resistance, survival, colour, increased fecundity and/or lower age of maturation. Genetic improvement can be mediated by selective breeding, via hybridization, or other genetic manipulation techniques.
3. Reduce dependence on wild-caught juveniles
In 2008 aquaculture accounted for 46% of total food fish supply, around 115 million tonnes. Although wild caught juveniles are still utilised in the industry, concerns over sustainability of extracting juveniles, and the variable timing and magnitude of natural spawning events, make hatchery production an attractive alternative to support the growing demands of aquaculture.
Production steps
Broodstock
Broodstock
conditioning is the process of bringing adults into spawning condition by
promoting the development of gonads. Broodstock conditioning can also extend
spawning beyond natural spawning periods, or for production of species reared
outside their natural geographic range with different environmental conditions.
Some hatcheries collect wild adults and then bring them in for conditioning
whilst others maintain a permanent breeding stock. Conditioning is achieved by
holding broodstock in flow-through tanks at optimal conditions for light,
temperature, salinity, flow rate and food availability (optimal levels are
species specific). Another important aspect of broodstock conditioning is
ensuring the production of high quality eggs to improve growth and survival of
larvae by optimising the health and welfare of broodstock individuals. Egg
quality is often determined by the nutritional condition of the mother. High
levels of lipid reserves in particular are required to improve larval survival
rates.
Spawning
Natural spawning can
occur in hatcheries during the regular spawning season however where more
control over spawning time is required spawning of mature animals can be
induced by a variety of methods. Some of the more common methods are:
Manual stripping : For shellfish, gonads are generally removed and gametes are extracted or washed free. Fish can be manually stripped of eggs and sperm by stroking the anaesthetised fish under the pectoral fins towards the anus causing gametes to freely flow out.
Environmental manipulation: Thermal shock, where cool water is alternated with warmer water in flow-through tanks can induce spawning. Alternatively, if environmental cues that stimulate natural spawning are known, these can be mimicked in the tank e.g. changing salinity to simulate migratory behaviour. Many individuals can be induced to spawn this way, however this increases the likelihood of uncontrolled fertilisation occurring.
Chemical injection: A number of chemicals can be used to induce spawning with various hormones being the most commonly used.
Manual stripping : For shellfish, gonads are generally removed and gametes are extracted or washed free. Fish can be manually stripped of eggs and sperm by stroking the anaesthetised fish under the pectoral fins towards the anus causing gametes to freely flow out.
Environmental manipulation: Thermal shock, where cool water is alternated with warmer water in flow-through tanks can induce spawning. Alternatively, if environmental cues that stimulate natural spawning are known, these can be mimicked in the tank e.g. changing salinity to simulate migratory behaviour. Many individuals can be induced to spawn this way, however this increases the likelihood of uncontrolled fertilisation occurring.
Chemical injection: A number of chemicals can be used to induce spawning with various hormones being the most commonly used.
Fertilisation
Prior to fertilisation,
eggs can be gently washed to remove wastes and bacteria that may contaminate
cultures. Promoting cross-fertilisation between a large number of
individuals is necessary to retain genetic diversity in hatchery produced
stock. Batches of eggs are kept separate, fertilised with sperm obtained from
several males and allowed to stand for an hour or two before samples are analysed
under a microscope to ensure high rates of fertilisation and to estimate
numbers to be transferred to larval rearing tanks.
Larvae
Rearing larvae through the early
life stages is conducted in nurseries which are generally closely associated
with hatcheries for fish culture whilst it is common for shellfish nurseries to
exist separately. Nursery culture of larvae to rear juveniles of a size
suitable for transferral to on-growing facilities can be performed in a variety
of different systems which may be entirely land-based, or larvae may be later
transferred to sea-based rearing systems which reduce the need to supply feed.
Juvenile survival is dependent on very high quality water conditions. Feeding
is an important component of the rearing process. Although many species are
able to grow on maternal reserves alone (lecithotrophy), most commercially
produced species require feeding to optimise survival, growth, yield and
juvenile quality. Nutritional requirements are species specific and also vary
with larval stage. Carnivorous fish are commonly fed with live prey; rotifers are
usually offered to early larvae due to their small size, progressing to larger Artemia
nauplii or zooplankton. The production of live feed on-site or
buying-in is one of the biggest costs for hatchery facilities as it is a
labour-intensive process. The development of artificial feeds is targeted to
reduce the costs involved in live feed production and increase the consistency
of nutrition, however decreased growth and survival has been found with these
alternatives.
Settlement of shellfish
The hatchery production of
shellfish also involves a crucial settling phase where free-swimming larvae
settle out of the water onto a substrate and undergo metamorphosis
if suitable conditions are found. Once metamorphosis has taken place the
juveniles are generally known as spat, it is this phase which is then
transported to on-growing facilities. Settlement behaviour is governed by a
range of cues including substrate type, water flow, temperature, and the
presence of chemical cues indicating the presence of adults, or a food source
etc. Hatchery facilities therefore need to understand these cues to induce
settlement and also be able to substitute artificial substrates to allow for
easy handling and transportation with minimal mortality.
Hatchery design
Hatchery designs are highly
flexible and are tailored to the requirements of site, species produced,
geographic location, funding and personal preferences. Many hatchery facilities
are small and coupled to larger on-growing operations, whilst others may
produce juveniles solely for sale. Very small-scale hatcheries are often
utilized in subsistence farming to supply families or communities particularly
in south-east Asia. A small-scale hatchery unit consists of larval rearing
tanks, filters, live food production tanks and a flow through water supply. A
generalized commercial scale hatchery would contain a broodstock holding and
spawning area, feed culture facility, larval culture area, juvenile culture area,
pump facilities, laboratory, quarantine area, and offices and bathrooms.
Expense
Labour is generally the largest
cost in hatchery production making up more that 50% of total costs. Hatcheries
are a business and thus economic viability and scale of production
are vital considerations. The cost of production for stock-enhancement programmes
is further complicated by the difficulty of assessing the benefits to wild
populations from restocking activities.
Issues
Genetic
Hatchery facilities present three
main problems in the field of genetics. The first is that maintenance of a
small number of broodstock can cause inbreeding and potentially lead to inbreeding depression thus affecting the
success of the facility. Secondly, hatchery reared juveniles, even from a
fairly large broodstock, can have greatly reduced genetic diversity compared to
wild populations (the situation is comparable to the founder
effect). Such fish that escape from farms or are released for restocking
purposes may adversely affect wild population genetics and viability. This is
of particular concern where escaped fish have been actively bred or are
otherwise genetically modified. The third key issue is that genetic
modification of food items is highly undesirable for many people. See: Genetically modified food
controversies
Fish farms
Other arguments that surround fish
farms such as the supplementation of feed from wild caught species, the
prevalence of disease, fish welfare issues and potential effects on the environment are also
issues for hatchery facilities. For more information see: Aquaculture,
Mariculture,
Fish
farming
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