The document discusses the basic biological requirements for successful aquaculture, including temperature, water flow, water quality, protection from predators/pathogens/competitors, food, stocking densities, culture unit type, and protection from environmental stressors. It states that temperature and food availability are usually the two most important factors influencing growth and survival, and optimizing these is important for maximizing production. The document provides examples of temperature and salinity tolerances for different marine and freshwater species.
The European lobster (Homarus gammarus) is an ecologically important species of the North-eastern Atlantic which supports wild trap fisheries that are worth around £30 million each year to the UK alone. By weight the species is the highest-value seafood among those landed regularly in the UK and Ireland, where 75 percent of the ~5,000t annual landings for the species are made. As such, lobsters provide essential diversity to fragile inshore fisheries and vital income for rural coastal economies. However, populations across its range are pressured by rising exploitation, from which traditional fisheries management has failed to prevent extensive regional stock collapses in the recent past, and now struggles to stimulate recovery. While lobsters have long been transported as a live export commodity, chiefly to France and the Iberian peninsula, emerging markets, particularly those in East Asia, threaten to create additional demand for the species which far exceeds current capture yields. Improvements in hatchery rearing success have seen a number of recent aquaculture initiatives employed, in the hope of both generating restoration and improved sustainability of wild harvests, and instigating commercial aquaculture possibilities.
The European lobster (Homarus gammarus) is an ecologically important species of the North-eastern Atlantic which supports wild trap fisheries that are worth around £30 million each year to the UK alone. By weight the species is the highest-value seafood among those landed regularly in the UK and Ireland, where 75 percent of the ~5,000t annual landings for the species are made. As such, lobsters provide essential diversity to fragile inshore fisheries and vital income for rural coastal economies. However, populations across its range are pressured by rising exploitation, from which traditional fisheries management has failed to prevent extensive regional stock collapses in the recent past, and now struggles to stimulate recovery. While lobsters have long been transported as a live export commodity, chiefly to France and the Iberian peninsula, emerging markets, particularly those in East Asia, threaten to create additional demand for the species which far exceeds current capture yields. Improvements in hatchery rearing success have seen a number of recent aquaculture initiatives employed, in the hope of both generating restoration and improved sustainability of wild harvests, and instigating commercial aquaculture possibilities.
What is the stocking density of fish in semi intensive cultureihn FreeStyle Corp.
Stocking Density: Stocking density also known as per-unit stocking amount or stocking rate, refers to the quantity of fry or fingerlings per unit of water area.
Poly Culture: The concept of poly culture of fish is based on the concept of total utilization of different trophic and spatial niches of a pond in order to obtain maximum fish production per unit area. Different compatible species of fish of different trophic and spatial niches are raised together in the same pond to utilize all sorts of natural food available in the pond.
Semi Intensive Culture: Semi-intensive culture systems depend largely on natural food which is increased over baseline levels by fertilization and/or use of supplementary feed to complement natural food.
This presentation gives an overview of various aspects relevant to sustainable aquaculture. it consists of 3 sections:
- what is aquaculture
- threats, challenges & opportunities
- conclusions
Fish culture is classified based on the number of fish species as monoculture and polyculture. This is the culture of single species of fish in a pond or tank. The culture of trout, tilapia, catfish , carps are typical examples of monoculture.
"The Health of our Planet as well as our own health and future food security all hinge on how well we treat the Blue water "
FOA Director General Jose Graziano Da Silva
What is the stocking density of fish in semi intensive cultureihn FreeStyle Corp.
Stocking Density: Stocking density also known as per-unit stocking amount or stocking rate, refers to the quantity of fry or fingerlings per unit of water area.
Poly Culture: The concept of poly culture of fish is based on the concept of total utilization of different trophic and spatial niches of a pond in order to obtain maximum fish production per unit area. Different compatible species of fish of different trophic and spatial niches are raised together in the same pond to utilize all sorts of natural food available in the pond.
Semi Intensive Culture: Semi-intensive culture systems depend largely on natural food which is increased over baseline levels by fertilization and/or use of supplementary feed to complement natural food.
This presentation gives an overview of various aspects relevant to sustainable aquaculture. it consists of 3 sections:
- what is aquaculture
- threats, challenges & opportunities
- conclusions
Fish culture is classified based on the number of fish species as monoculture and polyculture. This is the culture of single species of fish in a pond or tank. The culture of trout, tilapia, catfish , carps are typical examples of monoculture.
"The Health of our Planet as well as our own health and future food security all hinge on how well we treat the Blue water "
FOA Director General Jose Graziano Da Silva
Presentation on “FAO, One Health, Environmental Stewardship and Veterinary Medicine” delivered on the occasion of the World Aquatic Veterinary Medical Association Conference, held in Basseterre, St. Kitts and Nevis, from on 9 November 2018.
Standard water quality requirements and management strategies for fish farmin...eSAT Journals
A study on standard water quality requirements and management strategies suitable for fish farming is presented. The water quality criteria studied based on physical, chemical and biological properties of water include temperature, turbidity, total suspended solids (TSS), total dissolved solid (TDS), nitrate- nitrogen, pH, biochemical oxygen demand (BOD) and total hardness. Water samples from Otamiri River in Imo state, Nigeria, were analyzed based on the afore-mentioned criteria to assess its suitability as a source of water for fish farming. The results of the analysis compared with international standards revealed that the river temperature of 26.90C, nitrate-nitrogen value of 0.015 mg/l and total suspended solids of 18.60 mg/l fall within the acceptable range for fish farming. However, the pH of 5.82, total hardness of 5.8 mg/l, total dissolved solids of 13.60 mg/l and biochemical oxygen demand of 0.6 mg/l all differed slightly from the standard recommended values. This study will aid fish farmers on the necessary treatment needed to effectively use water from this source for fish farming.
Keywords: Water quality criteria, Otamiri River, biochemical oxygen demand, total suspended and total dissolved solids.
This is a brief account of the economics of fish industry, based mostly in Pakistan, detailing some edible freshwater species, culture methods, and economic importance of fish in general.
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Francesca Gottschalk from the OECD’s Centre for Educational Research and Innovation presents at the Ask an Expert Webinar: How can education support child empowerment?
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Prepare a presentation or a paper using research, basic comparative analysis, data organization and application of economic information. You will make an informed assessment of an economic climate outside of the United States to accomplish an entertainment industry objective.
Operation “Blue Star” is the only event in the history of Independent India where the state went into war with its own people. Even after about 40 years it is not clear if it was culmination of states anger over people of the region, a political game of power or start of dictatorial chapter in the democratic setup.
The people of Punjab felt alienated from main stream due to denial of their just demands during a long democratic struggle since independence. As it happen all over the word, it led to militant struggle with great loss of lives of military, police and civilian personnel. Killing of Indira Gandhi and massacre of innocent Sikhs in Delhi and other India cities was also associated with this movement.
Embracing GenAI - A Strategic ImperativePeter Windle
Artificial Intelligence (AI) technologies such as Generative AI, Image Generators and Large Language Models have had a dramatic impact on teaching, learning and assessment over the past 18 months. The most immediate threat AI posed was to Academic Integrity with Higher Education Institutes (HEIs) focusing their efforts on combating the use of GenAI in assessment. Guidelines were developed for staff and students, policies put in place too. Innovative educators have forged paths in the use of Generative AI for teaching, learning and assessments leading to pockets of transformation springing up across HEIs, often with little or no top-down guidance, support or direction.
This Gasta posits a strategic approach to integrating AI into HEIs to prepare staff, students and the curriculum for an evolving world and workplace. We will highlight the advantages of working with these technologies beyond the realm of teaching, learning and assessment by considering prompt engineering skills, industry impact, curriculum changes, and the need for staff upskilling. In contrast, not engaging strategically with Generative AI poses risks, including falling behind peers, missed opportunities and failing to ensure our graduates remain employable. The rapid evolution of AI technologies necessitates a proactive and strategic approach if we are to remain relevant.
Unit 8 - Information and Communication Technology (Paper I).pdfThiyagu K
This slides describes the basic concepts of ICT, basics of Email, Emerging Technology and Digital Initiatives in Education. This presentations aligns with the UGC Paper I syllabus.
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In this webinar you will learn how your organization can access TechSoup's wide variety of product discount and donation programs. From hardware to software, we'll give you a tour of the tools available to help your nonprofit with productivity, collaboration, financial management, donor tracking, security, and more.
A Strategic Approach: GenAI in EducationPeter Windle
Artificial Intelligence (AI) technologies such as Generative AI, Image Generators and Large Language Models have had a dramatic impact on teaching, learning and assessment over the past 18 months. The most immediate threat AI posed was to Academic Integrity with Higher Education Institutes (HEIs) focusing their efforts on combating the use of GenAI in assessment. Guidelines were developed for staff and students, policies put in place too. Innovative educators have forged paths in the use of Generative AI for teaching, learning and assessments leading to pockets of transformation springing up across HEIs, often with little or no top-down guidance, support or direction.
This Gasta posits a strategic approach to integrating AI into HEIs to prepare staff, students and the curriculum for an evolving world and workplace. We will highlight the advantages of working with these technologies beyond the realm of teaching, learning and assessment by considering prompt engineering skills, industry impact, curriculum changes, and the need for staff upskilling. In contrast, not engaging strategically with Generative AI poses risks, including falling behind peers, missed opportunities and failing to ensure our graduates remain employable. The rapid evolution of AI technologies necessitates a proactive and strategic approach if we are to remain relevant.
Palestine last event orientationfvgnh .pptxRaedMohamed3
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2. Basic Biological Requirements
All living organisms have basic biological requirements for growth, reproduction and
survival. These requirements will vary with species, and may even change throughout
the life of the organism. In aquaculture, in order to obtain the best growth and survival in
these animals it is important to concentrate on optimising several special requirements:
● Water temperature (affects metabolic rate);
● Water flow;
● Water quality (salinity, oxygen, pH, etc);
● Protection from Pests, Predators, Pathogens and Competitors
● Food (quantity and quality);
● Stocking densities (numbers of other livestock or other competitors for food, etc);
● Types of culture unit;
● Protection from elements (sun, wind, rough weather, etc);
● Genetics (selectively bred from a hatchery or wild caught);
● Stress which can be caused by a number of different factors, most of which are
discussed later in this presentation.
3. Most Important
Factors
Temperature and food availability (quantity and quality) are
usually the two factors having the greatest influence on stock growth
and survival. If these factors are not optimised then the growth and
survival of any species is likely to be compromised and suboptimal.
Most aquaculture production systems are designed and operated to
optimise these in an economical manner. These are discussed in the
following slides but (the former is discussed in detail in Session 11,
feeding is discussed in detail in Session 12).
4. Water Temperature
All fish, molluscs and crustaceans are cold-blooded or
Poikilotherms. They have limited ability to manage
their body temperatures which means it is determined
by the surrounding waters ambient temperature.
Therefore, temperature is a key requirement as it
effects the metabolic rate, and thus growth rates.
The terms tropical or warmwater species generally
refers to those that originate from tropical climates
with water temperatures over 20OC, whereas
coldwater or temperate species normally live in water
below 20OC.
5. Water Temperature
However, the optimal temperature range varies with species - eg in Rainbow
Trout the optimal oC is around 14-16 oC, whereas in Tilapia it is around 24-32
oC.
Higher temperatures above this range make the livestock more prone to
stress, which can lead to disease infections, and even death.
Any lower temperatures below this range can lead to slowing of growth, with
very low temperatures causing stress, disease or death.
Therefore for any species there is an optimal, upper limit and lower limit
temperature – some examples for temperature profiles of different species
are given on the following slides
6. Temperature Tolerances of Marine Species
(Figures relate to adults)
Temperature
(o
C)
Southern
Bluefin
Tuna
Mussels Abalone Ocean
Trout
Atlantic
Salmon
No growth
(death)
>22 >24 >24 >22 >22
Optimal
growth
12 - 13 17 – 21 16 – 20 17 – 19 16 – 19
Slow or no
growth
<10 <13 <13 <10 <11
Temperatures in the sea are usually fairly constant. Seasonal variations
can result in changes of 2 to 5o
C but usually these occur over several
months. In contained waters (such as ponds, tanks, raceways),
temperatures can vary by several degrees over a 24 hour period. In
shallow bays the temperature can vary with the tides!
7. Temperature
(o
C)
Pacific
Oysters
Sydney
rock
Oysters
Marine
Finfish
(Snapper)
Barramund
i
Prawn
s
No growth
(death)
>26 >30 >26 >33 >30
Optimal
growth
18 - 20 22 - 26 18 – 24 26 – 30 27 – 28
Slow or no
growth
<13 <16 <16 <24 <20
Temperatures in the sea are usually fairly constant. Seasonal variations
can result in changes of 2 to 5o
C but usually these occur over several
months. In contained waters (such as ponds, tanks, raceways),
temperatures can vary by several degrees over a 24 hour period. In
shallow bays the temperature can vary with the tides!
Temperature Tolerances of Marine Species
(Figures relate to adults)
8. Temperature Tolerances of FW Species
To obtain a rough estimate of water temperatures, calculate the halfway
point between the average monthly maximum and minimum air
temperatures (Meteorological Bureau). This is only useful for ponds less
than 2m deep.
Low temperature = low growth = loss of production.
Temperature
(oC)
Barramundi
Murray
Cod
Other
Native
Finfish
Yabby
Red
claw
No growth
(death)
>33 >30 >28 >33 >32
Optimal
growth
26 - 30 23 - 28 21 - 26
22 –
28
26 - 30
Slow or no
growth
<24
<17 –
18
<15 –
17
<15 <20
Figures relate to adults
9. Temperature Tolerances of FW Species
To obtain a rough estimate of water temperatures, calculate the halfway
point between the average monthly maximum and minimum air
temperatures (Meteorological Bureau). This is only useful for ponds
less than 2m deep.
Low temperature = low growth = loss of production.
Temperature
(oC)
Ornamentals Marron Silver
Perch
Rainbow
Trout
Eels
No growth
(death)
>24 >30 >30 >24 >28
Optimal
growth
18 - 22 20 – 25 19-21 15 – 18 18 - 22
Slow or no
growth
<14 – 15 <12 – 14 <15 <10 <12
Figures relate to adults
10. Water Flow
Water flow serves a variety of functions, and ensuring
adequate water flow in aquaculture production systems is
critical to successful farming. Some of the key functions of
water flow for fish and crustaceans include:
● Replenishes oxygen in the water.
● Bring in food (suspended zooplankton, small Finfish,
shrimp, etc), however, these usually represent a small
proportion of the food requirements of the Finfish or
Crustaceans.
● Removes wastes (faeces, uneaten food, carbon dioxide,
nitrogenous products).
● Will also bring in pests (eg net or tank fouling organisms),
competitors, predators and diseases.
● Too much flow can also damage the Finfish or Crustaceans
often won’t be able to feed properly leading to emancipation
and maybe death.
11. Water Flow - Molluscs
Water flow is also important for Molluscan species to
replenish oxygen in the water. It can also bring in food
for the culture organism (Bivalves eat suspended
phytoplankton, abalone and other Gastropods mostly
eat drift algae [seaweeds] or algal scum on surfaces).
The water flow replenishes food supply or nutrients for
seaweed / algal growth and, removes wastes (faeces,
uneaten food, pseudo-faeces, carbon dioxide,
nitrogenous products).
It will also bring in pests (eg fouling organisms),
competitors, predators and diseases, therefore
appropriate exclusion measures must be taken. Too
much water flow can also damage the Molluscs being
grown or the culture structures.
12. Water Quality
As well as the amount of water flow, the quality of the water is
also important. There are many different parameters of water
quality, with the most important including pH, dissolved oxygen,
salinity and nitrogenous wastes. Levels of pollution such as
sewage, heavy metals, petroleum products, etc) and
contaminants such as sewage can effect food safety, as well
as growth and health of livestock. Suspended solids or
sediments (eg clay or silt) can block gills and smother the
livestock which reduces feeding rates and growth.
It must be recognised that water quality will vary daily, weekly
and seasonally across the year.
13. Reflection question
What are the main water quality requirements of your holding or culture
stock? If you have several species, do you know the requirements
for all?
Species name: ________________
Temperature (oC) ________________
Dissolved oxygen (mg/L) ________________
Salinity (g/L) ________________
pH ________________
NH3 or NO2 ________________
Water flow (cm/sec) ________________
Turbidity (secchi disc cm) ________________
Other (________________)
14. Predators, Pathogens & Competitors -
Fish
A wide range of organisms can reduce the health or even
kill the Finfish or Crustaceans. They can be divided into
the following groups:
● Pests can cause fouling which can be a major issue
with seacages or pump ashore tanks of Crustaceans
or Finfish.
● Predators and pathogens are often difficult to control
in open water systems such as cages, better control is
possible in on-land systems such as tanks and ponds.
● Competitors can be for space, food or oxygen.
Individuals from the same species can be competitors
(larger, faster growing individuals can out compete
smaller animals).
15. Predators, Pathogens & Competitors -
Molluscs
A wide range of organisms can also reduce the
health of, or even kill Molluscs. Pests in terms of
fouling organisms can be a major issue with
Bivalve culture and often one of the major work
tasks on mollusc farms is removing this fouling.
Predators and pathogens are often difficult to
control in open water systems, and better control is
possible in on-land systems.
Competition can also effect Molluscs in terms of
space, food or oxygen. Individuals from the same
species can be competitors (larger, faster growing
individuals can out compete smaller animals).
16. Food for Finfish & Crustaceans
All Finfish and Crustaceans require food to grow, in terms
of quality (protein, carbohydrates, fats, vitamins etc.) and
quantity of feeds. Naturally occurring live foods are
important for fry and juveniles however for growout most
species are fed formulated (artificial) diets such as
crumbles and pellets.
The quality, quantity, availability and timing of feeding will
influence the growth and survival. Therefore, feed
management is often closely managed to ensure it is not
wasted – feed costs can be as high as 50 to 60% of total
production costs. This is easy to control in on-land
systems (easy access), however, site selection is very
important for open water (cage) culture systems (weather
conditions can delay feedings).
17. Food for Finfish & Crustaceans
Phytoplankton or algae can be eaten by some
herbivorous species – in this case there needs to be
nutrients and light for photosynthesis (nutrients can
come from land-based sources, usually washed
down rivers or waterways, or from upwellings or
current flow). This is sometimes referred to as
‘greenwater’ culture.
However, the majority of juveniles eat zooplankton
(need to be small enough for the animal to ingest).
They may also eat small insects, worms, Finfish,
Crustaceans and so on. Organic matter, either
suspended or benthic (detritus) can be eaten by
some scavenger species (eg catfish).
18. Food for Finfish & Crustaceans
Nearly all modern Finfish and Crustacean
farms utilise man-made pelleted diets
formulated for specific species requirements of
the adults.
They occasionally may be given live feeds or
other wet foods. However this is more
common in the Ornamental sector and on
Tuna farms.
This is discussed in detail in Session 12
Foods and Feeding of Stock.
19. Food for Molluscs
All Molluscs also require food to grow. Naturally occurring
foods such as algae and seaweeds or formulated (artificial)
diets such as abalone pellets are required. The quality,
quantity, availability and timing of feeding will influence growth
and survival.
This is easy to control in on-land systems, however, site
selection is very important for open water culture systems
which rely on naturally occurring feed organisms for feeding
Bivalve stock.
When choosing a site for mollusc farms, it is important to
choose one that has good concentrations of suitable
microalgal species
20. Competition for Food - Fish
‘Competition’ can occur between individuals when
there are too many animals in the one area which
results in increased competition for food.
Larger more aggressive Finfish or Crustaceans will
tend to dominate the feeding, and feeding
hierarchies can be established.
This is overcome by ensuring sufficient feeding
levels and the spreading of feed around the pond.
This is overcome by regular size grading – see
Session 15 Handling and Harvesting Stock for
more information.
Careful observation is needed to ensure that all
stocks are feeding.
21. Competition for Food - Mollusc
‘Shading’ can occur when there are too many
filter feeders (Bivalves) in the one area which
results in increased competition on the lease for
food.
Food needs can vary between species, eg oysters
and razorfish (a type of clam) are okay together as
the razorfish eat more benthic materials (detritus).
However, the situation is not so good for oysters
and mussels, as mussels filter at a much higher
rate and would out compete the oysters for food.
The layout of shellfish leases in an area need to
take this into account to maximise the production
of the area.
22. Stocking Densities - Fish
Stocking density is a measure of how many fish are stocked per unit – this can be
measured or expressed in many ways e.g.
● Kg of fish per cubic metre of water
● Number of fish per tank
● Number of fish per litre
● Number of fish per square metre of floor space
Appropriate stocking densities are critical and they can provide a method to manage
or slow growth rates due to the level of competition between stock (mainly in tanks).
However, we need to ensure that Finfish are not damaging each other at high
densities, eg. fin nipping, spiking, scale loss. Understocking can be just as big a
problem as overstocking, eg. some species need a critical mass of animals to initiate
appropriate feeding behaviour such as Finfish feeding schools.
This is also discussed in Session 15.
23. Stocking Densities - Crustacean
Appropriate stocking densities are critical for good, even growth rates of
Crustaceans. Excessive levels result in slow growth rates due to the level of
competition (space, feed, oxygen) between stock. Damage to legs and antennae can
also occur at high densities with elevated stress offering an opening to disease.
Cannibalism can also increase with stocking density, with increased cannibalism
occurring during moulting.
As most crustaceans are benthic or live on the floor of the culture system, stocking
density is generally expressed in quantity per square metre.
This is also discussed in Session 15 Handling and Harvesting Stock.
24. Stocking Densities - Mollusc
Appropriate stocking densities are critical and they provide a method to control
growth rates (fast or slow) due to the level of competition between Molluscs.
Understocking can be just as big a problem as overstocking, eg not enough oysters
in a basket can lead to excessive rumbling which damages the growing margin of
the shell.
Stocking densities should take into account numbers of other filter feeders that
would compete with Molluscs for food.
This is also discussed in Session 15 Handling and Harvesting Stock.
25. Type of Culture or Holding Unit - Fish
The overall traits of the species to be cultured or held must be taken into account
when selecting the type of unit or structure. The type of culture system can influence
a wide range of factors including:
• Access to food and oxygen;
• Culture unit fouling levels;
• Stocking densities;
• Ease of handling, stocking, harvesting.
ith most species there is often a range of technologies that can be chosen, eg both
Rainbow Trout and Barramundi are grown in freshwater ponds, raceways and
cages, seawater cages, recirculating tanks and flow-through tanks and raceways,
whilst Yabbies are mainly grown in earthen ponds. The type of system will depend
on the biological needs of the culture species and the economics of providing this in
a way that generates a profit for the farmer.
26. Type of Culture or Holding Unit - Mollusc
The types of culture units can influence a wide range of factors including:
● Access to food and oxygen;
● Rumbling or fouling levels;
● Stocking densities;
● Ease of handling, stocking, harvesting.
Single seed or individual Bivalves can utilise a range of different culture units, whilst
attached Bivalves are usually only on sticks or a similar substrate. Abalone need a
substrate to move around on, either cages, tanks or raceways.
27. Type of Culture or Holding Unit
We have already discussed Extensive Production systems, these are generally
Farm ponds and dams and are similar to natural conditions.
● Stocking densities are low (close to natural levels)
● Little or no water quality maintenance.
● Stock uses naturally occurring feed.
● Cost of production is low but so are yields.
● Usually hobby ventures or small scale production in non-specialised waterways
such as irrigation ditches, gully dams, natural soaks etc.
Limited food and control over the environment limit productivity and can lead to
stress and compromises growth and survival on the culture species in extensive
production systems.
28. Types of Culture Unit
Semi-intensive – commercial ponds & dams is usually undertaken
in specially constructed ponds, tanks, dams or areas of enclosed
water.
● Stocking densities are moderate to high
● Moderate to high water quality maintenance (aeration & exchange)
● Stock uses naturally occuring and supplemented feed.
● Cost of production is raised but so are yields.
● Ponds can be used for controlled breeding, commercial growout,
holding and stock manipulation
The ability to have some control over critical factors such as oxygen
levels and other environmental factors, along with provision of
artificial feeds improves the stress management of the culture species
and increases growth and survival on the culture species in semi-
intensive production systems.
29. Type of Culture or Holding Unit
Intensive – Battery culture generally occurs in indoor tanks, raceways or ponds.
These are often highly engineered systems with the capacity to precisely control the
culture environment.
● Stocking densities are high to very high.
● Rigid control of water quality parameters and maintenance.
● Specially formulated feed for maximum growth rates and water quality control.
● Cost of production is high due to capital (equipment) and operating costs (labour,
power, feed etc) but results in very high productivity.
● System often used to fatten or purge stocks before market and in the
manipulation of brood stock.
The ability to precisely control the environment ensure the culture species receives
the conditions for good growth and survival meaning productivity is highest in
intensive culture systems.
30. Protection from Elements - Fish
The local climatic conditions can impact fish and
the sun, wind and rough weather are the main
considerations for Finfish. The sun can dry out
skin and lead to sunburn if the culture unit is too
shallow, this can lead to stress or death. Wind can
cause jerking of the cages which causes stress to
fish and wears equipment or lead to erosion in
earthen ponds.
In a previous training module, we discussed the
issue of climate change and increased extreme
weather events which needs to be considered -
farms in cyclone prone areas need to be
constructed appropriately.
31. Environmental Elements - Crustaceans
The local climatic conditions can impact fish
and the sun, wind, lunar cycles and rain are
the main considerations. Sunlight can
influence algal blooms and water
temperature. Wind can cause surface
turbulence in the pond waters assisting in
aeration and mixing. Lunar cycles coincide
with moulting, and may play a role in
reproduction.
Rainfall and runoff may lower pond salinity
also affecting moulting cycles.
32. Protection from Elements - Molluscs
The local climatic conditions can impact fish and
the sun, wind and rough weather are the main
considerations. Sun can dry out fouling and other
external pests, but too much can lead to stress or
death of the Mollusc being grown. Wind can
hasten the drying process and can be a major
problem in warm climates.
Rough weather can lead to increased rumbling
within the culture units or stripping or losses of
Molluscs from the culture units.
33. Genetics
Genetics plays a major role in the performance of all living animals.
Agriculture and increasingly aquaculture relies heavily on selective
breeding of varieties of animals that grow faster, have higher yields,
better survival or disease resistance.
With wild caught seedstock (eg Mussels, Tuna) the grower doesn’t
know much about the genetic stock they came from, and has no
capacity to choose stock that will perform better under culture
conditions. With hatchery bred and reared seedstock, the grower
has much better control over the genetics, eg can undertake
selective breeding to enhance particular traits such as fast growth,
disease resistance and so on.
Selective breeding programs are already being undertaken by many
organisations to improve productivity, this along with Genetic
Modification will play a major role in the future of aquaculture
34. Stress
Stress is a major issue with production of any living organism. In aquaculture,
stress can be caused by a number of different factors, including:
● Poor handling
● Overstocking
● Suboptimal environment (water quality)
● Suboptimal feeds
● Presence of pests, predators, competitors.
Stress is discussed in more detail in the next section.