Aquaculture Midterm Coverage PDF

Summary

This presentation covers different types of aquaculture systems, including freshwater, brackishwater, and marine aquaculture. It details the characteristics, species, and practices of each system, including benefits and challenges. The presentation is a survey of aquaculture systems in the Philippines using ABE's PC 419/419L syllabus.

Full Transcript

SURVEY OF AQUACULTURE
SYSTEMS IN THE
PHILIPPINES
ABE PC 419/419L
Freshwater Aquaculture Systems
Freshwater ponds - enclosed, man-
made or natural water bodies where fish
and other aquatic species are raised in a
controlled environment. These systems
are commonly used in rural and
agricultural areas due to their relatively
simple design and management.
Freshwater Aquaculture Systems
Species Cultured
Nile Tilapia (Oreochromis niloticus): One of the most commonly farmed fish
in the Philippines due to its fast growth, high yield, and adaptability to
varying water conditions.
Catfish (Clarias batrachus): Known for its resilience and ability to thrive in
low-oxygen environments, making it suitable for farming in ponds with
lower water exchange.
Freshwater Prawn (Macrobrachium rosenbergii): Valued for its high market
price, prawn farming in ponds can be integrated with fish species like
tilapia (polyculture) to maximize pond productivity.
Freshwater Aquaculture Systems
Characteristics of Freshwater Ponds
Size and Depth: Ponds typically range from small backyard setups to large
commercial operations, with depths varying between 1 to 3 meters.

Water Source: Ponds are generally filled with water from nearby rivers,
lakes, or wells, with water flow being controlled to maintain quality.

Stocking Density: The stocking rate depends on species and culture
method (extensive, semi-intensive, or intensive). Tilapia, for example, is
commonly stocked at high densities in semi-intensive and intensive
systems.
Freshwater Aquaculture Systems
Geographical Distribution
Luzon: Major freshwater aquaculture activities are concentrated in Central
Luzon (e.g., Pampanga, Nueva Ecija), where vast areas of agricultural land
are converted into fishponds.
Mindanao: Regions like Lanao del Norte and Davao have growing
freshwater aquaculture industries due to favorable water conditions and
government support.
Visayas: Iloilo and Cebu are emerging areas for freshwater aquaculture,
particularly tilapia farming, benefiting from community-based aquaculture
initiatives.
Freshwater Aquaculture Systems
Benefits of Freshwater Aquaculture
Accessibility: Freshwater ponds are often accessible to small-scale farmers,
requiring minimal investment and offering a sustainable income source.

Flexibility: These systems allow for diverse farming options, from
monoculture to polyculture (e.g., combining fish and prawns).

Environmental Control: Farmers can manage water quality, feeding, and
disease prevention more easily in ponds than in open water systems.
Brackishwater Aquaculture Systems

Brackishwater Fishponds - aquaculture systems
located in coastal areas where freshwater from rivers or
streams mixes with saltwater from the sea, creating a
low-salinity environment. These ponds are widely used
for farming species that thrive in such conditions, such
as milkfish (Chanos chanos) and shrimp (Penaeus
species).
Brackishwater Aquaculture
Milkfish (ChanosSystems
Species Cultured
chanos): The Philippines is one of the
top producers of milkfish globally. This species is highly
favored in brackishwater ponds due to its ability to adapt
to varying salinity levels and its fast growth. It is a staple
in the Filipino diet, making its production critical for both
local consumption and export.

Shrimp (Penaeus monodon, P. vannamei): Shrimp
farming, particularly for species like the black tiger
prawn (P. monodon) and the whiteleg shrimp (P.
vannamei), is a major component of the Philippine
aquaculture industry. Shrimp are farmed in both
extensive and intensive systems, often in ponds with
controlled water exchange.
 Brackishwater Aquaculture
Systems
Characteristics of Brackishwater Fishponds
Location: These ponds are usually situated in coastal lowlands, mangrove
areas, or tidal flats. Their proximity to both freshwater and seawater sources
allows for the careful regulation of salinity levels, which is essential for
optimal species growth.

Water Management: Effective water management is crucial in brackishwater
aquaculture. Ponds rely on tidal exchange or pumps to bring in seawater and
remove waste water, maintaining ideal water quality for the species being
farmed.

Pond Size and Depth: Brackishwater ponds are generally larger than
freshwater ponds, with sizes ranging from 1 to 10 hectares and depths
between 0.5 to 2 meters, depending on the species cultured and the farming
method (extensive, semi-intensive, or intensive).
 Brackishwater Aquaculture
Systems
Importance in Coastal Areas
Livelihood and Employment: Brackishwater fishponds provide significant
employment opportunities for coastal communities, supporting thousands of
families involved in fish and shrimp farming.

Contribution to Food Security: Milkfish and shrimp are high-demand
commodities, both domestically and internationally. Brackishwater aquaculture
ensures a steady supply of these species, contributing to food security and
economic stability in coastal regions.

Integration with Mangrove Ecosystems: In many areas, brackishwater
aquaculture is integrated with mangrove restoration projects. Mangroves not
only provide natural barriers against storm surges and coastal erosion but also
enhance the ecological sustainability of fishponds by improving water quality
and providing habitat for juvenile aquatic species.
 Brackishwater Aquaculture
Systems
Role in Philippine Aquaculture
Economic Importance: Brackishwater aquaculture is a cornerstone of the
Philippine aquaculture industry, particularly in regions such as the Ilocos
Region, Western Visayas, and Central Luzon. The production of high-value
species like shrimp has significant export potential, contributing to foreign
exchange earnings and enhancing the economic status of coastal areas.

Sustainability and Challenges: While brackishwater aquaculture plays a vital
role, it faces challenges such as overuse of water resources, environmental
degradation (e.g., destruction of mangroves), and disease outbreaks,
particularly in shrimp farming. Sustainable practices, such as integrated
coastal management and the use of biosecure systems, are essential to
address these issues.
 Brackishwater Aquaculture
Systems
Benefits of Brackishwater Aquaculture
High Yield Potential: Brackishwater ponds offer high production potential due
to favorable environmental conditions, which promote faster growth and
higher yields, especially for species like milkfish and shrimp.

Versatility: These systems can be adapted to raise a variety of species,
making them a flexible option for aquaculture in coastal regions.

Economic Diversity: In addition to local food production, brackishwater
aquaculture contributes significantly to export revenues, especially from
shrimp farming.
Marine Aquaculture Systems

Cage culture - a marine aquaculture system
where fish are raised in large cages or enclosures
submerged in coastal waters or open seas. These
cages are designed to contain the fish while
allowing water to flow freely through the structure,
maintaining water quality and simulating a natural
environment.
 Marine Aquaculture Systems

Species Cultured

Groupers (Epinephelus spp.): Groupers
are high-value fish prized for their
delicate flavor and high market
demand, especially in international
markets like Hong Kong and China.
Groupers thrive in cage culture
systems, where water quality and
feeding can be closely monitored.
 Marine Aquaculture Systems

Species Cultured

Red Snappers (Lutjanus
argentimaculatus): Another high-value
species raised in marine cages,
snappers are popular for their fast
growth rates and demand in both local
and export markets. They are often
farmed alongside other species to
optimize space and production in cage
culture systems.
 Marine Aquaculture Systems
Characteristics of Cage Culture
Location: Cages are typically deployed in calm, sheltered areas such as
bays, fjords, and coastal inlets. These locations provide protection from
harsh weather conditions and strong currents, while still allowing adequate
water exchange to maintain the health of the cultured species.

Structure: Cages can be made from durable materials like high-density
polyethylene (HDPE) or metal, and are either anchored to the seabed or
floated on the surface. The size of the cages can vary, with diameters
ranging from 10 to 20 meters or more, depending on the species being
cultured and the available space.

Stocking Density: Cage culture systems allow for high stocking densities,
which increases production efficiency. However, careful management of
stocking levels is essential to prevent overcrowding, stress, and disease
outbreaks in the fish.
 Marine Aquaculture Systems

Importance of Cage Culture in Philippine Aquaculture
Economic Value: Cage culture is a growing sector in Philippine aquaculture,
especially for high-value species like groupers and snappers. The ability to
raise these species in controlled environments allows farmers to meet local
and international demand for premium seafood, generating substantial
income.

Environmental Sustainability: While cage culture has high production
potential, it must be managed carefully to avoid environmental impacts,
such as nutrient pollution and the spread of diseases. Implementing best
practices, such as proper waste management and site rotation, can help
minimize these risks.
Marine Aquaculture Systems

Seaweed Farming - involves cultivating
different species of seaweed, such as
Eucheuma and Kappaphycus, in coastal
waters. Seaweed is grown on ropes or nets
submerged in shallow areas, where it
absorbs nutrients from the surrounding water
and sunlight to grow. This farming method is
relatively low-impact and sustainable
compared to other forms of aquaculture.
 Marine Aquaculture Systems
Contribution to Local Economies
Livelihood for Coastal Communities: Seaweed farming is an important
source of livelihood for many coastal communities in the Philippines,
particularly in regions like Tawi-Tawi, Zamboanga Peninsula, and Palawan.
It provides an accessible means of income for small-scale farmers,
requiring low startup costs and minimal maintenance.

Women’s Participation: Seaweed farming is often a family-based activity,
with women playing a significant role in harvesting and processing the
seaweed, thus contributing to gender empowerment and community
development.

Income Stability: Seaweed has consistent demand in both local and
global markets, making it a reliable source of income for farmers. It is
used in various industries, including food, cosmetics, pharmaceuticals,
and as a raw material for carrageenan, an important thickening agent in
 Marine Aquaculture Systems
Export Market and Global Demand
Carrageenan Industry: The Philippines is one of the world's largest
producers of carrageenan, a gel-like substance extracted from
seaweed. Carrageenan is used in a wide range of products, including
dairy products, toothpaste, and cosmetics. The export of seaweed
and carrageenan is a significant contributor to the national economy.

Sustainability and Environmental Benefits: Seaweed farming is a
sustainable practice that contributes to the health of marine
ecosystems. Seaweed absorbs carbon dioxide and excess nutrients
from the water, helping to mitigate the effects of ocean acidification
and eutrophication. Additionally, seaweed farms provide habitat for
marine life, promoting biodiversity.
 Marine Aquaculture Systems
Role in Marine Aquaculture
Integration with Other Systems: Seaweed farming is often integrated
with other marine aquaculture practices, such as fish and shellfish
farming. In Integrated Multi-Trophic Aquaculture (IMTA), seaweed is
used to absorb excess nutrients generated by fish farming, creating a
balanced and sustainable ecosystem.

Climate Resilience: Seaweed farming is resilient to changes in climate
and can be an adaptable livelihood for coastal communities affected
by climate change. Its ability to grow in a variety of water conditions
makes it an important component of climate-adaptive aquaculture
strategies.
Benefits of Marine Aquaculture
Systems
High-Value Production: Cage culture provides opportunities to
farm premium species like groupers and snappers, while seaweed
farming boosts the local economy and contributes to international
markets.

Sustainability: Seaweed farming enhances marine health and
promotes ecological balance, while sustainable cage culture
practices help reduce environmental impacts.

Livelihood and Food Security: Both cage culture and seaweed
farming play a crucial role in supporting livelihoods in coastal
communities and contributing to local food security.
 REVIEW OF BASIC
BIOLOGICAL
CHARACTERISTICS OF
IMPORTANT AQUACULTURE
SPECIES
ABE PC 419/419L
 Selection Criteria for Aquaculture
1 Species
GROWTH RATE - refers to how quickly an aquatic species reaches market size,
which directly impacts production cycles, profitability, and resource efficiency.

Fast-growing Species: In aquaculture, species with fast growth rates are preferred
because they reduce the time and resources needed to reach harvestable size, thus
increasing overall productivity.

Tilapia - one of the most popular species for aquaculture due to its rapid growth
and ability to reach market size in just 4 to 6 months. Its adaptability to a wide
range of environmental conditions also makes it a favored choice for both small-
and large-scale farms.

Milkfish (Bangus) - known for its fast growth in brackishwater and marine
environments, milkfish can reach marketable size within 6 to 8 months, making it
one of the staple species in Philippine aquaculture. Its fast growth ensures that
farmers can harvest more frequently, maximizing yield.
 Selection Criteria for Aquaculture
Species
2 DISEASE RESISTANCE- the ability of a species to withstand or recover from diseases
and environmental stresses, such as poor water quality or fluctuating temperatures.

Species with High Disease Resistance: Aquaculture species that are resilient to
common diseases and environmental stresses are more profitable since they reduce the
need for intensive management, medication, or frequent water quality adjustments.

Tilapia - widely regarded for its hardiness and resistance to diseases, particularly in
suboptimal water conditions. Its ability to survive in low-oxygen environments and
tolerate poor water quality makes it a robust choice for farmers.

Catfish - known for its resilience, catfish is another species that can thrive in low-
oxygen or high-ammonia conditions, making it less vulnerable to the challenges that
often lead to disease outbreaks in more sensitive species.

Milkfish - although milkfish can be affected by environmental stresses, its overall
disease resistance is strong, especially in controlled brackishwater environments.
 Selection Criteria for Aquaculture
3 MARKET DEMAND- refers to Species
consumer preferences and the commercial viability of a species.
Species that are in high demand offer better opportunities for profit, making their farming a key
focus for aquaculture operations.

High-demand Species: Aquaculture species that are in constant demand in local and export
markets are prioritized to ensure profitability. Market trends, export opportunities, and consumer
preferences shape the selection of species for farming.
Prawns (Shrimp) - particularly Penaeus monodon (black tiger prawn) and Penaeus vannamei
(whiteleg shrimp), are highly sought after in both local and international markets. Shrimp
farming is a lucrative industry, with significant demand for high-quality prawns in global
seafood markets, making them an attractive species for aquaculture ventures.

Milkfish - a staple in the Filipino diet and enjoys high local market demand. In addition, it is
exported to international markets such as the Middle East, where it is consumed by the Filipino
diaspora. Its consistent demand makes milkfish farming a highly profitable venture.

Tilapia - widespread acceptance and relatively low market price make it one of the most
commonly farmed and consumed species in the world. It has a high demand in local markets
for everyday consumption and is gaining popularity in export markets, particularly in the U.S.
 Selection Criteria for Aquaculture
4 Species
OTHER CRITERIA TO CONSIDER

Feed Efficiency: Species that efficiently convert feed into body mass (high feed
conversion ratio, or FCR) are economically favorable since feed is often the most
significant expense in aquaculture operations. Tilapia and milkfish have relatively low
FCRs, making them cost-effective species to farm.

Reproduction: Aquaculture species that reproduce easily in captivity reduce the need
for wild broodstock, ensuring a steady supply of juveniles for farming. Species like tilapia
breed readily in captivity, while species like shrimp require specialized hatchery
conditions.

Environmental Impact: Species that have minimal impact on the environment, either
due to their ability to thrive in low-intensity systems (e.g., seaweed, filter-feeding
bivalves) or their sustainability in integrated aquaculture systems, are becoming
increasingly important in the context of sustainable aquaculture practices.
Production Cycles of Selected
Aquaculture Species
Production Cycle Overview
Key Stages in the Life Cycle
Fry: This is the earliest stage of life for most fish species, immediately after
hatching. Fry are small, fragile, and require special care, usually in a hatchery
or nursery. The fry stage is characterized by rapid growth, and they need
adequate nutrition and protection from environmental stresses.

Juvenile: After the fry stage, fish grow into juveniles, which are more resilient
but still require proper environmental conditions and feed. During this phase,
they are usually transferred to larger enclosures or grow-out ponds for further
development.

Grow-Out: The grow-out phase is where the fish grow to marketable size. This
stage typically involves transferring fish to ponds, cages, or other large
production systems where they are fed and managed intensively until they
Production Cycles of Selected
Aquaculture Species
Production Cycle Overview
Key Stages in the Life Cycle
Production Cycles of Selected
Aquaculture Species
Production Cycle Overview
Tilapia: From Breeding to Market Size
Breeding: Tilapia are known for their rapid reproduction in captivity. Breeding
occurs in controlled environments like hatcheries or ponds, where broodstock
(adult fish used for reproduction) are kept. Females lay eggs in nests, and
males fertilize them. In many cases, the eggs are collected and artificially
incubated to increase survival rates.

Fry to Juvenile Stage: Once the eggs hatch, fry are reared in tanks or
nursery ponds. During this stage, they are given high-protein feed to ensure
fast growth. Tilapia fry are hardy and grow quickly, reaching juvenile stage in a
few weeks.

Grow-Out: Juvenile tilapia are transferred to larger grow-out ponds or cages
where they are raised to market size. This stage typically lasts between 4 to 6
months, depending on environmental conditions and feeding regimes. Tilapia
Production Cycles of Selected
Aquaculture Species
Production Cycle Overview
Milkfish: Hatchery, Nursery, and Grow-Out Phases
Hatchery Phase: Milkfish breeding is typically done in hatcheries, where
broodstock are maintained to spawn fertilized eggs. Hatcheries provide
controlled conditions for the eggs to hatch and the larvae to grow into fry. This
phase requires precise control of water quality, temperature, and feeding to
maximize survival.

Nursery Phase: After hatching, milkfish fry are transferred to nursery ponds
or tanks where they are raised until they become juveniles. This phase lasts for
about 1 to 2 months, during which the fry are given finely ground feeds to
promote fast growth and development.

Grow-Out Phase: Juvenile milkfish are then moved to larger grow-out ponds,
brackishwater ponds, or marine cages. The grow-out phase lasts 6 to 8
months, during which the fish are fed regularly and monitored for growth.
 Production Cycles of Selected
Aquaculture Species
Prawn (Shrimp) Production Cycle
Life Cycle: Hatchery Stage: Grow-Out Stage: Importance of Water
The life cycle of prawns, Prawn hatcheries play a Postlarvae are transferred Quality:
such as the black tiger critical role in producing to grow-out ponds, where Throughout all stages of
prawn (Penaeus postlarvae for farming. they are raised to the prawn production
monodon) or whiteleg Hatcheries provide a marketable size (15-25 cycle, maintaining
shrimp (Penaeus controlled environment grams for shrimp). The optimal water quality is
vannamei), starts with for eggs to develop into grow-out stage lasts 4 to 6 crucial. Poor water
eggs that hatch into larvae and then into months, and during this conditions can lead to
larval stages (nauplius, postlarvae. Water quality time, careful management disease outbreaks, slow
of feeding and water
zoea, and mysis). After management (e.g., growth, and increased
quality is essential to
the larval stage, they salinity, temperature) is mortality.
ensure good growth and
develop into postlarvae, crucial at this stage to
prevent disease. Prawns
which are more robust ensure high survival
are highly sensitive to
and can be transferred to rates.
water parameters, so
grow-out ponds.
regular monitoring of
 Production Cycles of Selected
Aquaculture Species
Prawn (Shrimp) Production Cycle
 Production Cycles of Selected
Aquaculture Species
Catfish Production Cycle
Life Cycle: The catfish production cycle starts with spawning, where female catfish lay eggs in
nests or tanks. These eggs are fertilized by males and hatch into fry.
Hatchery Stage: Hatcheries are used to incubate eggs and rear catfish fry in controlled conditions.
Once hatched, the fry are kept in nursery tanks or ponds where they are fed and allowed to grow
into juveniles. Catfish fry are relatively resilient but still require proper feeding and water
management.
Grow-Out Stage: Juvenile catfish are then transferred to grow-out ponds or tanks, where they are
fed and managed until they reach marketable size (usually 300 grams to 1 kilogram). Catfish are
known for their fast growth and ability to thrive in less-than-ideal water conditions, such as low
oxygen or higher ammonia levels.
Role of Hatcheries: Hatcheries play an important role in ensuring a steady supply of fry and
juveniles for catfish farming. By controlling the breeding environment, hatcheries can improve
survival rates and enhance growth performance.
Importance of Water Quality: While catfish are hardy and can tolerate poor water quality better
than most species, maintaining good water conditions still leads to faster growth and higher yields.
Regular monitoring of water parameters such as dissolved oxygen, ammonia, and pH is crucial
 Environmental and Water Quality
Requirements
OPTIMAL ENVIRONMENTAL PARAMETERS
Temperature
Temperature is a key environmental factor that affects metabolic rates, growth,
reproduction, and overall health of aquaculture species.

Optimal Ranges for Different Species: Each species has a specific temperature range in
which it thrives. Deviations from this range can slow growth, increase stress, or even lead
to mortality.

⚬ Tilapia: The optimal temperature range for tilapia is 25°C to 30°C. At these
temperatures, their metabolism and growth rates are highest. Temperatures below
20°C slow their growth and make them more susceptible to diseases, while
temperatures above 35°C can be lethal.

⚬ Milkfish (Bangus): Milkfish thrive in warm tropical waters, with an optimal
temperature range of 26°C to 32°C. Lower temperatures can slow their growth, while
 Environmental and Water Quality
Requirements
OPTIMAL ENVIRONMENTAL PARAMETERS
DISSOLVED OXYGEN
Dissolved oxygen (DO) is the amount of oxygen available in water for fish and other
aquatic organisms to breathe. DO is critical for respiration, and low levels can lead to
stress, poor growth, or mortality.
Importance for Species Survival: Different species have varying requirements for dissolved
oxygen. Maintaining adequate levels is crucial, especially in high-density farming systems
where oxygen demand is high.

⚬ Prawns (Shrimp): Prawns are highly sensitive to dissolved oxygen levels. The optimal
DO level for prawns is above 5 mg/L. Levels below this can cause stress, reduced feed
intake, and slower growth. Oxygen levels below 2 mg/L can lead to mass mortality.

⚬ Tilapia: Tilapia are relatively hardy and can survive in low-oxygen environments (as
low as 2-3 mg/L), but their optimal growth occurs when DO levels are around 5-7 mg/L.
 Environmental and Water Quality
Requirements
WATER QUALITY MONITORING
KEY TOOLS AND TECHNIQUES
Water Testing Kits: These are used to measure key water quality parameters such as
pH, ammonia, nitrite, nitrate, and dissolved oxygen. Regular testing helps farmers monitor
and maintain optimal water conditions for aquaculture species.

Dissolved Oxygen Meters: A DO meter is essential for monitoring the oxygen levels in
water, especially in high-density farming systems where oxygen depletion can occur
rapidly.

pH Meters: A pH meter is used to measure the acidity or alkalinity of water. It is
important to keep the pH within the optimal range for the species being cultured.

Ammonia and Nitrite Test Kits: Ammonia and nitrite are toxic byproducts of fish waste
and decomposing organic matter. Monitoring these levels is crucial because high
concentrations can cause stress, poor growth, and even death.
 Environmental and Water Quality
Requirements
WATER QUALITY MONITORING

IMPORTANCE OF MAINTAINING PH, AMMONIA, AND Nitrogen Levels
pH: The pH of the water affects the solubility and toxicity of chemicals, such as ammonia.
Most aquaculture species thrive in water with a pH range of 6.5 to 8.5. For example:
⚬ Tilapia: Tolerates a wide pH range but grows best when the pH is between 6.5 and 8.5.
⚬ Prawns: Require a pH range of 7.0 to 8.5. A pH that is too acidic or too alkaline can
stress prawns and lead to poor growth and susceptibility to diseases.

Ammonia (NH3): Ammonia is a toxic nitrogen compound that results from the breakdown
of organic matter and fish waste. High ammonia levels are dangerous for all aquaculture
species as they interfere with respiration and can cause death.
⚬ Safe Ammonia Levels: Ideally, ammonia levels should be below 0.05 mg/L for most
species. Even low levels of ammonia can cause stress, while levels above 0.5 mg/L can
be lethal.
 Environmental and Water Quality
Requirements
WATER QUALITY MONITORING

IMPORTANCE OF MAINTAINING PH, AMMONIA, AND
Nitrogen Levels

Nitrogen Compounds (Nitrite and Nitrate): Nitrite
(NO2) is toxic to fish and can cause nitrite poisoning
(brown blood disease), while nitrate (NO3) is less toxic
but should still be monitored in recirculating systems.

⚬ Nitrite: Should be kept below 0.1 mg/L to prevent
toxicity.
⚬ Nitrate: Although less harmful, nitrate levels should
ideally be kept below 50 mg/L to avoid long-term
stress on fish and prawns.
 Culture Practices for Tilapia and
Milkfish
EXTENSIVE, SEMI-INTENSIVE, AND INTENSIVE CULTURE METHODS

Extensive Culture:
Description: This method involves low stocking densities and minimal input, relying
primarily on natural food sources like plankton and detritus in ponds or bodies of water.
There is little to no artificial feeding, and the growth rate of fish is slower compared to
more intensive systems.

Application: Common in rural areas with large available land or bodies of water, extensive
systems are mainly used by small-scale farmers due to low cost. However, the yield per
hectare is relatively low.

Example: Tilapia and milkfish grown in natural ponds, relying on the natural productivity
of the water for their food.
 Culture Practices for Tilapia and
Milkfish
EXTENSIVE, SEMI-INTENSIVE, AND INTENSIVE CULTURE METHODS

Semi-intensive Culture:
Description: This method involves moderate stocking densities and partial reliance on
both natural food and supplemental feeding. Fertilizers may be used to enhance natural
food production, and commercial feeds are used to boost fish growth.

Application: Semi-intensive systems are more efficient in terms of space and yield
compared to extensive methods, and they are widely used in commercial aquaculture.
Pond management practices are crucial, including regular water exchange and
fertilization.

Example: Tilapia and milkfish ponds that are fertilized and supplemented with formulated
feeds. Stocking densities range from 5,000 to 10,000 fish per hectare for tilapia.
 Culture Practices for Tilapia and
Milkfish
EXTENSIVE, SEMI-INTENSIVE, AND INTENSIVE CULTURE METHODS

Intensive Culture:
Description: This method is characterized by high stocking densities, complete reliance on
commercial feeds, and frequent monitoring and management of water quality. Intensive
systems require aeration, water exchange, and disease control to manage high-density
environments.

Application: Used for large-scale, commercial production where maximizing output per
unit area is essential. Intensive systems have higher operational costs but yield
significantly more fish per hectare than semi-intensive or extensive systems.

Example: Tilapia and milkfish cultured in tanks, cages, or highly managed ponds with
controlled feed rations, aeration, and water exchange. Stocking densities in intensive
systems can exceed 20,000 fish per hectare for tilapia.
 Culture Practices for Tilapia and
Milkfish
STOCKING DENSITIES, FEEDING PRACTICES, AND DISEASE MANAGEMENT

STOCKING DENSITIES:
Tilapia: In semi-intensive systems, stocking densities range from 5,000 to 10,000 fish per hectare.
In intensive systems, densities can go as high as 20,000 to 30,000 fish per hectare.
Milkfish: Milkfish can be stocked at 5,000 to 15,000 fish per hectare in semi-intensive systems and
up to 50,000 fish per hectare in intensive systems like marine cages.

Feeding Practices:
Natural Feed: In extensive and semi-intensive systems, fish rely on the natural productivity of
ponds, such as algae, plankton, and organic matter.
Supplemental Feeding: Semi-intensive systems use supplemental feeds to boost growth.
Commercial pellet feeds are often introduced when natural feed becomes insufficient.
Complete Feeds: Intensive systems depend entirely on formulated feeds to ensure rapid growth.
Feeds are specifically designed to meet the nutritional requirements of tilapia and milkfish at
different stages of growth.
 Culture Practices for Tilapia and
Milkfish
STOCKING DENSITIES, FEEDING PRACTICES, AND DISEASE MANAGEMENT

DISEASE MANAGEMENT:
Tilapia: Disease management in tilapia culture involves maintaining good water quality,
reducing stress, and using probiotics or antibiotics when necessary. Common diseases
include Streptococcus and Aeromonas infections, which are often triggered by poor
water conditions or high stocking densities.

Milkfish: Disease outbreaks in milkfish ponds can be minimized through proper water
management and stocking practices. Vibriosis is a common bacterial disease in milkfish
farming, especially in brackishwater environments.
 CULTURE PRACTICES FOR
PRAWNS AND CATFISH
Water Exchange and Aeration Practices
Water Exchange:
Prawns (Shrimp): Water exchange is critical in prawn farming to maintain optimal
water quality, prevent the build-up of toxic substances like ammonia, and ensure that
the prawns have enough oxygen. Farmers typically perform 10-20% water exchange
daily in semi-intensive and intensive systems. In highly intensive systems, recirculating
aquaculture systems (RAS) may be used to filter and reuse water.

Catfish: Catfish are relatively hardy but still benefit from regular water exchange,
especially in high-density farming systems. For optimal growth, water exchange is
done to control waste build-up and maintain oxygen levels. In smaller systems, partial
water exchanges are conducted weekly.
 CULTURE PRACTICES FOR
PRAWNS AND CATFISH
Water Exchange and Aeration Practices
Aeration:
Prawns: Aeration is vital in shrimp ponds to maintain dissolved oxygen levels.
Paddlewheel aerators or diffused aeration systems are commonly used in semi-
intensive and intensive shrimp farms. Aeration ensures that prawns have sufficient
oxygen, particularly at night when oxygen levels drop.

Catfish: While catfish are more tolerant of low oxygen levels, intensive systems still
require aeration to enhance growth rates and prevent stress. Paddlewheel or airlift
aerators are used to keep oxygen levels stable, especially during feeding times when
oxygen demand spikes.
 CULTURE PRACTICES FOR
PRAWNS AND CATFISH
Disease Prevention and Control in Different Farming Systems
Prawns (Shrimp):
Common Diseases: Prawns are susceptible to viral infections such as White Spot
Syndrome Virus (WSSV) and Yellowhead Disease, which can cause mass mortality.
Bacterial infections like vibriosis are also common.

Prevention Strategies: Good water quality management, biosecurity measures (e.g.,
screening broodstock for diseases), and the use of probiotics or immunostimulants can
help prevent diseases. Water quality monitoring for parameters like ammonia, nitrite,
and salinity is crucial for minimizing stress on prawns.

Vaccines: Some farms use vaccines to prevent specific diseases, while others may
employ strict quarantine and treatment protocols for infected ponds.
 CULTURE PRACTICES FOR
PRAWNS AND CATFISH
Disease Prevention and Control in Different Farming Systems
Catfish:
Common Diseases: Catfish are prone to bacterial diseases such as Columnaris and
Edwardsiella, especially in high-density systems. Parasitic infestations, such as those
caused by Ichthyophthirius (Ich), are also common.

Prevention Strategies: Disease prevention in catfish farming includes maintaining
water quality, minimizing stress, and using antibiotics or probiotics as preventive
measures. Vaccination is available for some bacterial diseases like Edwardsiella.

Biosecurity: Implementing biosecurity measures, such as disinfection of equipment and
proper sanitation practices, helps to reduce the spread of pathogens.
 SUMMARY
Overview of Aquaculture Systems in the Philippines:
⚬ Freshwater systems (e.g., ponds for tilapia, catfish).
⚬ Brackishwater systems (e.g., fishponds for milkfish and prawns).
⚬ Marine systems (e.g., cage culture for groupers and snappers, seaweed farming).
Importance of Biological Characteristics:
⚬ Selection of species based on growth rate, disease resistance, and market demand
(e.g., tilapia, milkfish, prawns).
⚬ Understanding life cycles and production cycles for effective management.
Environmental Management for Successful Aquaculture:
⚬ Maintaining optimal water quality (temperature, dissolved oxygen, salinity).
⚬ Regular water quality monitoring (pH, ammonia, nitrite).
⚬ Sustainable practices to ensure long-term viability and production efficiency.
Key Takeaways:
⚬ Proper selection of species and culture systems leads to efficient and profitable
aquaculture.
⚬ Effective environmental management and disease control are critical for sustaining
productivity.
⚬ Aquaculture’s role in contributing to food security and local economies is significant.