Aquatic biotechnology
Lionheart009
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Nov 15, 2013
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About This Presentation
All the detailed information on Aquatic Biotechnology.
Aquaculture - definition, economics, advantages,etc
Slide Content
Topics
Aquaculture
Environmental applications of Aquatic Biotechnology
Aquaculture
Environmental applications of Aquatic Biotechnology
Introduction to Aquatic
Biotechnology
Aquatic biotechnology find out to use living
organisms (such as bacteria) or parts of living
organisms (such as DNA) from a marine
environment
To create or improve a wide variety
of products
From pharmaceuticals to materials
that fight pollution
Aquatic biotechnology scientists might develop
and test drugs
Made from marine organisms
Develop non-toxic coatings that prevent the
accumulation of barnacles (one type of bird)
On hulls of ships or on underwater parts of power
plants
Biotechnology
Aquatic biotechnology find out to use living
organisms (such as bacteria) or parts of living
organisms (such as DNA) from a marine
environment
To create or improve a wide variety
of products
From pharmaceuticals to materials
that fight pollution
Aquatic biotechnology scientists might develop
and test drugs
Made from marine organisms
Develop non-toxic coatings that prevent the
accumulation of barnacles (one type of bird)
On hulls of ships or on underwater parts of power
plants
Introduction to Aquatic
Biotechnology
Given that water, especially marine water, covers
nearly 75 % of the earth's surface
It should not surprise you to learn that aquatic
environments are a
Rich source of biotechnology applications
Potential solution to a range of problems
Aquatic organisms exist in a range of extreme
conditions such as
Frigid polar seas
Extraordinarily high pressure at great depths
High salinity
Exceedingly high temperatures
Low light conditions
Biotechnology
Given that water, especially marine water, covers
nearly 75 % of the earth's surface
It should not surprise you to learn that aquatic
environments are a
Rich source of biotechnology applications
Potential solution to a range of problems
Aquatic organisms exist in a range of extreme
conditions such as
Frigid polar seas
Extraordinarily high pressure at great depths
High salinity
Exceedingly high temperatures
Low light conditions
Introduction to Aquatic
Biotechnology
As a result, aquatic organisms have evolved a
fascinating number of
Metabolic pathways
Reproductive mechanisms
Sensory adaptations
They harbor a wealth of unique genetic
information and potential applications
We will consider many fascinating aspects of
aquatic biotechnology
By exploring how both marine and freshwater
organisms can be used for biotechnology applications
Biotechnology
As a result, aquatic organisms have evolved a
fascinating number of
Metabolic pathways
Reproductive mechanisms
Sensory adaptations
They harbor a wealth of unique genetic
information and potential applications
We will consider many fascinating aspects of
aquatic biotechnology
By exploring how both marine and freshwater
organisms can be used for biotechnology applications
Introduction to Aquatic
Biotechnology
In the United States
Less than $50 million is spent
annually for research and
development in aquatic
biotechnology
In contrast
Japan spends between $900 million
and $1 billion annually
The successful research of Asian
countries that have invested in basic
science research on aquatic
biotechnology and the financial
success of their products have
encouraged other countries to invest
a significant amount of time and
resources in aquatic biotechnology
Biotechnology
In the United States
Less than $50 million is spent
annually for research and
development in aquatic
biotechnology
In contrast
Japan spends between $900 million
and $1 billion annually
The successful research of Asian
countries that have invested in basic
science research on aquatic
biotechnology and the financial
success of their products have
encouraged other countries to invest
a significant amount of time and
resources in aquatic biotechnology
Introduction to Aquatic
Biotechnology
Several research priorities have been identified to explore
the seemingly endless possibilities of utilizing aquatic
organisms:
Increasing the world's food supply
Restoring and protecting marine ecosystems
Identifying novel compounds for the benefit of human health and
medical treatments
Improving seafood safety and quality
Discovering and developing new products with applications in the
chemical industry
Seeking new approaches to monitor and treat disease
Increasing knowledge of biological and geochemical processes in
the world's oceans
Biotechnology
Several research priorities have been identified to explore
the seemingly endless possibilities of utilizing aquatic
organisms:
Increasing the world's food supply
Restoring and protecting marine ecosystems
Identifying novel compounds for the benefit of human health and
medical treatments
Improving seafood safety and quality
Discovering and developing new products with applications in the
chemical industry
Seeking new approaches to monitor and treat disease
Increasing knowledge of biological and geochemical processes in
the world's oceans
Aquaculture
The cultivation of aquatic animals, such as
finfish and shellfish, and aquatic plants for
recreational or commercial purposes is
known as aquaculture
Specifically, marine aquaculture is called
mariculture
Although aquaculture can be considered a
type of agricultural biotechnology
It is typically considered a form of aquatic
biotechnology
In this section, we will primarily discuss farming
of both marine and freshwater species of finfish
and shellfish
The cultivation of aquatic animals, such as
finfish and shellfish, and aquatic plants for
recreational or commercial purposes is
known as aquaculture
Specifically, marine aquaculture is called
mariculture
Although aquaculture can be considered a
type of agricultural biotechnology
It is typically considered a form of aquatic
biotechnology
In this section, we will primarily discuss farming
of both marine and freshwater species of finfish
and shellfish
shrimp
catfish
shellfish
catfish
shellfish
The Economics of Aquaculture
Worldwide demand for
aquaculture products is
expected to grow by 70%
during the next 30 years
If demand continues to
rise and wild catches
continue to decline
We will see a deficit of
consumable fish and
shellfish
Aquaculture together with
better resource
management practices will
in part overcome this
problem
Worldwide demand for
aquaculture products is
expected to grow by 70%
during the next 30 years
If demand continues to
rise and wild catches
continue to decline
We will see a deficit of
consumable fish and
shellfish
Aquaculture together with
better resource
management practices will
in part overcome this
problem
The Economics of Aquaculture
Aquaculture in the United States is big business
It is a greater than $36 billion industry providing nearly 19% of the world's seafood
supply
Aquaculture production in the United States has nearly doubled over
the last 10 years
This increase is expected to continue while similar increases in aquaculture are
occurring globally
Some aspects of raising fish are economically cheaper than animal
farming or commercial fishing
Ex. It takes approximately 7 pounds of grain to raise one pound of beef, but less
than 2 pounds of fish meal are needed to raise approximately 1 pound of most fish
Fish species that are fed genetically engineered food cost around 10
cents/pound
But the return is often 70 to 80 cents/pound on the raised fish
Yielding a good return on an investment
Aquaculture in the United States is big business
It is a greater than $36 billion industry providing nearly 19% of the world's seafood
supply
Aquaculture production in the United States has nearly doubled over
the last 10 years
This increase is expected to continue while similar increases in aquaculture are
occurring globally
Some aspects of raising fish are economically cheaper than animal
farming or commercial fishing
Ex. It takes approximately 7 pounds of grain to raise one pound of beef, but less
than 2 pounds of fish meal are needed to raise approximately 1 pound of most fish
Fish species that are fed genetically engineered food cost around 10
cents/pound
But the return is often 70 to 80 cents/pound on the raised fish
Yielding a good return on an investment
The Economics of Aquaculture
Aquaculture in the United States became a major industry in the 1950s
When catfish farming was established in the Southeast
Aquaculture facilities now exist in every state
Farm-raised catfish grow nearly 20% faster in fish-farms compared to
catfish in the wild
And are ready for market sale in approximately 2 years
Aquaculture in the United States became a major industry in the 1950s
When catfish farming was established in the Southeast
Aquaculture facilities now exist in every state
Farm-raised catfish grow nearly 20% faster in fish-farms compared to
catfish in the wild
And are ready for market sale in approximately 2 years
Some of the most successful examples of the
business potential of aquaculture in the United
States include
Alabama and Mississippi Delta catfish industry
Salmon farming in Maine and Washington
Trout-farming in Idaho and West Virginia
Crawfish farming in Louisiana
Similarly, Florida, Massachusetts, and other states
have established successful shellfish farms
That have benefited struggling commercial fishermen
business potential of aquaculture in the United
States include
Alabama and Mississippi Delta catfish industry
Salmon farming in Maine and Washington
Trout-farming in Idaho and West Virginia
Crawfish farming in Louisiana
Similarly, Florida, Massachusetts, and other states
have established successful shellfish farms
That have benefited struggling commercial fishermen
Aquaculture Abroad
Many other countries are actively engaged in aquaculture practices.
Chile is the second largest exporter worldwide.
Ecuador, Colombia, and Peru have rapidly growing industries.
Greek farms are the leading producers of farmed sea bass in the world.
Norway is a leading producer of salmon.
Canada produces over 70,000 tons of Atlantic and Pacific salmon
The largest production province in Canada is British Columbia with over 100 salmon farms.
Expanding markets are underway in Argentina, Algeria, Puerto Rico, Scotland,
Iceland, the Faroe Islands, Ireland, Russia, Indonesia, New Zealand, Thailand, the
Philippines, India and many other nations
Many of the countries most actively engaged in developing aquaculture
industries are doing so
Because local waters have been overfished to the point where natural stocks of finfish and
shellfish have been severely depleted
Many other countries are actively engaged in aquaculture practices.
Chile is the second largest exporter worldwide.
Ecuador, Colombia, and Peru have rapidly growing industries.
Greek farms are the leading producers of farmed sea bass in the world.
Norway is a leading producer of salmon.
Canada produces over 70,000 tons of Atlantic and Pacific salmon
The largest production province in Canada is British Columbia with over 100 salmon farms.
Expanding markets are underway in Argentina, Algeria, Puerto Rico, Scotland,
Iceland, the Faroe Islands, Ireland, Russia, Indonesia, New Zealand, Thailand, the
Philippines, India and many other nations
Many of the countries most actively engaged in developing aquaculture
industries are doing so
Because local waters have been overfished to the point where natural stocks of finfish and
shellfish have been severely depleted
Aquaculture Abroad
A shrimp farm is an aquaculture
business for the cultivation of marine
shrimp for human consumption
Commercial shrimp farming began in
the 1970s
Production grew steeply
Particularly to match the market demands
of the U.S., Japan and Western Europe
About 75% of farmed shrimp is
produced in Asia
In particular in China and Thailand
The largest exporting nation is Thailand
A shrimp farm is an aquaculture
business for the cultivation of marine
shrimp for human consumption
Commercial shrimp farming began in
the 1970s
Production grew steeply
Particularly to match the market demands
of the U.S., Japan and Western Europe
About 75% of farmed shrimp is
produced in Asia
In particular in China and Thailand
The largest exporting nation is Thailand
Aquaculture Abroad
From Research to Reality:
Biotechnology solutions to the
Shrimp Industry
The Shrimp Biotechnology Business
Unit (SBBU) was established by the
Thailand National Center for Genetic
Engineering and Biotechnology
(BIOTEC) in Bangkok, Thailand
SSBU has been working since 1999 to
commercialize solutions developed by
the Thai research to help the shrimp
industry
http://www.usm.my/7AFF2004/7th%20Asian%20Fisheries%20Forum_files/MainExhibition.htm
From Research to Reality:
Biotechnology solutions to the
Shrimp Industry
The Shrimp Biotechnology Business
Unit (SBBU) was established by the
Thailand National Center for Genetic
Engineering and Biotechnology
(BIOTEC) in Bangkok, Thailand
SSBU has been working since 1999 to
commercialize solutions developed by
the Thai research to help the shrimp
industry
http://www.usm.my/7AFF2004/7th%20Asian%20Fisheries%20Forum_files/MainExhibition.htm
Aquaculture Abroad
SBBU develops diagnostic
kits
PCR kits and test strips
And also provides expertise
in shrimp health
management
Which ranges from
diagnostic analysis, to
contract research for the
shrimp industry, training and
consulting.
http://www.usm.my/7AFF2004/7th%20Asian%20Fisheries%20Forum_files/MainExhibition.htm
SBBU develops diagnostic
kits
PCR kits and test strips
And also provides expertise
in shrimp health
management
Which ranges from
diagnostic analysis, to
contract research for the
shrimp industry, training and
consulting.
http://www.usm.my/7AFF2004/7th%20Asian%20Fisheries%20Forum_files/MainExhibition.htm
Local Aquaculture
The HBOI Aquaculture Division's mission
is to develop economically feasible and
environmentally sustainable methods to
farm aquatic organisms for
Food
Sport
Stock enhancement
Aquarium markets
Pharmaceuticals
The Aquaculture Division is a leader in the
research and development of culture
technologies for
Molluscs
Crustaceans
Marine ornamentals
Food fish
Seaweed
Biomedical species
http://www.hboi.edu/index_04.html
The HBOI Aquaculture Division's mission
is to develop economically feasible and
environmentally sustainable methods to
farm aquatic organisms for
Food
Sport
Stock enhancement
Aquarium markets
Pharmaceuticals
The Aquaculture Division is a leader in the
research and development of culture
technologies for
Molluscs
Crustaceans
Marine ornamentals
Food fish
Seaweed
Biomedical species
http://www.hboi.edu/index_04.html
Environmental Applications of Aquatic
Biotechnology
Unfortunately the world's oceans have long served as dumping
grounds for the wastes of humanity and industrialization
Little thought has been given to the effect of pollution on
Fish stocks
Marine organisms
and the environment
Clearly oceans do not have an infinite ability to accept waste
products without consequences
Critical wetlands and other estuarine habitats important for the
spawning of many marine species and the growth of young
marine organisms are showing signs of severe decline due to
pollution and human impact
Biotechnology
Unfortunately the world's oceans have long served as dumping
grounds for the wastes of humanity and industrialization
Little thought has been given to the effect of pollution on
Fish stocks
Marine organisms
and the environment
Clearly oceans do not have an infinite ability to accept waste
products without consequences
Critical wetlands and other estuarine habitats important for the
spawning of many marine species and the growth of young
marine organisms are showing signs of severe decline due to
pollution and human impact
Environmental Applications of Aquatic
Biotechnology
The variety of environmental applications of marine biotechnology is
quite astounding
From developing new ways of dealing with biofouling on engineered
materials in the ocean environment
Bioremediation and restoration of damaged marine habitats
Monitoring for disease outbreak and management of natural resources
http://www.marinebiotech.org/biorem.html
Biotechnology
The variety of environmental applications of marine biotechnology is
quite astounding
From developing new ways of dealing with biofouling on engineered
materials in the ocean environment
Bioremediation and restoration of damaged marine habitats
Monitoring for disease outbreak and management of natural resources
http://www.marinebiotech.org/biorem.html
Environmental Applications of Aquatic
Biotechnology
Biofilming, also called
biofouling, refers to the
attachment of organisms to
surfaces
These surfaces could be
manmade surfaces such as
Hulls of ships
Inner lining of pipes
Cement walls, and pilings used
around piers
Bridges
Buildings
Biofilming also occurs on the
surface of marine organisms,
especially shellfish
http://www.marinebiotech.org/biorem.html
Biotechnology
Biofilming, also called
biofouling, refers to the
attachment of organisms to
surfaces
These surfaces could be
manmade surfaces such as
Hulls of ships
Inner lining of pipes
Cement walls, and pilings used
around piers
Bridges
Buildings
Biofilming also occurs on the
surface of marine organisms,
especially shellfish
http://www.marinebiotech.org/biorem.html
Environmental Applications of Aquatic
Biotechnology
Biofilming occurs
In the plumbing of your home
On contact lenses, and
In your mouth
Bacteria that coat your teeth and bacteria that adhere to
implanted surgical devices and prostheses are examples of
biofilming
Biotechnology
Biofilming occurs
In the plumbing of your home
On contact lenses, and
In your mouth
Bacteria that coat your teeth and bacteria that adhere to
implanted surgical devices and prostheses are examples of
biofilming
Environmental Applications of Aquatic
Biotechnology
As a result, researchers are investigating
the natural mechanisms that many
organisms use to prevent biofouling on
their own surface
If biofilming is a problem for both
manmade surfaces and the surfaces of
marine organisms
How do clams, mussels, and even
turtles minimize biofilming and
thus prevent their shells from being
completely closed by biofilming
organisms?
Some organisms are thought to produce
repelling substances while other
organisms appear to produce molecules
that block adhesion of biofilming
organisms (Figure 10.15)
Biotechnology
As a result, researchers are investigating
the natural mechanisms that many
organisms use to prevent biofouling on
their own surface
If biofilming is a problem for both
manmade surfaces and the surfaces of
marine organisms
How do clams, mussels, and even
turtles minimize biofilming and
thus prevent their shells from being
completely closed by biofilming
organisms?
Some organisms are thought to produce
repelling substances while other
organisms appear to produce molecules
that block adhesion of biofilming
organisms (Figure 10.15)
Environmental Remediation
Native microorganisms or genetically engineered strains have been
used to degrade chemicals
In much the same way, marine organisms possess unique mechanisms
for breaking down substances
Including toxic organic chemicals such as phenols and toluene
Oil products found in harbors and adjacent to oil rigs, and
Toxic metals
One of the earliest techniques used in marine remediation involved
increasing the quantity of shellfish in polluted areas
Because these organisms strain the water during feeding
They act as a form of estuarine filters to remove wastes such as nitrogen compounds
and organic chemicals
Native microorganisms or genetically engineered strains have been
used to degrade chemicals
In much the same way, marine organisms possess unique mechanisms
for breaking down substances
Including toxic organic chemicals such as phenols and toluene
Oil products found in harbors and adjacent to oil rigs, and
Toxic metals
One of the earliest techniques used in marine remediation involved
increasing the quantity of shellfish in polluted areas
Because these organisms strain the water during feeding
They act as a form of estuarine filters to remove wastes such as nitrogen compounds
and organic chemicals
Environmental Remediation
Microbiologists at the USDA
have experimented with
growing nitrogenmetabolizing
algae on large mats called
scrubbers
So that they can be used as natural
filters
Scrubbers work like charcoal
filters in an aquarium
In that they bind nitrogenous wastes
Water contaminated with farm
animal wastes is passed over the
scrubbers
The algae absorb and metabolize the
wastes
Microbiologists at the USDA
have experimented with
growing nitrogenmetabolizing
algae on large mats called
scrubbers
So that they can be used as natural
filters
Scrubbers work like charcoal
filters in an aquarium
In that they bind nitrogenous wastes
Water contaminated with farm
animal wastes is passed over the
scrubbers
The algae absorb and metabolize the
wastes
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