Upload
others
View
7
Download
0
Embed Size (px)
Citation preview
Main areas of research • Isolation & screening of new strains
• Studies of limits to productivity and production of specific products
• Culture systems design
• Commercial process development
• Harvesting
• Developing novel technologies
– Non destructive oil extraction (milking)
– Efficient solar energy conversion to biomass and biofuel
– CO2 bioremediation
– Piggery anaerobic digestion treatment
– High value products (i.e. pharmacuticals) • Production of carotenoids (specially lutein & astaxanthin)
• Production of polysaccharides
• Market &Economic analyses
• Strain improvement (incl genetic engineering?)
What are algae? simple, non-flowering, and typically aquatic plants of a large
assemblage that includes the seaweeds and many single-
celled forms . Algae contain chlorophyll but lack true stems,
roots , leaves, and vascular tissue.
What are algae? Phycology is the study of algae. However, just what algae are is
difficult to define, because they belong to many different and
unrelated taxonomic groups and include both prokaryotic and
eukaryotic representatives. Broadly speaking, the algae comprise all,
mainly aquatic, plants and plant-like chlorophyll a-containing
organisms that can use light energy to fix carbon from atmospheric
carbon dioxide (CO2) and evolve oxygen, but which are not
specialised land plants like mosses, ferns, coniferous trees and
flowering plants.
• What is photosynthesis:
• Date: 1898
synthesis of chemical compounds with the aid of radiant energy and
especially light; especially : formation of carbohydrates from carbon
dioxide and a source of hydrogen (as water) in the chlorophyll-containing
tissues of plants exposed to light (http://www.merriam-webster.com/dictionary/photosynthesis)
• It is an improbable process (uphill reaction)
Photosynthesis
Algae VS Bacteria
Photosynthesis:
• What is photosynthesis:
• Date: 1898
synthesis of chemical compounds with the aid of radiant energy and
especially light; especially : formation of carbohydrates from carbon
dioxide and a source of hydrogen (as water) in the chlorophyll-containing
tissues of plants exposed to light (http://www.merriam-webster.com/dictionary/photosynthesis)
• It is an improbable process (uphill reaction)
• Oxygenic photosynthesis is one of the key fundamental biological
process which support life on the earth.
• Chloroplast are responsible for trapping light energy and convert it
to Chemical energy
Habitats
• Water (freshwater to hypersaline brines)
• Soil
• Trees etc.
• Symbionts of lichens, ferns, cycads,
sponges, molluscs, corals, flatworms etc
etc.
Prokaryote
Ancestor
Heterotrophic
Flagellate
Glaucophyta
Rhodophyta
Photosynthetic
Heterotrophic
Flagellate
Cyanobacterium
S!
Flagella lost
Chlorophyta
Loss of phycobilisomes Formation of chlorophyll b Small subunit RuBisCo gene transferred to nucleus
Heterokontophyta Haptophta
Dinophyta
Cryptophyta
Primaeval Brown
Flagellate(s?) Hetrotrophic
dinoflagellate Hetrotrophic
Cryptophyte
Hetrotrophic
Haptophyte
Hetrotrophic
hetrokontophyte
S! S! S!
S!
Heterotrophic
dinoflagellate
Dinophyta
Dinophyta Dinophyta
S! S!
S!
Hetrotrophic
euglenoid
Euglenophyta
S!
Chloroplast Lost
PROKARYOTES
EUKARYOTES
• Photoautotrophy
– Light + inorganic nutrients
– Most microalgae
• Heterotrophy
– Organic compounds (dark)
– Some species (esp. greens, euglenoids & dinos)
• Mixotrophy
– Mixture of phototrophy + heterotrophy
• Phagotrophy
Chlorella – Japan, Taiwan (Indonesia, Czech Republic)
Spirulina – Mexico, USA, Thailand (China, India, Taiwan)
Dunaliella salina – Australia, Israel, USA (India, China)
Haematococcus – USA (India, Israel)
Late 1950’s
1960’s
1970’s
1990’s
+ Microalgae for aquaculture
Products Carotenoids
Fatty Acids
Phycobilins
Enzymes
Vitamins
Polysaccharides
Bioactive
Compounds
Biomass
Biofuels
Algae in Aquaculture
Algae in their own right
Algae as larval feeds (especially for
molluscs, crustaceans and, to a lesser
extent, fish)
Algal carotenoids as pigmenters in feed
(prawns, salmonid fish)
Algae as food in growout stage (molluscs)
N
N
H
H
HO
OH
O
O
Selected Bioactives
Cryptophycins (anti-mitotic) from Nostoc
sp. [US Patents 5945315, 5952298,
5955423]
Cyanovirins (anti-viral) [US Patents
5998587, 6015876]
Antibacterials [US Patent 5866150] from
Chaetoceros sp.
Sunscreens - carotenoids, scytonemin,
mycosporine amino acids [Canadian
Patent Application 2251457] from
Plectonema boryanum
Algae and the Environment
New applications for microalgae in wastewater
treatment higher efficieny wastewater treatment through
immobilised algae or hyperconcentrated algal cultures
new culture systems (tropical & temperate)
algal/bacterial systems in soil bioremediation
heavy metal absorption
Detection systems for toxic algae DNA probes, immunological markers
Management of algal blooms Species-specific viruses
Algae and the Environment
Algae and renewable energy Liquid fuels (biodiesel, bioethanol)
Hydrogen production
Algae in mine site revegetation
Recent Mauna Loa CO2 February 2012: 393.65 ppm
February 2011: 391.76 ppm
Source: http://www.esrl.noaa.gov/gmd/ccgg/trends/
Why microalgae • Faster growth rate
• No need for agricultural land
• Can grow on saline water
• Needs less nutrient (milking!)
Algae Oil
Remaining Biomass
Other
Product(s)?
Saline
Water
Light Nutrients CO2 from Power
Station or similar
source
Recycle water
Anaerobic
Digestion
Animal
feed
Methane
Nutrients
Algae
sugars Ethanol
Biodiesel
GROW
HARVEST
EXTRACT
HTL Bio-oil 20% dry
AAllggaa PPrroodduuccttss EEssttiimmaatteedd CCoosstt
(($$UUSS//kkgg ddrryy wwtt))
Chlorella Biomass >15
Crypthecodinium DHA < 3
Dunaliella Beta-carotene < 10
Haematococcus Astaxanthin < 200
Spirulina Biomass 12 - 18
Aquaculture spp Biomass 60 - 200+
Estimated from lowest sale price of product
Culture Systems
• Extensive Open Ponds (Dunaliella salina)
• Raceway Ponds (Spirulina)
• Centre Pivot Ponds (Chlorella)
• Hybrid (Closed reactor/open raceway)
(Haematococcus pluvialis)
• Fermentor (Crypthecodinium cohnii)
• Big Bags (Aquaculture species)
• Tubular Photobioreactor (?)
In exponential growth
dx = dt (1)
Where is the ‘specific growth rate with
dimension of 1/t
Eqn 1 can be integrated (x=x0 at t=0)
x = x0et (2)
Eqn 2. can be solved to:
ln x/x0 = t (3)
When x = 2x0
ln 2 = t2 (4)
and
t2 = ln 2/ = 0.693/ (5)
Where t2 is the ‘doubling time’
Measuring Growth