When placed in oxygen-rich seawater, the copepod eggs hatch within 24 hours. (Photo: Sintef)
Faith in industry
Researchers at SINTEF and the Norwegian University of Science and Technology (NTNU) are already producing copepod eggs intensively for their experiments with various species of marine fish larvae. Female copepods produce 30-50 eggs per day for up to 50 days.
So far the researchers have been able to utilise a fraction of this production, but the potential is enormous: in theory, starting with just three copepods per millilitre of water in a 10-m3 tank, 450-825 million eggs could be produced per day, assuming equal numbers of males and females in the tank.
Project manager Gunvor Øie of SINTEF Fisheries and Aquaculture is confident that commercial production of copepod eggs is feasible. (Photo: Torkil Marsdal Hanssen)
“Copepods are currently fed live microalgae,” explains project manager Gunvor Øie of SINTEF Fisheries and Aquaculture.
“We are collaborating with microalgae producers on developing a special feed in paste form that will provide more control over feeding. In addition we believe we can increase the ratio of females in the production tanks. Cost-effective, stable, predictable production of copepod eggs, however, will require upscaling, further technology development and automation of processes – which we are very optimistic about.”
Just add seawater…
The researchers have found that older, properly stored eggs hatch just as well as fresh eggs. When harvested, the eggs are placed in bottles of oxygen-free seawater and stored in a dark refrigerator.
“The eggs can be stored like this for at least seven months,” explains Dr Øie. “When a farm’s fish larvae need copepods, the desired number of eggs can be transferred to oxygen-rich seawater and will hatch within 24 hours.”
Industrial production of copepod eggs will allow greater control over nutritional composition. The eggs can also be disinfected against parasites, bacteria and viruses.
“We know that a diet of copepods substantially improves fry quality in species such as Ballan wrasse, cod and halibut,” continues Dr Øie.
“Industrial production also opens up possibilities for farming new marine species for which fry production has proved difficult – such as with tuna, groupers and aquarium fish. Using our copepods, for instance, mandarinfish have now been bred in captivity for the first time.”
- The copepod subclass comprises thousands of species. They are crustaceans, typically 1-2 mm long, and are a natural source of food for marine fish species in the wild.
- A diet of copepods promotes faster growth, improves survival and results in fewer malformations in production fish larvae than a diet of rotifers (rotifera) and artemia (crustaceans), which are currently the two most commonly used first-feed species.
- Copepods can be harvested by filtering seawater, but their abundance varies with the season and weather conditions, and filtering provides little control over species composition, nutritional content, parasites, bacteria or viruses.
- The research being carried out now is funded by the Norwegian Seafood Research Fund and is managed by the Ballan wrasse producers.