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| Live fish caught at record depth | Live fish caught at record depth |
| (about 4 hours later) | |
| A live deep-sea fish has been caught at a record depth of 2,300m on the hot vents of the Mid-Atlantic Ridge. | A live deep-sea fish has been caught at a record depth of 2,300m on the hot vents of the Mid-Atlantic Ridge. |
| Three shrimp species were also pulled to the surface, researchers report in the journal Deep-Sea Research. | Three shrimp species were also pulled to the surface, researchers report in the journal Deep-Sea Research. |
| Scientists have engineered a new device that allows recovery of live animals under their natural pressure at greater depths than previously achieved. | |
| Next they hope to be able to transfer the animals into an experimental lab to study their normal biology. | Next they hope to be able to transfer the animals into an experimental lab to study their normal biology. |
| "Pressurised recovery has been around for the past 30 years, but this is the deepest fish-capture under pressure - the previous record was 1,400m. This is also the first time pressurised capture has occurred at a hydrothermal vent," said Dr Bruce Shillito, marine biologist at the Universite Pierre et Marie Curie, Paris, France. | "Pressurised recovery has been around for the past 30 years, but this is the deepest fish-capture under pressure - the previous record was 1,400m. This is also the first time pressurised capture has occurred at a hydrothermal vent," said Dr Bruce Shillito, marine biologist at the Universite Pierre et Marie Curie, Paris, France. |
| The shrimp species were caught at 1,700m (5,600ft; Mirocaris fortunata and Chorocaris chacei) and 2,300m (7,500ft; Rimicaris exoculata) at two vent fields, Lucky Strike and Rainbow, on the Mid-Atlantic Ridge.Scientists watch the deep-sea fish inside the Periscop onboard ship | The shrimp species were caught at 1,700m (5,600ft; Mirocaris fortunata and Chorocaris chacei) and 2,300m (7,500ft; Rimicaris exoculata) at two vent fields, Lucky Strike and Rainbow, on the Mid-Atlantic Ridge.Scientists watch the deep-sea fish inside the Periscop onboard ship |
| Dr Shillito explains: "At depths of over 1,000m, it is difficult to recover animals alive. Catching with no pressure is as good as catching dead. Fish are the most fragile - even a fisherman with a 100m line will probably reel in a catch whose gas bladder is in its mouth." | Dr Shillito explains: "At depths of over 1,000m, it is difficult to recover animals alive. Catching with no pressure is as good as catching dead. Fish are the most fragile - even a fisherman with a 100m line will probably reel in a catch whose gas bladder is in its mouth." |
| Although the fish caught by the team was a zoarcid (Pachycara saldanhai) and had no gas bladder, it was sensitive to full decompression. | Although the fish caught by the team was a zoarcid (Pachycara saldanhai) and had no gas bladder, it was sensitive to full decompression. |
| At the surface, under pressure, the fish was active and remained upright, however upon release of pressure its movement became uncoordinated and within a few minutes it was totally motionless. | At the surface, under pressure, the fish was active and remained upright, however upon release of pressure its movement became uncoordinated and within a few minutes it was totally motionless. |
| A similar effect, caused by decompression, was also observed in the shrimp species. At the surface, under pressure, most shrimps were in an upright position and swimming actively and continuously. | A similar effect, caused by decompression, was also observed in the shrimp species. At the surface, under pressure, most shrimps were in an upright position and swimming actively and continuously. |
| When a separate shrimp sample was caught and pulled to the surface without pressure, the animals jerked violently, and after a few hours were dead. | When a separate shrimp sample was caught and pulled to the surface without pressure, the animals jerked violently, and after a few hours were dead. |
| The samples were examined onboard the ship "Pourquoi Pas?" during the Momareto cruise, which was organised by Ifremer, the French Research Institute for Exploitation of the Sea. | The samples were examined onboard the ship "Pourquoi Pas?" during the Momareto cruise, which was organised by Ifremer, the French Research Institute for Exploitation of the Sea. |
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| First deep-sea shrimps caught around hydrothermal vent | First deep-sea shrimps caught around hydrothermal vent |
| The next step for Dr Shillito's team is to be able to transfer its catch from the sampling device into a better equipped experimental tank, without decompression, allowing the scientists to observe the animals' normal behaviour and responses to different environments. | The next step for Dr Shillito's team is to be able to transfer its catch from the sampling device into a better equipped experimental tank, without decompression, allowing the scientists to observe the animals' normal behaviour and responses to different environments. |
| "We are particularly interested in the Pompeii worm (Alvinella pompejana), a vent worm which is thought to be the most thermo-tolerant marine organism, yet remains to be recovered in good enough shape. It is intriguing to find out how heat-resistant this animal is," Dr Shillito told BBC News. | "We are particularly interested in the Pompeii worm (Alvinella pompejana), a vent worm which is thought to be the most thermo-tolerant marine organism, yet remains to be recovered in good enough shape. It is intriguing to find out how heat-resistant this animal is," Dr Shillito told BBC News. |
| Despite covering about 60% of the Earth's surface, the deep-sea floor ecosystem is poorly understood. Dr Shillito says: "We urgently need to find out more about the place we are destroying." | Despite covering about 60% of the Earth's surface, the deep-sea floor ecosystem is poorly understood. Dr Shillito says: "We urgently need to find out more about the place we are destroying." |
| He adds: "At a time when we are over-fishing the depths of the ocean, we know more about cooking recipes than the biological features of deep-sea fauna." | He adds: "At a time when we are over-fishing the depths of the ocean, we know more about cooking recipes than the biological features of deep-sea fauna." |
| A new device | A new device |
| The new sampling system for pressured recovery, which has been named Periscop, was developed by Dr Shillito in conjunction with Mr Gerard Hamel, a mechanics engineer at the Universite Pierre et Marie Curie. | The new sampling system for pressured recovery, which has been named Periscop, was developed by Dr Shillito in conjunction with Mr Gerard Hamel, a mechanics engineer at the Universite Pierre et Marie Curie. |
| It received funding from Exocet/d, a large European research programme. | It received funding from Exocet/d, a large European research programme. |
| It has three compartments which perform different tasks - capture at depth, recovery of the deep-sea species under natural pressure, and transfer to the lab with no decompression. | It has three compartments which perform different tasks - capture at depth, recovery of the deep-sea species under natural pressure, and transfer to the lab with no decompression. |
| "In most previous attempts involving pressurised recovery, a single container fulfilled these three tasks - this may lead to contradictory technical requirements," explains Dr Shillito. | "In most previous attempts involving pressurised recovery, a single container fulfilled these three tasks - this may lead to contradictory technical requirements," explains Dr Shillito. |
| The plastic capture box is attached to a submersible arm which allows movement and suction for sampling. The animal is then transferred into a pressurised box. This is kept at the same pressure as the sampling depth during ascent by a pressure compensator. | The plastic capture box is attached to a submersible arm which allows movement and suction for sampling. The animal is then transferred into a pressurised box. This is kept at the same pressure as the sampling depth during ascent by a pressure compensator. |
| "We used pressurised water to maintain pressure, which is a safer and a simpler alternative to gas. We hope this method of pressurised recovery will become standard," Dr Shillito said. | "We used pressurised water to maintain pressure, which is a safer and a simpler alternative to gas. We hope this method of pressurised recovery will become standard," Dr Shillito said. |
| As well as pressure shock, when animals are pulled to the surface they suffer from changes in temperature. | As well as pressure shock, when animals are pulled to the surface they suffer from changes in temperature. |
| "The temperature at depths below 2,000m is pretty constant all over the world - around 2-4C, yet the surface waters where we were sampling were 22-25C," explains Dr Shillito. | "The temperature at depths below 2,000m is pretty constant all over the world - around 2-4C, yet the surface waters where we were sampling were 22-25C," explains Dr Shillito. |
| He adds: "Heating is difficult to prevent without getting out the heavy gear - using active cooling systems, requiring energy and computer controls - but at least we know that every sample has had the same temperature history; they have the same background story." | He adds: "Heating is difficult to prevent without getting out the heavy gear - using active cooling systems, requiring energy and computer controls - but at least we know that every sample has had the same temperature history; they have the same background story." |
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