Robot dodecahedron mounted on a submersible (circled area)
brennan phillips
The robotic dodecahedron can capture fragile deep-sea animals, collect tissue samples, and build three-dimensional scans of the creatures, potentially speeding up the cataloging of deep-sea life. Up to 66% of marine species are still unknown to science.
brennan phillips RAD2 Sampler and colleagues at the University of Rhode Island have developed the RAD2 Sampler, which is designed to be mounted on any submersible to collect fresh tissue samples in situ from living animals. They hope this will reveal more about the creature than existing techniques, which are typically exposed to stress when pulled up from the depths.
RAD2 is a dodecahedron with an internal volume large enough to hold a basketball. It can be folded and unfolded on command to temporarily capture organisms for detailed examination and take small tissue samples that are stored directly on board the submarine for later genetic analysis. It is designed to.
The ultimate goal is to take a small biopsy and release the animal relatively unscathed, but RAD2's current technique (called tissue cutting) is “a little more crude,” Phillips said.
RAD2 has already been tested on two expeditions, collecting up to 14 tissue samples a day at a depth of around 1200 meters. “We could get small pieces of tissue, and sometimes we could get whole animals,” he says. “It depended on how big it was. So I can't say we've been able to release the animal unharmed after that, but we're moving towards that.”
The robot sampler is also equipped with a 4K resolution video camera to capture high-quality footage of the animal in motion, and a virtual model of the animal is constructed by various 3D scanning devices. In the future, Phillips said, he might be able to put sensors on each of his 12 sides of the dodecahedron and take different measurements of living things at once.
Phillips called other sampling methods “outdated” and said they essentially require people to manually put things into jars for later analysis, or use submersibles to do the same thing. Masu.
Preservation at the point of collection using RAD2 improves the quality of tissue samples and also allows researchers to detect which genes are expressed, further informing animal behavior and physiology. Phillips said it could shed some light. “This is a luxury item,” he says. “This is the best you can get with this animal, better than anyone we’ve ever had.”
eva stewart Researchers at the University of Southampton in the UK say that while digital data on deep-sea life can be a useful tool for research, there is no substitute for capturing and preserving entire samples.
“There are thousands of type specimens here. [at the university]” says Stewart.Some of them were collected by Swedish scientists carl linnaeusShe died in 1778 and says: Once you have the specimen, you are done. Even as our science changes, we can keep coming back to it. ”
But Stewart said underwater scans are useful for gelatinous and other delicate animals that are difficult to collect intact, and for how the creatures behave in their natural environment, rather than after being hoisted onto the deck of a boat. I agree that it may be helpful to understand.
“We've been conducting research to examine gene expression in sea cucumbers because we want to understand how sea cucumbers behave when they're stressed or affected by things like climate change,” says Stewart. he says. “But when you collect them and bring them to the surface, it's stressful. So being able to harvest tissue from them in a more natural way means you know what their natural baseline is, so they can It means we may be able to see more clearly what happens when placed in different environments.”
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Source: www.newscientist.com
