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"This research is like a kind of "bristling" experiment," Lang

June 1, 2018 by Carolyn Mueller

"This research is like a kind of "bristling" experiment," Lang said. "We're able to measure the surface of the skin in a very tiny area, and we can make out the wrinkles that are there." It also indicates that mako sharks are able to swim through the air on land and over the ocean, creating a more dynamic surface.

Lang's team also showed how the scales could be made to be flexible like that of mako sharks, but the study was published last week in an online online edition of the journal Science.

The study was done at two facilities in southern California. The first was the University of Alabama's Manta Beach research facility. The other was the Marine Aquaculture and Biotechnology Center at the University of Oklahoma's Lawrence Berkeley National Laboratory. Both facilities were funded by the National Science Foundation. The Manta Beach facility was funded by the National Science Foundation. The scientists used a variety of methods to measure the scales and to assess how closely they were able to connect the skin to the brain. The team then used a combination of laser imaging techniques to measure the scales and to determine how flexible the scales were.

The scientists measured the scales on a 3,000-piece-shaped plastic sleeve called the "mako shark skin" that was cut and glued onto a microscope to measure the scales. The researchers used a similar system to measure the scales on the skin inside the shark's head. They measured the scales on a piece of plastic called the "fibula" on either side of the shark's head. The researchers measured in a different manner the scales on the skin inside the shark's body.

One of the researchers on the Manta Beach team used "fibula" as a tool to measure the surface tension at the tip of the shark's head using a computer-assisted laser. The researchers also used a computer-assisted laser technique to measure the surface tension at the tip of the shark's head using a microfibre to measure the strength of the skin.

The Manta Beach researchers used a combination of laser imaging and video analysis to measure the skin's surface tension. The researchers used microfibre to measure the skin stiffness at the tips of the shark's head and the strength of the skin underneath and beneath the shark's body. The team used an ultrasound tool to measure how flexible the scales were. The researchers placed a microfibre inside the shark's body, and then used a motion sensor to measure its surface tension.