Visitor Counter

hitwebcounter web counter
Visitors Since Blog Created in March 2010

Click Below to:

Add Blog to Favorites

Coyotes-Wolves-Cougars.blogspot.com

Grizzly bears, black bears, wolves, coyotes, cougars/ mountain lions,bobcats, wolverines, lynx, foxes, fishers and martens are the suite of carnivores that originally inhabited North America after the Pleistocene extinctions. This site invites research, commentary, point/counterpoint on that suite of native animals (predator and prey) that inhabited The Americas circa 1500-at the initial point of European exploration and subsequent colonization. Landscape ecology, journal accounts of explorers and frontiersmen, genetic evaluations of museum animals, peer reviewed 20th and 21st century research on various aspects of our "Wild America" as well as subjective commentary from expert and layman alike. All of the above being revealed and discussed with the underlying goal of one day seeing our Continent rewilded.....Where big enough swaths of open space exist with connective corridors to other large forest, meadow, mountain, valley, prairie, desert and chaparral wildlands.....Thereby enabling all of our historic fauna, including man, to live in a sustainable and healthy environment. - Blogger Rick

Subscribe via email to get updates

Enter your email address:

Receive New Posting Alerts

(A Maximum of One Alert Per Day)

Sunday, May 3, 2015

Fish have a kind of full-body flow antenna that is a network of microscopic hair cells, much like the hair cells of our inner ear.............. These detect minute changes in water velocity and direction.............. Clumps of these cells are called neuromasts, and some of them are on the surface of the fish between the scales. ............. Others are embedded inside canal systems................. The entire hydrodynamic antenna is referred to as the lateral line..........These "antenna" give fish the ability to "turn on a dime" so as to avoid perceived dangers, using their sense of changing(water current) flows in precise ways to guide their movements..............It might be that someday, using technologies learned from fish, we will hear with our skin............... That may sound pretty far-fetched today, but as our great 20th century Naturalist, Aldo Leopold always stated: "keep all the cogs and wheels"-----nature is where the best designs are found...

http://northernwoodlands.org/outside_story/article/fish-flow#.VUPCn82V9jM.mailto




Fish Go With the Flow
Illustration by Adelaide Tyrol

 
There are times when fish appear telepathic. Consider the uncanny way a school of bait fish moves as one to avoid a predator, or the way goldfish in their lighted bowl turn towards the glass when someone walks into the dark room. Researchers often describe this ability as “touch-from-a-distance.” But fishy sixth sense is closer to hearing than touch. It’s what allows salmon to deftly ply the currents and eddies as they make their spawning runs upstream. They listen to the flow.
Fish have a kind of full-body flow antenna that is a network of microscopic hair cells, much like the hair cells of our inner ear. These detect minute changes in water velocity and direction. Clumps of these cells are called neuromasts, and some of them are on the surface of the fish between the scales.  Others are embedded inside canal systems. The entire hydrodynamic antenna is referred to as the lateral line.
Jimmy Liao, a neuroscientist and researcher in biomechanics at the University of Florida, was particularly interested in learning more about the distribution of neuromasts on the fish’s head. “The remarkable thing,” Liao told me, “is that all 30,000 or so known bony fish species have the same configuration of sensory canals  – one goes over the eye, another under the eye and the third along the chin.”
Liao teamed up with New York University mathematician Leif Ristroph and physics professor Jun Zhang from Shanghai to map the neuromasts of one of these head canal branches and then see what happened when they subjected that configuration to flowing water. It wouldn’t work to attach heavy sensors and wires to a real fish, so they built a plastic fish molded from an actual rainbow trout and attached tiny pressure sensors to it. The plastic trout went into a water-filled flume where they could dial up water current with an electric propeller.
What they learned confirmed their hypothesis, that the greatest density of sense cells is found precisely where pressure changes are felt the greatest. “The distribution of neuromasts is not randomly evolved,” Liao told me, “but designed in an optimal way.” Fish use the sense of changing flows in precise ways to guide their movements.  
Liao’s neuro-mechanical analysis of the lateral line may lead to technological innovations.  For example, “engineers designing deep ocean submersibles can incorporate flow sensors to guide the craft in the dark. Our research can tell them how many flow detectors are needed and where they should be placed,” Liao said.
There may be applications for human hearing as well. Because fish neuromasts are on the surface, they’re much easier to study than the nearly identical hair cells inside a person’s inner ear. Scientists working to cure deafness, for example, need to better understand how nerve cells translate the physical movement of hair cells in the inner ear to the electric impulses lighting up various regions of the brain.
It might be that someday, using technologies learned from fish, we will hear with our skin.  That may sound pretty far-fetched today, but sometimes nature is where the best designs are found.
Tim Traver is an author and freelance writer. Previously, he served as executive director of the Upper Valley Land Trust and co-directed the social service organization COVER Home Repair.

No comments: