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  Visitors & Friends > News > Releases > Scripps > Article News Releases
April 12, 2001
MEASURING THE
MUSCLE: NEW STUDY BY SCRIPPS RESEARCHERS DEPICTS HOW THE TUNA'S BODY IS
BUILT FOR SPEED
Results may be
important for design of robotic, self-propelled aquatic vehicles
Images available upon request
These muscles are the fundamental sources that fish use to power steady swimming and bursts of speed to elude predators and to capture prey. Scientists have long predicted that tuna, with their highly streamlined body and elevated internal temperatures, are equipped with a "high performance" muscle system. Tuna, researchers suspected, power their swimming by projecting muscle force from the mid-body, where the muscle is concentrated, back to the tail, which essentially acts as a natural, thrust-producing hydrofoil.
"The anatomy has been known for a long time, especially the idea that the connective tissue architecture in tunas allows muscles to focus their action further down the body," said Shadwick, a professor in Scripps's Marine Biology Research Division. "We've taken measurements directly from swimming fish to show it working this way." In other fishes, such as trout and mackerel, swimming muscles are distributed more uniformly along the body. When their muscles shorten and produce power, the burst is seen as a wave of contraction that causes the entire body to undulate. Tuna, however, contain swimming muscles located primarily in the central part of the body. Tendons that angle to the backbone link the muscle with the tail. Using ultrasound technology, Shadwick and his colleagues attached tiny transducers directly to tuna muscles to record the muscle electrical activity and contraction as tuna swam in a large water tunnel. A device called a sonomicrometer measured the muscle shortening by timing the ultrasound signal between pairs of transducers.
Shadwick says the results of the study hold implications for research in comparative physiology and the evolutionary biology of fishes. The results also could be important for the design of robotic, self-propelled autonomous underwater vehicles that mimic biological design. The results have
prompted Shadwick to move to other species. With new support from the
National Science Foundation, he and Scripps researcher Jeffrey Graham have
launched a new study to search for the same results in lamnid sharks.
Note: Images available
at http://scrippsnews.ucsd.edu/releases2001/shadwick_tuna1.html
Scripps Institution of Oceanography, at the University of California, San Diego, is one of the oldest, largest, and most important centers for global science research and graduate training in the world. The National Research Council has ranked Scripps first in faculty quality among oceanography programs nationwide. The scientific scope of the institution has grown since its founding in 1903 to include biological, physical, chemical, geological, geophysical, and atmospheric studies of the earth as a system. More than 300 research programs are under way today in a wide range of scientific areas. The institution has a staff of about 1,300, and annual expenditures of approximately $140 million, from federal, state, and private sources. Scripps operates the largest U.S. academic fleet with four oceanographic research ships and one research platform for worldwide exploration. Scripps Institution of Oceanography on the World Wide Web: http://scripps.ucsd.edu Scripps News on the World Wide Web: http://scrippsnews.ucsd.edu
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Now,
through a study sponsored by the National Science Foundation and conducted
at Scripps Institution of Oceanography at the University of California, San
Diego, and the National Marine Fisheries Laboratory in Honolulu, researchers
have for the first time documented this muscle action in motion. Stephen
Katz, Douglas Syme, and Robert Shadwick report their results in the April 12
edition of the journal Nature.
"When
we went inside the fish with ultrasound, we saw that the muscle contraction
caused bending to occur further down the body," said Shadwick. "We
now know that because the muscle tunas use for cruising is close to the
backbone-not adjacent to the skin as in other fish-it is allowed to do large
amounts of shortening, which means more work and more power production.
That's the essence of how this fish is different from others.
Hydrodynamically, that's a more effective way to swim. If all the middle
segments throughout the body were undulating, it would create much more
drag. Tunas have a more streamlined body and the motion at the tail acts
almost like a propeller."