News Release

Unique means of animal locomotion reported for first time

Novel 'two-body' system could have implications for robotics, human biomechanics

Peer-Reviewed Publication

Tufts University

Caterpillar Crawl

video: Tufts University-led researchers studying caterpillars have reported on a unique system of locomotion never before reported for any animal, which may have implications for robot design and for human biomechanics. In a study published online June 22 in the journal Current Biology, the biologists reported that the gut of the crawling tobacco hawkmoth caterpillar (Manduca sexta) moves forward independently of and in advance of the surrounding body wall and legs, rather than moving along with them. This novel two-body mechanical system involves "visceral-locomotory pistoning" in which the body segments (represented by green spheres) contract in a longitudinal wave from back to front, while the gut (represented by the long cylinder) changes size under action by the front and back of the body. Collaborating with Tufts were researchers from Virginia Tech and Argonne National Laboratory. (Michael Simon/Tufts University. Not to scale.) view more 

Credit: Michael Simon/Tufts University

MEDFORD/SOMERVILLE, Mass. -- Biologists at Tufts University's School of Arts and Sciences studying crawling caterpillars have reported a unique "two-body" system of locomotion that has not previously been reported in any animal.

In an article published online July 22 in the journal Current Biology, the Tufts-led team reported that the gut of the crawling tobacco hawkmoth caterpillar (Manduca sexta) moves forward independently of and in advance of the surrounding body wall and legs, rather than moving along with them. Collaborating with Tufts were researchers from Virginia Tech and Argonne National Laboratory.

"Understanding this novel motion system may help efforts to design soft-bodied robots," said the article's senior author, Barry Trimmer, Tufts professor of biology and Henry Bromfield Pearson Professor of Natural Sciences in the School of Arts and Sciences. "It may also prompt re-examination of the potential role soft tissues play in biomechanical performance of humans and other animals."

Surprises Inside the Caterpillar

Anyone who has ever observed caterpillars knows that they crawl from back to front in waves. But advanced imaging reveals a surprising picture of what goes on inside.

The researchers used synchronized X-ray and visible light microscopy and videos to study the relative timing of movements of the crawling caterpillars' gut body wall and prolegs (unjointed leg-like structures on the mid-body that grip).

They found that the gut -- essentially a tube suspended at the rear and head of the caterpillar and decoupled from the body wall -- moved nearly a full step in advance of the surrounding structures. In contrast, gut movement was "in step" with motion of the head and rear.

Furthermore, points within the gut moved at different rates, suggesting that the gut was effectively shortening and lengthening during each crawl cycle.

"Although internal tissue movement caused by locomotion has been identified in many organisms, the caterpillars seemed to be propelling themselves by means of a two-body system -- the body wall container and the gut it contained. This may contribute to the extraordinary freedom of movement seen in these soft-bodied crawlers," said first author Michael Simon. Simon conducted the study as part of his doctoral research in Trimmer's laboratory, which focuses on how cell signaling contributes to the functions of the central nervous system and has extensively studied Manduca sexta.

In addition to Simon and Trimmer, authors on the paper included Tufts Research Assistant Professor William A. Woods; Tufts undergraduate Yevgeniy Serebrenik; Sharotka Simon, of Brandeis University; Tufts Graduate School of Arts and Sciences doctoral student Linnea van Griethuijsen; John Socha of Virginia Tech; and Wah-Keat Lee of Argonne National Laboratory.

More research is needed to determine if this phenomenon gives caterpillars an evolutionary advantage, in the same way that synchronizing breathing and tissue movements benefits running vertebrates, or arm swinging by walking humans increases stability and reduces metabolic costs.

Regardless, Simon says that this insight may offer valuable application to robotics. "The focus to date has been on robots' external design but we also have to look at how it's most advantageous to arrange the inside of the robot and any payload. Would motion be enhanced, for example, by packing more mass toward the rear, as these caterpillars seem to do?"

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This work was funded by a National Science Foundation grant. Use of the Advanced Photon Source at Argonne National Laboratory was supported by the U. S. Department of Energy, Office of Science, Office of Basic Energy Sciences.

Simon Michael A, Woods William A Jr, Serebrenik Yevgeniy V, Simon Sharotka M, van Griethuijsen Linnea I, Socha John J, Lee Wah-Keat, Trimmer Barry A, (2010), "Visceral-locomotory Pistoning in Crawling Caterpillars (Manduca sexta)", Current Biology, DOI: 10.1016/j.cub.2010.06.059.

Tufts University, located on three Massachusetts campuses in Boston, Medford/Somerville and Grafton, and in Talloires, France, is recognized among the premier research universities in the United States. Tufts enjoys a global reputation for academic excellence and for the preparation of students as leaders in a wide range of professions. A growing number of innovative teaching and research initiatives span all Tufts campuses, and collaboration among the faculty and students in the undergraduate, graduate and professional programs across the university's schools is widely encouraged.


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