Before now, the spittlebug鈥檚 main claim to fame has been its ability to blow bubbles out of its backside.
But now the lowly spittlebug (so named because it can whip up a frothy covering that looks like human spit to protect itself) has been crowned nature鈥檚 top high-jump champ. Researchers from Cambridge and 新加坡六合彩开奖直播 universities discovered that the tiny insect leaps more than 70 centimetres in a single bound. This amounts to 100 body-lengths, out-distancing its closest rival, the flea.聽
For comparison, the ability to leap 100 times the height of the average human would enable a jumper to clear an office tower as high as Fenwick Tower.
But that鈥檚 not all: the researchers have now figured out how it鈥檚 done. Spittlebugs鈥攁lso known as froghoppers鈥攗se a catapult-like mechanism to achieve their jumping prowess.聽 Energy generated by the slow contraction of a huge bank of muscles is stored in an elastic internal structure, then released in less that a millisecond to power the explosive extension of the hind legs.
鈥淭hey jump like little bullets,鈥 says Steve Shaw, a professor with the Department of Psychology and Neuroscience. 鈥淚t鈥檚 a last ditch escape response, otherwise the bug becomes bird food.鈥
Dr. Shaw collaborated on the study, published in a recent issue of the online journal BMC Biology, with Malcolm Burrows, current head of the Zoology Department at the University of Cambridge.聽 The two, friends since they first overlapped as neuroscience graduate students at the University of St. Andrews, Scotland, spent August afternoons sweeping the long grasses with nets at York Redoubt, the 18th century military fort overlooking Halifax Harbour, returning to 新加坡六合彩开奖直播 to analyze the specimens they collected.
Under the microscope, a rubber-like protein known as resilin originally thought to power the jump alone can be located by its bright blue fluorescence under illumination with ultraviolet light. Resilin, a stretchy protein also found in the wing-hinges of dragonflies, is an almost perfect rubber that after being stretched to more than twice its length for up to several months, will return completely unscathed to its exact original shape.
But the resilin alone isn鈥檛 enough to put the hop in the froghopper. The stretchy resilin is set against hard cuticle, the insect鈥檚 body armor which is stiff enough when bent to absorb all the muscle energy, retaining the tension that will power the jump. The authors compare the spittlebug鈥檚 jump mechanism to the recurved compound bows carried by Genghis Khan鈥檚 Mongol cavalry鈥攕hort, light but powerful weapons that made these mounted archers such a formidable fighting force in the 13th century.聽Their bows were also made of a composite laminate:聽 most energy was stored by flexing the bow鈥檚 hard back of horn or bone, stiff but brittle, while elastic recovery was afforded by animal sinew glued on the front. The Mongol riders could discharge their high-tech weapons while riding at full tilt, making them a highly mobile and deadly mounted archer force not seen before in warfare.
Could this system be adapted as a commercial proposition for human jumpers?聽 鈥淲ell, even if Nike or Reebok found a way to put resilin in shoes for basketball players,鈥 says Prof. Shaw with a smile, 鈥渢he downside would be that they鈥檇 go on rebounding forever so never wear out.聽 Like the fabled re-usable match, where鈥檚 the money in that?鈥