Taken for a spin: scientists look to spiders for the goods on silk.To illustrate the amazing properties of spider silk Spider silk, also known as gossamer, is a fiber spun by spiders. Spider silk is a remarkably strong material. Its tensile strength is comparable to that of high-grade steel — according to Nature[1], spider dragline silk has a tensile strength of roughly 1. , Nikola Kojic offers an arresting example. Imagine a circular web with a diameter of 100 meters--about the length of a football field--spun from a silk thread about a centimeter thick. Concentric circles 4 cm apart attach to the web's spokes, also 4 cm apart. This larger-than-life web "could stop a jumbo jet in midflight," says Kojic. Impressive-as would be the jumbo spider that one could imagine crawling over to the jet. But beyond the monster-movie possibilities, the scenario demonstrates what scientists covet cov·et v. cov·et·ed, cov·et·ing, cov·ets v.tr. 1. To feel blameworthy desire for (that which is another's). See Synonyms at envy. 2. To wish for longingly. See Synonyms at desire. most about spider silk: its exceptional capacity to absorb kinetic energy kinetic energy: see energy. kinetic energy Form of energy that an object has by reason of its motion. The kind of motion may be translation (motion along a path from one place to another), rotation about an axis, vibration, or any combination of . Scientists would like to exploit that property in items ranging from bulletproof Refers to extremely stable hardware and/or software that cannot be brought down no matter what unusual conditions arise. See industrial strength. bulletproof - Used of an algorithm or implementation considered extremely robust; lossage-resistant; capable of correctly vests to suspension cables for bridges. Spiders store tiny amounts of silk. Harvesting the material from the animals isn't practical, says Kojie, a biomedical bi·o·med·i·cal adj. 1. Of or relating to biomedicine. 2. Of, relating to, or involving biological, medical, and physical sciences. engineer at the Massachusetts Institute of Technology Massachusetts Institute of Technology, at Cambridge; coeducational; chartered 1861, opened 1865 in Boston, moved 1916. It has long been recognized as an outstanding technological institute and its Sloan School of Management has notable programs in business, (MIT MIT - Massachusetts Institute of Technology ). Instead, scientists have focused their efforts on making synthetic versions of spider silks, but they haven't yet produced a material as tough as the original. The best industrial fibers, such as Kevlar, don't absorb as much kinetic energy as spider silk does. Their manufacture, moreover, is not environmentally friendly Environmentally friendly, also referred to as nature friendly, is a term used to refer to goods and services considered to inflict minimal harm on the environment.[1] because it requires organic solvents and high temperatures and pressures. In contrast, natural spider silk is produced at room temperature with water as a solvent, says Chris Holland Chris Holland (born 11 September 1975 in Whalley, Lancashire) is an English professional footballer who plays as a midfielder for Southport, having joined in 2007 from Boston United. , a zoologist at the University of Oxford in England. "It's made in the spider, and with the spider eating flies. That produces a fiber that we can't even come close to." Some researchers are considering silk from the spider's perspective. This research is providing insights into the roles that the threads play in spiders' lives. But a focus on the spider may also offer the best chance at replicating the material. New studies examine the flow of the material during the spinning process to learn how a spider makes a thread. At the center of these pursuits lies the winning formula. "Until we know the full system," says Holland, "we won't be able to make a silk as well as the spider can." PROPERTY VALUES When researchers talk about mimicking spider-silk production, they are usually referring to dragline drag·line n. 1. A line used for dragging. 2. A kind of dredging machine. silk. Orbweaving spiders, which spin circular webs with characteristic wagonwheel spokes, use dragline silk for the web's outer rim and spokes. This thread is also the animal's lifeline when it drops from a height. Researchers prize dragline silk for its strength and its toughness, two distinct properties, explains Todd A. Blackledge, a behavioral ecologist at the University of Akron Enrollment in fall 2006 was 23,539 students.[1] The school offers more than 200 undergraduate degrees [2] and 100 graduate degrees [3]. The University's best-known program is its College of Polymer Science and Polymer Engineering, which is located in a in Ohio. The more stationary weight a rope can support, the stronger it is. In contrast, toughness refers to the amount of kinetic energy that a material can absorb without breaking. To lasso lasso (lăs`ō, lăs  `), light, strong rope, usually with a smooth, hard finish, made of a fine quality of hemp or nylon. a running horse, for
example, the rope needs to be tough. Bulletproof vests, which protect
the wearer by halting an oncoming slug, are tough.
"Dragline silk is as strong as steel, but not as strong as Kevlar," says Blackledge. "But [this silk's] toughness is far superior to either of these" The orb weavers spin five fibrous silks and two adhesive silks. Among the fibrous silks is dragline, or major-ampullate silk. Orb weaving spiders build the spirals on their webs with minor-ampullate and capture-spiral silk. The spiders wrap their captured prey with aciniform silk and construct their egg sacs primarily from tnbuliform silk. When building a web, "what a spider is doing is spinning a little miniature environment," Blackledge says. From mating to catching food to protecting the animal from the elements and predators, a web affects various aspects of a spider's life. The properties of silk become relevant, for example, when investigating how a particular type of web catches prey. "You can't really ask that question without understanding the material being used to spin that web," Blackledge says. Researchers are most familiar with the mechanics of dragline and capture-spiral silk, which is sticky, extremely stretchy stretch·y adj. stretch·i·er, stretch·i·est 1. Capable of being stretched: a stretchy fabric. 2. Tending to stretch excessively. Adj. 1. , and tough. The properties of these two silks make webs effective for trapping flying insects, explains Black]edge. The dragline frame of the web absorbs the brunt of an insect's energy. The capture-spiral silk absorbs some energy but sticks to and stretches with the insect, so that it decelerates slowly and doesn't bounce off the web. To learn about the lesser-known silks, Blackledge and his colleague Cheryl Y. Hayashi of the University of California, Riverside The University of California, Riverside, commonly known as UCR or UC Riverside, is a public research university and one of ten campuses of the University of California system. studied the five fibrous silks of the orb-weaving silver garden spider, Argiope argentata Argiope argentata is a member of the Argiope genus of spiders and is also known as the Silver Argiope. Description As with most members of the Argiope genus the female of the species tends to be much larger than the male. . They collected two of the silks directly from the spiders and the other silks from webs, wrapped prey, and egg sacs. They extended the fibers and measured the silks' mechanical properties using a tensile-testing machine. In the July 1, 2006 Journal of Experimental Biology, Black]edge and Hayashi reported that the silks make up a diverse toolkit of fibers "that seem fine-tuned for particular ecological functions." For example, in keeping with its prey-capturing role, the capture-spiral silk is 10 times as stretchy as the other silks. Meanwhile, the tubuliform silk of the protective egg sacs is the stiffest. Furthermore, the researchers found that acinifonn silk, the threads that the spider uses to wrap and secure freshly captured--and still wriggling--prey, is two to three times as tough as the other silks, including dragline. For a materials scientist interested in a high-performance fiber that absorbs kinetic energy, notes Blackledge, "the prey-wrapping silk may be a better model to study than the dragline." Blackledge is interested in the extent to which shifts in spider behavior The behavior of spiders is an often neglected topic in the study of arachnology, stemming from the fact that it is much easier to collect dead specimens for later examination than to observe them in their often unaccessible habitat, or to create laboratory conditions suitable for the have influenced the performance of silks. "When the silk is used in a new ecological context, what happens to the material properties?" Black]edge asks. MATERIAL DIFFERENCE Silk's mechanical properties primarily derive from two critical factors: the proteins that make up the material and the spinning process that transforms the liquid generated inside a spider into a solid fiber. Randolph V. Lewis, a molecular biologist at the University of Wyoming UW is a national research university prominent in the fields of environment and natural resource research, specializing in agriculture, energy, geology, and water resource related fields. in Laramie, and his coworkers have determined the amino acid amino acid (əmē`nō), any one of a class of simple organic compounds containing carbon, hydrogen, oxygen, nitrogen, and in certain cases sulfur. These compounds are the building blocks of proteins. sequence of several silks. They've found distinct amino acid motifs that contribute to different silks' properties. For example, the two major proteins in dragline silk contain frequently occurring stretches of the amino acid alanine alanine (ăl`ənēn'), organic compound, one of the 20 amino acids commonly found in animal proteins. Only the l-stereoisomer participates in the biosynthesis of proteins (see stereochemistry). . Lewis says that these alanine repeats give the fiber strength by permitting one protein chain to snap tightly to another, much as Lego blocks combine. Minor-ampullate silk, which is not as strong as dragline, has shorter stretches of alanines. Meanwhile, capture-spiral silk has a motif, based on a sequence of five amino acids that's repeated up to 68 times in a row (SN: 2/21/98, p. 119). Lewis speculates that this sequence introduces a series of spiraling molecular springs into the protein, which may explain the silk's extreme stretchiness Noun 1. stretchiness - the capacity for being stretched stretchability, stretch elasticity, snap - the tendency of a body to return to its original shape after it has been stretched or compressed; "the waistband had lost its snap" . Lewis' group has built artificial silk genes and inserted them into the common bacterium Escherichia coli Escherichia coli (ĕsh'ərĭk`ēə kō`lī), common bacterium that normally inhabits the intestinal tracts of humans and animals, but can cause infection in other parts of the body, especially the urinary tract. to make proteins that are shorter than the natural versions. The researchers add the resulting proteins to organic solvents, spin this material into fibers with a commercial spinning machine, and test its mechanical properties. If the researchers increase the number of capture-spiral-silk motifs, for example, the elasticity of the fiber grows, although not in direct proportion to the number of motifs. While scientists know a lot about the sequence of individual chains and a bit about the chains' interactions with each other, higher levels of structure are "basically completely unknown," Lewis notes. A silk thread contains hundreds of thousands of protein chains, each of which folds on its own and also arranges itself among other chains in the fiber, he says. He and his colleagues have begun nuclear magnetic resonance nuclear magnetic resonance: see magnetic resonance. nuclear magnetic resonance (NMR) Selective absorption of very high-frequency radio waves by certain atomic nuclei subjected to a strong stationary magnetic field. studies to explore these structural details. "The spider hasn't given us all the secrets," Lewis says. GO WITH THE FLOW Silk's transformation to a solid fiber from a thick liquid containing primarily protein and water begins in specialized glands, one for each type of silk. In each gland, a structure called the tail secretes the starting solution, or spinning dope, into a storage sac. When the spider is ready to spin, the dope moves into a duct. The diameter of the duct narrows as it reaches a nozzle from which the thread exits the spider. To understand the characteristics of the spinning dope, some scientists have turned to rheology, the study of how materials deform and flow. Silk dope has properties intermediate between those of typical liquids and solids, explains Gareth H. McKinley, a mechanical engineer at MIT. Such viscoelastic Adj. 1. viscoelastic - having viscous as well as elastic properties natural philosophy, physics - the science of matter and energy and their interactions; "his favorite subject was physics" materials are thick rather than runny run·ny adj. run·ni·er, run·ni·est Inclined to run or flow: runny icing; a runny nose. runny Adjective [-nier, -niest . They're also elastic: After being stretched, they return to their original states. Silly putty Silly Putty synthetic clay; uses ranging from bouncing balls to false mustaches. [Am. Hist.: Sann, 165] See : Fads and uncooked egg white are two familiar examples of viscoelastic materials, McKinley says. The handful of previous rheology studies of dope used samples that had been diluted to make their volumes large enough to be tested. But machines that can work with small samples of material are now available, notes Holland. Scientists can test tiny amounts of silk dope that have been extracted from a spider. Reports on freshly obtained dragline-dope samples were published last fall by an Oxford team, led by zoologist Fritz Vollrath and including Holland, and by McKinley's team, which includes Kojic. An important concept in theology is shear, the sliding motion of adjacent layers of material. Silk dope experiences shear forces as it moves through the spinning duct. McKinley's group built a microrheometric device that measures how the viscosity of the dope changes in response to shear forces. The researchers place the sample--a drop of dope the size of a pen tip--between two plates. The lower plate remains stationary as the upper plate moves back and forth. The machine's action is much like rubbing a drop of lotion between thumb and forefinger forefinger /fore·fin·ger/ (-fing-ger) index finger; the second finger, counting the thumb as first. fore·fin·ger n. See index finger. to gauge its slipperiness, says McKinley. The researchers found that the faster the upper plate moves, the more readily the dope flows. Shear forces align the proteins in the dope, Kojic says, "and as the proteins align, it becomes easier for them to move relative to one another." Adds McKinley, "Take a big bucket of spaghetti. If you keep stirring it clockwise, it gets easier because the spaghetti strands are lining up." This effect explains how the thick dope can progress through the narrowing duct in an energy-efficient manner, Kojic notes. The team calculated that overall, the viscosity of the dope decreases 10-fold as it flows through the duct. Vollrath, Holland, and their colleagues examined shear viscosity by using a commercial rheometer rhe·om·e·ter n. An instrument for measuring the flow of viscous liquids, such as blood. . Like McKinley's team, they found that the dope flows more easily as the shear rate Shear rate is a measure of the rate of shear deformation:  For the simple shear case, it is just a gradient of velocity in a flowing material. increases. To learn how a spider spins a continuous fiber, McKinley's group developed another microrheometrie device that measures the dope's resistance to stretching, its extensional viscosity. The device's operation is akin to a saliva-dabbed thumb and forefinger pulling apart rather than sliding. A laser determines the diameter of the resulting silk. The researchers found that the dope's extensional viscosity increases 100-fold as the dope is pulled into a thread. This change prevents the thread from breaking before it solidifies. The researchers reported their results in the Nov. 1, 2006 Journal of Experimental Biology. "Hopefully, [the findings] give you guidelines on how you would want to formulate a synthetic equivalent" says McKinley. By testing an artificial silk in a similar way, "you can see whether you match these properties," adds Kojic. FLOWING FARTHER Vollrath's team also compared the rheology of the dragline dope with that of silkworm silkworm, name for the larva of various species of moths, indigenous to Asia and Africa but now domesticated and raised for silk production throughout most of the temperate zone. The culture of silkworms is called sericulture. dope. Spiders and silkworms evolved the capacity to spin silk independently of each other, Holland says. The dopes contain different proteins, and the resulting fibers have distinct properties. Yet "what we see is that the flow properties are very similar," Holland says. Despite their differences, the spider and silkworm "use similar tricks," he continues. "This gives fantastic insight into how silk production has evolved and how the production of an energy-efficient, high-performance fiber is made by nature." Moreover, Holland and his colleagues reported in the November 2006 Nature Materials Nature Materials is a monthly multi-disciplinary journal aimed at bringing together cutting-edge research across the entire spectrum of materials science. The journal’s Impact Factor of 19. , both the spider and silkworm dopes behave like melted polymers. This is "a most welcome observation," they say, because well-developed theories of polymers can be used in studies of silk dope. With rheology proving to be "a valuable tool in showing how silk is physically processed," says Holland, scientists can now move forward in an area that was largely absent from previous attempts to replicate silk. As scientists working to make artificial silks apply new information about dope and how spiders spin it, perhaps they should take a longer-range view of success. As Blackledge notes, "Spiders have been spinning these silks for almost 400 million years." |
|
||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion