Beyond Jell-O: new ideas gel in the lab. (This Week).The gelatin in your dessert bowl and the absorbant in your baby's diapers are known technically as hydrogels. Now, researchers have created a new variety of hydrogels that they hope to use for more complex pursuits, including drug delivery, bone repair, and organ replacement. Hydrogels are networks of polymers that don't dissolve in water. Instead, they swell up, or gel. Many hydrogels, like the colorful edible gelatin, are made from natural proteins, while others are artificial. To make the new hydrogels, Timothy Deming of the University of California, Santa Barbara History The predecessor to UCSB, Santa Barbara State College, focused on teacher training, industrial arts, home economics, and foreign languages. Intense lobbying by an interest group in the City of Santa Barbara led by Thomas Storke and Pearl Chase persuaded the State and his colleagues made polymers of amino acids by using synthetic-chemistry techniques. For each polymer, the researchers used two types of amino acids. Each molecule contained a chain of one amino acid that's water soluble linked to a chain of another that isn't. This created polymers with a hydrophilic hydrophilic /hy·dro·phil·ic/ (-fil´ik) readily absorbing moisture; hygroscopic; having strongly polar groups that readily interact with water. hy·dro·phil·ic adj. , or water-loving, part and a hydrophobic, or water-averse, part. Generally, chemical organizations of this kind fold into spherical structures called micelles in water. In these structures, the water-averse part becomes the center of a sphere and the water-loving part becomes the outside. However, the new polymers surprised the researchers by forming hydrogels instead, says team member Andrew Nowak of UC-Santa Barbara. The researchers discovered that their new hydrogels have traits that could make them useful. They don't liquefy liquefy /liq·ue·fy/ (lik´wi-fi) to become or cause to become liquid. even at temperatures as high as 90 [degrees] C--much higher than the melting point of many hydrogels. Also, they quickly regain their gel-like quality, or stiffness, after being physically broken up. Moreover, compared with most hydrogels, the new materials gel in water containing much less polymer. The research provides important insight into what makes good hydrogels, says team member Darrin Pochan of the University of Delaware [3] The student body at the University of Delaware is largely an undergraduate population. Delaware students have a great deal of access to work and internship opportunities. in Newark. The strongest hydrogels formed from polymers that included hydrophobic amino acids that take on helical shapes, such as strings of leucine leucine (l  `sēn), organic compund, one of the 20 amino acids commonly found in animal proteins. . Stiff gels also formed when the researchers used a string of valine valine (văl`ēn), organic compound, one of the 22 α-amino acids commonly found in animal proteins. Only the l-stereoisomer appears in mammalian protein. , a zigzagging structure, as the hydrophobic amino acid. In contrast, polymers made with blocks of amino acids that assume more random conformations formed much weaker hydrogels. Such knowledge is useful for designing hydrogels with particular properties, says Nowak. Since the new hydrogels are made of amino acids found in natural proteins, they could be used in materials intended to break down in the body, says Pochan. In addition, he says, the new hydrogels have well-ordered networks of pores on both the nanometer and micrometer micrometer (mīkrŏm`ətər, mī`krōmē'tər). 1 Instrument used for measuring extremely small distances. scales. Typically, hydrogel hy·dro·gel n. A colloidal gel in which the particles are dispersed in water. hydrogel a gel that contains water. hydrogel Wound care A polymer absorptive wound dressing. See Dressing. structures are less ordered, akin to cooked spaghetti. The new structures could be designed to carry drugs or serve as scaffolds for growing tissue or depositing minerals. The porous networks are certainly the appropriate size for such applications, especially for growing cells into tissue, comments Shuguang Zhang of 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, . |
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