Ultrasound 'eye' scans organs from within.Ultrasound 'eye' scans organs from within A pinhead-sized ultrasound device, threaded through body passages with a catheter, prvides inside views of anatomic cavities, depicting these hard-to-image regions in two and three dimensions, reports radiologist Barry B. Goldberg. Using a television screen, Goldberg displayed his preliminary 3-D images publicly for the first time last week at the annual meeting of the American Association for the Advancement of Science American Association for the Advancement of Science (AAAS), private organization devoted to furthering the work of scientists and improving the effectiveness of science in the promotion of human welfare. in Washington, D.C. The tiny ultrasound transducer, initially developed for detecting plaque buildup inside arteries, could help reveal abnormalities within a variety of passageways such as the ureter ureter (y  rē`tər), thick-walled tube that conveys urine from the kidney to the urinary bladder. It is approximately 10 in. (25. , fallopian tubes Fallopian tubesThe narrow ducts leading from a woman's ovaries to the uterus. After an egg is released from the ovary during ovulation, fertilization (the union of sperm and egg) normally occurs in the fallopian tubes. and bile ducts Bile ducts Tubes that carry bile, a thick yellowish-green fluid that is made by the liver, stored in the gallbladder, and helps the body digest fats. Mentioned in: Liver Transplantation, Percutaneous Transhepatic Cholangiography , Goldberg suggests. These inner recesses are difficult to picture with conventional ultrasound techniques, which use much larger transducers and which view body tissues from the outside looking in, he says. "We see beyond the [tissue] surface," Goldberg says. "We are able to picture abnormalities that before were very difficult to see by any other methods." In the January AMERICAN JOURNAL OF RADIOLOGY, he ad his co-workers at Thomas Jefferson University It began as Jefferson Medical College in 1824. On July 1, 1969 the institution officially became Thomas Jefferson University. The university is made up of three colleges:
When the transducer reaches its target site in the body, it sends out sound waves and receives them as they bounce back from nearby tissue layers. The transducer rotates 360 degrees to create a series of 2-D cross sections. For a 3-D image, a computer combines successive cross sections, piling them up like slies of bread in a loaf. Unlike magnetic resonance imaging magnetic resonance imaging (MRI), noninvasive diagnostic technique that uses nuclear magnetic resonance to produce cross-sectional images of organs and other internal body structures. or CAT scans, the ultrasound 'eyeball' could easily be inserted during surgery to depict abnormalities embedded within tissue, Goldberg says. Eric vanSonnenberg, an ultrasound researcher at the University of California, San Diego UCSD is consistently ranked among the top ten public universities for undergraduate education in the United States by U.S. News & World Report.[3] It is a Public Ivy. [1] For graduate studies, most of UCSD's Ph.D. , says 2-D imaging of tubes such as the ureter holds promise but needs more evaluation to compare its clinical potential with that of other approaches. As for 3-D imaging, "it may turn out to be useful," but practical applications remain speculative, he cautions. Goldberg agrees that his experiments have yet to establish the clinical advantages of the new 3-D views, but he suggests the added dimensions might, for instance, help physicians assess a tumor's size and how deeply it has invaded adjacent tissue, improving their ability to make treatment decisions. |
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