National Academies Press: OpenBook

Memorial Tributes: Volume 8 (1996)

Chapter: Rowland Wells Redington

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Suggested Citation:"Rowland Wells Redington." National Academy of Engineering. 1996. Memorial Tributes: Volume 8. Washington, DC: The National Academies Press. doi: 10.17226/5427.
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Page 194
Suggested Citation:"Rowland Wells Redington." National Academy of Engineering. 1996. Memorial Tributes: Volume 8. Washington, DC: The National Academies Press. doi: 10.17226/5427.
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Page 195
Suggested Citation:"Rowland Wells Redington." National Academy of Engineering. 1996. Memorial Tributes: Volume 8. Washington, DC: The National Academies Press. doi: 10.17226/5427.
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Page 196
Suggested Citation:"Rowland Wells Redington." National Academy of Engineering. 1996. Memorial Tributes: Volume 8. Washington, DC: The National Academies Press. doi: 10.17226/5427.
×
Page 197
Suggested Citation:"Rowland Wells Redington." National Academy of Engineering. 1996. Memorial Tributes: Volume 8. Washington, DC: The National Academies Press. doi: 10.17226/5427.
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Page 198
Suggested Citation:"Rowland Wells Redington." National Academy of Engineering. 1996. Memorial Tributes: Volume 8. Washington, DC: The National Academies Press. doi: 10.17226/5427.
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Page 199

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ROWLAND WELLS REDINGTON 1 924-1 995 BY LEWIS S. EDELHEIT AND WALTER L. ROBB Rowf AND W. RED REDINGTON, who died on June 22, 1995, was a physicist and manager of technology who lecI enormous- ly successful innovation projects that set the world standarcl in CAT scanning and magnetic resonance imaging. His greatest strength was captured by a journalist who labeled him "mecli- cal imaging's player coach." RecI had a remarkable ability to bring out the best in each member of the large teams neecled to create world leaclership in medical imaging systems. Recl's colleagues most vividly recall his laugh. Sharp, explo- sive, anct infectious, it expressed the zest that marked his efforts whether it was skippering a sailboat, learning wood- working, or leacling a research and development team on a technical leap that would carry General Electric beyond the competition in a pioneering fielcl. Recl was born in Otega, New York, in 1924. His mother was a schoolteacher, and his father ran a feed store en cl tinkerer! with farm machinery. He earned his bachelor's degree in me- chanical engineering from Stevens Institute of Technology in 1945 and went to work as an aerodynamicist for Curtiss Wright in Buffalo, New York. But the view from his window of war surplus airplanes being scrapped contrasted sharply with the excitement being generated not far away in Ithaca, where Cor- nell University was assembling one of the worId's best physics departments, uncler the leadership of Hans Bethe, Richard 195

196 MEMORIAL TRIBUTES Feynman, and Robert R. Wilson. Red earned a Ph.D. degree in physics from Cornell, writing his dissertation on the diffu- sion of barium in barium oxide. On graduation in 1951, he joined General Electric's (GE) Corporate-leve! Research and Development Center in Schenectady, New York. At the bench, he worked on new concepts for electron mul- tiplier tubes for infrared-light imaging, helped develop improved video cameras, published papers on subjects rang- ing from electrostatic optics to infrared absorption, and earned patents in such areas as camera tubes en c! electropho- tographic processes. He would ultimately publish ninety-nine technical papers and earn twenty-six U.S. patents. By the early 1970s Red had become a manager of a small group developing imaging technology. Its efforts ranged from a concept for three-dimensional television that never made it out of the lab to a program on electronic fluoroscope for GE's x-ray business that achieved some technical success. Then, in 1973, an innovation burst on the scene. Godfrey Hounsfield, an engineer at EMI in Great Britain, introduced the first practical computerized axial tomography x-ray sys- tem, soon popularly known as the CAT scanner. GE x-ray marketers were not initially impressed. X-rays had achieved a resolution of one millimeter or less while the CAT scanner could at best achieve one centimeter. X-ray imaging was instantaneous, while the first CAT scanner required min- utes to acquire data. Surely CAT was at best a research device with a market measured in tens of units, not hundreds or thousands. Red, however, appreciated the advantages that had inspired Hounsfield. Here was a way to distinguish density differences of as little as one-half of one percent, a feat impossible with conventional x-ray systems. That meant, for example, that brain tumors could now be found without painful and some- times dangerous injection of air or other contrast materials, or exploratory surgery. Hospitals began ordering CAT scan- ners instead of conventional x-ray systems. This got the attention of GE business leaclers, and they came to the Re- search and Development Center and to Reci.

ROWLAND WELLS REDINGTON 197 Hounsfield's initial machine had used a principle called "translate-rotate" to send and detect the hundreds of pencil- shaped x-ray beams that providecl data for making an image. One might get into the business by simply imitating this ap- proach. However, Red and his colleagues at the Research and Development Center thought they could do better. In 1974 Recl sold a more ciaring approach to GE Meclical Systems business leadership. GE would leapfrog the EMI ap- proach with an advanced scanner employing a fan beam instead of a pencil beam, and continuous rotation of the x-ray tube and detectors in place of the translate-rotate approach. It offered a faster scan, one that might image the head or body in just five seconds. But it also offered daunting chal- lenges. Neither the required detectors, nor the complicated mathematical algorithms needed to reconstruct the image, then existed. Housfield himself had looker! at the continuous rotation approach and declared it impractical. Rec3 and his team initially developed the concept for a pro- totype capable of imaging a five-inch diameter object, and targeted mammography as an application. In 1974 the GE Research and Development Center launchecI a joint project with the Mayo Clinic to build a fan-beam CAT scanner for breast cancer screening. Putting together a multiclisciplinary team of dozens of people, Red led the effort that built, on schedule, this pioneering fan-beam scanner. Even before its delivery to the Mayo Clinic in 1975, however, GE committed to a next step, a "whole body" fan-beam scanner aimed at the commercial market. It was built on the foundation created by Recl and his team. For example, the algorithms for fan-beam CAT scan reconstruction were developed for GE by Gabor Herman and colleagues at the University of Buffalo, and the xenon x-ray detector was developed by GE's John Houston and N. Rey Whetten. As the fan-beam scanner quickly moved from lab project to commercial procluct, Red remained deeply involved. He spent one week a month at the University of California, San Fran- cisco, in 1976, helping to coax top performance out of GE's first prototype scanner. He helpecl solve a crucial problem

198 MEMORIAL TRIBUTES that had lecI to images that macle skulls look thicker than they actually were. The "thircl generation" CAT technology that RecT champi- oned has since become the world standard. As it dicI, and as GE built a highly profitable business, Red began looking for another frontier. It proved to be magnetic resonance (MR). MR haci entered physics in the late 1940s with the pioneer- ing work of Bloch and Purcell and was applied to medicine in the early 1970s by Lauterbur en c! Damaclian. It offered a way to use the combination of a strong, uniform magnetic field and radio signals that make images of the inside of the body without x-rays. Again, here was an area that initially looked dubious as an improvement on x-rays. Resolution was poor, en cl though you could make a two-dimensional "slice" image, it looked initially like a bacI CAT scan. Red, however, saw opportunity. Asked to put together a team on MR, Rec! went out and looked for the very best peo- ple in the field. Two of the university researchers he fount! were recognizes! as worIcl class, but he was warned that they were prima clonnas who couIcl never work together. He hired them both anyway, and under his coaching, they complement- ed each other as technical leaclers. Red was similarly able to bring out the best in people already available at the GE lab en c! blend them into what became a worIc3-cIass team. Reci urged that MR's advantage was the ability to do spec- troscopy as well as imaging: that is, to measure the levels of chemicals inside the brain or body without surgery or use of needles. When GE Meclical Systems suggested that Red lead a research program on imaging, Rec3 replied "that's not re- search, that's clevelopment." The outcome was an agreement by GE Medical Systems in 1981 to purchase for Recl's research team a 1.5 Tesla magnet, about three times the field strength of the magnet other MR researchers were `using, for research on both spectroscopy en c! imaging. Competitors saicl that good images couIcl never be macle on high-fielc! systems. Red's team proved them wrong by produc- ing, in 1982, better-quality images than those seen anywhere else in the world. As MR established its ability to provide imag

ROWLAND WELLS REDINGTON 199 es of "soft" tissues of the brain that were much better than even CAT scanning, this capacity gave GE a competitive edge. (Spectroscopy, the other target of the program, was accom- plishecl with technical success, but has not so far proven of major clinical value.) Again, close teamwork with GE Medical Systems rapidly turned the lab prototype into a product. GE's Signa(D magnetic resonance imager, introduced in 1983, put GE into a commercial leadership position that it has never relinquished. Red subsequently returned to the bench to do research on magnetic resonance microscopy, and retired from GE in 1989. Among his numerous awards were the prize for Tnclustrial Ap- plications of Physics sponsored by the American Institute of Physics, en c! the "Engineer of the Year" award from 1989, pre- sentecl by Design News Magazine. He remained a great coach and mentor to many scientists and engineers. Throughout his career, Red pursuccI a wide variety of inter- ests. He was an avid sailboat racer on Lake George. His crews never left the boat without a goof! day. Winning was less im- portant than trying out new gadgets. He enjoyed practical jokes. He collected old mantelpieces and parts for MG auto- mobiles and was a long-standing volunteer fireman. Recl's marriage to the former Shirley Bennett in 1947 re- sulted in a devotee! lifelong partnership. Their shared interest in gardening led to an outstanding garden of dwarf conifers, and leadership in many local and national horticultural soci- eties. Their deaths were only a few months apart. Red's success resulted from his rare combination of skills. He could do first-rate technical work himself, head a team to come up with a new idea, sell the idea to a skeptical manage- ment, and clefencI the idea when the world said it couldn't be done. Through it all, he earned not only the respect but also the affection of all involved. Themes he pioneered in the 1970s and 19SOs are staples of the research en c! development of the 199Os: teamwork between businesses and laboratories, multidisciplinary effort, speed, and quality. As he put it: "build it the very best way you know how, grab the top of the market, then work at reducing costs. But whatever you A, don't com- promise quality at the start, because you can never recover."

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