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Roger Wolcott Sperry

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Title: Roger Wolcott Sperry  
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Collection: 1913 Births, 1994 Deaths, American Neuroscientists, American Nobel Laureates, American Psychologists, California Institute of Technology Faculty, Cognitive Neuroscientists, Consciousness Researchers and Theorists, Foreign Members of the Royal Society, Foreign Members of the Russian Academy of Sciences, Foreign Members of the Ussr Academy of Sciences, Harvard University Staff, History of Neuroscience, National Medal of Science Laureates, Neuropsychologists, Nobel Laureates in Physiology or Medicine, Oberlin College Alumni, People from West Hartford, Connecticut, Recipients of the Albert Lasker Award for Basic Medical Research, University of Chicago Alumni, Wolf Prize in Medicine Laureates
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Roger Wolcott Sperry

Roger Wolcott Sperry
Born August 20, 1913 (2009-08-20)
Hartford, Connecticut
Died Did not recognize date. Try slightly modifying the date in the first parameter. (aged 80)
Pasadena, California
Fields Neuropsychology
Alma mater Oberlin College
University of Chicago
Doctoral advisor Paul A. Weiss
Known for Split-brain research
Chemoaffinity hypothesis
Notable awards 1981 Nobel Prize in Physiology or Medicine

Roger Wolcott Sperry (August 20, 1913 – April 17, 1994) was a neuropsychologist, neurobiologist and Nobel laureate who, together with David Hunter Hubel and Torsten Nils Wiesel, won the 1981 Nobel Prize in Physiology and Medicine for his work with split-brain research.[1][2][3][4][5] A Review of General Psychology survey, published in 2002, ranked Sperry as the 44th most cited psychologist of the 20th century.[6]


  • Early life 1
  • Career 2
  • Nobel Prize 3
  • Personal life 4
  • Awards 5
  • Bibliography 6
  • References 7
  • Sources 8
  • External links 9

Early life

Sperry was born in Hartford, Connecticut, to Francis Bushnell and Florence Kraemer Sperry. His father was in banking, and his mother trained in business school. He was raised in an upper middle-class environment, which stressed academic achievement.[7] Roger had one brother, Russell Loomis. Their father died when Roger was 11. Afterwards, his mother became assistant to the principal in the local high school.

Sperry went to [8]


In 1942, Sperry began work at the Yerkes Laboratories of Primate Biology, then a part of Harvard University. There he focused on experiments involving the rearranging of motor and sensory nerves.[9] He left in 1946 to become an assistant professor, and later associate professor, at the University of Chicago. In 1949, during a routine chest x-ray, there was evidence of tuberculosis. He was sent to Saranac Lake in the Adironack Mountains in New York for treatment. It was during this time when he began writing his concepts of the mind and brain, and was first published in the American Scientist in 1952.[10] In 1952, he became the Section Chief of Neurological Diseases and Blindness at the National Institutes of Health and finished out the year at the Marine Biology Laboratory in Coral Gables, FL. Sperry went back to The University of Chicago in 1952 and became an Associate Professor of Psychology. He was not offered tenure at Chicago and planned to move to Bethesda, Maryland but was held up by a delay in construction at the National Institutes of Health. During this time Sperry's friend Victor Hepburn invited him to lecture about his research at a symposium. There were professors from the California Institute of Technology in the audience of the symposium who, after listening to Sperry’s lecture, were so impressed with him they offered him a job as the Hixson Professor of Psychobiology.[11] In 1954, he accepted the position as a professor at the California Institute of Technology (Caltech as Hixson Professor of Psychobiology) where he performed his most famous experiments with Joseph Bogen, MD and many students including Michael Gazzaniga.

Under the supervision of Paul Weiss while earning his Ph.D. at the University of Chicago, Sperry became interested in neuronal specificity and brain circuitry and began questioning the existing concepts about these two topics. He asked the simple question first asked in his Introduction to Psychology class at Oberlin: Nature or nurture? He began a series of brilliant experiments in an attempt to answer this question. Sperry took the motor nerves from the right hind legs of rats and switched them with the motor nerves in the left hind legs of other rats and vice versa. He would then place the rats in a cage that had an electric grid on the bottom separated into four sections. Each leg of the rat was placed into one of the four sections of the electric grid. A shock was administered to a specific section of the grid, for example the grid where the rat’s left back leg was located would receive a shock. Every time the left paw was shocked the rat would lift his right paw and vice versa. Sperry wanted to know how long it would take the rat to realize he was lifting the wrong paw. After repeated tests Sperry found that the rats never learned to lift up the correct paw, leading him to the conclusion that some things are just hardwired and cannot be relearned. In Sperry’s words, “no adaptive functioning of the nervous system took place.” [12] During Sperry's postdoctoral years with Karl Lashley at Harvard and at the Yerkes Laboratories of Primate Biology in Orange Park, Florida, he continued his work on neuronal specificity that he had begun as a doctoral student and initiated a new series of studies involving salamanders. The optic nerves were sectioned and the eyes rotated 180 degrees. The question was whether vision would be normal after regeneration or would the animal forever view the world as "upside down" and right-left reversed. Should the latter prove to be the case, it would mean that the nerves were somehow "guided" back to their original sites of termination. Restoration of normal vision (i.e., "seeing" the world in a "right-side-up" orientation) would mean that the regenerating nerves had terminated in new sites, quite different from the original ones. The animals reacted as though the world was upside down and reversed from right to left. Furthermore, no amount of training could change the response. These studies, which provided strong evidence for nerve guidance by "intricate chemical codes under genetic control" (1963) culminated in Sperry's chemoaffinity hypothesis (1951).[13]

Sperry later served on the Board of Trustees and as Professor of Psychobiology Emeritus at California Institute of Technology.

Nobel Prize

Sperry was granted numerous awards over his lifetime, including the California Scientist of the Year Award in 1972, the National Medal of Science in 1989, the Wolf Prize in Medicine in 1979, and the Albert Lasker Medical Research Award in 1979, and the Nobel Prize for Medicine/Physiology in 1981 that he shared with David H. Hubel and Torsten N. Wiesel. Sperry was awarded this award for his work with “split-brain” patients. The brain is divided into two hemispheres, the left and right hemispheres, connected in the middle by a part of the brain called the corpus callosum. In “split-brain” patients, the corpus callosum has been severed due to the patients suffering from epilepsy, a disease that causes intense and persistent seizures. Seizures begin in one hemisphere and continue into the other hemisphere. Cutting the corpus callosum prevents the seizures from moving from one hemisphere to the other, which then prevents seizures from occurring, thus allowing the patients to function normally instead of suffering from continuous seizures.

Sperry first became interested in “split-brain” research when he was working on the topic of interocular transfer, which occurs when “one learns with one eye how to solve a problem then, with that eye covered and using the other eye, one already knows how to solve the problem”.[11] Sperry asked the question: “how can the learning with one eye appear with the use of the other?”[12] Sperry cut nerves in the eyes of cats so the left eye was connected to the left hemisphere and the right eye was connected to the right hemisphere; he also cut the corpus callosum. The cats were then taught to distinguish a triangle from a square with the right eye covered.[11] Then the cats were presented the same problem with the left eye covered; the cats had no idea what they had just learned with the right eye and because of this could be taught to distinguish a square from a triangle. Depending on which eye was covered, the cats would either distinguish a square from a triangle or a triangle from a square, demonstrating that the left and right hemispheres learned and remembered two different events. This led Sperry to believe that the left and right hemispheres function separately when not connected by the corpus callosum.

Sperry’s research with “split-brain” cats helped lead to the discovery that cutting the corpus callosum is a very effective treatment for patients who suffer from epilepsy. Initially after the patients recovered from surgery there were no signs that the surgery caused any changes to their behavior or functioning. This observation rendered the question: if the surgery had absolutely no effect on any part of the patients' normal functioning then what is the purpose of the corpus callosum? Was it simply there to keep the two sides of the brain from collapsing, as Karl Lashley jokingly put it? Sperry was asked to develop a series of tests to perform on the “split-brain” patients to determine if the surgery caused changes in the patients' functioning or not.

Working with his graduate student Michael Gazzaniga, Sperry invited several of the “split-brain” patients to volunteer to take part in his study to determine if the surgery affected their functioning. These tests were designed to test the patients' language, vision, and motor skills. When a person views something in the left visual field (that is on the left side of their body), the information travels to the right hemisphere of the brain and vice versa. In the first series of tests, Sperry would present a word to either the left or right visual field for a short period of time. If the word was shown to the right visual field, meaning the left hemisphere would process it, then the patient could report seeing the word. If the word was shown to the left visual field, meaning the right hemisphere would process it, then the patient could not report seeing the word. This led Sperry to believe that only the left side of the brain could articulate speech. However, in a follow-up experiment, Sperry discovered that the right hemisphere does have some language abilities. In this experiment, he had the patients place their left hands in a tray full of objects located under a partition so the patient would not be able to see the objects. Then a word was shown to the patient's left visual field, which was processed by the right side of the brain. This word described one of the objects in the tray, so the patient's left hand picked up the object corresponding to the word. When participants were asked about the word and the object in their hand, they claimed they had not seen the word and had no idea why they were holding the object. The right side of the brain had recognized the word and told the left hand to pick it up, but because the right side of the brain cannot speak and the left side of the brain had not seen the word, the patient could not articulate what they had seen.

In another series of experiments further examining the lateralization of language in the left and right hemispheres, Sperry presented one object to the left visual field and a different object to the right visual field of the “split-brain” patients. The patient’s left hand was put under a partition and then the patient was asked to draw with their left hand what they had been shown. The patients would draw what they had seen in their left visual field, but when asked what they had drawn would describe what had been shown to their right visual field. These tests proved that when the corpus callosum is severed, it breaks the connection between the left and right hemispheres, making them unable to communicate with each other. Not only are they unable to communicate with each other, but also without the corpus callosum connecting them one hemisphere has no idea that the other hemisphere even exists. There was even evidence of this outside the laboratory when some of the patients reported that, “while their left hand was unbuttoning their shirt, the right hand would follow along behind and button it again.”[14] These experiments were beneficial to numerous people in many different ways.

In his words, each hemisphere is:

indeed a conscious system in its own right, perceiving, thinking, remembering, reasoning, willing, and emoting, all at a characteristically human level, and . . . both the left and the right hemisphere may be conscious simultaneously in different, even in mutually conflicting, mental experiences that run along in parallel
— Roger Wolcott Sperry, 1974

This research contributed greatly to understanding the lateralization of brain function. In 1989, Sperry also received the National Medal of Science. Afterwards in 1993, Sperry received the Lifetime Achievement Award from APA.

In addition to his contribution in establishing the lateralized function of the brain, Sperry is noted for his "chemoaffinity hypothesis", which has not only been influential in formation of testable hypotheses in how precise neuronal wiring diagram is established in the brain, but the hypothesis itself has been verified by numerous experiments.

"The cells and fibers of the brain must carry some kind of individual identification tags, presumably cytochemical in nature, by which they are distinguished one from another almost, in many regions, to the level of the single neurons"
— Roger Wolcott Sperry

In the words of a 2009 review article in Science magazine: "He suggested that gradients of such identification tags on retinal neurons and on the target cells in the brain coordinately guide the orderly projection of millions of developing retinal axons. This idea was supported by the identification and genetic analysis of axon guidance molecules, including those that direct development of the vertebrate visual system." This was confirmed in the seventies by Marshall W. Nirenberg's work on chick retinas and later on Drosophila melanogaster larvae.[15]

The experiments conducted by Sperry focused on four major ideas which were also called “turnarounds”: equipotentiality, split brain studies, nerve regeneration and plasticity, and psychology of the consciousness.[16]

Personal life

In 1949, Sperry married Norma Gay Deupree. They had one son, Glenn Michael, and one daughter, Janeth Hope.[17] Sperry was a quiet, thoughtful, and modest man with an insatiable curiosity. He never stopped working, questioning, or learning up until his death in 1994 of ALS or Lou Gehrig's Disease. You could often find Sperry in his office with his feet propped up on his desk scribbling in his notebook or deep in thought. Sperry was an avid paleontologist and displayed his large fossil collection in his home. He was also a very talented sculptor, artist, and ceramicist. He enjoyed going on camping and fishing trips with his wife and children in Baja, California.[11]


• 1931–1935 Amos C. Miller Scholarship, Oberlin College • 1941–1942 National Research Council Fellowship • 1954 Distinguished Alumni Citation, Oberlin College • 1960 Elected National Academy of Sciences • 1963 Elected American Academy of Arts and Sciences • 1969 Howard Crosby Warren Medal, Society of Experimental Psychologists • 1971 Distinguished Scientific Contribution Award, American Psychological Association • 1972 Co-recipient, William Thomson Wakeman Research Award, National Paraplegia Foundation • 1972 California Scientist of the Year Award • 1972 Honorary Doctor of Science Degree, Cambridge University • 1973 Passano Award in Medical Science • 1974 Elected Honorary Member American Neurological Association • 1974 Elected American Philosophical Society • 1975 Co-recipient Claude Bernard Science Journalism Award • 1976 Karl Lashley Award of [8]


  • "
  • "Interhemispheric relationships: the neocortical commissures; syndromes of hemisphere disconnection." (with M.S. Gazzaniga, and J.E. Bogen) In: P. J. Vinken and G.W. Bruyn (Eds.), Handbook Clin. Neurol (Amsterdam: North-Holland Publishing Co.) 4: 273-290 (1969)
  • "Lateral specialization in the surgically separated hemispheres." In: F. Schmitt and F. Worden (Eds.), Third Neurosciences Study Program (Cambridge: MIT Press) 3: 5-19 (1974)
  • "Science and moral priority: merging mind, brain and human values." Convergence, Vol. 4 (Ser. ed. Ruth Anshen) New York: Columbia University Press (1982)


  1. ^
  2. ^
  3. ^
  4. ^
  5. ^
  6. ^
  7. ^ Antonio E. Puente, "Roger Wolcott Sperry (1913–1994)", American Psychologist, 1995
  8. ^ a b
  9. ^ Antonio E. Puente,"Roger Wolcott Sperry (1913–1994)" American Psychologist (November 1995),50(11), pg.940-941
  10. ^
  11. ^ a b c d
  12. ^ a b
  13. ^
  14. ^
  15. ^ "From Neuroblastoma to Homeobox Genes, 1976-1992". The Marshall W. Nirenberg Papers. Profiles in Science, National Library of Medicine. Accessed on 2010-02-16.
  16. ^ Gregor A. Kimble, Michael Wertheimer, Portraits of Pioneers in psychology, vol 4
  17. ^


  • For further information about Sperry's life consult
  • American Psychologist

External links

  • Obituary at The National Academies Press
  • biography
  • Roger W. Sperry - Autobiography
  • The Roger W. Sperry Site
  • PBS page for him
  • , Vol.5, No.1 (21 January 1994)Humankind AdvancingTributes to Sperry in
  • Neuroscience at Wikiversity
  • "The science-values relation: impact of the consciosness relation., by Roger Wolcott Sperry; in Religion, Science, and the Search for Wisdom.
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