Paul György
Born(1893-04-07)April 7, 1893
DiedMarch 1, 1976(1976-03-01) (aged 82)
EducationUniversity of Budapest (M.D., 1915)
Alma materUniversity of Heidelberg (1920-1933)
Cambridge University (1933-1935)
Case Western Reserve University (1935-1944)
Known forDiscovery of biotin, riboflavin, vitamin B6
SpouseMargaret Gyrözy (née John)
AwardsJohn Howland Award (1968)
National Medal of Science (1975)
Scientific career
FieldsPediatrics, Biochemistry, Nutrition
InstitutionsUniversity Hospitals of Cleveland (1933-1935)
Hospital of the University of Pennsylvania (1950-1957)
Philadelphia General Hospital (1957-1953)

Paul György (April 7, 1893 – March 1, 1976) was a Hungarian-born American biochemist, nutritionist, and pediatrician best known for his discovery of three B vitamins: riboflavin, B6, and biotin.[1][2][3] Gyorgy was also well known for his research into the protective factors of human breast milk, particularly for his discoveries of Lactobacillus bifidus growth factor activity in human milk and its anti-staphylococcal properties.[1][3] He was a recipient of the National Medal of Science in 1975 from President Gerald Ford.[4]

Early life and career

Gyorgy was born on April 7, 1893, in Nagyvárad, Hungary to a Jewish family. He was said to be an avid reader and musician as a child.[1] His father was a general practitioner in the community. Influenced by his father's occupation and with his parents' encouragement, Gyorgy began to pursue a career in medicine. He attended the University of Budapest Medical School and graduated with Doctor of Medicine degree in 1915.[1]

In 1920, after the end of World War I, Gyorgy was offered a job at the University of Heidelberg as an assistant to the physician and researcher Ernst Moro. He remained at the University of Heidelberg until 1933, obtaining full professorship in 1927 at the age of 34 years. It was at the University of Heidelberg that Gyorgy first discovered and isolated riboflavin along with his colleague Th. Wagner-Jauregg and the Nobel-winning chemist Richard Kuhn.[1] Gyorgy remained at the University of Heidelberg until 1933, when the political unrest in Germany spurred his move to the Nutrition Laboratory at the University of Cambridge in England. He stayed as a researcher in there until 1935, during which time he discovered vitamin B6.[3]

In 1935, Gyorgy went to the United States as a visiting assistant professor of pediatrics at Case Western Reserve University. Two years later he was appointed as an associate professor at the university as well as an associate pediatrician at two hospitals within the University Hospitals of Cleveland system. He isolated biotin in 1940 while at Case Western Reserve University.[3]

In 1944, Gyorgy moved to the University of Pennsylvania School of Medicine, this time as an Associate Research Professor of Pediatrics. His research at this time involved looking at the protective factors found in human breast milk. He was promoted to Professor of Pediatrics in 1946, later becoming a Professor Emeritus in 1963. From 1950 to 1957, he was also Pediatrician-in-Chief at the Hospital of the University of Pennsylvania and later on, Chief of Pediatrics at Philadelphia General Hospital from 1957 to 1963.[3]

Scientific research

Gyorgy was responsible for the discovery of three B vitamins, work he conducted with others during his time at Heidelberg, Cambridge, and Cleveland. Later in his career, Gyorgy investigated the protective factors found in human breast milk at the University of Pennsylvania.

Discovery of riboflavin

By 1927 a series of experiments, performed in part by Elmer McCollum and others, had shown that water-soluble vitamin B was primarily made of two parts: the anti-neuritic factor B1 (now known as thiamine) and the more heat-stable factor B2.[5] By 1932 Gyorgy had found that the heat-stable B2 was not in fact a single substance, but actually a complex made up of two factors: the growth-promoting factor (later found to be riboflavin) and the anti-pellagra factor (later found to be niacin (vitamin B3)).[6] Gyorgy, in collaboration with chemist Richard Kuhn and physician Th. Wagner-Jauregg at the University of Heidelberg, had noticed that rats kept on a B2-free diet were unable to gain weight. Isolation of concentrated B2 from yeast revealed the presence of a bright yellow-green fluorescent product that when fed to the rat, restored normal growth. The amount of growth restored was directly proportional to the intensity of the fluorescent product. The bright yellow substance had been previously found in milk by scientists Warburg and Christian, who had described the it as 'yellow oxidation ferment' but were unable to discover its function. Gyorgy, Kuhn, and Warner-Jauregg suggested the name 'flavin' for their yellow pigments and proposed that they were likely the same as the yellow pigments seen by Warberg and Christian.[7]

By 1933, the Heidelberg team were the first to isolate crystalline flavin from milk and accordingly, termed the substance lactoflavin. They, along with other teams, went on to isolate similar flavins from many other sources such as egg white (ovoflavin) and liver (heptoflavin). All these compounds were found to be chemically identical and in 1937, the name riboflavin was formally adopted by the Council of Pharmacy and Chemistry of the American Medical Association.[5]

Discovery of B6

During his experiments with riboflavin, Gyorgy noticed that rats already on a thiamine-only diet developed pellagra-like symptoms, even when given pure riboflavin. The symptoms were only relieved when rats were given supplements derived from a flavin-free extract of bakers' yeast. In contrast, rats given this extract but no riboflavin failed to exhibit pellagra-like symptoms but were unable to gain weight until riboflavin was added back into the diet. These results confirmed the presence of an 'anti-pellagra' factor that was biologically distinct from the newly discovered riboflavin.[8]

In 1934, Gyorgy named this new anti-pellagra factor B6 in order to distinguish it from other B vitamins and set about isolating and characterizing it during his time at the University of Cambridge. In 1936, Gyorgy and his colleague, Thomas William Birch, were successful in isolating crystalline B6 from fish and wheat germ.[9][10]

Discovery of biotin

By 1927, scientists such as Margarete Boas and Helen Parsons had performed experiments demonstrating the symptoms associated with egg-white injury.[11][12] They had found that rats fed large amounts of egg-white as their only protein source exhibited neurological dysfunction, dermatitis, and eventually, death. Gyorgy began investigating the factor responsible for egg-white injury in 1933 and in 1939, was successful identifying what he called vitamin H.[13][14] Further chemical characterization of vitamin H revealed that it was water-soluble and present in high amounts in the liver.[15][16] By this time, multiple groups had independently isolated the same compound under different names. In 1936, Kögl and Tönnis had isolated what they called biotin from egg yolk and in 1939, West had isolated what he called co-enzyme R.[17] By 1940, it was recognized that all three compounds were identical and were collectively given the name biotin.[18] Gyorgy continued his work on biotin and in 1941 published a paper demonstrating that egg-white injury was caused by the binding of biotin by avidin.[19][20]

Protective factors in breast milk

In 1950, Gyorgy began investigating the microbial properties in human breast milk. He began by comparing the intestinal flora of normal breast-fed infants to those who were fed cow's milk formulas.[21] He found that the breast-fed infants had a prevalence of a certain variant of Lactobacillus bifidus, a bacterium considered to be an essential part of normal human gut flora. Further testing revealed the presence of factors in human breast milk that acted as essential growth promoting factors to the L. bifidus variant.[22][23]

In 1962, Gyorgy also discovered anti-staphylococcus properties of human breast milk. He injected mice with different doses of virulent Staphylococcus aureus and found that those given human breast milk obtained protection from infection, resulting in a higher survival rate than those that were given only cow's milk.[24]

Personal life

Gyorgy married Margaret John on October 23, 1920, in Weimar, Germany. The couple had three sons: Hans, who became an organic chemist, Michael, who became a physicist, and Tilbert, a surgeon. Gyorgy enjoyed classical music and was also an avid painter and gardener.[3]

Awards and honors

Gyorgy received the 1975 National Medal of Science from President Gerald Ford for his "discovery of three vitamins and related research that have greatly improved human nutrition".[4] Gyorgy had already died by the time of the 1976 award ceremony and his medal was accepted by his wife, Margaret John.[1] Other awards included:[1][3]

Later years and death

Gyorgy's later life revolved around his work in Southeast Asia, where he was involved in conducting nutritional field studies aimed at improving nutrition, particularly in Thailand and Indonesia.[3] During this time, he was an organizer of the Protein Advisory Group of the World Health Organization and UNICEF, eventually becoming President of the group from 1960 to 1964.[1] Gyorgy died on March 1, 1976, of pneumonia at Morristown Memorial Hospital in Morristown, New Jersey, at the age of 82.[2]


  1. ^ a b c d e f g h International Society for Research in Human Milk and Lactation. "Paul György". ISRHML. Archived from the original on 2017-12-19. Retrieved 2017-11-19.
  2. ^ a b "PAUL GYORGY 82, NUTRITIONIST DIES". The New York Times. 1976-03-11. ISSN 0362-4331. Retrieved 2017-11-09.
  3. ^ a b c d e f g h Barness, L.A.; Tomarelli, R. M. (1979). "Paul György (1893-1976): A Biographical Sketch". Journal of Nutrition. 109 (1): 19–23. doi:10.1093/jn/109.1.17. PMID 372504.
  4. ^ a b "The President's National Medal of Science: Recipient Details | NSF - National Science Foundation".
  5. ^ a b Northrop-Clewes, Christine A.; Thurnham, David I. (2012). "The Discovery and Characterization of Riboflavin". Annals of Nutrition and Metabolism. 61 (3): 224–30. doi:10.1159/000343111. ISSN 0250-6807. PMID 23183293. S2CID 7331172.
  6. ^ György, Paul (1935). "Investigations on the vitamin B2 complex". Biochemical Journal. 29 (3): 741–759. doi:10.1042/bj0290741. ISSN 0264-6021. PMC 1266542. PMID 16745720.
  7. ^ Swaminathan, M. (1942). "Riboflavin and Its Role in Nutrition". The Indian Medical Gazette. 77 (11): 650–656. ISSN 0019-5863. PMC 5169433. PMID 29012685.
  8. ^ György, Paul; Eckardt, Robert Edward (1940-07-04). "Further investigations on vitamin B6 and related factors of the vitamin B2 complex in rats. Parts I and II". Biochemical Journal. 34 (8–9): 1143–1154. doi:10.1042/bj0341143. ISSN 0264-6021. PMC 1265394. PMID 16747297.
  9. ^ Birch, Thomas William; György, Paul (1936). "A study of the chemical nature of vitamin B6 and methods for its preparation in a concentrated state". Biochemical Journal. 30 (2): 304–315. doi:10.1042/bj0300304. ISSN 0264-6021. PMC 1263399. PMID 16746020.
  10. ^ György, Paul (1938). "Crystalline Vitamin B6". Journal of the American Chemical Society. 60 (4): 983–984. doi:10.1021/ja01271a505.
  11. ^ Boas, Margaret Averil (1927). "The Effect of Desiccation upon the Nutritive Properties of Egg-white". Biochemical Journal. 21 (3): 712–724.1. doi:10.1042/bj0210712. ISSN 0264-6021. PMC 1251968. PMID 16743887.
  12. ^ Parsons, Helen T.; Kelly, Eunice (1980-11-01). "The Character of the Dermatitis-Producing Factor in Dietary Egg White as Shown by Certain Chemical Treatments". Nutrition Reviews. 38 (11): 377–379. doi:10.1111/j.1753-4887.1980.tb05948.x. ISSN 0029-6643. PMID 7005763. S2CID 86107167.
  13. ^ György, Paul (1939-12-01). "The Curative Factor (vitamin H) for Egg White Injury, with Particular Reference to Its Presence in Different Foodstuffs and in Yeast". Journal of Biological Chemistry. 131 (2): 733–744. doi:10.1016/S0021-9258(18)73468-6. ISSN 0021-9258.
  14. ^ György, Paul; Kuhn, Richard; Lederer, Edgar (1939-12-01). "Attempts to Isolate the Factor (vitamin H) Curative of Egg White Injury". Journal of Biological Chemistry. 131 (2): 745–759. doi:10.1016/S0021-9258(18)73469-8. ISSN 0021-9258.
  15. ^ Birch, T. W.; György, Paul (1939-12-01). "Physicochemical Properties of the Factor (vitamin H) Curative of Egg White Injury". Journal of Biological Chemistry. 131 (2): 761–766. doi:10.1016/S0021-9258(18)73470-4. ISSN 0021-9258.
  16. ^ Vigneaud, Vincent du; Hofmann, Klaus; Melville, Donald B.; György, Paul (1941-08-01). "Isolation of Biotin (vitamin H) from Liver". Journal of Biological Chemistry. 140 (2): 643–651. doi:10.1016/S0021-9258(18)51355-7. ISSN 0021-9258.
  17. ^ West, P. M.; Wilson, P. W. (1939-06-30). "The Relation of "coenzyme R" to Biotin". Science. 89 (2322): 607–608. Bibcode:1939Sci....89..607W. doi:10.1126/science.89.2322.607. ISSN 0036-8075. PMID 17751623. S2CID 30138816.
  18. ^ György, Paul; Rose, Catharine S.; Hofmann, Klaus; Melville, Donald B.; Vigneaud, Vincent Du (1940-12-27). "A Further Note on the Identity of Vitamin H with Biotin". Science. 92 (2400): 609. Bibcode:1940Sci....92..609G. doi:10.1126/science.92.2400.609. ISSN 0036-8075. PMID 17795447.
  19. ^ György, Paul; Rose, Catharine S.; Eakin, Robert E.; Snell, Esmond E.; Williams, Roger J. (1941). "Egg-White Injury as the Result of Nonabsorption or Inactivation of Biotin". Science. 93 (2420): 477–478. Bibcode:1941Sci....93..477G. doi:10.1126/science.93.2420.477. JSTOR 1668938. PMID 17757050.
  20. ^ Gyorgy, P.; Rose, C. S. (1943). "The Liberation of Biotin from the Avidin-Biotin Complex (AB)". Experimental Biology and Medicine. 53 (1): 55–57. doi:10.3181/00379727-53-14183. S2CID 84419614.
  21. ^ György, Paul; Norris, Robert F.; Rose, Catharine S. (1954-01-01). "Bifidus factor. I. A variant of Lactobacillus bifidus requiring a special growth factor". Archives of Biochemistry and Biophysics. 48 (1): 193–201. doi:10.1016/0003-9861(54)90323-9. PMID 13125589.
  22. ^ Gauhe, Adeline; György, Paul; Hoover, John R. E.; Kuhn, Richard; Rose, Catharine S.; Ruelius, Hans W.; Zilliken, Friedrich (1954-01-01). "Bifidus factor. IV. Preparations obtained from human milk". Archives of Biochemistry and Biophysics. 48 (1): 214–224. doi:10.1016/0003-9861(54)90326-4. PMID 13125592.
  23. ^ György, Paul; Rose, Catharine S. (1955). "Further observations on the metabolic requirements of Lactobacillus bifidus var. Pennsylvanicus". Journal of Bacteriology. 69 (5): 483–490. doi:10.1128/JB.69.5.483-490.1955. ISSN 0021-9193. PMC 357573. PMID 14381364.
  24. ^ Gyorgy, Paul; Dhanamitta, Sakorn; Steers, Edward (1962). "Protective Effects of Human Milk in Experimental Staphylococcus Infection". Science. 137 (3527): 338–340. Bibcode:1962Sci...137..338G. doi:10.1126/science.137.3527.338. JSTOR 1708962. PMID 13903311. S2CID 11118555.