Difference between revisions of "Timeline of bacteriology"
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− | This is a '''timeline of bacteriology''', attempting to describe important events in the development of the field. | + | This is a '''timeline of bacteriology''', attempting to describe important events in the development of the field. For the treatment of bacterial diseases, visit {{w|Timeline of antibiotics}}. |
==Big picture== | ==Big picture== |
Revision as of 21:25, 14 June 2018
This is a timeline of bacteriology, attempting to describe important events in the development of the field. For the treatment of bacterial diseases, visit Timeline of antibiotics.
Contents
Big picture
Time period | Development summary |
---|---|
17th century | Experimental explorations with microorganisms is already conducted in this century.[1] |
18th century | Botanists and zoologists try to structure and classify the world of the invisible living organisms.[1] |
1854–1920 | This period is known as the "golden age of microbiology", in which standardized microbiological techniques are developed and most of the disease-causing bacteria are discovered. Louis Pasteur and Robert Koch stand out as the great scientists in the field.[2] German physician Robert Koch introduces the science of microorganisms to the medical field, identifying bacteria as the cause of infectious diseases and process of fermentation in diseases. French Scientist Louis Pasteur develops techniques to produce vaccines. |
1940s | The genetics of bacteriophages begin to be studied vigorously, after the development of techniques for the study of bacteriophage infection in single bacteria.[3] |
1990s | The first bacterium genome is sequenced.[4] |
Full timeline
Year | Event type | Details | Geographical location |
---|---|---|---|
2 billion BC | A bacterium becomes symbiotic with the cell from which animals and plants later develop. Chromosomes from this bacterium’s mitochondria would later carry 37 genes in the human body.[5] | ||
220 million BC | Bacteria and single-celled animals and plants from this period become encased in tree resin on the northern edge of the Tethys Ocean. Scientists in 2006 study the organisms in amber of this time from a town in the Italian Dolomites. Ciliates and amoeba in the amber appear identical to modern examples.[5] | ||
1590 | Scientific development | Dutch spectacle-maker Zacharias Janssen and his brother Hans Janssen produce the operational compound microscope.[6] | |
1676 | Scientific development | Dutch merchant Antony Van Leeuwenhoek observes microorganisms using a single lens microscope designed by him and names them animalcules.[7] Van Leeuwenhoek is considered the first to discover microorganisms.[8] | |
1749 | Scientific development | English biologist John Needham indicates that bacteria and other microorganisms arose spontaneously from meat.[6][9][10][11] | United Kingdom |
1762 | Scientific development | Austrian medical doctor Marcus Antonius Von Plenciz in Vienna publishes a germ theory of infectious diseases and reports that each disease is caused by a separate organism.[6][12][2][13] | Austria |
1828 | Scientific development | German naturalist Christian Gottfried Ehrenberg introduces new technical terms "bakterium/bakteria", replacing the vaguer "germ" and "miasma."[14][7][15] | |
1835 | Scientific development | Christian Gottfried Ehrenberg coins the term Bacillus to contain rod-shaped bacteria.[16][17][18] | |
1839 | Scientific development | German physiologist Theodor Schwann demonstrates the cellular basis of the body, asserting that all organs and tissues are composed of a multitude of structural units called cells.[19][20][21] | |
1840 | Scientific development | German pathologist Friedrich Gustav Jakob Henle offers his theory of contagion by arguing that the "material of contagions is endowed with a life of its own, which is, in relation to the diseased body, a parasitic organism.[22] | |
1844 | Scientific development | Italian entomologist Agostino Bassi asserts that microorganisms cause human disease.[8] | |
1847 | Publication | Cranston R. Low and T.C. Dodds publish the illustrated Atlas of Bacteriology.[14] | |
1857 | Scientific development | German scientific instrument maker Carl Zeiss launches its first Zeiss compound microscope.[23] | Germany |
1858 | Publication | French biologist Louis Pasteur publishes Memoire sur la fermentation appelée lactique (Memoir on Lactic Fermentation) which is considered a foundation stone of the cell theory, microbiology, and bacteriology.[24][25] | France |
1865 | Scientific development | British surgeon Joseph Lister develops antiseptic surgery, which greatly increases survival rates.[26] | |
c.1868 | Scientific development | German botanist Ferdinand Cohn starts studying bacteria. From his accurate studies of their morphology, or bodily form, Cohn is among the first to attempt to arrange the different varieties of bacteria into genera and species on a systematic basis.[27] Cohn studies on algae and photosynthetic bacteria would lead him to describe several bacteria including Bacillus and Beggiatoa. The field of bacteriology is considered by many to have been founded by Ferdinand Cohn.[7] | |
1872 | Scientific development | German botanist Joseph Schroeter grows pigmented bacterial colonies on potato slices incubated in a moist environment.[28][29][30][31] | |
1872 | Publication | Ferdinand Cohn publishes Untersuchungen ueber Bacterien (Investigations on Bacteria).[14] | Germany |
1873 | Scientific development | Norwegian physician Gerhard Armauer Hansen identifies the acidfast bacillus (AFB) Mycobacterium leprae, the first bacterium to be implicated as a cause of a human infection.[31][32][33][34] | |
1876 | Scientific development | Louis Pasteur discards the theory of spontaneous generation and investigates the principles of the process later called pasteurization.[6] | France |
1876 | Scientific development | German physician and microbiologist Robert Koch in Berlin isolates the anthrax bacillus, and becomes the first to show a specific organism as the cause of a disease.[6][35][36][37] | Germany |
1877 | Publication | English microbiologist Edgar Crookshank publishes Manual of Bacteriology.[14] | United Kingdom |
1877 | Scientific development | Louis Pasteur notes that some bacteria produce substances that kill other bacteria, setting the basis of antibiotics.[38] | France |
1878 | Scientific development | Robert Koch observes bacteria bearing a close resemblance to staphylococci.[39] | |
1878 | Scientific development | British pioneer of antiseptic surgery Joseph Lister becomes the first person to obtain a pure culture of a bacterium (Streptococcus lactis) in a liquid medium. Lister isolates a pure culture from sour milk and names it Bacterium lactis.[40][41][42][43] | |
1878 | Scientific development | American botanist Thomas Jonathan Burrill, professor at the University of Illinois, describes the causative agent as a bacterium, demonstrating for the first time a bacterial disease of plants.[31][44][45][46] | United States |
1879 | Scientific development | German physician Albert Ludwig Sigesmund Neisser identifies what would later be called Neisseria gonorrhoeae, the pathogen that causes gonorrhea.[31][47][48][49] | |
1880 | Scientific development | Louis Pasteur manages to isolate the bacterium responsible for chicken cholera and grows it in pure culture. [39][50][38] | France |
1880 | Publication | George M. Sternberg M.D. translation of Les bactéries becomes the first general bacteriology book in English.[51] | |
1881 | Scientific development | German Jewish physician Paul Ehrlich introduces the dye methylene blue into bacteriology.[52] | |
1881 | Scientific development | British surgeon Alexander Ogston, Professor at the University of Aberdeen, carries out the first detailed studies on staphylococci.[6] After injecting the bacteria into animals and producing experimental infections in the laboratory, Ogston links staphylococcus to the serious infections then called "hospital sepsis".[53][54] | United Kingdom |
1882 | Scientific development | German pathologist and microbiologist Carl Friedländer discovers the microorganism that he believes causes bacterial pneumonia. The organism would later be named Bacillus friedlanderi.[55][56][57] | |
1882 | Scientific development | Robert Koch discovers Mycobacterium tuberculosis as the cause of tuberculosis.[35] | |
1883 | Publication | Belfield publishes the first original general bacteriology book in English, On the Relations of Micro-organisms to Disease.[51] | |
1883 | Scientific development | Robert Koch leads an expedition to Egypt and India, and discovers bacterium Vibrio cholerae as the cause of cholera.[35] | Egypt, India |
1883 | Scientific development | French biochemists Ulysse Gayon and Gabriel Dupetit isolate in pure culture two strains of denitrifying bacteria, and show that individual organic compounds, such as sugars and alcohols, can replace complex organics and serve as reductants for nitrate, as well as serving as carbon sources.[31] | |
1884 | Scientific development | German Jewish internist Arthur Nicolaier discovers the causal agent of tetanus Clostridium tetani.[6][58][59][60] | Germany |
1884 | Scientific development | Danish bacteriologist Hans Christian Gram discovers a differential stain used the identification of bacteria.[6] | |
1884 | Scientific development | French microbiologist Charles Chamberland develops an unglazed porcelain filter that retains bacteria.[31] | |
1884 | Scientific development | Russian zoologist Élie Metchnikoff shows how amoeboid cells in the interstitial fluid and blood engulf organisms or microscopical foreign particles, so destroying the ingested bacteria in the phenomenon of phagocytosis, a term coined by him. Metchnikoff would propose a theory of cellular immunity.[31][61][62][63] | |
1885 | Scientific development | German-Austrian pediatrician Theodor Escherich identifies a bacterium, a natural inhabitant of the human gut, and names it Bacterium coli. Escherich shows that certain strains are responsible for infant diarrhea and gastroenteritis.[64][65][66] | |
1886 | Scientific development | German agricultural chemist Hermann Hellriegel and Hermann Wilfarth establish the relationship between legumes and nitrogen fixing bacteria.[6] | |
1886 | Scientific development | F. Frankel isolates Pneumococcus bacteria.[6][67] | |
1886 | Publication | E.M. Crookshank publishes An Introduction to Practical Bacteriology. Based Upon the Methods of Koch.[14] | United States |
1886 | Scientific development | American pathologist Theobald Smith isolates the gram-negative bacillus responsible for enteric typhoid.[14] | United States |
1887 | Publication | Loeffler publishes Geschichte zur Bakteriologie (History of Bacteriology).[14] | Germany |
1888 | Scientific development | The first work on nitrogen fixation by the root nodule bacteria is performed by Dutch microbiologist Martinus Beijerinck, who discovers bacteria living inside small lumps or nodules on the roots of Vicia and Lathyrus (yellow pea) plants.[6][68][69][70] | |
1889 | Organization | The Society of American Bacteriologists is founded.[14] | United States |
1890 | Scientific development | Ukrainian microbiologist Sergei Winogradsky first demonstrates N2 fixation by free living soil bacteria.[6] | |
1891 | Scientific development | Poland-born German botanist Walter Migula discoveres the gram-negative, flagellated-motile rod-like microbe, bacillus Pseudomonas sp, later renamed Pseudomonas pyocyaneas (aeruginosa), a dangerous "hospital pathogen.[14] | |
1891 | Publication | J. Buchanan publishes An Encyclopedia of the Practice of Medicine Based on Bacteriology.[14] | |
1892 | Scientific development | American bacteriologists William H. Welch and George Nuttall identify and isolate Clostridium perfringens, the organism responsible for causing gangrene.[31][71][72][73] | |
1892 | Publication | Alexander C. Abbott publishes The Principles of Bacteriology: A Practical Manual for Students and Physicians.[14] | United States |
1893 | Publication | British chemist Percy F. Frankland publishes Bacteriology in its Relations to Chemical Science.[14] | United Kingdom |
1893 | Publication | Volume 1 appears of Journal of Pathology and Bacteriology, with both Rudolf Virchow and Élie Metchnikoff contributing to the opening issues.[14] | |
1893 | Publication | German bacteriologist Samuel Leopold Schenk in Vienna publishes Grundrisse der Bakteriologie fur Aertze und Studierende (Elements of Bacteriology for Practitioners and Students).[14] | Austria |
1893 | Publication | Russian bacteriologist Georgy Gabrichevsky in Saint Petersburg publishes Rukovodstvok klinicheskoj bacteriologii (Guide to Clinical Bacteriology for Doctors and Students).[14] | Russia |
1894 | Scientific development | Martinus Beijerinck isolates the first sulfate-reducing bacterium, Spirillum desulfuricans (Desulfovibrio desulfuricans). Beijerinck shows that this bacterium extracts energy by metabolizing sulfur compounds.[74][75][31] | |
1894 | Publication | American bacteriologist Frederick George Novy publishes Directions for Laboratory Work in Bacteriology.[14] | |
1894 | Scientific development | Swiss bacteriologist Alexandre Yersin discovers Pasteurella pestis.[6] | |
1894 | Scientific development | Japanese physician Kitasato Shibasaburō discovers the plague bacillus Yersinia pestis.[6][76][77][78] | Hong Kong |
1894 | Scientific development | German bacteriologist Richard Friedrich Johannes Pfeiffer discovers that when cholera bacteria are injected into the peritoneum of a guinea pig immunized against the infection, the pig rapidly dies.[31][79][80][81] | |
1895 | Publication | E.V. Freudenreich publishes Dairy Bacteriology: a Short Manual.[14] | |
1895 | Scientific development | Sergei Winogradsky isolates Clostridum pasteurianum, the first free-living nitrogen-fixing organism.[31][82][83][84] | |
1896 | Scientific development | Austrian scientist Max von Gruber and H. Durham first describe the agglutination of bacteria by their related immune sera.[31][85][86][87] | |
1898 | Scientific development | Japanese bacteriologist Shiga Kiyoshi discovers dysentery bacillus Shigella (named after him).[6][88][89][90] | Japan |
1900 | Scientific development | Shiga Kiyoshi develops a dysentery antiserum.[88] | Japan |
1904 | Scientific development | Dutch microbiologist Martinus Beijerinck obtains the first pure culture of sulfur-oxidizing bacterium, Thiobacillus denitrificans. Under anaerobic conditions it uses carbon dioxide as a source of carbon.[31] | |
1905 | Scientific development | Austrian bacteriologist Franz Schardinger isolates aerobic bacilli which produce acetone, ethanol, and acetic acid. These are important industrial chemicals.[31] | |
1905 | Scientific development | German zoologist Fritz Schaudinn and German germatologist Erich Hoffmann identify and describe the bacterium Treponema pallidum in patients with acute syphilis.[31][91][92][93] | |
1905 | Scientific development | Japanese biologist Shigetane Ishiwata discovers that the cause of a disease outbreak in silkworms is a new species of bacteria. Ishiwata names it Bacillus sotto (later called Bacillus thuringiensis).[31] | |
1906 | Scientific development | N. L. Sohngen manages to enrich two distinct acetate utilizing bacteria, finding that formate and hydrogen, plus carbon dioxide, could act as precursors for methane.[31][94][95][96] | |
1907 | Publication | Edward B. Voorhees and Jacob G. Lipman publish A Review of Investigations in Soil Bacteriology.[14] | United States |
1907 | Scientific development | Erwin Smith and C.O. Townsend discover that the Gram-negative soil bacterium Agrobacterium tumefaciens, a member of the eubacterial family Rhizobiaceae, is the organism responsible for the elicitation of crown gall tumors in plants.[31][97][98][99] | |
1908 | Publication | Samuel Cate Prescott and Charles Winslow publish Elements of Water Bacteriology.[14] | United States |
1908 | Publication | Edwin O. Jordan publishes A Text-Book of General Bacteriology.[14] | United States |
1909 | Publication | Professor Dr. A. Dieudonne and C.F. Bolduan in New York publish Bacterial Food Poisoning. A Concise Exposition of the Etiology, Bacteriology, Pathology, Symptomatology, Prophylaxis and Treatment of So-Called Ptomaine Poisoning.[14] | United States |
1909 | Scientific development | American pathologist Howard Taylor Ricketts describes the bacterium that causes Rocky Mountain spotted fever in humans. This organism, Rickettsia, is transmitted by ticks.[31][100][101] | |
1909 | Publication | E.R. Stitt publishes Practical Bacteriology, Blood Work and Animal Parasitology. The book includes bacteriological keys and clinical notes.[14] | United States |
1909 | Scientific development | Danish chemist Sigurd Orla-Jensen proposes that physiological characteristics of bacteria are of primary importance in their classification. Orla-Jensen's ideas, first published in the same year, are based on the assumption that the first organisms on Earth must have developed in the dark in an environment devoid of organic matter, therefore independent of the presence of other life forms. The only organisms known today to be capable of that are chemosynthetic bacteria.[31][102][103][104] | |
1910 | Publication | Emily Stoney publishes Bacteriological and Surgical Technique for Nurses.[14] | United States |
1910 | Publication | P. Hanson Hiss Jr. and Hans Zinsser publish The Textbook of Bacteriology.[14] | |
1910 | Scientific development | American plant Erwin Frink Smith publishes the earliest description of the pathogenic relationship of Corynebacterium michiganense to tomato.[6][105][106][107] Smith is considered to have played a major role in demonstrating that bacteria could cause plant disease.[108][109] | |
1912 | Publication | Albert Schneider in Philadelphia publishes Pharmaceutical Bacteriology with Special Reference to Disinfection and Sterilization.[14] | |
1912 | Publication | John Wright in Bristol publishes Public Health Chemistry and Bacteriology. A Handbook.[14] | United Kingdom |
1912 | Publication | Clemesha William Wesley publishes The Bacteriology of Surface Waters in the Tropics.[14] | |
1915 | Virus discovery | English bacteriologist Frederick Twort discovers the micrococcus phage and becomes the first to describe bacteriophages (viruses that infect bacteria).[110][111][112][113] | |
1916 | Publication | The Journal of Bacteriology is established.[14] | United States |
1920 | Publication | The Society of American Bacteriologists committee issues its final report on the characterization and classification of bacterial types.[31][114] | United States |
1923 | Publication | The Bergey's Manual of Determinative Bacteriology is published. It is written to provide a modern identification key for bacteria but little of it is based on direct experience of the organisms.[41] | |
1926 | Scientific development | American bacteriologist Thomas Milton Rivers, director of the Rockefeller Hospital, distinguishes between bacteria and viruses, establishing virology as a separate area of study.[31] Rivers announces the theory that viruses could not reproduce outside cells[115], and states that a virus needs a living tissue for reproduction.[116] | United States |
1926 | Scientific development | Team of scientists headed by Dr. Everitt Murray isolates from rabbits a bacterium that is responsible for listeriosis in humans. Named Bacterium monocytogenes in reference to the mononuclear leucocytosis observed in the affected animals, it would be later renamed Listeria monocytogenes in honor of Dr. Joseph Lister.[31][117][118][119] | |
1928 | Scientific development | Scottish bacteriologist Alexander Fleming discovers antibiotic penicillin.[6][120][121][122] | United Kingdom |
1928 | Scientific development | English bacteriologist Frederick Griffith discovers transformation in bacteria. Griffith finds that extracts from killed encapsulated streptococci could change the living, harmless bacteria to the disease-producing virulent type. [6][123][124][125] | |
1928 | Scientific development | Frederick Griffith, in his experiments with the bacterium Streptococcus pneumoniae, the species that causes a severe form of pneumonia in mammals, discovers transformation in bacteria and establishes the foundation of molecular genetics.[31][126][127][128] | |
1931 | Organization | The Society of Agricultural Bacteriologists is founded.[129] | United Kingdom |
1931 | Scientific development | Dutch-American microbiologist Cornelius Bernardus van Niel shows that photosynthetic bacteria use reduces compounds as electron donors without producing oxygen.[31][130][131][132] | |
1934 | Scientific development | American microbiologist Alice Catherine Evans accomplishes the first typing of a strain of bacteria with bacteriophage.[31] | |
1937 | Scientific development | Hungarian physicist Ladislaus Laszlo Marton publishes the first electron micrographs of bacteria.[31] | |
1943 | Scientific development | Italian microbiologist Salvador Luria and German–American biophysicist Max Delbrück provides convincing evidence of mutations in bacteria.[133][134][135][136] | |
1944 | Scientific development | Oswald Avery, Colin Munro MacLeod and Maclyn McCarty show the significance of DNA as hereditary material by studies of transformation in bacteria.[6][137][138][139] | |
1945 (February 16) | Organization | The Microbiology Society is formally inaugurated at a meeting in London. Sir Alexander Fleming is elected as the first President.[129] | United Kingdom |
1946 | Scientific development | American molecular biologist Joshua Lederberg and American geneticist Edward Tatum discover bacterial conjugation.[3][6][140][141][142] | |
1947 | Scientific development | American molecular biologist Joshua Lederberg shows that bacteria can exchange and recombine genes.[133] | |
1951 | Publication | The International Journal of Systematic and Evolutionary Microbiology is established.[143] | |
1952 | Scientific development | American biologists Norton Zinder and Joshua Lederberg discover the transduction in bacteria.[6] | |
1971 | Scientific development | B. Pierson and K. Castenholz discover the green non-sulphus bacteria Chloroflexus.[6][144][145] | |
1977 | Scientific development | American microbiologist Carl Woese recognizes that archaea have a separate line of evolutionary descent from bacteria.[146] | |
1977 | Scientific development | Health officials in the United States discover that some germs within one family of bacteria, Enterobacteriaceae, could produce an enzyme capable of breaking down common antibiotics.[147] | United States |
1995 | Scientific development | Haemophilus Influenzae becomes the first bacterium genome to be sequenced.[4] | |
2000 | Scientific development | The first genome of a plant pathogen, the bacterium Xylella fastidiosa, is completed.[148] | Brazil |
2018 | Scientific development | Research paper shows evidence that hand dryers generate invisible “bacterial highways” inside buildings.[149][150] | |
2018 | Scientific development | Researchers from the University of Quebec’s National Institute of Scientific Research discover an oil-hungry bacterium that could be ideal for oil spill cleanup.[151] | Canada |
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How the timeline was built
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See also
External links
References
- ↑ 1.0 1.1 Kreuder‐Sonnen, Katharina. "History of Bacteriology".
- ↑ 2.0 2.1 Vasanthakumari, R. Textbook of Microbiology.
- ↑ 3.0 3.1 Ravin, Arnold W. The Evolution of Genetics.
- ↑ 4.0 4.1 "The History of DNA Timeline". dna-worldwide.com. Retrieved 30 April 2018.
- ↑ 5.0 5.1 "Timeline of Microbiology". timelines.ws. Retrieved 14 February 2018.
- ↑ 6.00 6.01 6.02 6.03 6.04 6.05 6.06 6.07 6.08 6.09 6.10 6.11 6.12 6.13 6.14 6.15 6.16 6.17 6.18 6.19 6.20 6.21 "History of Virology and Bacteriology". biologydiscussion.com. Retrieved 14 February 2018.
- ↑ 7.0 7.1 7.2 Saini, B.L. Introduction to Biotechnology. Retrieved 14 February 2018.
- ↑ 8.0 8.1 Arp, Robert. 1001 Ideas That Changed the Way We Think.
- ↑ BAGYARAJ, D. J.; RANGASWAMI, G. AGRICULTURAL MICROBIOLOGY.
- ↑ Sheehan, Jonathan; Wahrman, Dror. Invisible Hands: Self-Organization and the Eighteenth Century.
- ↑ A system of bactriology in relation to medicine, Volume 1.
- ↑ Murchie, Guy. The Seven Mysteries of Life: An Exploration in Science & Philosophy.
- ↑ Chia, Mantak; Dao, Johnathon. The Eight Immortal Healers: Taoist Wisdom for Radiant Health.
- ↑ 14.00 14.01 14.02 14.03 14.04 14.05 14.06 14.07 14.08 14.09 14.10 14.11 14.12 14.13 14.14 14.15 14.16 14.17 14.18 14.19 14.20 14.21 14.22 14.23 14.24 14.25 14.26 14.27 Dyer, PhD. "Bacteriology, c.1810-c.1917: Chronology of a Victorian Medical Advance". victorianweb.org. Retrieved 11 April 2018.
- ↑ Breverton, Terry. Breverton's Encyclopedia of Inventions: A Compendium of Technological Leaps, Groundbreaking Discoveries and Scientific Breakthroughs that Changed the World.
- ↑ Biofilms in the Food and Beverage Industries (P M Fratamico, B A Annous, N W Guenther ed.).
- ↑ Breverton, Terry. Breverton's Encyclopedia of Inventions: A Compendium of Technological Leaps, Groundbreaking Discoveries and Scientific Breakthroughs that Changed the World.
- ↑ Islam, M. Tofazzal; Rahman, Mahfuz; Pandey, Piyush; Jha, Chaitanya Kumar; Aeron, Abhinav. Bacilli and Agrobiotechnology.
- ↑ Ljunggren, Bengt; Bruyn, G. W. The Nobel Prize in Medicine and the Karolinska Institute: The Story of Axel Key and Alfred Nobel.
- ↑ Biotechnology and Genetic Engineering. Facts On File, Incorporated.
- ↑ Kumar, Rajesh. Biology.
- ↑ MINDELL, David P. The Evolving World.
- ↑ "Carl Friedrich Zeiss". micro.magnet.fsu.edu. Retrieved 10 April 2018.
- ↑ Smith, Kendall A. "Louis Pasteur, the Father of Immunology?". PMC 3342039. doi:10.3389/fimmu.2012.00068.
- ↑ Debrac, Patrice. Louis Pasteur.
- ↑ Graf, Noreen M.; Millington, Michael J. Psychosocial Aspects of Disability: Insider Perspectives and Strategies for Counselors.
- ↑ "Ferdinand Cohn". britannica.com. Retrieved 14 February 2018.
- ↑ Kango, Naveen. Textbook of Microbiology.
- ↑ Easter, Martin C. Rapid Microbiological Methods in the Pharmaceutical Industry.
- ↑ Grove, David. Tapeworms, Lice, and Prions: A Compendium of Unpleasant Infections.
- ↑ 31.00 31.01 31.02 31.03 31.04 31.05 31.06 31.07 31.08 31.09 31.10 31.11 31.12 31.13 31.14 31.15 31.16 31.17 31.18 31.19 31.20 31.21 31.22 31.23 31.24 31.25 31.26 "Significant Events By Years". asm.org. Retrieved 8 April 2018.
- ↑ Demaitre, Luke. Leprosy in Premodern Medicine: A Malady of the Whole Body.
- ↑ Kazda, Jindrich. The Ecology of Mycobacteria.
- ↑ Wolfe, Scott W.; Pederson, William C.; Hotchkiss, Robert N.; Kozin, Scott H.; Cohen, Mark S. Green's Operative Hand Surgery: The Pediatric Hand E-Book.
- ↑ 35.0 35.1 35.2 Goering, Richard; Dockrell, Hazel; Zuckerman, Mark; Chiodini, Peter L. Mims' Medical Microbiology E-Book.
- ↑ Vardaxis, Nicholas J. Immunology for the Health Sciences.
- ↑ Susser, Mervyn; Stein, Zena. Eras in Epidemiology: The Evolution of Ideas.
- ↑ 38.0 38.1 Williams, William F. Encyclopedia of Pseudoscience: From Alien Abductions to Zone Therapy.
- ↑ 39.0 39.1 Fairbrother, R. W. A Text-Book of Medical Bacteriology. Retrieved 14 February 2018.
- ↑ Okeke, Iruka N. Divining Without Seeds: The Case for Strengthening Laboratory Medicine in Africa. p. 165.
- ↑ 41.0 41.1 Logan, N. A. Bacterial Systematics. Retrieved 14 February 2018.
- ↑ Hui, Yiu H. Handbook of Food Science, Technology, and Engineering, Volume 4.
- ↑ Handbook of Food and Beverage Fermentation Technology (Y. H. Hui, Lisbeth Meunier-Goddik, Jytte Josephsen, Wai-Kit Nip, Peggy S. Stanfield ed.).
- ↑ Paracer, Surindar; Ahmadjian, Vernon. Symbiosis: An Introduction to Biological Associations.
- ↑ Schumann, Gail Lynn. Plant diseases: their biology and social impact.
- ↑ Annual Report and Proceedings of the ... Annual Meeting of the Illinois State Horticultural Society for the Year ... Illinois State Horticultural Society.
- ↑ Liu, Dongyou. Molecular Detection of Human Bacterial Pathogens.
- ↑ Borchardt, Kenneth A.; Noble, Michael A. Sexually Transmitted Diseases: Epidemiology, Pathology, Diagnosis, and Treatment.
- ↑ Ellis, Albert; Abarbanel, Albert. The Encyclopædia of Sexual Behaviour, Volume 2.
- ↑ SONI. FUNDAMENTALS OF BOTANY VOL-1.
- ↑ 51.0 51.1 Transactions of the Illinois State Academy of Science, Volumes 85-86. Illinois State Academy of Science. Retrieved 14 February 2018.
- ↑ Foster, W. D. A History of Medical Bacteriology and Immunology. Retrieved 14 February 2018.
- ↑ K. Altman, Lawrence. Who Goes First?: The Story of Self-Experimentation in Medicine.
- ↑ Damani, Nizam. Manual of Infection Prevention and Control. Retrieved 15 February 2018.
- ↑ Christodoulides, Myron. Meningitis: Cellular and Molecular Basis. Retrieved 15 February 2018.
- ↑ Grove, David. Tapeworms, Lice, and Prions: A compendium of unpleasant infections.
- ↑ Austrian, Robert. Life with the Pneumococcus: Notes from the Bedside, Laboratory, and Library.
- ↑ Roos, Karen L.; Tunkel, Allan R. Bacterial Infections of the Central Nervous System.
- ↑ Proceedings, American Philosophical Society (vol. 114, No. 5, 1970.
- ↑ Artenstein, Andrew W. Vaccines: A Biography.
- ↑ Aneja, K. R. A Textbook of Basic and Applied Microbiology.
- ↑ Mann, R.D. Modern Drug use: An Enquiry on Historical Principles.
- ↑ Wood, Arron; Ellyard, David. Who Discovered What When.
- ↑ Aarne Vesilind, P.; Morgan, Susan M.; Heine, Lauren G. Introduction to Environmental Engineering - SI Version.
- ↑ Morabito, Stefano. Pathogenic Escherichia coli.
- ↑ The Name's Familiar II.
- ↑ BAGYARAJ, D. J.; RANGASWAMI, G. AGRICULTURAL MICROBIOLOGY.
- ↑ Maczulak, Anne. Allies and Enemies: How the World Depends on Bacteria.
- ↑ Velazquez, E.; Rodriguez-Barrueco, C. First International Meeting on Microbial Phosphate Solubilization.
- ↑ Fred, Edwin Broun; Baldwin, Ira Lawrence; McCoy, Elizabeth. Root Nodule Bacteria and Leguminous Plants.
- ↑ Oriani, Giorgio; Marroni, Alessandro; Wattel, Frances. Handbook on Hyperbaric Medicine.
- ↑ Finegold, Sydney. Anaerobic Infections in Humans.
- ↑ Kumar Biswas, Samar. Orthopedics: A Postgraduate Companion.
- ↑ King-thom, Chung; Jong-kang, Liu. Pioneers In Microbiology: The Human Side Of Science.
- ↑ Srivastava, S. Understanding Bacteria.
- ↑ Benedict, Carol Ann. Bubonic Plague in Nineteenth-century China.
- ↑ Cunningham, Andrew; Williams, Perry. The Laboratory Revolution in Medicine.
- ↑ Simpson, W. J. A Treatise on Plague: Dealing with the Historical, Epidemiological, Clinical, Therapeutic and Preventive Aspects of the Disease.
- ↑ Rapid Immunotests for Clinical, Food and Environmental Applications.
- ↑ Tiwari, Prateeksha M. Nobel Prize Winners of the World.
- ↑ Endotoxin in Health and Disease (Helmut Brade ed.).
- ↑ Klipp, Werner; Masepohl, Bernd; Gallon, John R.; Newton, William E. Genetics and Regulation of Nitrogen Fixation in Free-Living Bacteria.
- ↑ Palacios, Rafael; Newton, William E. Genomes and Genomics of Nitrogen-fixing Organisms.
- ↑ de Bruijn, Frans J. Biological Nitrogen Fixation.
- ↑ Grafe, Alfred. A History of Experimental Virology.
- ↑ Goding, James W. Monoclonal Antibodies: Principles and Practice.
- ↑ Easter, Martin C. Rapid Microbiological Methods in the Pharmaceutical Industry.
- ↑ 88.0 88.1 "Shiga Kiyoshi". britannica.com. Retrieved 16 February 2018.
- ↑ Martinez, Danielle. "Shigellosis". austincc.edu. Retrieved 16 February 2018.
- ↑ Grove, David. Tapeworms, Lice, and Prions: A compendium of unpleasant infections.
- ↑ Baird, J. Kevin; Marzuki, Sangkot. War Crimes in Japan-Occupied Indonesia: A Case of Murder by Medicine.
- ↑ Li, Hongjun. Radiology of Infectious Diseases:, Volume 2.
- ↑ Grove, David. Tapeworms, Lice, and Prions: A compendium of unpleasant infections.
- ↑ Marchaim, Uri. Biogas Processes for Sustainable Development, Issues 95-96.
- ↑ Florkin, Marcel. Comparative Biochemistry V1: A Comprehensive Treatise.
- ↑ Perlman, D.; Umbreit, Wayne W. Advances in Applied Microbiology.
- ↑ Peña, Leandro. Transgenic Plants: Methods and Protocols.
- ↑ Kozlov, Andrei P. Evolution by Tumor Neofunctionalization: The Role of Tumors in the Origin of New Cell Types, Tissues and Organs.
- ↑ Liu, Tong-Xian; Kang, Le. Recent Advances in Entomological Research: From Molecular Biology to Pest Management.
- ↑ Hagan, William Arthur; Bruner, Dorsey William; Timoney, John Francis. Hagan and Bruner's Microbiology and Infectious Diseases of Domestic Animals: With Reference to Etiology, Epizootiology, Pathogenesis, Immunity, Diagnosis, and Antimicrobial Susceptibility.
- ↑ Indian Journal of Animal Sciences, Volumes 23-24.
- ↑ Oren, Aharon; Papke, R. Thane. Molecular Phylogeny of Microorganisms.
- ↑ South African journal of dairy technology, Volumes 11-12.
- ↑ Broun Fred, Edwin; Lawrence Baldwin, Ira; McCoy, Elizabeth. Root Nodule Bacteria and Leguminous Plants.
- ↑ Strider, D. L. Bacterial Canker of Tomato Caused by Corynebacterium Michiganense: A Literature Review and Bibliography.
- ↑ BAGYARAJ, D. J.; RANGASWAMI, G. AGRICULTURAL MICROBIOLOGY.
- ↑ Plant Pathology Concepts and Laboratory Exercises, Third Edition (Bonnie H. Ownley, Robert N. Trigiano ed.).
- ↑ "Erwin Frink Smith". Apsnet.org. Retrieved 2018-02-15.
- ↑ Rogers, A. D. III (1952). Erwini Frink Smith. Memoirs of the American Philosophical Society. 31. p. 675.
- ↑ Lobocka, Malgorzata; Szybalski, Waclaw T. Bacteriophages, Part 2.
- ↑ Shors. Understanding Viruses.
- ↑ Kutter, Elizabeth; Sulakvelidze, Alexander. Bacteriophages: Biology and Applications.
- ↑ Goyal, Sagar M.; Gerba, Charles P.; Bitton, Gabriel. Phage ecology.
- ↑ Trautwein Henrici, Arthur. The biology of bacteria: an introduction to general microbiology.
- ↑ Hess, David J. Can Bacteria Cause Cancer?: Alternative Medicine Confronts Big Science.
- ↑ Suppressed Inventions (Jonathan Eisen ed.).
- ↑ Rosaler, Maxine. Listeriosis.
- ↑ Foodborne Infections and Intoxications.
- ↑ Requena, Jose M. Stress Response in Microbiology.
- ↑ Hessenbruch, Arne. Reader's Guide to the History of Science.
- ↑ New Scientist 1 Mar 1984.
- ↑ Pommerville, Jeffrey C. Alcamo's Fundamentals of Microbiology.
- ↑ Leth Stone, Carol. The Basics of Biology.
- ↑ Nickerson, Cheryl A.; Schurr, Michael. Molecular Paradigms of Infectious Disease: A Bacterial Perspective.
- ↑ Chao, Hsiang-Ke; Chen, Szu-Ting; Millstein, Roberta L. Mechanism and Causality in Biology and Economics.
- ↑ Chao, Hsiang-Ke; Chen, Szu-Ting; Millstein, Roberta L. Mechanism and Causality in Biology and Economics.
- ↑ Russell, Peter J.; Hertz, Paul E.; McMillan, Beverly. Biology: The Dynamic Science, Volume 1 (Units 1 & 2).
- ↑ Tobin, Allan J.; Dusheck, Jennie. Asking about Life.
- ↑ 129.0 129.1 "TIMELINE". microbiologysociety.org. Retrieved 7 April 2018.
- ↑ Karp, Gerald. Cell and Molecular Biology: Concepts and Experiments.
- ↑ Journal of the Faculty of Agriculture, Hokkaido University.
- ↑ Mostofa, Khan M.G.; Yoshioka, Takahito; Mottaleb, Abdul; Vione, Davide. Photobiogeochemistry of Organic Matter: Principles and Practices in Water Environments.
- ↑ 133.0 133.1 Yount, Lisa. A to Z of Biologists.
- ↑ Zlatanova,, Jordanka; van Holde, Kensal E. Molecular Biology: Structure and Dynamics of Genomes and Proteomes.
- ↑ Snyder, Larry; Champness, Wendy. Molecular Genetics of Bacteria.
- ↑ Watson, James D. A Passion for DNA: Genes, Genomes, and Society.
- ↑ Kratz, Rene. Microbiology the Easy Way.
- ↑ Newton, David E. DNA Technology: A Reference Handbook: A Reference Handbook.
- ↑ Bourgeois, Suzanne. Genesis of the Salk Institute: The Epic of Its Founders.
- ↑ Schaechter, Moselio. Desk Encyclopedia of Microbiology.
- ↑ Khanna, Pragya. Cell and Molecular Biology.
- ↑ Russell, Peter. Int Std Ed-General Biology.
- ↑ "International Journal Of Systematic And Evolutionary Microbiology (IJSEM) Puts Archive Online For Free". science20.com. Retrieved 8 May 2018.
- ↑ Clayton, Roderick K.; Sistrom, W. R. The Photosynthetic Bacteria.
- ↑ Madigan, Michael T. Studies on the Physiological Ecology of Chloroflexus Aurantiacus, a Filamentous Photosynthetic Bacterium.
- ↑ Woese CR, Fox GE (November 1977). "Phylogenetic structure of the prokaryotic domain: the primary kingdoms". Proceedings of the National Academy of Sciences of the United States of America. 74 (11): 5088–90. Bibcode:1977PNAS...74.5088W. PMC 432104. PMID 270744. doi:10.1073/pnas.74.11.5088.
- ↑ Scutti, Susan. "Unusual forms of 'nightmare' antibiotic-resistant bacteria detected in 27 states". edition.cnn.com. Retrieved 13 April 2018.
- ↑ Travensolo, Regiane F.; Carareto-Alves, Lucia M.; Costa, Maria V. C. G.; Lopes, Tiago J. S.; Carrilho, Emanuel; Lemos, Eliana G. M. "Xylella fastidiosa gene expression analysis by DNA microarrays".
- ↑ "INNOVATION BY DESIGN FAST COMPANY CO.DESIGN COLLECTIONS NEWSLETTERS INNOVATION FESTIVAL CURRENT ISSUE Current Issue SUBSCRIBE Follow us: ADVERTISEMENT 04.13.1812:00 PM EVIDENCE Bathroom Hand Dryers Are Creating "Bacterial Highways" In Your Office". fastcodesign.com. Retrieved 13 April 2018.
- ↑ Huesca-Espitia, Luz del Carmen; Aslanzadeh, Jaber; Feinn, Richard; Joseph, Gabrielle; Murray, Thomas S.; Setlow, Peter; Schaffner, Donald W. "Deposition of Bacteria and Bacterial Spores by Bathroom Hot-Air Hand Dryers".
- ↑ Dormehl, Luke. "Biologists have found an oil-hungry bacterium that's ideal for oil spill cleanup". digitaltrends.com. Retrieved 13 April 2018.