Adolph Strecker | |
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| Born | Friederich Adolph Ludwig Ewald Strecker 21 October 1822 |
| Died | 7 November 1871 (aged 49) |
| Alma mater | University of Giessen |
| Known for | Strecker synthesis of amino acids, Strecker degradation |
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| Institutions |
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| Doctoral advisor | Justus Liebig |
Adolph Strecker (21 October 1822 – 7 November 1871) was a German chemist who is remembered primarily for his work with amino acids.
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Transcription
Hey. So we're going to be talking about amino acid synthesis. And we're just going to stick with two of the main methods for synthesizing amino acids. And they both just happened to be named after old German chemists because synthesizing amino acids was probably hot stuff back in the mid to late 1800s, And the first method that we're going to be talking about is Gabriel synthesis, named after Siegmund Gabriel. And the second method is called Strecker synthesis, which is named after Adolph Strecker. So let's start out with Gabriel synthesis first. In Gabriel synthesis, we begin with a molecule of what's called phthalimidomalonic ester. So n-phthalimidomalonic ester is what this molecule is called, and that's kind of a mouthful so I'm just going to call this "thad." All righty, so here's our molecule of what I'm going to call "thad." And this is sort of the foundation upon which we're going to build our alpha amino acid. And so let me draw an alpha amino acid over here to kind of remind us what our end product or end goal is going to be. And so remember that an amino acid has, first, the amino group, and I'm going to draw it in the protonated form. And then we have our alpha carbon, and then the R group, or side chain, is over here. And then bound to the alpha carbon is the hydrogen and a carobxylic acid group. So if we come back over to our molecule thad over here, we can see that the nitrogen atom is going to serve as our amino group. And then we have our alpha carbon here in the center, and then our carboxylic acid, here, is on the bottom. And then we have this temporary ester group at the top. So I'm going to highlight those key atoms for you here, the nitrogen and the alpha carbon and the carbonyl carbon. And the reason why we started out with all these other groups attached to our key atoms is for various reasons. For example, our amide is prevented or, quote, "protected" from acting as a nucleophile by having this phthalimide group attached to it. And then the carboxylic acid is protected with this ethyl ester that's attached, and the [INAUDIBLE] carbon is further activated by this additional ester group at the top. Now in the presence of a base and having a source of an alkyl group, our molecule of thad will become alkylated to look like this. So now you can see that the alkyl group here has been substituted onto the carbon atom, and so this is known as the alkylated step. And then the next step involves acid hydrolysis, which yields this molecule. And as you can see here, the phthalimide group was hydrolyzed along with the two esters. And this is the hydrolyzed step. And then finally, we can add a little heat to decarboxylate this molecule or remove its carboxyl group up top here. And we get our final alpha amino acid. OK, so this is Gabriel synthesis in a nut shell. So you start out with an n-phthalimidomalonic ester, and then you add up a base and a source of an alkyl group. And you get an alkylated amide malonic acid here, and then you hydrolyze this to get your carboxylic acid group as well as your amino group. Then you add a little heat for decarboxylation, and you wind up with the final amino acid that's produced here. And so now that we have Gabriel synthesis down, let's move on to Strecker synthesis here. So let's make a little room for that. So next we have Strecker's synthesis, and the Strecker method is considered to be a somewhat more elegant way of synthesizing amino acids because it's really a lot more simple and efficient And just remember that simplicity is elegant. And there are just three starting components, and these are ammonia, which serves as the precursor for our amino group; potassium cyanide, which serves as the precursor for the carboxylic acid group; and then either an aldehyde or a ketone, which serves as the scaffold on which the amino and carboxylic acid groups will be bound. And this provides the carbon that will become our alpha carbon. So let's take an aldehyde and react it with ammonia in the presence of an acid. This will give us an imine as well as a molecule of water, and then the imine can be protonated again in the presence of an acid. And this time, a cyanide ion will attack the protonated imine, which generates an alpha amino nitrile. And then, finally, the hydrolysis of this alpha amino nitrile yields an alpha amino acid. And so there you have it-- Strecker synthesis. You can see how it's a very simple and efficient and, therefore, elegant way of synthesizing amino acids.
Life and work
Strecker was born in Darmstadt, the son of Friedrich Ludwig Strecker, an archivist working for the hessian Grand Duke, and Henriette Amalie Johannette Koch. Adolph Strecker attended school in Darmstadt until 1838 when he changed to the higher Gewerbeschule. After receiving his abitur in 1840, Strecker began studying science at the University of Giessen, where Justus Liebig was a professor. In August 1842, Strecker received his PhD and began teaching at a realschule in Darmstadt. He refused one offer to work for Liebig, but in 1846 he accepted another and became Liebig's private assistant at the University of Giessen. Strecker finished his habilitation in 1848 and became a lecturer at the university.
Strecker investigated a wide variety of problems in both organic and inorganic chemistry during his time at Giessen. Examples include the molecular masses of silver and carbon, the reactions of lactic acid, the decomposition of hippuric acid by nitric acid, and the separation of cobalt and nickel.
Strecker wanted to leave Giessen for a position at the University of Berlin, but when he heard of an open position at Norway's University of Christiania, he applied for it and in 1851 became a professor there. While in Norway, Strecker focused on organic chemistry, covering a broad range of topics from organometallic chemistry to natural products.
Strecker left Norway on Christian Gottlob Gmelin's death in 1860 to accept the latter's position at the University of Tübingen. There he conducted research on guanine, xanthine, caffeine, and theobromine, and on the very toxic thallium oxides, which damaged his health severely. He moved to the University of Würzburg in 1870, but his first semester was interrupted by the Franco-Prussian War of 1870–1871. Strecker became an officer during the war and returned to the university after it, where he started his last semester. In the summer of 1871 he undertook a recreational holiday in Berchtesgaden, Bavaria, but his health began to deteriorate. Strecker died in Würzburg, where he is buried in the Hauptfriedhof.
Strecker synthesis
The Strecker synthesis of amino acids involves the reaction of potassium cyanide, ammonium chloride, and an aldehyde to make an alpha amino acid.[1][2][3][4] The reaction can also be run with ammonia, hydrogen cyanide, and an aldehyde.
Because of the relative simplicity of the reactants, the Strecker synthesis has been invoked by those studying both the origin of life and meteoritic amino acids.[5][6]
Also named for Strecker are the Strecker degradation, which involves the conversion of amino acids into imines and then into ketones, and the Strecker sulfite alkylation.
Notable people who taught Strecker
- Justus von Liebig (1803–1873)
Notable students of Strecker
- Georg Zehfuss (de) (1832–1901)
Family
Strecker, while serving as a professor in Norway, returned to Germany for several holidays. During one such visit to Darmstadt, Strecker, on July 3, 1852, married Karoline Auguste Natalie Weber (1852–1853), who died 16 months later – on October 13, 1853. She had given birth on October 2, 1853, to Friederike Caroline Sophie Christiane Natalie Strecker. Adolph Stecker married a second time on September 29, 1855.
References
- ^ Strecker, A. (1850). "Ueber die künstliche Bildung der Milchsäure und einen neuen, dem Glycocoll homologen Körper". Annalen der Chemie und Pharmacie. 75 (1): 27–45. doi:10.1002/jlac.18500750103.
- ^ Strecker, A. (1854). "Ueber einen neuen aus Aldehyd – Ammoniak und Blausäure entstehenden Körper (p )". Annalen der Chemie und Pharmacie. 91 (3): 349–351. doi:10.1002/jlac.18540910309.
- ^ Kendall, E. C.; McKenzie, B. F. Organic Syntheses, Coll. Vol. 1, p.21 (1941); Vol. 9, p.4 (1929). (Article)
- ^ Clarke, H. T.; Bean, H. J. Organic Syntheses, Coll. Vol. 2, p.29 (1943); Vol. 11, p.4 (1931). (Article)
- ^ Mason, Stephen (1991). Chemical Evolution. Oxford: Clarendon Press. pp. 236–237. ISBN 0-19-855272-6.
- ^ Sephton, Mark A. (2002). "Organic Compounds in Carbonaceous Meteorites". Natural Product Reports. 19 (3): 292–311. doi:10.1039/b103775g. PMID 12137279.
External links
- Adolph Strecker obituary by Rudolf Wagner from Berichte der Deutschen Chemischen Gesellschaft, 1872, part V, pp. 125–131
- Obituary in the Journal of the Chemical Society, 1872, volume 25, p. 353
- Adolph Strecker by B. Lepsius (1892), Allgemeine Deutsche Biographie, volume 36, Leipzig: Duncker & Humblot – entry for Strecker
- Adolph Strecker – brief biography and two pictures at Tübingen University
- Regnault-Strecker's kurzes Lehrbuch der Chemie. Vieweg, Braunschweig 1851 Digital edition by the University and State Library Düsseldorf
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This page was last edited on 14 September 2023, at 17:11