Aromatic rings Birch reaction

Birch Reductions reduction of aromatic rings Organic Reactions 1976, 23, 1. Tetrahedron 1986, 42, 6354. Cornprehensice Organic Synthesis 1991, voJ. 8, 107. 

Dissolving-Metal Reduction of Aromatic Compounds and Alkynes. Dissolving-metal systems constitute the most general method for partial reduction of aromatic rings. The reaction is called the Birch reduction,214 and the usual reducing medium is lithium or sodium in liquid ammonia. An alcohol is usually added to serve as a proton source. The reaction occurs by two successive electron transfer/proto-nation steps. 

Angular methylation. A recent synthesis 11-ketoprogesterone (6) requires introduction of the C, j-methyl group into the p,"y-unsaturated ketone 1, obtained by Birch reduction of a precursor with an aromatic ring A Reaction of 1 with CH,l,/C,H,ZnI, the Sawada modification of the Simmons-Smith rc.igcnt, is not successful, and the diethyl... 

The elaboration of a method for the reduction of aromatic rings to the corresponding dihydrobenzenes under controlled conditions by A. J. Birch opened a convenient route to compounds related to the putative norprogesterone. This reaction, now known as the Birch reduction,is typified by the treatment of... 

Direct Electron Transfer. We have already met some reactions in which the reduction is a direct gain of electrons or the oxidation a direct loss of them. An example is the Birch reduction (15-14), where sodium directly transfers an electron to an aromatic ring. An example from this chapter is found in the bimolecular reduction of ketones (19-55), where again it is a metal that supplies the electrons. This kind of mechanism is found largely in three types of reaction, (a) the oxidation or reduction of a free radical (oxidation to a positive or reduction to a negative ion), (b) the oxidation of a negative ion or the reduction of a positive ion to a comparatively stable free radical, and (c) electrolytic oxidations or reductions (an example is the Kolbe reaction, 14-36). An important example of (b) is oxidation of amines and phenolate ions ... 

A solution of lithium, sodium, potassium or calcium in liquid ammonia can reduce a wide variety of unsaturated groups. Thus when aromatic rings are reduced by such metals in liquid ammonia, non-conjugated cyclohexadienes are produced. The reaction is called Birch reduction. 

At the outset of our studies of the reactivity of I and II, it was necessary to investigate claims that tertiary henzamides were inappropriate substrates for the Birch reduction. It had been reported that reduction of A,A-dimethylbenzamide with sodium in NH3 in the presence of tert-butyl alcohol gave benzaldehyde and a benzaldehyde-ammonia adduct. We formd that the competition between reduction of the amide group and the aromatic ring was strongly dependent on reaction variables, such as the alkali metal (type and quantity), the availability of a proton source more acidic than NH3, and reaction temperature. Reduction with potassium in NH3-THF solution at —78 °C in the presence of 1 equiv. of tert-butyl alcohol gave the cyclohexa-1,4-diene 2 in 92% isolated yield (Scheme 3). At the other extreme, reduction with lithium in NH3-THF at —33 °C in the absence of tert-butyl alcohol gave benzaldehyde and benzyl alcohol as major reaction products. ... 

Direct electron transfer We have already met some reactions in which the reduction is a direct gain of electrons or the oxidation a direct loss of them. An example is the Birch reduction (5-10), where sodium directly transfers an electron to an aromatic ring. An example from this chapter is found in the bimolecular reduction of ketones (9-62), where again it is... 

Morphine is biosynthesized from norreticuline through intramolecular oxidative coupling of the electron-rich aromatic rings, transformation that is difficult to achieve with chemical oxidizing agents. The most convenient synthesis, illustrated in Scheme 23, consists of partial saturation of the aromatic ring by the Birch reaction followed by an acid-Catalyzed Grewe-type cyclization to form the required tetracyclic skeleton (48). 

A common illicit synthesis of methamphetamine involves an interesting variation of the Birch reduction. A solution of ephedrine in alcohol is added to liquid ammonia, followed by several pieces of lithium metal. The Birch reduction usually reduces the aromatic ring (Section 17-14C), but in this case it eliminates the hydroxyl group of ephedrine to give methamphetamine. Propose a mechanism, similar to that for the Birch reduction, to explain this unusual course of the reaction. 

The loss of resonance energy involved in the reduction of an aromatic ring makes this a difficult process. If the reaction is carried out using hydrogen and a catalyst, high pressure and temperature are required. However, reduction can be achieved by the stepwise addition of electrons using sodium or lithium in liquid ammonia, followed by protonation from an alcohol. This reaction, which has had wide application in the laboratory, is known as the Birch reduction. It is commonly used... 

Extensive investigations have been made into further methods for the reduction of aromatic rings based on the use of dissolving metals in other solvents, especially the lower molecular weight amines (the Benkeser reduction), electrochemical methods (cathodic reductions), photochemical methods and the reaction of radical anions with silylating reagents rather than proton sources. The aim of much of this work has been to produce the normal Birch products more conveniently or cheaply, but very often the outcome has been quite distinct. The alternative method may then provide access to products which are not so easily obtained by the standard metal-liquid ammonia methodology. 

The total synthesis of galbulimima alkaloid GB 13 was accomplished by L.N. Mander and co-workers. The Birch reduction of a complex intermediate was necessary in order to prepare a cyclic a,p-unsaturated ketone. The treatment of the substrate with lithium metal in liquid ammonia first resulted in a quantitative reductive decyanation of the C6a cyano group. The addition of excess ethanol to the reaction mixture reduced the aromatic ring to the corresponding enol ether that was hydrolyzed in a subsequent step to afford the unsaturated ketone. 

The Birch reduction is the organic reduction of aromatic rings by sodium in liquid ammonia invented by Arthur Birch. The reaction product is a 1,4-cyclohexadiene. The metal can also be lithium or potassium and the hydrogen atoms are supplied by an alcohol such as ethanol or tertbutanol. Sodium in liquid ammonia gives an intense blue color. 

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