The Hofmann rearrangement (Hofmann degradation) is the organic reaction of a primary amide to a primary amine with one less carbon atom. The reaction involves oxidation of the nitrogen followed by rearrangement of the carbonyl and nitrogen to give an isocyanate intermediate. The reaction can form a wide range of products, including alkyl and aryl amines.
600px|thumb|center|The Hofmann rearrangement
The reaction is named after its discoverer, August Wilhelm von Hofmann, and should not be confused with the Hofmann elimination, another name reaction for which he is eponymous.
Mechanism
The reaction of bromine with sodium hydroxide forms sodium hypobromite in situ, which transforms the primary amide into an intermediate isocyanate. The formation of an intermediate nitrene is not possible because it implies also the formation of a hydroxamic acid as a byproduct, which has never been observed. The intermediate isocyanate is hydrolyzed to a primary amine, giving off carbon dioxide. lead tetraacetate, N-bromosuccinimide, and (bis(trifluoroacetoxy)iodo)benzene have all been used for Hofmann rearrangements.
The intermediate isocyanate can be trapped with various nucleophiles to form stable carbamates or other products rather than undergoing decarboxylation. In the following example, the intermediate isocyanate is trapped by methanol.
600px|center|thumb|Formation of a [[Carbamate|carbamate ester via a Hofmann rearrangement using NBS and DBU]]
In a similar fashion, the intermediate isocyanate can be trapped by tert-butyl alcohol, yielding the tert-butoxycarbonyl (Boc)-protected amine.
The Hofmann Rearrangement also can be used to yield carbamates from α,β-unsaturated or α-hydroxy amides or nitriles from α,β-acetylenic amides in good yields (≈70%).
In the Schestakov rearrangement, the substrate is a urea and the product a diacyl hydrazide.
Applications
- The preparation of anthranilic acid from phthalimide
- The conversion of Nicotinamide into 3-Aminopyridine
- A process for chemical synthesis and isolation of gabapentin with high yield and purity starts with conversion of 1,1-cyclohexanediacetic anhydride to an amide by reaction with a solution of ammonia in isopropanol and is followed by a Hofmann rearrangement in an freshly prepared aqueous solution of sodium hypobromite.
See also
- Beckmann rearrangement
- Curtius rearrangement
- Haloform reaction
- Lossen rearrangement
- Schmidt reaction
- Weerman degradation
- Wolff rearrangement