Aldehyde synthesis, using thiazoles

Thiazole-aldehyde synthesis Preparation of aldehydes from C-2 substituted thiazoles by thiazolyl-to-formyl conversion, see A. Dondoni, Carbohydrate synthesis via thiazoles, in Modem Synthetic Methods, R. Scheffold, ed., Verlag Helvetica Chimica Acta, Basel, 1992, p. 377 A. Dondoni, Acyclic diastereoselective synthesis using functionalized thiazoles. Routes to carbohydrates and related natural products, in New Aspects of Organic Chemistry, Z. Yoshida and Y. Ohshiro, eds., Kodansha, Tokyo, and VCH, Weinhcim, 1992, p. 105. 

Dondoni et al. prepared a 1-hydroxyethylene peptide using a thiazole-aldehyde synthesis starting from an amino acid.[38] The aldehyde is converted into an alkanoate by Wittig alkenation and reduction of the double bond (Scheme 18). Then, removal of the tert-bu-tyldimethylsilyl group gives the unsubstituted lactone. In the last step, the lactone is alkylated using the method reported by Kleinman and co-workers. 20 ... 

This reaction was first reported by Hantzsch and Weber in 1887. It is the formation of thiazole derivatives by means of condensation of a-haloketones (or aldehydes) and thioamides. Therefore, it is generally known as the Hantzsch thiazole synthesis. In addition, other names, including the Hantzsch synthesis, Hantzsch reaction, and Hantzsch thiazole reaction are also used from time to time. Besides thioamides, other thio-ketone derivatives such as thiourea, dithiocarbamates, and ketone thiosemicarbazone can also condense with a-halo ketones (or aldehydes) to form thiazoles. This reaction occurs because of the strong nucleophilicity of the sulfur atom in thioamides or thioureas, and normally gives excellent yields for simple thiazoles but low yields for some substituted thiazoles, as of dehalogenation. This reaction has been proven to be a multistep reaction, and the intermediates have been isolated at low temperatures, in which the dehydration of cyclic intermediates seems to be the slow step. It is found that a variety of reaction conditions might result in the racemized thiazoles that contain an enolizable proton at their chiral center, and it is the intermediate not the final product that is involved in the racemization. Therefore, some modifications have been made to reduce or even eliminate the epimeriza-tion upon thiazole formation. In addition, this reaction has been modified using a-tosyloxy ketones to replace a-haloketones. ... 

A recent total synthesis of tubulysin U and V makes use of a one-pot, three-component reaction to form 2-acyloxymethylthiazoles <06AG(E)7235>. Treatment of isonitrile 25, Boc-protected Z-homovaline aldehyde 26, and thioacetic acid with boron trifluoride etherate gives a 3 1 mixture of two diastereomers 30. The reaction pathway involves transacylation of the initial adduct 27 to give thioamide 28. This amide is in equilibrium with its mercaptoimine tautomer 29, which undergoes intramolecular Michael addition followed by elimination of dimethylamine to afford thiazole 30. The major diastereomer serves as an intermediate in the synthesis of tubulysin U and V. 

However, recently the yield of the first step of this imidazole synthesis was improved dramatically by replacement of the basic catalyst (tBuOK) by a milder basic catalyst, sodium cyanide19. Due to these milder reaction conditions a greater variety of aldehydes, one of the starting materials for the synthesis of imidazoles, can be used increasing the flexibility of the method20 even more. This synthon approach can also be used to prepare the bioiscsteric substituted thiazole analogs21. 

The most commonly used method for the preparation of fused thiazoles involves the reaction of a-mercapto N-heterocyclic compounds of type (138) with an a-halocarbonyl compound or ester to give S-alkylated intermediates (139) which can be dehydrated to (140). When R2 is alkoxy, thiazolones (141) are formed (Hantzsch synthesis). Strong dehydrating agents are necessary to cyclize aldehydes and ketones (139) to fused thiazoles. The method has been used to prepare (dihydro) imidazo[2,l-6]thiazoIes and thiazolo[3,2- ]-s-triazoles (80JHC1321, 78JHC401, 82IJC(B)243). 

Tominaga and coworkers [82,83] reported a thiirane synthesis starting from 2-mercapto-l,3-thiazole derivative 180 bearing a trimethylsilyl group (Scheme 56). Treatment of 180 with CsF in acetonitrile and then with an aldehyde provided adducts 182 that fragmented via the spiro-isomer 183. Interestingly, the use of TASF as the fluorine anion source provided alcohols 185. The latter products were slowly transformed into the respective thiiranes 184 and thiazolidinone on storage (Table 9). 

There has been considerable research into the electrolytic reduction of aromatic carboxylic acids to the corresponding aldehydes. A general procedure has been described in which key elements are the use of the ammonium salt of the acid, careful control of the pH and the presence of an organic phase (benzene) to extract the aldehyde and thus minimize overreduction. The method appears to work best for relatively acidic substrates for example, salicylaldehyde was obtained in 80% yield. Danish workers have shown that, under acidic conditions, controlled electrolytic reductions are possible for certain pyridine-, imidazole- and thiazole-carboxylic acids. In these cases, it is thought that the product aldehydes are protected by geminal diol formation. A chemical method which is closely related to electrolysis is the use of sodium amalgam as reductant. Although not widely used, it was successfully employed in the synthesis of a fluorinated salicylaldehyde. ... 

An aerobic version of the TPAP oxidation has been developed [47] and adapted by the Ley group to PSP [48]. This method was applied by this group in the aforementioned total synthesis of epothilone C [22]. The synthesis of the thiazole fragment (Scheme 4.8) requires the oxidation of primary alcohol 33 to the corresponding aldehyde 34. This was achieved using catalytic PSP under an oxygen atmosphere. 

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