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Thioamide

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General structure of a thioamide

A thioamide (rarely, thionamide, but also known as thiourylenes) is a functional group with the general structure R1−C(=S)−NR2R3, where R1, R2 and R3 are any groups (typically organyl groups or hydrogen). Analogous to amides, thioamides exhibit greater multiple bond character along the C-N bond, resulting in a larger rotational barrier.[1]

Examples

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A well-known thioamide is thioacetamide, which is used as a source of the sulfide ion and is a building block in heterocyclic chemistry. Thiocyanuric acid is a tristhioamide.

Thioamides or anti-thyroid drugs are also a class of drugs that are used to control thyrotoxicosis.

Preparation and structure

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Thioamides are typically prepared by treating amides with phosphorus sulfides such as phosphorus pentasulfide, a reaction first described in the 1870s.[2][3][4] Alternative routes include the use of Lawesson's reagent[5] or the reaction of nitriles with hydrogen sulfide:

Thionamide Synthesis

The Willgerodt-Kindler reaction also gives benzylthioamides.[6]

The C(R)(N)(S) core of thioamides is planar. Using thioacetamide as representative: the C-S, C-N, and C-C distances are 1.68, 1.31, and 1.50 Å, respectively. The short C-S and C-N distances indicate multiple bonding.[7]

Thioamides in biochemistry and medicine

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Thioamides are also a class of drugs that are used to control thyrotoxicosis.

Thioamides have been incorporated into peptides as isosteres for the amide bond.[8] Peptide modifications are analogues of the native peptide, which can reveal the structure-activity relationship (SAR). Analogues of peptides can also be used as drugs with an improved oral bioavailability. Thioamides inhibit the enzyme thyroid peroxidase in the thyroid, reducing the synthesis of triiodothyronine (T3) and thyroxine (T4), thereby blocking uptake of iodotyrosines from the colloid. They also block iodine release from peripheral hormone. Maximum effects occur only after a month, since hormone depletion is caused by reduced synthesis, which is a slow process.

References

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  1. ^ Wiberg, Kenneth B.; Rablen, Paul R. (1995). "Why Does Thioformamide Have a Larger Rotational Barrier Than Formamide?". J. Am. Chem. Soc. 117 (8): 2201–2209. doi:10.1021/ja00113a009.
  2. ^ "Preparation of thiamides". Journal of the Chemical Society, Abstracts. 34: 396. 1878. doi:10.1039/CA8783400392.
  3. ^ Gompper, R.; Elser, W. (1973). "2-Methylmercapto-N-Methyl-Δ2-Pyrroline". Organic Syntheses; Collected Volumes, vol. 5, p. 780.
  4. ^ Schwarz, George (1955). "2,4-Dimethylthiazole". Organic Syntheses; Collected Volumes, vol. 3, p. 332.
  5. ^ Shabana, R.; Scheibye, S.; Clausen, K.; Olesen, S.O.; Lawesson, S.-O. (1980). "Studies on organophosphorus compounds XXXI. Synthesis of thiolactams and thioimides". Nouveau Journal de Chimie. 1980 (4): 47.
  6. ^ Rolfs, Andreas; Liebscher, Jürgen (1998). "3-Morpholino-2-Phenylthioacrylic Acid Morpholide and 5-(4-Bromobenzoyl-2-(4-Morpholino)-3-Phenylthiophene". Organic Syntheses; Collected Volumes, vol. 9, p. 99.
  7. ^ Trevor W. Hambley; David E. Hibbs; Peter Turner; Siân. T. Howard; Michael B. Hursthouse (2002). "Insights into Bonding and Hydrogen Bond Directionality in Thioacetamide from the Experimental Charge Distribution". J. Chem. Soc., Perkin Trans. (2): 235–239. doi:10.1039/B109353C.
  8. ^ Artis, Dean R.; Lipton, Mark A. (1998). "Conformations of Thioamide-Containing Dipeptides: A Computational Study". J. Am. Chem. Soc. 120 (47): 12200–12206. doi:10.1021/ja982398t.