79-16-3 Usage
Chemical Properties
colourless liquid or solid. Soluble in water, ethanol, benzene, ether, chloroform, insoluble in petroleum ether.
Uses
N-Methylacetamide is used as a chemical intermediate in the production of life science, agrochemicals, electronic materials and construction materials. It is also used as a solvent, in electrochemistry.
Definition
ChEBI: N-methylacetamide is a monocarboxylic acid amide that is the N-methyl derivative of acetamide. It has a role as a metabolite. It is a member of acetamides and a monocarboxylic acid amide. It is functionally related to an acetamide.
Production Methods
Af-Methylacetamide has been prepared by reaction of methylamine with hot acetic acid (D'Alelio and Reid, 1937) and with acetic anhydride (Mauger and Soper, 1946). Other methods include heating iV,N-dimethylurea with acetic acid (US Patent, 1936) and reduction/hydrogenation of N-(hydroxymethyl)acetamide (US Patent, 1944).
Industrial uses
Even though N-methylacetamide shares many general physical and chemical properties with dimethylacetamide, it has not found the extensive industrial applications of the latter. N-methylacetamide dissolves many inorganic salts.
Safety Profile
Moderately toxic by
intraperitoneal and subcutaneous routes.
Mddly toxic by ingestion and intravenous
routes. An experimental teratogen.
Experimental reproductive effects. Mutation
data reported. When heated to
decomposition it emits toxic fumes of NOx.
Metabolism
In a recent comparative toxicity and metabolism study on four formamides and on N-methylacetamide, the sole metabolite of N-methylacetamide in the urine of mice was identified as N-(hydroxymethyl)acetamide (Kestell et al 1987). There was no evidence of induction of hepatic drug metabolizing enzymes in rats following treatment with N-methylacetamide (Ackerman and Leibman, 1977). N-Methylacetamide influenced neither the sleeping time induced by hexobarbital nor the metabolism of hexobarbital or aniline.
Purification Methods
Fractionally distil it under vacuum, then fractionally crystallise it twice from its melt. Likely impurities include acetic acid, methyl amine and H2O. For a detailed purification procedure, see Knecht and Kolthoff, Inorg Chem 1 195 1962. Although N-methylacetamide is commercially available it is often extensively contaminated with acetic acid, methylamine, water and an unidentified impurity. The recommended procedure is to synthesise it in the laboratory by direct reaction. The gaseous amine is passed into hot glacial acetic acid, to give a partially aqueous solution of methylammonium acetate which is heated to ca 130o to expel water. Chemical methods of purification such as extraction by pet ether, treatment with H2SO4, K2CO3 or CaO can be used but are more laborious. Tests for purity include the Karl Fischer titration for water; this can be applied directly. Acetic acid and methylamine can be detected polarographically. In addition to the above, purification of N-methylacetamide can be achieved by fractional freezing, including zone melting, repeated many times, or by vacuum distillation under reduced pressures. For details of zone melting techniques, see Knecht in Recommended Methods for Purification of Solvents and Tests for Impurities, Coetzee Ed. Pergamon Press 1982.[Beilstein 4 IV 176.]
Check Digit Verification of cas no
The CAS Registry Mumber 79-16-3 includes 5 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 2 digits, 7 and 9 respectively; the second part has 2 digits, 1 and 6 respectively.
Calculate Digit Verification of CAS Registry Number 79-16:
(4*7)+(3*9)+(2*1)+(1*6)=63
63 % 10 = 3
So 79-16-3 is a valid CAS Registry Number.
InChI:InChI=1/C3H7NO/c1-3(5)4-2/h1-2H3,(H,4,5)
79-16-3Relevant articles and documents
Metal array fabrication based on ultrasound-induced self-assembly of metalated dipeptides
Isozaki, Katsuhiro,Haga, Yusuke,Ogata, Kazuki,Naota, Takeshi,Takaya, Hikaru
, p. 15953 - 15966 (2013)
Pd- and Pt-bound bis-metalated peptides were synthesised by the condensation of Pd- or Pt-aldimine-complex-bound glutamic acids to afford the four possible metal isomers of bis-Pd and bis-Pt-homometalated dipeptides and PdPt- and PtPd-heterometalated dipeptides without metal disproportionation. Ultrasound-induced self-assembly of these bis-metalated peptides proceeded effectively to afford supramolecular gels that displayed well-ordered metal arrays. The formation of parallel β-sheet type aggregates through interpeptide amide-amide hydrogen bonding was confirmed by IR, scanning electron microscopy (SEM), and synchrotron X-ray diffraction analyses (WAXS and SAXS). The mechanism of the ultrasound-induced self-assembly of the metalated dipeptides was elucidated via kinetic and association experiments by 1H NMR, in which ultrasound-triggered dissociation of intramolecular hydrogen bonds between the chloride ligands of the Pd- and Pt-complexes and amides initially occurred. This was followed by the formation of intermolecular amide-amide hydrogen bonds, which afforded the corresponding oligomeric peptide self-assembly as the nucleus for supramolecular aggregation. The observed first-order relationship of the gelation rate versus the sonication frequency suggested that the microcavitation generated under sonication conditions acted as a crucial trigger and provided a reaction field for efficient self-assembly.
Amide bond formation in aqueous solution: Direct coupling of metal carboxylate salts with ammonium salts at room temperature
Nielsen, John,Tung, Truong Thanh
supporting information, p. 10073 - 10080 (2021/12/10)
Herein, we report a green, expeditious, and practically simple protocol for direct coupling of carboxylate salts and ammonium salts under ACN/H2O conditions at room temperature without the addition of tertiary amine bases. The water-soluble coupling reagent EDC·HCl is a key component in the reaction. The reaction runs smoothly with unsubstituted/substituted ammonium salts and provides a clean product without column chromatography. Our reaction tolerates both carboxylate (which are unstable in other forms) and amine salts (which are unstable/volatile when present in free form). We believe that the reported method could be used as an alternative and suitable method at the laboratory and industrial scales. This journal is
Regioselective Intramolecular Allene Amidation Enabled by an EDA Complex**
Liu, Lu,Ward, Robert M.,Schomaker, Jennifer M.
, p. 13783 - 13787 (2020/10/06)
The addition of radicals to unsaturated precursors is a powerful tool for the synthesis of both carbo- and heterocyclic organic building blocks. The recent advent of mild ways to generate N-centered radicals has reignited interest in exploiting highly regio-, chemo-, and stereoselective transformations that employ these reactive intermediates. While the additions of aminyl, iminyl, and amidyl radicals to alkenes and alkynes have been well-studied, analogous additions to allenes are scarce. Allenes offer several attractive features, including potential for selective amidation at three distinct sites via judicious choice of precursor or radical source, the opportunity for axial-to-point chirality transfer, and productive trapping of vinyl or allyl radical intermediates to diversify functionality in the products. In this article, we report a regioselective addition of amidyl radicals to allenes to furnish an array of valuable N-heterocycle scaffolds.
