Iodomethane 5-alkylation

Keywords gas-solid reaction, thiohydantoins, methylamine, methylammonium salts, iodomethane, alkylation... 

N-Alkylpyrroles may be obtained by the Knorr synthesis or by the reaction of the pyrrolyl metallates, ie, Na, K, and Tl, with alkyl haUdes such as iodomethane, eg, 1-methylpyrrole [96-54-8]. Alkylation of pyrroles at the other ring positions can be carried out under mild conditions with allyhc or hensylic hahdes or under more stringent conditions (100—150°C) with CH I. However, unless most of the other ring positions are blocked, poly alkylation and polymerisation tend to occur. N-Alkylation of pyrroles is favored by polar solvents and weakly coordinating cations (Na", K" ). More strongly coordinating cations (Li", Mg " ) lead to more C-alkylation. 

The first use of chiral oxazolines as activating groups for nucleophilic additions to arenes was described by Meyers in 1984. " Reaction of naphthyloxazoline 3 with phenyllithium followed by alkylation of the resulting anion with iodomethane afforded dihydronaphthalene 10 in 99% yield as an 83 17 mixture of separable diastereomers. Reductive cleavage of 10 by sequential treatment with methyl fluorosulfonate, NaBKi, and aqueous oxalic acid afforded the corresponding enantiopure aldehyde 11 in 88% yield. 

Meyers has demonstrated that chiral oxazolines derived from valine or rert-leucine are also effective auxiliaries for asymmetric additions to naphthalene. These chiral oxazolines (39 and 40) are more readily available than the methoxymethyl substituted compounds (3) described above but provide comparable yields and stereoselectivities in the tandem alkylation reactions. For example, addition of -butyllithium to naphthyl oxazoline 39 followed by treatment of the resulting anion with iodomethane afforded 41 in 99% yield as a 99 1 mixture of diastereomers. The identical transformation of valine derived substrate 40 led to a 97% yield of 42 with 94% de. As described above, sequential treatment of the oxazoline products 41 and 42 with MeOTf, NaBKi and aqueous oxalic acid afforded aldehydes 43 in > 98% ee and 90% ee, respectively. These experiments demonstrate that a chelating (methoxymethyl) group is not necessary for reactions to proceed with high asymmetric induction. 

P-amino acid products. Treatment of oxazoline 53 with 7V-lithiopiperidine followed by alkylation with iodomethane affords aniline derivative 54 in 94% yield and 99% de. Hydrolysis of the oxazoline group provided amino acid 55 in 92% yield and >99% ee. 

In addition to their systematic names, many simple alkyl halides are also named by identifying first the alkyl group and then the halogen, for example, CH3T can be called either iodomethane or methyl iodide. Such names are well entrenched in the chemical literature and in daily usage, but they won t be used in this book. 

Ethers can be prepared by reaction of an alkoxide or phenoxide ion with a primary alkyl halide. Anisole, for instance, results from reaction of sodium phenoxide with iodomethane. What kind of reaction is occurring Show the mechanism. 

A useful variation of the Williamson synthesis involves silver oxide, Ag20, as a mild base rather than NaH. Under these conditions, the free alcohol reacts directly with alkyl halide, so there is no need to preform the metal alkoxide intermediate. Sugars react particularly well glucose, for example, reacts with excess iodomethane in the presence of Ag20 to generate a pentaether in 85% yield. 

An alkylation reaction is used to introduce a methyl or primary alkyl group onto the a position of a ketone, ester, or nitrile by S 2 reaction of an enolate ion with an alkyl halide. Thus, we need to look at the target molecule and identify any methyl or primary alkyl groups attached to an a carbon. In the present instance, the target has an a methyl group, which might be introduced by alkylation of an ester enolate ion with iodomethane. 

Many of the reactions of amines are familiar from past chapters. Thus, amines react with alkyl halides in S 2 reactions and with acid chlorides in nucleophilic acyl substitution reactions. Amines also undergo E2 elimination to yield alkenes if they are first qualernized by treatment with iodomethane and then heated with silver oxide, a process called the Hofmann elimination. 

In the case of 2,3-dihydro-l-benzothiepin 1-oxide (5), alkylation with iodomethane and silver (I) tetrafluoroborate leads to the methoxysulfonium salt 6 in 65% yield.86... 

Dibenz[r,e,]azcpinium salts, e.g. 3 and 6, arc also obtained by O- and 5-alkylation of 6,7-dihydro-5//-dibenz[f,e]azepin-7-ones 2 and -7-thiones 5 with trimethyloxonium tetrafluo-roborate.181 iodomethane,181 or methyl trifluoromethanesulfonate.12 Treatment of the tri-fluoromethanesulfonates 3 and 6 (X = OTf), or the tetrafluoroborate 6 (X = BF4) with 2 M sodium hydroxide in dichloromethane liberates the free bases 4 and 7, respectively.7,181... 

S-Alkylation of 9-methoxy-5//-pyrido[3.2-e]azcpine-7(6//)-thione (10), prepared from the pyridoazepin-7-one 9 with phosphorus pentasulfide in pyridine, is achieved to give 11 in high yield with iodomethane in basic solution.191... 

The 4-phenylbenzodiazepin-l-one 5a is alkylated at N2 by reaction with iodomethane or io-doethane under alkaline conditions to yield derivatives 15.130... 

Alkylation of the anion 2 with iodomethane or other haloalkanes provides alkyldicarbonyl(t/5-cyclopentadienyl)iron complexes such as 53,0 (see also Houben-Weyl, Vol. 13/9a, p 209). Migratory insertion of carbon monoxide occurs on treatment with phosphanes or phosphites9 -11 (see also Houben-Weyl, Vol. d3/9a, p257) to provide chiral iron-acyl complexes such as 6. This is the most commonly used preparation of racemic chiral iron-acyl complexes. 

Most of the above reactions are used for the cleavage of aryl sulphones. Recently, a note has appeared109 in which the use of potassium metal dispersed ultrasonically in toluene to cleave saturated cyclic sulphones is described. Addition of iodomethane permits the isolation of acyclic alkyl methyl sulphones (as outlined in equation (44)). 

The first ruthenium porphyrin alkyls to be reported were prepared from the zerovalent dianion, [Ru(Por)] with iodomethane or iodocthane, giving the ruthe-nium(lV) dialkyl complexes Ru(Por)Me2 or Ru(Por)Et2 (Por = OEP, TTP). Alternatively, the Ru(lV) precursors Ru(Por)X2 react with MeLi or ArLi to produce Ru(Por)Mc2 or Ru(Por)Ar2 (Ar = / -C(,H4X where X = H, Me, OMe, F or Cl) 147-149 The osmium analogues can be prepared by both methods, and Os(Por)R2 where R = Me, Ph and CH2SiMe2 have been reported.Some representative structures are shown in Fig. 5, and the preparation and interconversion of ruthenium porphyrin alkyl and aryl complexes are shown in Scheme 10. 

In addition to methyl iodide the term iodomethane can be used. For purposes of classification the alkyl halides are to be regarded as esters. The halogen does not ionize and its mobility increases in the order chloride, bromide, iodide. 

Highly acidic triply-activated methylene groups are readily alkylated under mildly basic conditions, e.g. dicyanoacetic esters are converted into the quaternary ammonium salts, which give the 2,2-dicyanopropionic esters upon reaction with iodomethane [129]. 

Oxidation of iodoalkanes involves removal of an electron from the halogen nonbonding orbital. The radical-cations of primary and secondary alkyl iodides can be identified in aqueous solution by their absorption spectra and have half-lives of microseconds [1]. They are formed during pulse radiolysis of the iodoalkane in aqueous solution in the presence of nitrous oxide. This system generates hydroxyl radicals, which remove an electron from the iodine atom lone pair. Iodoalkane radical-anions complex with the lone-pair on other heteroatoms to form a lollo three-electron bond. In aqueous solution, the radical-cation of iodomethane is involved in an equlibrium indicated by Equation 2.1. 

All the reactions hitherto described in Section VI have provided 6-substituted products, although it was pointed out that initial attack by an electrophile could involve the electron-rich 1,4-positions. N-Alkylation at the 1,4-positions occurs when N-unsubstituted dihydrodiazepinium salts are treated with iodomethane or iodoethane and potassium carbonate in dimethylformamide (86LA1387). 

Benzylic N-protection (entry 1) is often unsatisfactory since competitive reaction at the exocyclic methylene can occur [84JCS(PI)481 85S302]. As with bis(l-pyrazolyl)methane (Section I1,C,1)(83T4133), the nature of the isolated product is determined by the type of electrophile used, with benzyl halides and, to a certain extent, iodomethane reacting at the A-benzyl carbon atom, whereas most other electrophiles give rise to the normal C-2 alkylated products (90JHC673). This result was interpreted in terms of steric rather than thermodynamic factors, since the two species that reacted at the benzylic carbon required a bulkier pentacoordinate transition state, whereas all of the others were able to react via a lower coordinate species (90JHC673). 

Tertiary benzylic nitriles are useful synthetic intermediates, and have been used for the preparation of amidines, lactones, primary amines, pyridines, aldehydes, carboxylic acids, and esters. The general synthetic pathway to this class of compounds relies on the displacement of an activated benzylic alcohol or benzylic halide with a cyanide source followed by double alkylation under basic conditions. For instance, 2-(2-methoxyphenyl)-2-methylpropionitrile has been prepared by methylation of (2-methoxyphenyl)acetonitrile using sodium amide and iodomethane. In the course of the preparation of a drug candidate, the submitters discovered that the nucleophilic aromatic substitution of aryl fluorides with the anion of a secondary nitrile is an effective method for the preparation of these compounds. The reaction was studied using isobutyronitrile and 2-fluoroanisole. The submitters first showed that KHMDS was the superior base for the process when carried out in either THF or toluene (Table I). For example, they found that the preparation of 2-(2-methoxyphenyl)-2-methylpropionitrile could be accomplished h... 

S,)-4,5-Dihydro-4-isopropyl-2-piperidinooxazole (1), easily available from chiral (5)-2-ethoxy-4,5-dihydro-4-isopropyloxazole and piperidine, can be deprotonated quantitatively by sec-butyllithium/TMEDA in diethyl ether/THF to 2 as is evident from subsequent silylation in high yield to give 3 (R = TMS). Only one single diastereomer could be detected by capillary gas chromatography. The same result was found on alkylation of 2 with iodomethane as electrophile, but the yield of 3 (R = CH3) drops to 30% in this case59. 

Some further examples of stereoselective deprotonation/alkylation reactions of tricarbonyl-chromium complexed (V-methyl tetrahydroisoquinolines have been reported27. Starting with the enantiomerically pure (35)-methyl tetrahydroisoquinoline reaction with hexacarbonyl-chromium led to a mixture of endo- (40%) and exo- (60%) complexes, which were deprotonated with butyllithium and subsequently methylated with iodomethane. In this way methylation occurred firstly at the 4- and secondly at the 1-position. In all cases, the methyl group entered anti to the chromium complexed face. After separation of the alkylated complexes by chromatography and oxidative decomplexation, the enantiomerically pure diastereomers (—)-(l 5,35,47 )-and ( + )-(17 ,35,45)-1,2,3,4-tetrahydro-l,2,3,4-tetramethylisoquinolme were obtained, benzylic amines such as tetrahydroisoquinoline to 2-amino-4,5-dihydrooxazoles. Deprotona... 

Only one example has been reported in which an acyclic amine was alkylated with this method32. Using the oxazoline derivative of Af-methylbenzeneamine, deprotonation, subsequent alkylation with iodomethane at — 78 °C and removal of the oxazoline moiety afforded the 7 -confi-gurated a-methylbenzenamine in high yield (95%) with a selectivity of 64% ee. This value is nearly the same as that obtained on reaction of the tetrahydroisoquinoline derivatives at that temperature. Thus, as in the case of methanimidamides, no conclusions concerning the effectiv-ity of this approach in acyclic stereoselection can be drawn at present. 

The enantiomerically pure l-[(benzyl(dimethyl)silyl)methyl]pyrrolidine, obtained from ben-zyl(chloro)(dimethyl)silane and (5,)-2-(methoxymethyl)pyrrolidine , afforded after deprotonation and subsequent alkylation the diastereomerically pure (by NMR spectroscopy) (a-alkylben-zyl)silanes2. To obtain this high degree of diastereoselectivity, the alkylation had to be performed in the weakly complexing solvent diethyl ether. In THF a diastereomeric ratio of only 3 1 was found with iodomethane as alkylating agent. 

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