Functionally Substituted Alkyl Derivatives

6-31G and MP2/6-13G levels) on MCH2CO2M (M=Li or MgX) indicated a 1,3-1,3 -doubly bridged structure was the most stable.Crystal 

The compound, (LiCH2S02Ph.TMED)2, has a flattened chair-like 8-membered ring, involving Li, S and O (with Ph axial and CHg 

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The furoxans with functionally substituted alkyl groups in the 3,4-position have proved to be useful for the synthesis of thiosubstituted furoxanes (Schemes 26 and 27), which can be oxidized to sulfonyl derivatives (Scheme 26) <2001EJM771>. 

Intramolecular alkylation of the amino group has been applied more recently to the synthesis of functionally substituted pyrrolizidine derivatives. For example, Seiwerth and Djokic20 reported the synthesis of 3-substitutedpyrrolizidines. y-Tetrahydrofurylbutyric acid, via... 

An important method for construction of functionalized 3-alkyl substituents involves introduction of a nucleophilic carbon synthon by displacement of an a-substituent. This corresponds to formation of a benzylic bond but the ability of the indole ring to act as an electron donor strongly influences the reaction pattern. Under many conditions displacement takes place by an elimination-addition sequence[l]. Substituents that are normally poor leaving groups, e.g. alkoxy or dialkylamino, exhibit a convenient level of reactivity. Conversely, the 3-(halomethyl)indoles are too reactive to be synthetically useful unless stabilized by a ring EW substituent. 3-(Dimethylaminomethyl)indoles (gramine derivatives) prepared by Mannich reactions or the derived quaternary salts are often the preferred starting material for the nucleophilic substitution reactions. 

Moncrief summarized the work of Cohn and the information in the early literature. As early as 1923, it was known that rupture of the heterocyclic ring, as well as substitution of the imino hydrogen atom, results in the loss of sweetness. Thus, o-carboxybenzenesulfonamide and N-alkyl derivatives of saccharin are tasteless. This loss of sweetness would be expected, as the NH group is the only proton-donor function available in the molecule. 

Meyers lactams are widely used in synthesis of substituted synthons of interest and their functionalization is carried out under strong base conditions giving C-alkyl derivatives. Alkylation of bicyclic lactam 182 with electrophiles (alkyl, allyl, benzyl halides, chlorophosphonate), and a strong base (j-BuLi, LiHMDS, or KHMDS HMDS = hexamethyldisilazide) in THF at — 78 °C gave an endo-exo mixture of products where the major one is the rro/o-compound 183 in good yields. The ratios were determined by H NMR spectroscopy and are usually up to... 

Iodomethyltrialkyltin compounds, R3SnCH2I (from R3SnCl and ICH2ZnI), provide an entry to other functionally substituted organotin compounds. Reaction with nucleophiles such as R10, R1S, R 2N, or R 3P gives further a-substituted derivatives, and carbon nucleophiles can be used to locate the functional groups at more distant positions on the alkyl chain. Some examples are shown in Scheme 3. 

Allenylcobaloximes, e.g. 26, react with bromotrichloromethane, carbon tetrachloride, trichloroacetonitrile, methyl trichloroacetate and bromoform to afford functionalized terminal alkynes in synthetically useful yields (Scheme 11.10). The nature of the products formed in this transformation points to a y-specific attack of polyhaloethyl radicals to the allenyl group, with either a concerted or a stepwise formation of coba-loxime(II) 27 and the substituted alkyne [62, 63]. Cobalt(II) radical 27 abstracts a bromine atom (from BrCCl3) or a chlorine atom (e.g. from C13CCN), which leads to a regeneration of the chain-carrying radical. It is worth mentioning that the reverse reaction, i.e. the addition of alkyl radicals to stannylmethyl-substituted alkynes, has been applied in the synthesis of, e.g., allenyl-substituted thymidine derivatives [64],... 

Effectively, this is another example of the addition of a functional aromatic compound to an alkene, as the Murai reaction, but the mechanism is different. Alkyl substituted pyridine derivatives are interesting molecules for pharmaceutical applications. The a-bond metathesis reaction is typical of early transition metal complexes as we have learnt in Chapter 2. 

The course of the reaction of methyl-substituted benzene derivatives with cesium fluoroxysulfate in acetonitrile at 35-40 C strongly depends on the structure of the molecule. Toluene (16, R1 = R2 = H) and other alkyl-substituted benzenes 16 and 17 are mainly functionalized on the side chain, while 1,3.5-trimethylbenzene (18) gives mainly ring-substituted products 24 however. 1.2.4,5-tetramethylbenzene (19) and hexamethylbenzene again give mainly or exclusively side-chain products.25... 

A functionalized amino acid derivative has been synthesized by alkylation of a heteroatom-substituted Jt-allyl intermediate (Scheme 8E.27) [146], The alkylation of a Schiif base, which forms a 2-aza-7t-allyl intermediate, furnishes the malonate adduct with 85% ee despite the epimerizable nature of the newly generated stereogenic center. 

G. Trebicka, A. Chemoselective N-alkylation of 2-hydroxycarbazole as a model for the synthesis of N-substituted pyrrole derivatives containing acidic functions. Tetrahedron 1995, 51, 5681-5688. 

Addition of dimethylsulfonium methylide (122) to various Michael acceptors (121), followed by alkylation, has been reported to produce functionalized 1-substituted alkenes (124), arising via the unprecedented elimination (123), rather than the usual cyclopropanation products. In silyl substituted substrates, where a facile Peterson-type olefination is possible from the adduct, elimination took place instead. Aryl-substituted Michael acceptors (121 R1 = Ar) underwent a similar olefination to give 1-substituted styrene derivatives with moderate yields along with a side product, which arose by nucleophilic demethylation from the adduct of dimethylsulfonium methylide and arylidene malonates. Hammett studies revealed that selectivity for olefination versus demethylation increases as the aryl substituent becomes more electron deficient.164... 

Tables II to X give the melting points and, where applicable, the optical rotations of the inositols, inososes, inosamines, and quercitols, and of all of their known O-substituted derivatives. Anhydroinositols, although not substitution products in the strict sense, are included, as are the carbonyl-functional derivatives of the inososes. Halogen- and nitro-substituted cyclitols, and the C-methyl-inositols and their derivatives, are not included most of these compounds are referred to in the text. The derivatives are arranged in the following order salts (inosamines) or functional derivatives (inososes), carboxylic esters, borates, nitrates, sulfonic esters, phosphates, glycosides, acetals (and Schiff bases), ethers (and IV-alkyl derivatives), and anhydrides.

Fig. 5.47. Generation of functionalized aryl Grignard compounds through I/Hg exchange alkylation and hydroxy alkylation of the Grignard reagents to yield multiply substituted benzene derivatives.

In 1999 Trost and Schroder reported on the first asymmetric allylic alkylation of nonstabilized ketone enolates of 2-substituted cyclohexanone derivatives, e.g. 2-methyl-1-tetralone (45), by using a catalytic amount of a chiral palladium complex formed from TT-allylpaUadium chloride dimer and the chiral cyclohexyldiamine derivative 47 (equation 14). The addition of tin chloride helped to soften the lithium enolate by transmetala-tion and a slight increase in enantioselectivity and yield for the alkylated product 46 was observed. Besides allyl acetate also linearly substituted or 1,3-dialkyl substituted allylic carbonates functioned well as electrophiles. A variety of cyclohexanones or cyclopen-tanones could be employed as nucleophiles with comparable results . Hon, Dai and coworkers reported comparable results for 45, using ferrocene-modified chiral ligands similar to 47. Their results were comparable to those obtained by Trost. 

An important feature of the Suzuki reaction is that it allows cr/Z Z-alkenyl or alkyl-aryl coupling of fi-a//cy/-9-borabicyclo[3.3.3]nonane derivatives with haloalkenes and haloarenes without concomitant p-hydride elimination. The required organoboranes are obtained by hydroboration of the appropriate alkenes or functionally substituted alkenes with 9-BBN. The coupling reaction tolerates the presence of functional groups in both reaction partners, thus circumventing a requirement of their prior pro-tection. ... 

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