With Support-Bound Alkylating Agents

More reactive electrophiles, such as benzyl and allyl halides, as well as a- or 3-halo-carbonyl compounds, react smoothly with amines, often even at room temperature. Support-bound chloro- and bromoacetamides, for instance, react cleanly with a wide range of aliphatic and aromatic amines to yield glycine derivatives (Entries 1-4, Table 10.2 [22-32]). This reaction is usually conducted in DMSO at room temperature (2-12 h), but for sensitive amines DMF or NMP might offer milder reaction conditions (Entry 3, Table 10.2). Higher yields can often be obtained by increasing the reaction temperature and the concentration of the amine. 

Merrifield resin [33-37] and other support-bound benzyl halides [38] have also been used to alkylate amines (Entries 5-10, Table 10.2). Similarly, resin-bound allyl bromides react cleanly with aliphatic or aromatic amines (Entry 16, Table 10.2). Entry 15 in Table 10.2 is a rare example of the N-alkylation of an amine under the conditions 

The Mitsunobu reaction is usually only suitable for the alkylation of negatively charged nucleophiles rather than for the alkylation of amines, and only a few examples of such reactions (mainly intramolecular N-alkylations or N-benzylations) have been reported (Entry 15, Table 10.2). Halides, however, are very efficiently alkylated under Mitsunobu conditions, and it has been found that the treatment of resin-bound ammonium iodides with benzylic alcohols, a phosphine, and an azodicarboxylate leads to clean benzylation of the amine (Entry 9, Table 10.3). Unfortunately, alkylations with aliphatic alcohols do not proceed under these conditions. The latter can, however, also be used to alkylate resin-bound aliphatic amines when (cyanomethyl)-phosphonium iodides [R3P-CH2CN+][r] are used as coupling reagents [62]. These reagents convert aliphatic alcohols into alkyl iodides, which then alkylate the amine (Entry 10, Table 10.3). 

Polystyrene-bound secondary aliphatic amines and /V-alkyl amino acids can be ally-lated by treatment with a diene and an aryl iodide or bromide in the presence of palla-dium(II) acetate (Entry 14, Table 10.3). As the diene, 1,3-, 1,4-, and 1,5-dienes can be used, and, besides aryl halides, heteroaryl bromides have also been successfully used [63], This remarkable reaction is likely to proceed via the formation of an aryl palladium complex, with subsequent insertion of an alkene into the C-Pd bond. The resulting organopalladium compound does not undergo ( -elimination (as in the Heck reaction), but isomerizes to an allyl palladium complex, which reacts with the amine to give the observed allyl amines. 

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The preparation of tertiary amines with the aid of insoluble supports has mostly been performed by 3-elimination of support-bound quaternary ammonium salts or by N-alkylation of secondary amines with support-bound alkylating agents (Figure 3.28). 

Support-bound alkylating agents have been used to N-alkylate pyridines and dihydropyridines (Entries 7 and 8, Table 15.21). Similarly, resin-bound pyridines can be N-alkylated by treatment with a-halo ketones (DMF, 45 °C, 1 h [267]) or other alkylating agents [246]. Polystyrene-bound l-[(alkoxycarbonyl)methyl]pyridinium salts can be prepared by N-alkylating pyridine with immobilized haloacetates (Entry 8, Table 15.21). These pyridinium salts react with acceptor-substituted alkenes to yield cyclopropanes (Section 5.1.3.6). Pyridinium salts have also been prepared by reaction of resin-bound primary amines with /V-(2,4-dinitrophenyl)pyridinium salts [268,269]. 

Table 10.2. Alkylation of amines with support-bound strong alkylating agents.

A patent application describes the synthesis of 2,4-quinazolinediones from either immobilized amine reagents or immobilized isocyanates [206]. Utilizing the amine route (Method A in Scheme 36), an Fmoc-protected amino acid immobilized on Sasrin resin [207] was treated with piperidine to provide the free amine derivative. Reaction of a resin-bound amino acid with 2-carboxymethyl phenyl-isocyanate and cyclization of the resulting urea upon treatment with DBU afforded a support-bound 2,4-quinazolinedione. Treatment of the resin with a reactive alkylating agent in the presence of DBU for 10-48 h at 20-70 °C provided the N -alkylated quinazolinedione. The compounds were released from the resin with TFA/CH2CI2. 

Several different types of linker have been developed that yield amides upon cleavage. These linkers can often also be used to prepare sulfonamides, carbamates, or ureas. There are essentially three different strategies for the release of amides from insoluble supports (a) cleavage of the benzylic C-N bond of resin-bound N-alkyl-N-benzylamides (backbone amide linkers, BAL linkers), (b) nucleophilic cleavage of resin-bound acylating agents with amines, and (c) acylation/debenzylation of resin-bound /V-benzyl-/V,A -dialkylamines. 

Aldehydes and ketones have also been prepared by nucleophilic cleavage of resin-bound O-alkyl hydroxamic acids (Weinreb amides [744]) with lithium aluminum hydride [745] or Grignard reagents (Entries 1 and 2, Table 3.41). Similarly, support-bound thiol esters can be cleaved with Grignard reagents to yield ketones [272], or with reducing agents to yield aldehydes (Entry 3, Table 3.41). Polystyrene-bound sele-nol esters (RCO-Se-Pol) react with alkynyl cuprates to yield alkynyl ketones [746]. 

Illustrative examples of the acylation of support-bound amines with carbodiimides as coupling agents are listed in Table 13.3. Difficulties are usually encountered in the acylation of a-alkylamino acid derivatives (which are significantly less nucleophilic than simple secondary amines Entries 3 and 4) and Al-alkyl (Entries 5 and 6) or iV-aryl anilines. Acylations with haloacetic or related acids containing a leaving group prone to nucleophilic displacement should not be performed with the aid of HOBt and bases because O-alkylation of HOBt by the product occurs readily. 

Trichloroacetimidates are the only type of imino ethers to have found some application in solid-phase synthesis. Trichloroacetimidates can readily be prepared from support-bound alcohols by treatment with trichloroacetonitrile and a base (Entry 6, Table 13.18). Because trichloroacetimidates are good alkylating agents, this reaction offers a convenient alternative for converting support-bound aliphatic alcohols into alkylating agents. Trichloroacetimidates prepared from Wang resin or from hydroxymethyl polystyrene are quite stable and can be stored for several months without decomposition [253],... 

Support-bound indoles can be modified in several ways. N-Alkylation of polystyrene-bound indoles has been achieved by treatment with reactive alkylating agents (Mel, BnBr, BrCH2C02R) in conjunction with NaH or KOrBu as a base in DMF at room temperature (Entries 1 and 2, Table 15.7). The aminomethylation of indole at C-3 proceeds smoothly on cross-linked polystyrene. The resulting (aminomethyl)in-doles are thermally unstable and undergo substitution reactions with various carbon nucleophiles (e.g. cyanide or nitroacetates) at higher temperatures (Entry 4, Table... 

Reissert compounds (l-acyl-l,2-dihydro-2-quinolinecarbonitriles) have been prepared on cross-linked polystyrene and C-alkylated in the presence of strong bases (Entry 8, Table 15.25). Treatment of polystyrene-bound C-alkylated Reissert compounds with KOH leads to the release of isoquinolines into solution (Entry 9, Table 15.25). The reaction of support-bound quinoline- and isoquinoline /Y-oxides with acy-lating agents followed by treatment with electron-rich heteroarenes and enamines has been used to prepare alkylated and arylated derivatives of these heterocycles (Entry 10, Table 15.25 see also Table 15.26). 

The present procedure2 describes the conversion of resin-bound, primary aliphatic amines into isothiocyanates and the conversion of the latter into 3-aminothiophenes. The generation of isothiocyanates is related to known procedures,3 in which amines are first treated with carbon disulfide and the resulting dithiocarba-mates are desulfurized by treatment with a condensing agent (alkyl chloroformates, carbodiimides, lead or mercury salts, etc.). The presence of resin-bound isothiocyanates on the polystyrene support could be qualitatively ascertained by infrared spectroscopy (KBr-pellet strong absorption at 2091 cm-1). 

Hydroxylamines and hydrazines can be acylated on insoluble supports using the same type of acylating agent as is used for the acylation of amines [146-149]. Because of their higher nucleophilicity, hydroxylamines or hydrazines can be acylated more readily than amines, and unreactive acylating agents such as carboxylic esters can sometimes be successfully employed (Table 13.10). Polystyrene-bound O-alkyl hydroxamic acids can be N-alkylated by treatment with reactive alkyl halides and bases such as DBU (Entry 5, Table 13.10). 

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