Polymer-supported reactions alkylations

A direct synthesis of chiral propargylic alcohols from 1-alkynes and aldehydes in the presence of Zn(OTf)2, EtjN, and (+)-A-methylephedrine has a broad scope. Several new ligands are found suitable for inducing asymmetric addition of R2Zn (mostly diethylzinc) to aldehydes. These include 42, 43, 44, 45, and Other (3-amino alcohols that show desirable features are S-ew-morpholinoisoborneol, which is more stable in air than the dimethylamino analogue, (S)-2-(pyrrolidin-l-yl)-l,2,2-triph-enylethanol, and a polymer-supported A-alkyl-a,a-diphenyl-L-prolinols. A,A-Dibutyl-norephedrine is useful in a solvent-free reaction. ... 

Polymer Supported Reactions. The conversion of alcohols into alkyl chlorides and of acids into acid chlorides by aryl phosphines and carbon tetrachloride proceeds more rapidly when the phosphine is polymer supported. In these reactions the main pathway appears to involve inter-reaction of two phosphorus-containing groups on the same polymer molecule. ... 

In recent years organic chemists have shown considerable interest in polymer-supported reactions. Such reactions have several attractive features one of which is that isolation of the products is simplified because the supported species can easily be filtered off from the non-supported species. This article is concerned with olefin synthesis by phase transfer catalysed polymer-supported Wittig reactions. Two main types are considered, those in which the phosphine is the supported species (see Scheme 1) and those in which the alkyl halide is the supported species (see Scheme 2). An example of the third type in which the carbonyl compound is the supported species is also given ... 

Selenium-based linkers 590 can also be synthesized from polystyrene via lithiation and subsequent addition of dimethyldiselenide to the polymer support. Reaction of bromine gives selenenyl bromide that can be reduced to the lithium selenium resin in the presence of liBH4 that is alkylated subsequently [318]. Other approaches include the addition of former synthesized selenium-containing building blocks to the resin, for example, the hnker systems generated by Elofsson et al. [319] and Nakamura et al. [320,321]. 

Moberg et al. [146] modified further the bis(pyridylamide) ligand described by Trost for the preparation of a polymer-supported pyridylamide (113 in Scheme 60) for the microwave-accelerated molybdenum-catalyzed al-lylic alkylation. TentaGel resin was tested in the presence of high concentrations of reactants and gave, after a 30 min reaction, total conversion in the... 

Another example where PEG played the role of polymeric support, solvent, and PTC was presented by the group of Lamaty [72]. In this study, a Schiff base-proteded glycine was reacted with various electrophiles (RX) under microwave irradiation. No additional solvent was necessary to perform these reactions and the best results were obtained using cesium carbonate as an inorganic base (Scheme 7.64). After alkylation, the corresponding aminoesters were released from the polymer support by transesterification employing methanol in the presence of triethylamine. 

Another metal-catalyzed microwave-assisted transformation performed on a polymer support involves the asymmetric allylic malonate alkylation reaction shown in Scheme 12.4. The rapid molybdenum(0)-catalyzed process involving thermostable chiral ligands proceeded with 99% ee on a solid support. When TentaGel was used as as support, however, the yields after cleavage were low (8-34%) compared with the corresponding solution phase microwave-assisted process (monomode cavity) which generally proceeded in high yields (>85%) [30],... 

In contrast with the reactions involving sulphide or hydrogen sulphide anions, aryl alkyl thioethers and unsymmetrical dialkyl thioethers (Table 4.3) are obtained conveniently by the analogous nucleophilic substitution reactions between haloalkanes and aryl or alkylthiols under mildly basic conditions in the presence of a quaternary ammonium salt [9-15] or polymer-supported quaternary ammonium salt [16]. Dimethyl carbonate is a very effective agent in the formation of methyl thioethers (4.1.4.B) [17]. 

The base-catalysed addition of thiols to Jt-electron-deficient alkenes is an important aspect of synthetic organic chemistry. Particular use of Triton-B, in place of inorganic bases, has been made in the reaction of both aryl and alkyl thiols with 1-acyloxy-l-cyanoethene, which behaves as a formyl anion equivalent in the reaction [1], Tetra-n-butylammonium and benzyltriethylammonium fluoride also catalyse the Michael-type addition of thiols to a,P-unsaturated carbonyl compounds [2], The reaction is usually conducted under homogeneous conditions in telrahydrofuran, 1,2-dimethoxyethane, acetone, or acetonitrile, to produce the thioethers in almost quantitative yields (Table 4.22). Use has also been made of polymer-supported qua-... 

In a manner analogous to that used for the formation of 5-alkyl thioacetates using a polymer-supported quaternary ammonium salt (4.1.31), the dithiocarbamate anion can be 5-alkylated under mild conditions [3]. The corresponding arylation reaction with activated aryl systems requires more vigorous conditions ... 

Alkyl and glycosyl isocyanates and isothiocyanates are produced in good yield under phase-transfer catalytic conditions using either conventional soluble catalysts or polymer-supported catalysts [32, 33]. Acyl isothiocyanates are obtained under similar conditions [34]. A-Aryl phosphoramidates are converted via their reaction with carbon disulphide under basic conditions into the corresponding aryl isothiocyanates, when the reaction is catalysed by tetra-n-butylammonium bromide [35]. 

In the main, the original extractive alkylation procedures of the late 1960s, which used stoichiometric amounts of the quaternary ammonium salt, have now been superseded by solid-liquid phase-transfer catalytic processes [e.g. 9-13]. Combined soliddiquid phase-transfer catalysis and microwave irradiation [e.g. 14-17], or ultrasound [13], reduces reaction times while retaining the high yields. Polymer-supported catalysts have also been used [e.g. 18] and it has been noted that not only are such reactions slower but the order in which the reagents are added is important in order to promote diffusion into the polymer. 

The reductive dehalogenation of haloalkanes has also been achieved in high yield using polymer supported hydridoiron tetracarbonyl anion (Table 11.15). In reactions where the structure of the alkyl group is such that anionic cleavage is not favoured, carbonylation of the intermediate alkyl(hydrido)iron complex produces an aldehyde (see Chapter 8) [3]. 

Chiral benzamides I and the pyrrolobenzodiazepine-5,11-dio-nes n have proven to be effective substrates for asymmetric organic synthesis. Although the scale of reaction in our studies has rarely exceeded the 50 to 60 g range, there is no reason to believe that considerably larger-scale synthesis will be impractical. Applications of the method to more complex aromatic substrates and to the potentially important domain of polymer supported synthesis are currently under study. We also are developing complementary processes that do not depend on a removable chiral auxiliary but rather utilize stereogenic centers from the chiral pool as integral stereodirectors within the substrate for Birch reduction-alkylation. 

Various transition metal catalysts, including those based on Rh, Pt, Pd, Co, and Ti, have been bound to polymer supports—mainly through the phosphenation reaction described by Eq. 9-65 for polystyrene but also including other polymers, such as silica and cellulose, and also through other reactions (e.g., alkylation of titanocene by chloromethylated polystyrene). Transition-metal polymer catalysts have been studied in hydrogenation, hydroformylation, and hydrosilation reactions [Chauvin et al., 1977 Mathur et al., 1980]. 

Undesirable intermolecular reactions can be avoided during certain synthetic conversions. Thus it is often useful to carry out C-alkylation and C-acylation of compounds that form enolate anions, for example, esters with a-hydrogens. Such reactions are often complicated by self-condensation since the enolate anion can attack the carbonyl group of a second ester molecule. Attachment of the enolizable ester to a polymer support at low loading levels allows the alkylation and acylation reactions (Eq. 9-79) to be performed under... 

When the reactions of alkyl bromides (n-Q-Cg) with phenoxide were carried out in the presence of cosolvent catalyst 51 (n = 1 or 2,17 % RS) under triphase conditions without stirring, rates increased with decreased chain length of the alkyl halide 82). The substrate selectivity between 1-bromobutane and 1-bromooctane approached 60-fold. Lesser selectivity was observed for polymer-supported HMPA analogue 44 (5-fold), whereas the selectivity was only 1,4-fold for polymer-supported phosphonium ion catalyst 1. This large substrate selectivity was suggested to arise from differences in the effective concentration of the substrates at the active sites. In practice, absorption data showed that polymer-supported polyethylene glycol) 51 and HMPA analogues 44 absorbed 1-bromobutane in preference to 1-bromooctane (6-7 % excess), while polymer-supported phosphonium ion catalyst 1 absorbed both bromides to nearly the same extent. 

Initial investigations of base-catalyzed imidization of polymeric systems, in particular PMDA/ODA based polyfamic alkyl esters), have been difficult due to the insolubility of the polyimide precursor at imidization levels exceeding 40%. Nevertheless, preliminary studies indicate that the base-catalyzed polymer imidization reaction appears to be significantly slower at ambient temperatures as compared to the phthalamide model compounds. It is yet unclear whether this is a direct result of the conformational aspects associated with the polymer chain or solubility considerations arising from the less soluble, partially imidized polymer chain. Since much of the initial work involved IR studies of supported... 

Xu, W. Mohan, R. Morrissey, M. M. Polymer Supported Bases in Solution-Phase Synthesis. 2. A Convenient Method for /V-Alkylation Reactions of Weakly Acidic Heterocycles, Bioorg. Med. Chem. Lett. 1998, 8, 1089. 

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