Nucleophilic polymers

Di)acyl donor (Di)nucleophile Polymers prepared References... 

This strategy has previously been referred to as t A nucleophilic polymer is a scavenger of solid-supported scavengers (SSS), polymer- electrophiles and vice versa,... 

The simplest examples of this class are the quenching living cationic polymers with living anionic or nucleophilic polymers. Namely, living poly(vi-nyl ethers) derived from the HI/ZnI2 system are allowed to react with living anionic polystyrene with the lithium counterion [115], poly(methyl methacrylate) with a silyl ketene acetal terminal by group transfer po-... 

An interesting example of intra-polymeric catalysis is provided by the effect of polymer side chains on the aminolysis of polymer-bound nitrophenyl ester [41a], as illustrated in Fig. 10. Thus, apparent reactivity of the polymer-bound carbonyl groups is substantially increased by changing the polymer side chains from phenyl to methoxycarbonyl, and to dimethylamide. This type of intra-polymeric catalysis (shown schematically by species 9 in Fig. 11) assumes special significance in crosslinked polymers and solid phase synthesis. An important implication of this catalytic effect for polymer synthesis is that when an activated polymer intermediate (8) is not sufficiently reactive towards a given nucleophile, polymer reactivity can be enhanced by partial aminolysis with dimethyl-amine [25]. 

There are also examples where the non-cross-linked polymeric reagent is most readily available by direct polymerization of suitably functionalized monomers. For example, polymerization of a crown ether which contains styrene units is possible by free radical or anionic methods (15). In the case of anionic oligomerization (Equation 6) or in the case of the metalation shown in Equation 4, the reactive intermediate macromolecule is a nucleophilic polymer which can be derivatized with a variety of electro-... 

Blackburn, R.S., Burkinshaw, S.M., 2(X)3. Treatment of cellulose with cationic, nucleophilic polymers to enable reactive dyeing at neutral pH without electrolyte addition. J. Appl. 

Chitosan is a multi-nucleophilic polymer due to the presence of the NH2 and OH functional groups. The initial sites where substitution occurs are the more nucleophilic amino groups. However, the experimental conditions and protection of the NH2 groups reduces the intermolecular hydrogen bonding and creates space for water molecules to fill in and solvate the hydrophilic groups of the polymer backbone (Sashiwa and Shigemasa 1999). A -alkylated derivatives can be obtained by the treatment of chitosan with aldehydes or ketones via formation of Schiff base intermediates, aldimines (from reactions with aldehydes), or ketimines (from reactions with ketones) followed by reduction of the imine with sodium borohydride. 

A significant impact has been made by resesurchers at Dynapol in the area of polymer bound dyes as nonabsorbable food colorants. The hi molecular weights of the colorants prevent their absorption from the gastrointestinal tract and toxicity problems are avoided. 3 The general procedure for preparing many of these macromolecular dyes is the reaction between a nucleophilic polymer, preferably polyvinylamine, with bromoanthraqulnones,catalyzed by Cu(l). 

When a particle is stabilized by a weak nucleophilic polymer such as polyphosphate, the adsorption of a stronger nucleophile such as T may lead to the detachment of the particle from the polymer chain. Only one experiment has yet been made to study this effect, using stopped flow technique. When a silver sol is mixed with a Nal solution under the conditions of Figure 27, the plasmon band of silver decreases within 0.2 s. The light scattering of the solution was also recorded. As can be seen, it decays within the same time interval. This effect has been attributed to the detachment of the particles from the polymer chain. However, at very much longer times, i.e. in the 100 s range, the... 

As an application of this nucleophilic reactivity, 2-aminothiazole was used to partially convert into amide the polymer obtained from acrylic acid, benzene, and acetic anhydride (271). An aqueous medium is reported to favor the reaction between acetic anhydride and 2-aminothiazole (272). 

The actual process of solid phase peptide synthesis outlined m Figure 27 15 begins with the attachment of the C terminal ammo acid to the chloromethylated polymer m step 1 Nucleophilic substitution by the carboxylate anion of an N Boc protected C terminal... 

Suitable catalysts are /-butylphenylmethyl peracetate and phenylacetjdperoxide or redox catalyst systems consisting of an organic hydroperoxide and an oxidizable sulfoxy compound. One such redox initiator is cumene—hydroperoxide, sulfur dioxide, and a nucleophilic compound, such as water. Sulfoxy compounds are preferred because they incorporate dyeable end groups in the polymer by a chain-transfer mechanism. Common thermally activated initiators, such as BPO and AIBN, are too slow for use in this process. 

The direction of nucleophilic ring opening of unsymmetrical perfluoroepoxides has been shown to be a function of the nature of the nucleophile and the solvent (23,28). Although many oligomeric products have been prepared by this procedure and variations of it, no truly high polymers have been obtained... 

Another commercial appHcation of nucleophilic reactions of nitro-free duoroaromatics is the manufacture of polyetheretherketone (PEEK) high performance polymers from 4,4 -diduoroben2ophenone [345-92-6], and hydroquinone [121-31-9] (131) (see PoLYETHERS, AROMATIC). 

The reaction of a hydroperoxide with 2-methylaziridine [75-55-8] has been described (94). The reaction of ethyleneknine with phenols (95) and carboxyHc acids (96,97) produces ethylamine ethers and esters, respectively. However, these reactions frequentiy yield product mixtures which contain polyaminoalkylated oxygen nucleophiles and polymers, in addition to the desked products (1). The selectivity of the reaction can often be improved by using less than the stoichiometric amount of the aziridine component (98,99). 

The polymerization of ethyleneimine (16,354—357) is started by a catalyticaHy active reagent (H or a Lewis acid), which converts the ethyleneimine into a highly electrophilic initiator molecule. The initiator then reacts with nitrogen nucleophiles, such as the ethyleneimine monomer and the subsequendy formed oligomers, to produce a branched polymer, which contains primary, secondary, and tertiary nitrogen atoms in random ratios. Termination takes place by intramolecular macrocycle formation. 

The very high reactivity of the P—Cl bonds in (4) forms the basis for the now well-known macromolecular substitution method, which has been used to synthesize polymers of types (1) and (2) and some polymers that are hybrids of these and (3). The method involves nucleophilic reactions of (4), and to some extent of its difluoro analogue, with alkoxides or amines. 

Polyetherification is similar to a polycondensation process formation of high molecular weight polymer requires precise adjustment of composition to approximately 1 1 ratio of bisphenol to dihalosulfone. Trace amounts of water gready reduce the molecular weight attainable owing to side reactions that unbalance the stoichiometry (76). The reactivity of the halosulfone is in the order expected for two-step nucleophilic aromatic displacement reactions ... 

I itro-DisplacementPolymerization. The facile nucleophilic displacement of a nitro group on a phthalimide by an oxyanion has been used to prepare polyetherimides by heating bisphenoxides with bisnitrophthalimides (91). For example with 4,4 -dinitro monomers, a polymer with the Ultem backbone is prepared as follows (92). Because of the high reactivity of the nitro phthalimides, the polymerkation can be carried out at temperatures below 75°C. Relative reactivities are nitro compounds over halogens, Ai-aryl imides over A/-alkyl imides, and 3-substituents over 4-substituents. Solvents are usually dipolar aprotic Hquids such as dimethyl sulfoxide, and sometimes an aromatic Hquid is used, in addition. 

In another process for the synthesis of PPS, as well as other poly(arylene sulfide)s and poly(arylene oxide)s, a pentamethylcyclopentadienylmthenium(I) TT-complex is used to activate -dichlorobenzene toward displacement by a variety of nucleophilic comonomers (92). Important facets of this approach, which allow the polymerization to proceed under mild conditions, are the tremendous activation afforded by the TT-coordinated transition-metal group and the improved solubiUty of the resultant organometaUic derivative of PPS. Decomplexation of the organometaUic derivative polymers may, however, be compHcated by precipitation of the polymer after partial decomplexation. 

Reactions of the Disulfide Group. Besides the thiol end groups, the disulfide bonds also have a marked influence on both the chemical and physical properties of the polysulftde polymers. One of the key reactions of disulfides is nucleophilic attack on sulfur (eq. 4). The order of reactivity for various thiophiles has been reported as (C2H O) P > R, HS , C2H5 S- >C,H,S- >C,H,P,... 

The first step in this scheme is a classical aromatic nucleophilic substitution. Details of the method have been expounded (14—17). References 14 and 15 are concerned with the synthesis of the diaryl hahde intermediate whereas References 16 and 17 discuss the synthesis of the polymers, with emphasis on the polymerisation of PPSF by this route. 

Solvent for Displacement Reactions. As the most polar of the common aprotic solvents, DMSO is a favored solvent for displacement reactions because of its high dielectric constant and because anions are less solvated in it (87). Rates for these reactions are sometimes a thousand times faster in DMSO than in alcohols. Suitable nucleophiles include acetyUde ion, alkoxide ion, hydroxide ion, azide ion, carbanions, carboxylate ions, cyanide ion, hahde ions, mercaptide ions, phenoxide ions, nitrite ions, and thiocyanate ions (31). Rates of displacement by amides or amines are also greater in DMSO than in alcohol or aqueous solutions. Dimethyl sulfoxide is used as the reaction solvent in the manufacture of high performance, polyaryl ether polymers by reaction of bis(4,4 -chlorophenyl) sulfone with the disodium salts of dihydroxyphenols, eg, bisphenol A or 4,4 -sulfonylbisphenol (88). These and related reactions are made more economical by efficient recycling of DMSO (89). Nucleophilic displacement of activated aromatic nitro groups with aryloxy anion in DMSO is a versatile and useful reaction for the synthesis of aromatic ethers and polyethers (90). 

Polyurethane Formation. The key to the manufacture of polyurethanes is the unique reactivity of the heterocumulene groups in diisocyanates toward nucleophilic additions. The polarization of the isocyanate group enhances the addition across the carbon—nitrogen double bond, which allows rapid formation of addition polymers from diisocyanates and macroglycols. 

Polymers of high VDC content are reactive toward strong bases to yield elimination products and toward nucleophiles to yield substitution products. Agents capable of functioning as both a base and a nucleophile react with these polymers to generate a mixture of products (119,133,134). 

Aqueous bases or nucleophiles have Httie impact on VDC polymers, primarily because the polymer is not wetted or swollen by water. However, these polymers do slowly degrade in hot concentrated aqueous sodium hydroxide solution (116). 

Metal carboxyiates have been considered as nucleophilic agents capable of removing aHyUc chlorine and thereby affording stabilization (143). Typical PVC stabilizers, eg, tin, lead, or cadmium esters, actually promote the degradation of VDC polymers. The metal cations in these compounds are much too acidic to be used with VDC polymers. An effective carboxylate stabilizer must contain a metal cation sufftcientiy acidic to interact with aHyUc chlorine and to facihtate its displacement by the carboxylate anion, but at the same time not acidic enough to strip chlorine from the polymer main chain (144). 

Micha.elAdditions. The reaction of a bismaleimide with a functional nucleophile (diamine, bisthiol, etc) via the Michael addition reaction converts a BMI building block into a polymer. The non stoichiometric reaction of an aromatic diamine with a bismaleimide was used by Rhc )ne Poulenc to synthesize polyaminobismaleimides as shown in Figure 6 (31). 

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