Thiolates with aluminum

The addition of alcohols to N-alkylidene selenoamides generated in situ leads to N-alkoxyalkyl selenoamides [84]. The substitution reaction of alkoxy groups of selenoesters [RC(Se)OR ] with aluminum thiolates or selenolates proceeds smoothly to give the corresponding esters [RC(Se)SR, RC(Se)SeR ] [7a, 85], whereas the addition of thiols to selenoaldehydes takes place at the selenium atom to afford selenenesulfides (RCH2SeSR ) [86]. 

Addition of chlorine to the exomethylene moiety in (48) under irradiation followed by dehydrochlorination with DBN gave 3-chloromethyH-oxacephem (75) in 86% yield. Methoxylation of (75), as reported in the previous section, was followed by a substitution reaction at the C-3 position with heterocyclic thiolates, to obtain 3-heterocyclicthiomethyl derivatives (76) in about 90% yield. The side-chain cleavage by the conventional method proceeded with little epimerization at C-7 giving exclusively the 7a-methoxy-7p-amino-l-oxacephem nucleus (77). Acylation with an appropriate acid chloride followed by deprotection with aluminum chloride or stannic chloride in anisole [32] afforded the representative oxacephem antibiotics, latamoxef (11a) [15], flomoxef (11b) [16] and 2355-S (11c) [17] in high yields. 

Treatment of thiiranes with lithium aluminum hydride gives a thiolate ion formed by attack of hydride ion on the least hindered carbon atoms (76RCR25), The mechanism is 5n2, inversion occurring at the site of attack. Polymerization initiated by the thiolate ion is a side reaction and may even be the predominant reaction, e.g. with 2-phenoxymethylthiirane. Use of THF instead of ether as solvent is said to favor polymerization. Tetrahydroborates do not reduce the thiirane ring under mild conditions and can be used to reduce other functional groups in the presence of the episulfide. Sodium in ammonia reduces norbornene episulfide to the exo thiol. 

Like the three-coordinate aluminum and gallium alkoxides, the corresponding thiolates, selenolates, and tellurolates require very bulky substituents at the chalcogen atom to ensure a low metal coordination number. In addition, the steric requirements associated with the preservation of the low coordination number at the metal are increased by the longer M—S and M—Se bond lengths. The ten examples of low-coordinate,... 

The thiolate species (182) and (183) do not require photo excitation in order to initiate polymerization (182) consumes 200 equivalents MMA in 18 h at 35 °C (Mn = 22,000, Mn(calc) = 20,000, Mw/ Mn= 1.12) 446 The propagating species is again believed to be an enolate.447 Propagation is accelerated upon addition of (185), with 100 equivalents of MMA requiring just 90 seconds for full conversion. The steric bulk of the Lewis acid prevents scrambling of the propagating enolate between the two aluminum centers.448 Hence, for aluminum diphenolates, ortho substitution is essential, whilst smaller Lewis acids such as Me3Al may only be used successfully at low temperatures, e.g., —40 °C. 

In the general context of donor/acceptor formulation, the carbonyl derivatives (especially ketones) are utilized as electron acceptors in a wide variety of reactions such as additions with Grignard reagents, alkyl metals, enolates (aldol condensation), hydroxide (Cannizzaro reaction), alkoxides (Meerwein-Pondorff-Verley reduction), thiolates, phenolates, etc. reduction to alcohols with lithium aluminum hydride, sodium borohydride, trialkyltin hydrides, etc. and cyloadditions with electron-rich olefins (Paterno-Buchi reaction), acetylenes, and dienes.46... 

In the past, several aluminum-alkyl, halide, and alkoxide complexes supported by multidentate ligands were examined for their catalytic lactide polymerization activities. To this end, monomeric aluminum complexes 148a, b (Fig. 21) were synthesized in our laboratory for producing polyesters with thiolate end groups [137]. These complexes initiated polymerizations under reflux condition in toluene and xylene forming PLAs with narrow molecular weight distributions (PDIs 1.15-1.25). 

Some strategies used for the preparation of support-bound thiols are listed in Table 8.1. Oxidative thiolation of lithiated polystyrene has been used to prepare polymeric thiophenol (Entry 1, Table 8.1). Polystyrene functionalized with 2-mercaptoethyl groups has been prepared by radical addition of thioacetic acid to cross-linked vinyl-polystyrene followed by hydrolysis of the intermediate thiol ester (Entry 2, Table 8.1). A more controllable introduction of thiol groups, suitable also for the selective transformation of support-bound substrates, is based on nucleophilic substitution with thiourea or potassium thioacetate. The resulting isothiouronium salts and thiol acetates can be saponified, preferably under reductive conditions, to yield thiols (Table 8.1). Thiol acetates have been saponified on insoluble supports with mercaptoethanol [1], propylamine [2], lithium aluminum hydride [3], sodium or lithium borohydride, alcoholates, or hydrochloric acid (Table 8.1). 

Another common trapping method is an intramolecular aldol reaction of the initially formed anion, as shown in equation (91) and Schemes 53 and 54.% In the first case, an aldol-like trapping of the iminium salt produced (411 equation 91 ).96b The initial heteronucleophile in the other two cases is ultimately lost from the product by oxidation and elimination, so that the overall process is C—C bond formation at the a-center of an enone. Thus, treatment of the formyl enone (412 Scheme 53) with an aluminum thiolate afforded in 60% yield the trapped product (413) which could be oxidized and eliminated to give (414).96c Addition of the corresponding aluminate species to the ketoacrylate (415 Scheme 54) produced only one diastereomer of the aldol product (416) which was converted into the alkene (417) in excellent yield.96 1... 

Acylation of a simple thiol with an alkyl carboxylate is not a very suitable method for preparation of S-alkyl thiocarboxylates. Transesterification is, however, possible if either the thiol or the carboxylic ester is activated. The enhanced reactivity of boron, aluminum and silicon thiolates has been utilized for the synthesis of a large variety of thiocarboxylic S-esters, including hydroxy derivatives (from lactones). a,P-Unsaturated thiol esters, e.g. cinnamoyl or 2-butenoyl derivatives, are also accessible. Michael addition, an undesirable side reaction of thiols, is completely avoided if alkyl trimethylsilyl sulfides ortris(arylthio)boranes are applied. ... 

There are remarkably few transformations of esters to thioesters. The use of bis(dimethylaluminum) thiolates produced an unoptimized 50% yield of 10b but was unattractive since the reagent required a separate preparation and it partially reacted with the aryl nitrile [53], Nor did simply mixing propyl mercaptan with 9 under enzymatic resolution conditions provide any equilibrium between 9 and 10b that might have allowed a dynamic resolution. The problem was ultimately solved by the use of silylated thiols and aluminum chloride (Fig. 9). 

Alkyl-2-cyclohexenones. The alkylation of 2-cyclohexenone can be initiated by conjugate addition and trapping of the aluminum enolate with an aldehyde. Regeneration of the double bond and removal of the hydroxyl group are accomplished by mesylation. Actually, the liberated thiolate displaces the allylic mesylate in the process thus the final operation involves desulfurization with Raney nickel. 

Few thiolate derivatives of beryllium are known. Di(t-butylthio)tii-beryllium tetra-t-butoxide, (<-BuS)2Be3(OBu-r)4, has been obtained from dichlorotriberyllium tetra-t-butoxide, Cl2Be3(OBu-04, and lithium butane-thiolate . Other beryllium thiolates are prepared by reaction of a thiol with dialkylberyllium or dialkyneberyllium and do not involve a thiolate anion as an intermediate Various other compounds such as thio-magnesium alkyls " and dimethyl(methylthio)aluminum are obtained analogously. 

Organoaluminum compounds also undergo insertion reaction with isocyanates. For example, aluminum trialkyls react with alkyl and aryl isocyanates to give carboxylic acid amides after hydrolysis . Alkyl aluminum chlorides react similarly . Aluminium trichloride also forms insertion products with isocyanates Diethylaluminum ethyl thiolate or dimethylamide react with equimolar amounts of alkyl or aryl isocyanates to give the expected insertion products 274. ... 

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