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Sulfur-centered

Deall lation. Chloroformates such as vinyl chloroformates (40) are used to dealkylate tertiary amines. Chloroformates are superior to the typical Von Braun reagent, cyanogen bromide, because of increased selectivity producing cleaner products. Other chloroformates such as aHyl, methyl, phenyl, and trichloroethyl have also been used in dealkylation reactions. Although the dealkylation reaction using chloroformates is mostiy carried out on tertiary amines, dealkylation of oxygen or sulfur centers, ie, ethers or thioethers, can also be achieved. a-Chloroethyl chloroformate [50893-53-3] (ACE-Cl) (41,42) is superior to all previously used chloroformates for the dealkylation reaction. ACE-Cl has the advantage that the conditions requked for ACE... [Pg.39]

One of the earliest useful methods for asymmetric opening of meso-epoxides with sulfur-centered nucleophiles was reported by Yamashita and Mukaiyama, who employed a heterogeneous zinc tartrate catalyst (Scheme 7.10) [20]. Epoxides other than cydohexene oxide were not investigated, and the enantioselectivity depended strongly on the identity of the thiol. [Pg.236]

Without question, the most significant advance in the use of sulfur-centered nucleophiles was made by Shibasaki, who discovered that 10 mol% of a novel gallium-lithium-bis(binaphthoxide) complex 5 could catalyze the addition of tert-butylthiol to various cyclic and acyclic meso-epoxides with excellent enantioselectiv-ities and in good yields (Scheme 7.11) [21], This work builds on Shibasaki s broader studies of heterobimetallic complexes, in which dual activation of both the electrophile and the nucleophile is invoked [22]. This method has been applied to an efficient asymmetric synthesis of the prostaglandin core through an oxidation/ elimination sequence (Scheme 7.12). [Pg.236]

Jacobsen demonstrated that the (salen)Cr system used to effect intermolecular, cooperative asymmetric azidolysis of meso-epoxides (Schemes 7.3 and 7.5) could be applied to sulfur-centered nucleophiles (Scheme 7.13). In order to overcome moderate enantioselectivity (<60% ee), a dithiol nucleophile was employed as part of a double resolution strategy in which the minor enantiomer of the monoaddition product reacts preferentially to form the meso- bis-addition product, thereby increasing the ee of the C2-symmetric bis-addition product. Enantiopure 1,2-mer-capto alcohols (>99% ee) were obtained from the meso-epoxide in ca. 50% overall yield by a burdensome (though effective) multistep sequence, [23]. [Pg.236]

The S-S linkage of disulfides and the C-S linkage of certain sulfides can undergo photoinduced homolysis. The low reactivity of the sulfur-centered radicals in addition or abstraction processes means that primary radical termination can be a complication. The disulfides may also be extremely susceptible to transfer to initiator (Ci for 88 is ca 0.5, Sections 6.2.2.2 and 9.3.2). However, these features are used to advantage when the disulfides are used as initiators in the synthesis of tel ec he lies295 or in living radical polymerizations. 96 The most common initiators in this context are the dithiuram disulfides (88) which are both thermal and photochemical initiators. The corresponding monosulfides [e.g. (89)J are thermally stable but can be used as photoinitiators. The chemistry of these initiators is discussed in more detail in Section 9.3.2. [Pg.103]

Certain, Y, Y-dialkyl dithioearbamates [e,g. benzyl A)/V-diethyl dithiocarbamate (14)] and xanthates have been used as photoinitiators. Photodissociation of the C-S bond of these compounds yields a reactive alkyl radical (to initiate polymerization) and a less reactive sulfur-centered radical (to undergo primary-radical termination) as shown in Scheme 9.9.30 41 4 ... [Pg.463]

Gilbert and coworkers18 were able to detect ESR spectra of sulfinyl radicals together with other sulfur-centered radicals during the oxidation of disulfides and thiols with a titanium(III)-peroxide couple reaction mechanisms involving sulfenic acids as intermediates have been discussed. [Pg.1083]

Arai Y., Koizumi T. Synthesis and Asymmetric Diels-Alder Reactions of Chiral. Alpha.,.Beta.-Unsaturated Sulfoxides Bearing a 2-Exo-Hydroxy-lO-Bornyl Group As an Efficient Ligand on the Sulfur Center Rev. Heteroat. Chem. 1992 6 202-217 Keywords allenic sulfoxide, a-sulfinylmaleate, a-sulfinylmaleimide, asymmetric synthesis, chiral unsaturated sulfoxides... [Pg.321]

K.-D. Asmus in Sulfur-Centered Reactive Intermediates in Chemistry and Biology, (C. Chatgilialoglu, K.-D. Asmus, eds.), Plenum Press, New York, 1990, p.l55... [Pg.29]

Redox Systems with Sulfur-Centered Species... [Pg.256]

IRON-SULFUR CENTERS INVOLVED IN PHOTOSYNTHETIC LIGHT REACTIONS... [Pg.335]

IRON-SULFUR CENTERS IN PHOTOSYNTHETIC LIGHT REACTIONS 341... [Pg.341]

Studies (see, e.g., (101)) indicate that photosynthesis originated after the development of respiratory electron transfer pathways (99, 143). The photosynthetic reaction center, in this scenario, would have been created in order to enhance the efficiency of the already existing electron transport chains, that is, by adding a light-driven cycle around the cytochrome be complex. The Rieske protein as the key subunit in cytochrome be complexes would in this picture have contributed the first iron-sulfur center involved in photosynthetic mechanisms (since on the basis of the present data, it seems likely to us that the first photosynthetic RC resembled RCII, i.e., was devoid of iron—sulfur clusters). [Pg.355]

It has always been assumed that these simple proteins act as electron-transfer proteins. This is also a fair conclusion if we take in account that different proteins were isolated in which the Fe(RS)4 center is in association with other non-heme, non-iron-sulfur centers. In these proteins the Fe(RS)4 center may serve as electron donor/ac-ceptor to the catalytic site, as in other iron-sulfur proteins where [2Fe-2S], [3Fe-4S], and [4Fe-4S] clusters are proposed to be involved in the intramolecular electron transfer pathway (see the following examples). [Pg.366]

These enzymes may contain other redox-active sites (iron-sulfur centers, hemes, and/or flavins), either in distinct domains of a single polypeptide or bound in separate subunits. These additional cofactors perform electron transfer from the molybdenum center to an external electron acceptor/donor. [Pg.396]

An important advance on these studies was the possibility of isolating AORs from Fe enriched media with obvious interest for an iron-sulfur center site labeling, with enhanced sensitivity of the Mossbauer studies. The work developed with bacterial systems is advantageous as compared with mammalian systems for isotopic labeling and opens the possibility of a direct measurement of substrate binding. Spectra of the enzyme in oxidized, partially reduced, benzaldehyde-reacted, and fully reduced states were recorded at different temperatures and with variable externally applied magnetic fields (222). In the oxidized enzyme, the clusters are diamag-... [Pg.401]

See other pages where Sulfur-centered is mentioned: [Pg.82]    [Pg.558]    [Pg.718]    [Pg.236]    [Pg.461]    [Pg.605]    [Pg.626]    [Pg.629]    [Pg.634]    [Pg.56]    [Pg.253]    [Pg.256]    [Pg.256]    [Pg.256]    [Pg.256]    [Pg.1]    [Pg.277]    [Pg.336]    [Pg.336]    [Pg.340]    [Pg.391]    [Pg.401]   
See also in sourсe #XX -- [ Pg.433 , Pg.434 , Pg.451 , Pg.457 , Pg.466 , Pg.470 , Pg.472 , Pg.473 ]



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