Tetramethyldisiloxane: A Practical Organosilane Reducing Agent

Pesti, Jaan A.; Larson, Gerald L.

doi:10.1021/acs.oprd.6b00124

Cited by 105 publications

(84 citation statements)

References 112 publications

(248 reference statements)

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“…This fact has largely been misunderstood in the peptide chemistry literature. Silicon is metallic in nature and has low electronegativity relative to hydrogen resulting in polarization of the Si―H bond . This polarization causes hydrogen to be hydridic and results in a milder reducing agent than the usual aluminum‐based, boron‐based, and other metal‐based hydrides .…”

Section: Introductionmentioning

confidence: 99%

Reduction of cysteine‐S‐protecting groups by triisopropylsilane

Ste.Marie

Hondal

2018

Journal of Peptide Science

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Triisopropylsilane (TIS), a hindered hydrosilane, has long been utilized as a cation scavenger for the removal of amino acid protecting groups during peptide synthesis. However, its ability to actively remove S-protecting groups by serving as a reductant has largely been mischaracterized by the peptide community. Here, we provide strong evidence that TIS can act as a reducing agent to facilitate the removal of acetamidomethyl (Acm), 4-methoxybenzyl (Mob), and tert-butyl (But) protecting groups from cysteine (Cys) residues in the presence of trifluoroacetic acid (TFA) at 37 °C. The lability of the Cys protecting groups in TFA/TIS (98/2) in this study are in the order: Cys(Mob) > Cys(Acm) > Cys(But), with Cys(Mob) being especially labile. Unexpectedly, we found that TIS promoted disulfide formation in addition to aiding in the removal of the protecting group. Our results raise the possibility of using TIS in orthogonal deprotection strategies of Cys-protecting groups following peptide synthesis as TIS can be viewed as a potential deprotection agent instead of merely a scavenger in deprotection cocktails based on our results. We also tested other common scavengers under these reaction conditions and found that thioanisole and triethylsilane were similarly effective as TIS in enhancing deprotection and catalyzing disulfide formation. Our findings reported herein show that careful consideration should be given to the type of scavenger used when it is desirable to preserve the Cys-protecting group. Additional consideration should be given to the concentration of scavenger, temperature of the reaction, and reaction time.

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Section: Introductionmentioning

confidence: 99%

Reduction of cysteine‐S‐protecting groups by triisopropylsilane

Ste.Marie

Hondal

2018

Journal of Peptide Science

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“…The choice of the reaction solvent (THF, toluene or acetonitrile) was done depending on the solubility of the substrates. This work represents the first application of TMDS as a reducing agent in Mn‐mediated reactions . Noteworthy, PMHS and TMDS have been successfully applied in reduction reactions with several Earth abundant metals such as Fe, Ni, Co, and Zn …”

Section: Resultsmentioning

confidence: 99%

“…Thus, replacement of phenylsilane by cheaper and safer silanes is highly desirable. Among commercially available silanes, diphenylsilane (Ph 2 SiH 2 ) and triethylsilane (Et 3 SiH) represent a good choice for a small and medium scale processes, while tetramethyldisiloxane (TMDS) and polymethylhydrosiloxane (PMHS) are the best options for large scale synthesis . Other cheap silanes, such as triethoxysilane present safety problems since can disproportionate partially to SiH 4 , which is a pyrophoric and explosive gas .…”

Section: Resultsmentioning

confidence: 99%

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A Manganese N‐Heterocyclic Carbene Catalyst for Reduction of Sulfoxides with Silanes

et al. 2019

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The first reduction of sulfoxides catalysed by a well‐defined manganese complex is described. A variety of sulfoxides are reduced to the corresponding sulfides in high yields using phenylsilane, diphenylsilane, and the economically feasible 1,1,3,3‐tetramethyldisiloxane (TMDS) as reducing agents in the presence of a Mn‐NHC complex. The reaction is performed under air and without the need of any additive. The involvement of radicals in the catalytic reaction is probed by spin‐trap experiments.

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“…[1] Among them, reduction of carboxamides, commonly mediated by metal hydrides,i so ne of the most frequently used processes that potentially delivers three possible products:a ldehydes,a lcohols,a nd amines (Scheme 1A). In contrast, alcohols or amines could be formed when I fragments through either CÀNo rC ÀOb ond scission, respectively,a nd the resulting aldehydes or imine/iminium intermediates are reduced by the second hydride.Atpresent, the state-of-the-art approaches for reduction of amides to alcohols are catalytic hydrogenation by well-defined pincer complexes,b ased on Ru, Fe,a nd Mn, under ah ighly pressurized H 2 atmosphere, [4] whereas those for the production of amines are facilitated by either hydrosilylation [5] with various metals [6] or organoboranes [7] as catalysts or electrophilic activation of amides with triflic anhydride. In contrast, alcohols or amines could be formed when I fragments through either CÀNo rC ÀOb ond scission, respectively,a nd the resulting aldehydes or imine/iminium intermediates are reduced by the second hydride.Atpresent, the state-of-the-art approaches for reduction of amides to alcohols are catalytic hydrogenation by well-defined pincer complexes,b ased on Ru, Fe,a nd Mn, under ah ighly pressurized H 2 atmosphere, [4] whereas those for the production of amines are facilitated by either hydrosilylation [5] with various metals [6] or organoboranes [7] as catalysts or electrophilic activation of amides with triflic anhydride.…”

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confidence: 99%

Controlled Reduction of Carboxamides to Alcohols or Amines by Zinc Hydrides

et al. 2019

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New protocols for controlled reduction of carboxamides to either alcohols or amines were established using ac ombination of sodium hydride (NaH) and zinc halides (ZnX 2 ). Use of ad ifferent halide on ZnX 2 dictates the selectivity,w herein the NaH-ZnI 2 system delivers alcohols and NaH-ZnCl 2 gives amines.Extensive mechanistic studies by experimental and theoretical approaches imply that polymeric zinc hydride (ZnH 2 ) 1 is responsible for alcohol formation, whereas dimeric zinc chloride hydride (HÀZnÀCl) 2 is the key species for the production of amines.

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Tetramethyldisiloxane: A Practical Organosilane Reducing Agent

Cited by 105 publications

References 112 publications

Reduction of cysteine‐S‐protecting groups by triisopropylsilane

Reduction of cysteine‐S‐protecting groups by triisopropylsilane

A Manganese N‐Heterocyclic Carbene Catalyst for Reduction of Sulfoxides with Silanes

Controlled Reduction of Carboxamides to Alcohols or Amines by Zinc Hydrides

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