scholarly journals Azulene-based Protecting Groups

2021 ◽  
Author(s):  
◽  
Thomas Bevan

<p>Protecting groups form an indispensable part of modern organic synthetic chemistry. Besides the benefits of selectively passivating certain reactive functionalities, they often provide handling benefits – such as a decrease in the polarity of the compound that facilitates purification, an increase in the structural order of a compound that allows for easier crystallisation, and chromophores that enable easy visualisation on fluorescent TLC plates under UV light.  Coloured protecting groups offer additional advantages in synthetic chemistry. They expedite purification by allowing the material to be tracked visually. Phase separation and column chromatography are easier to perform, and reduce the need for the collection of large numbers of fractions, while small-scale loss of material (left behind on taps or in flasks during routine handling) and spillages are much more readily apparent. Despite these advantages, only a few coloured protecting groups have been reported in the literature.  The azulenes are a class of compounds with several attractive qualities that can be exploited for use as protecting groups. They are coloured, but not overwhelmingly so. The colour is tunable through placement of electron-donating or electron-withdrawing groups at positions on the ring system, which further allows for protection/deprotection reactions to be designed that incorporate a colour change. Azulene itself is both non-polar and structurally compact, unlike many other organic chromophores such as triarylmethane dyes and carotenoids. Furthermore, azulene’s ability to stabilise both positive and negative charges through resonance with tropylium and cyclopentadienide motifs allows for unusual chemistry, and therefore potentially orthogonal modes of deprotection.  Four protecting group candidates incorporating azulene were devised. The 1-azulenylmethylene amine 79 and the 1-azulenesulfonamide 82 protecting group candidates for amines had fatal flaws that were discovered early, such as a tendency to rapidly degrade in open air. The 1-azulenecarboxylate protecting group candidate 74 for alcohols showed some promise, with a high-yielding protection reaction, but none of the deprotection conditions that were developed were sufficiently mild to be usable in a late-stage deprotection strategy on a complex target molecule.  The final protecting group candidate, 6-(2-[oxycarbonyl]ethyl)azulene 89, can be used for the protection of carboxylic acids, amines and alcohols as esters, carbamates and carbonates, respectively. The substitution at the 6-position of azulene allows for deprotection through an E1cB mechanism with mild base, involving a cyclopentadienide-stabilised carbanion intermediate, in a similar fashion to the FMOC protecting group. Mild conditions for the protection of all three were found: for carboxylic acids Steglich esterification is employed, and for alcohols and amines coupling with CDI is used. A selection of mild protocols for deprotection were developed, using bases such as DBU or TBAF, or involving two-step activation-deprotection procedures.  Finally, the compatibility of the protecting group 89 (dubbed Azul) with common and representative procedures in synthetic chemistry was investigated, such as with bases and with reaction conditions such as oxidations, reductions, cross-couplings, etc. Orthogonality with other common protecting groups (such as TBS, MOM, FMOC) was also explored. Some incompatibilities were found with strongly acidic conditions, high-temperature Suzuki cross-coupling reactions and Swern oxidations, but otherwise the Azul protecting group shows promise as a protecting group that expedites total synthesis through its colourful properties.</p>

2021 ◽  
Author(s):  
◽  
Thomas Bevan

<p>Protecting groups form an indispensable part of modern organic synthetic chemistry. Besides the benefits of selectively passivating certain reactive functionalities, they often provide handling benefits – such as a decrease in the polarity of the compound that facilitates purification, an increase in the structural order of a compound that allows for easier crystallisation, and chromophores that enable easy visualisation on fluorescent TLC plates under UV light.  Coloured protecting groups offer additional advantages in synthetic chemistry. They expedite purification by allowing the material to be tracked visually. Phase separation and column chromatography are easier to perform, and reduce the need for the collection of large numbers of fractions, while small-scale loss of material (left behind on taps or in flasks during routine handling) and spillages are much more readily apparent. Despite these advantages, only a few coloured protecting groups have been reported in the literature.  The azulenes are a class of compounds with several attractive qualities that can be exploited for use as protecting groups. They are coloured, but not overwhelmingly so. The colour is tunable through placement of electron-donating or electron-withdrawing groups at positions on the ring system, which further allows for protection/deprotection reactions to be designed that incorporate a colour change. Azulene itself is both non-polar and structurally compact, unlike many other organic chromophores such as triarylmethane dyes and carotenoids. Furthermore, azulene’s ability to stabilise both positive and negative charges through resonance with tropylium and cyclopentadienide motifs allows for unusual chemistry, and therefore potentially orthogonal modes of deprotection.  Four protecting group candidates incorporating azulene were devised. The 1-azulenylmethylene amine 79 and the 1-azulenesulfonamide 82 protecting group candidates for amines had fatal flaws that were discovered early, such as a tendency to rapidly degrade in open air. The 1-azulenecarboxylate protecting group candidate 74 for alcohols showed some promise, with a high-yielding protection reaction, but none of the deprotection conditions that were developed were sufficiently mild to be usable in a late-stage deprotection strategy on a complex target molecule.  The final protecting group candidate, 6-(2-[oxycarbonyl]ethyl)azulene 89, can be used for the protection of carboxylic acids, amines and alcohols as esters, carbamates and carbonates, respectively. The substitution at the 6-position of azulene allows for deprotection through an E1cB mechanism with mild base, involving a cyclopentadienide-stabilised carbanion intermediate, in a similar fashion to the FMOC protecting group. Mild conditions for the protection of all three were found: for carboxylic acids Steglich esterification is employed, and for alcohols and amines coupling with CDI is used. A selection of mild protocols for deprotection were developed, using bases such as DBU or TBAF, or involving two-step activation-deprotection procedures.  Finally, the compatibility of the protecting group 89 (dubbed Azul) with common and representative procedures in synthetic chemistry was investigated, such as with bases and with reaction conditions such as oxidations, reductions, cross-couplings, etc. Orthogonality with other common protecting groups (such as TBS, MOM, FMOC) was also explored. Some incompatibilities were found with strongly acidic conditions, high-temperature Suzuki cross-coupling reactions and Swern oxidations, but otherwise the Azul protecting group shows promise as a protecting group that expedites total synthesis through its colourful properties.</p>


Synthesis ◽  
2020 ◽  
Author(s):  
Ryan Moreira ◽  
Michael Noden ◽  
Scott D. Taylor

AbstractAzido acids are important synthons for the synthesis of complex peptides. As a protecting group, the azide moiety is atom-efficient, easy to install and can be reduced in the presence of many other protecting groups, making it ideal for the synthesis of branched and/or cyclic peptides. α-Azido acids are less bulky than urethane-protected counterparts and react more effectively in coupling reactions of difficult-to-form peptide and ester bonds. Azido acids can also be used to form azoles on complex intermediates. This review covers the synthesis of azido acids and their application to the total synthesis of complex peptide natural products.1 Introduction2 Synthesis of α-Azido Acids2.1 From α-Amino Acids or Esters2.2 Via α-Substitution2.3 Via Electrophilic Azidation2.4 Via Condensation of N-2-Azidoacetyl-4-Phenylthiazolidin- 2-Thi one Enolates with Aldehydes and Acetals2.5 Synthesis of α,β-Unsaturated α-Azido Acids and Esters3 Synthesis of β-Azido Acids3.1 Preparation of Azidoalanine and 3-Azido-2-aminobutanoic Acids3.2 General Approaches to Preparing β-Azido Acids Other Than Azi doalanine­ and AABA4 Azido Acids in Total Synthesis4.1 α-Azido Acids4.2 β-Azido Acids and Azido Acids Containing an Azide on the Side Chain5 Conclusions


1985 ◽  
Vol 63 (4) ◽  
pp. 823-827 ◽  
Author(s):  
Matthias Kamber ◽  
George Just

During the synthesis of γ-lactones bearing a phosphonic acid group at the γ-position, difficulties were encountered generating the free phosphonic acids from corresponding esters. A protecting group used for carboxylic acids was adapted to phosphonic acids, making this transformation easy.


Molecules ◽  
2021 ◽  
Vol 26 (8) ◽  
pp. 2341
Author(s):  
Flavio Cermola ◽  
Serena Vella ◽  
Marina DellaGreca ◽  
Angela Tuzi ◽  
Maria Rosaria Iesce

The synthesis of glycosides and modified nucleosides represents a wide research field in organic chemistry. The classical methodology is based on coupling reactions between a glycosyl donor and an acceptor. An alternative strategy for new C-nucleosides is used in this approach, which consists of modifying a pre-existent furyl aglycone. This approach is applied to obtain novel pyridazine C-nucleosides starting with 2- and 3-(ribofuranosyl)furans. It is based on singlet oxygen [4+2] cycloaddition followed by reduction and hydrazine cyclization under neutral conditions. The mild three-step one-pot procedure leads stereoselectively to novel pyridazine C-nucleosides of pharmacological interest. The use of acetyls as protecting groups provides an elegant direct route to a deprotected new pyridazine C-nucleoside.


2009 ◽  
Vol 43 (1) ◽  
pp. 247-255 ◽  
Author(s):  
Michael F. Tlusty ◽  
Anita Metzler ◽  
Sara Huckabone ◽  
Sutara Suanda ◽  
Saskia Guerrier

2015 ◽  
Vol 112 (39) ◽  
pp. 12026-12029 ◽  
Author(s):  
Yohei Yamashita ◽  
John C. Tellis ◽  
Gary A. Molander

Orthogonal reactivity modes offer substantial opportunities for rapid construction of complex small molecules. However, most strategies for imparting orthogonality to cross-coupling reactions rely on differential protection of reactive sites, greatly reducing both atom and step economies. Reported here is a strategy for orthogonal cross-coupling wherein a mechanistically distinct activation mode for transmetalation of sp3-hybridized organoboron reagents enables C-C bond formation in the presence of various protected and unprotected sp2-hybridized organoborons. This manifold has the potential for broad application, because orthogonality is inherent to the activation mode itself. The diversification potential of this platform is shown in the rapid elaboration of a trifunctional lynchpin through various transition metal-catalyzed processes without nonproductive deprotection or functional group manipulation steps.


ChemInform ◽  
2015 ◽  
Vol 46 (37) ◽  
pp. no-no
Author(s):  
Pengfei Wang ◽  
Wenya Lu ◽  
Dattatray A. Devalankar ◽  
Zhenying Ding

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