Detection and Amplification of Chirality by Helical Polymers

Yashima, Eiji; Maeda, Katsuhiro; Nishimura, Tatsuya

doi:10.1002/chem.200305295

Cited by 531 publications

(312 citation statements)

References 85 publications

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“…89 Recently there are fairly many examples of helical substituted polyacetylenes; for example, induced helices based on the combinations of poly(p-carboxyphenylacetylene) and its analogues with low molecular weight compounds, 29,90 helical poly(p-alkoxy-m,m-dihydroxyphenylacetylene) synthesized by using chiral Rh catalyst systems, 28,91 and poly(menthyl/chiral alkyl propiolates). 92,93 The most salient feature of helical poly(Npropargylamides) developed by us is that the helix is mainly induced by the intramolecular hydrogen bonding between amide groups in the side chain.…”

Section: Helical Structurementioning

confidence: 99%

“…See other reviews as well for photoelectronic functions and liquid crystalline properties of substituted polyacetylenes. 11,19,20,[26][27][28][29] Gas-Permeable Membranes Because of energy saving and environmental issues, the development of separation membranes is now an important subject in industries and our society. 24,103 In fact, various water-purification membranes are now practically utilized on a large scale, and gas separation membranes are also becoming more important.…”

Section: Functions Of Substituted Polyacetylenesmentioning

confidence: 99%

“…In particular, poly[(1-trimethylsilyl)-1-propyne] [poly (11)] is famous because it shows the highest gas permeability among all the existing polymers, and hence its gas permeability has been extensively studied so far. [22][23][24][25] The photoelectronic properties 11,19,20,[26][27][28] and helical structures [27][28][29][30] of substituted polyacetylenes have also been studied considerably.…”

Section: Introductionmentioning

confidence: 99%

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Substituted polyacetylenes

Masuda

2006

J. Polym. Sci. A Polym. Chem.

386

221

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This article reviews the chemistry of substituted polyacetylenes developed by our research group, more specifically, development of polymerization catalyst, synthesis of new polymers, elucidation of their structure, investigation of their properties, and development of their functions. The main features are as follows: a number of catalysts based on group 5, 6, and 9 transition metals (Nb, Ta, Mo, W, and Rh) have been developed, which include living polymerization catalysts. By using these catalysts, many new substituted polyacetylenes have been synthesized, whose molecular weights are very high (Mw = 104−106). Most of the polymers are soluble in many common solvents and stable enough in the air unlike polyacetylene. Some of these polymers exhibit interesting functions including high gas permeability and photoelectronic properties. © 2006 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 45: 165–180, 2007

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Section: Helical Structurementioning

confidence: 99%

Section: Functions Of Substituted Polyacetylenesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Substituted polyacetylenes

Masuda

2006

J. Polym. Sci. A Polym. Chem.

386

221

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“…M olecular helices are one of the major structural motifs of natural and synthetic polymers and oligomers (1)(2)(3)(4)(5)(6)(7). A fundamental property of a molecular helix is the average length over which it keeps its right-handed (P) or left-handed (M) integrity: the length over which neither uncoiling nor reversal of helix handedness occurs.…”

mentioning

confidence: 99%

“…A fundamental property of a molecular helix is the average length over which it keeps its right-handed (P) or left-handed (M) integrity: the length over which neither uncoiling nor reversal of helix handedness occurs. This parameter is important in structural biology because it reflects the stability of, for example, ␣-helical peptides; it is also important in material science because it determines the limit of chiral amplification that a given helical polymeric chain may reach (1,6). Helical integrity may also be useful to remotely control the stereochemistry of a reaction (8).…”

mentioning

confidence: 99%

Probing helix propensity of monomers within a helical oligomer

Dolain

Léger

Delsuc

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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A simple strategy is proposed to assess the propensity of a given monomer to follow or not follow a particular helical scheme and to study helix reversal phenomena within helical oligomers. It consists of placing a monomer having a low helix propensity between two conformationally stable helical segments. Helix reversion then occurs preferentially at the site of this monomer, leading to the formation of isomers having P (right-handed) or M (left-handed) helicities at each of the two helical segments. The proportion between the P-P͞M-M and P-M isomers is indicative of the stereochemical relations between the inserted monomer and the helical frame. Thus, xylylene or carboxylic acid anhydride spacers have been introduced between two helical oligoamides of 8-amino-2-quinolinecarboxylic acid. Both these spacers presumably lack some of the structural features that confer quinoline units with a high helix propensity. Only one species is observed in solution in the case of an anhydride spacer. This species was shown by x-ray crystallography to be a racemic mixture of P-P and M-M helices. Unexpectedly, the anhydride is consistently incorporated within helical oligoamides. For the xylylene spacer, the P-P͞M-M racemate and P-M meso compound are in equal proportions in chloroform, showing that this spacer does not have a propensity to adopt any helical conformation in this solvent. However, the equilibria between the various isomers are shifted in toluene, where one species largely prevails. This species was shown by x-ray crystallography to be the P-P͞M-M racemate. Molecular dynamics simulations are consistent with these solution data.conformation analysis ͉ folding ͉ helices M olecular helices are one of the major structural motifs of natural and synthetic polymers and oligomers (1-7). A fundamental property of a molecular helix is the average length over which it keeps its right-handed (P) or left-handed (M) integrity: the length over which neither uncoiling nor reversal of helix handedness occurs. This parameter is important in structural biology because it reflects the stability of, for example, ␣-helical peptides; it is also important in material science because it determines the limit of chiral amplification that a given helical polymeric chain may reach (1, 6). Helical integrity may also be useful to remotely control the stereochemistry of a reaction (8). For example, in a helical polymer, a single chiral residue may induce a local conformational preference for a particular handedness. This local preference is propagated and amplified by the helical integrity of the polymer until a partial uncoiling or helix reversal occurs. The average length over which a helix handedness keeps its integrity is determined by a combination of local conformational preferences in the helix backbone as well as intramolecular and solvent-driven interactions that define the helix propensity associated with the monomers (1-7). Long-range intermolecular helix-helix interactions and helix bundling have also been shown contribute to helix st...

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Chiral Polymers

Kakuchi¹,

Sakai²

2009

Encyclopedia of Polymer Science and Technology

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A number of chiral polymers are comprehensively described in this paper. The syntheses and characteristic features of various chiral polymers are introduced according to the origin of their chirality. The structure and synthetic methodology of polymers with a configurational chirality are systematically described, which includes enantiomer‐selective polymerization, asymmetric synthesis polymerization, and chirality induction. Helical polymers are described as one of the main issues in this article. Thus, helix‐sense‐selective polymerization, helicity induction, and chiral amplification are discussed in detail. This article also further includes the function and application of chiral polymers involving polymer‐supported chiral catalyst, chiral stationary phase for high‐performance liquid chromatography, a stimulus‐responsive polymer, and a scaffold for constructing three‐dimensionally well‐defined functionality arrays.

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Detection and Amplification of Chirality by Helical Polymers

Cited by 531 publications

References 85 publications

Substituted polyacetylenes

Substituted polyacetylenes

Probing helix propensity of monomers within a helical oligomer

Chiral Polymers

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