Helical Polymers: Synthesis, Structures, and Functions

Yashima, Eiji; Maeda, Katsuhiro; Iida, Hiroki; Furusho, Yoshio; Nagai, Kanji

doi:10.1021/cr900162q

Cited by 1,492 publications

(1,084 citation statements)

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“…A chiral modifier, chemically compatible with the host system, is often employed to imprint an achiral mesophase with a well-defined handedness 11 . For instance, on using a chiral mesogenic molecule as a dopant, a nematic liquid crystal phase will convert into a chiral nematic or cholesteric phase, in which the average molecular orientation develops a spatially organized helical arrangement, with a characteristic pitch and twist sign, which depend on subtle non-covalent interactions between the modifier and the host system 12 .…”

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Stirring competes with chemical induction in chiral selection of soft matter aggregates

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Stirring competes with chemical induction in chiral selection of soft matter aggregates

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“…If the chiral group is relatively small compared with the helix, we can shift the equilibrium while keeping the P and M helices as the approximate mirror image of each other. This is the basic concept of the dynamic helicity control, which has been used to obtain one-handed forms of various dynamic helical structures such as metal helicates and helical polymers [16,17]. Since the P and M forms are in dynamic equilibrium, we can change the P/M equilibrium ratio by the addition/removal or modification of the chiral auxiliary.…”

Section: Helicity Control Of Dynamic Helical Structuresmentioning

confidence: 99%

Dynamic Helicity Control of Oligo(salamo)-Based Metal Helicates

Akine

2018

Inorganics

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Much attention has recently focused on helical structures that can change their helicity in response to external stimuli. The requirements for the invertible helical structures are a dynamic feature and well-defined structures. In this context, helical metal complexes with a labile coordination sphere have a great advantage. There are several types of dynamic helicity controls, including the responsive helicity inversion. In this review article, dynamic helical structures based on oligo(salamo) metal complexes are described as one of the possible designs. The introduction of chiral carboxylate ions into Zn 3 La tetranuclear structures as an additive is effective to control the P/M ratio of the helix. The dynamic helicity inversion can be achieved by chemical modification, such as protonation/deprotonation or desilylation with fluoride ion. When (S)-2-hydroxypropyl groups are introduced into the oligo(salamo) ligand, the helicity of the resultant complexes is sensitively influenced by the metal ions. The replacement of the metal ions based on the affinity trend resulted in a sequential multistep helicity inversion. Chiral salen derivatives are also effective to bias the helicity; by incorporating the gauche/anti transformation of a 1,2-disubstituted ethylene unit, a fully predictable helicity inversion system was achieved, in which the helicity can be controlled by the molecular lengths of the diammonium guests.

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“…[1][2][3] Although a large number of singlestranded helical polymers and oligomers have been reported, [2][3][4][5][6][7][8][9][10][11][12] examples of double-stranded helical polymers and oligomers remain relatively scarce. 2,3,8,9,[13][14][15][16][17][18][19][20][21][22] We have recently reported on the rational design and synthesis of a series of complementary double-stranded helical oligomers [23][24][25][26][27][28] with an optical activity that consists of a crescent-shaped m-terphenyl-based backbone containing amidine and carboxylic acid groups. In our design, the formation of the intertwined duplex is driven by the formation of an amidiniumcarboxylate salt bridge, and the helicity of the duplexes can be readily controlled by the introduction of chiral substituents on the nitrogen atoms of the amidine residues.…”

Section: Introductionmentioning

confidence: 99%

“…9,15,18,19 We also reported on mterphenyl-based conjugated polymers, which contain optically active amidine groups (poly-A 1 ) and achiral carboxylic groups (poly-C), that folded into an intertwined double-stranded helical structure through the chiral amidinium-carboxylate salt bridges. 29 In this study, we synthesized a series of m-terphenyl-based random copolymers containing chiral and achiral amidines (poly-A x ) and their complementary homopolymers containing achiral carboxylic acids (poly-C), and investigated the effect of the chiral/achiral amidine contents on the amplification of the helical chirality 30,31 during the complementary double-helix formation ('the sergeants and soldiers effect') 3,4,32,33 (Figure 1) using absorption and circular dichroism (CD) spectroscopies. Such a unique amplification of the helical chirality along the polymer backbones assisted by a small chiral unit has been proven to be applicable to some stiff single-stranded helical polymers 3,7,9,[31][32][33][34][35][36][37][38][39] and supramolecular helical systems.…”

Section: Introductionmentioning

confidence: 99%

“…29 In this study, we synthesized a series of m-terphenyl-based random copolymers containing chiral and achiral amidines (poly-A x ) and their complementary homopolymers containing achiral carboxylic acids (poly-C), and investigated the effect of the chiral/achiral amidine contents on the amplification of the helical chirality 30,31 during the complementary double-helix formation ('the sergeants and soldiers effect') 3,4,32,33 (Figure 1) using absorption and circular dichroism (CD) spectroscopies. Such a unique amplification of the helical chirality along the polymer backbones assisted by a small chiral unit has been proven to be applicable to some stiff single-stranded helical polymers 3,7,9,[31][32][33][34][35][36][37][38][39] and supramolecular helical systems. 30,[40][41][42][43][44] In some artificial double-stranded helical oligomers, an excess of the one-handed helical structure was produced by a small number of chiral units that were introduced into an achiral strand.…”

Section: Introductionmentioning

confidence: 99%

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Chiral amplification in double-stranded helical polymers through chiral and achiral amidinium–carboxylate salt bridges

Makiguchi

Kobayashi

Furusho

et al. 2012

Polym J

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A series of m-terphenyl-based random copolymers of chiral and achiral amidines, and their complementary homopolymers of achiral carboxylic acids were prepared by the copolymerization of a p-diiodobenzene derivative, with the diethynyl monomers containing a chiral or achiral amidine group and a carboxyl group using the Sonogashira coupling reaction. The obtained chiral/achiral amidine copolymers assembled into a double-stranded helical structure upon complexation with the complementary achiral homopolymer of carboxylic acids through interstrand amidiniumÀcarboxylate salt bridges. The complexes exhibited characteristic induced cotton effects in the p-conjugated main-chain chromophore regions, indicating that the interstrand duplexes possess a preferred-handed double-helical structure. The effect of the chiral and achiral amidine contents on the amplification of the helical chirality ('the sergeants and soldiers effect') during the interstrand double-helix formation was investigated by comparing the cotton effect patterns and intensities of the duplexes with those of the corresponding all-chiral amidine-based double-helical polymer. Keywords: amidine; carboxylic acid; chirality; chiral amplification; circular dichroism; double helix INTRODUCTIONThe complementary double-helical structure of DNA is a key structural motif for its vital functions in biological systems, such as replication and the storage of genetic information, which has prompted chemists to develop synthetic double-helical polymers and oligomers (foldamers). [1][2][3] Although a large number of singlestranded helical polymers and oligomers have been reported, 2-12 examples of double-stranded helical polymers and oligomers remain relatively scarce. 2,3,8,9,[13][14][15][16][17][18][19][20][21][22] We have recently reported on the rational design and synthesis of a series of complementary double-stranded helical oligomers [23][24][25][26][27][28] with an optical activity that consists of a crescent-shaped m-terphenyl-based backbone containing amidine and carboxylic acid groups. In our design, the formation of the intertwined duplex is driven by the formation of an amidiniumcarboxylate salt bridge, and the helicity of the duplexes can be readily controlled by the introduction of chiral substituents on the nitrogen atoms of the amidine residues. 9,15,18,19 We also reported on mterphenyl-based conjugated polymers, which contain optically active amidine groups (poly-A 1 ) and achiral carboxylic groups (poly-C), that folded into an intertwined double-stranded helical structure through the chiral amidinium-carboxylate salt bridges. 29 In this study, we synthesized a series of m-terphenyl-based random copolymers containing chiral and achiral amidines (poly-A x ) and

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Helical Polymers: Synthesis, Structures, and Functions

Abstract: Figure 13. Structures of poly(dialkylsilane)s with different main-chain stiffness (74s76) and schematic illustrations of stiffness-dependent polymer wrapping behavior onto SWNT by the high-speed vibration milling (HSVM) method. (Reproduced with permission from ref 133.

Cited by 1,492 publications

References 718 publications

Stirring competes with chemical induction in chiral selection of soft matter aggregates

Stirring competes with chemical induction in chiral selection of soft matter aggregates

Dynamic Helicity Control of Oligo(salamo)-Based Metal Helicates

Chiral amplification in double-stranded helical polymers through chiral and achiral amidinium–carboxylate salt bridges

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