Synthesis and Investigation of the New Derivatives of Poly(Epichlorohydrin) Containing Energetic Groups

Atabaki, Fariborz; Keshavarz, Mohammad Hossein; Bastam, Naser Noorollahy

doi:10.1002/prep.201700162

Cited by 7 publications

(5 citation statements)

References 47 publications

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“…This change suggests the formation of hydrogen bonding between surface functional groups on MXene nanosheets and -OH groups on BC fragment nanofibers. Additionally, a peak at 1129 cm −1 associated with -C-O-stretching vibrations characteristic of tertiary alcohols provides evidence of exchange of epoxy groups on ECH, confirming the presence of chemical cross-linking in the cryogel structure [44]. It is important to note that the combination of physical and chemical cross-linking mechanisms plays an important role in enhancing the mechanical properties of these cryogels.…”

Section: Physicochemical Characterizationmentioning

confidence: 67%

MXene reinforced microporous bacterial cellulose/sodium alginate dual crosslinked cryogel for bone tissue engineering

Hu,

Cai,

Xia

2024

Biomed. Mater.

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The entangled assembly of bacterial cellulose (BC) nanofibers does not provide a three-dimensional (3D) macroporous structure for cellular infiltration thus hindering its use as a scaffold for bone tissue engineering. In addition, it is difficult to achieve uniform dispersion of bioactive agents in entangled BC nanofibers. To address this, the BC nanofibers were integrated with MXene, a two-dimensional nanomaterial known for its electrical signaling and mechanical strength, along with sodium alginate to form cryogel. The cryogel was fabricated using a cross-linking to enhance its mechanical properties, pores for cellular infilteration. MXene incorporation not only increased water absorption (852% to 1446%) and retention (692% to 973%) ability but also significantly improved the compressive stress (0.85 MPa to 1.43 MPa) and modulus (0.22 MPa to 1.17 MPa) confirming successful MXene reinforcement in cryogel. Biological evaluation revealed that the optimum concentration of MXene increased the cell proliferation and the osteogenic role of fabricated scaffolds was also confirmed through osteogenic gene expressions. The macropores in reconstructed MXene-BC-based cryogel provided ample space for cellular proliferation. The osteogenic role of the scaffold was examined through various gene expressions. The Quantitative polymerase chain reaction (QTPCR) revealed that MXene-loaded scaffolds especially in low concentration, had an obvious osteogenic effect hence concluding that BC can not only be reconstructed into the desired form but osteogenic property can be induced. These findings can open a new way of reconstructing BC into a more optimal structure to overcome its structural limitations and retain its natural bioactivities.

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Section: Physicochemical Characterizationmentioning

confidence: 67%

MXene reinforced microporous bacterial cellulose/sodium alginate dual crosslinked cryogel for bone tissue engineering

Hu,

Cai,

Xia

2024

Biomed. Mater.

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“…Nitrophenyl hydrazine derivatives have broad applications in the fields of medicinal and materials chemistry; they can be used as test reagents for carbonyl groups and as intermediates for the synthesis of pharmaceuticals [5][6][7][8][9].…”

Section: Commentmentioning

confidence: 99%

The crystal structure of 3-chloro-1-hydrazino-2,4,6-trinitrobenzene, C₆H₄ClN₅O₆

Xue

Xiang²,

Wang

et al. 2019

Zeitschrift Für Kristallographie - New Crystal Structures

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“…The polymerization warrants the formation of polymers having a blocktype structural constitution, in which the corresponding type of the hydroxyl-bearing compound serves as central units, epichlorohydrin monomeric units as the side groups and hydroxyls as the terminal groups. The structures of the epichlorohydrin polymers were confirmed by 1 H, 13 C, NMR and IR spectroscopies and gel-permeation chromatography. The level of the molecularweight characteristics of the test compounds was found to be little dependent on the type of the hydroxyl-bearing compound, whereas the viscosity and activation energy of the viscous flow are largely governed by the central block of the polymer.…”

Section: Introductionmentioning

confidence: 97%

“…Полимеризация обеспечивает образование полимеров блочного структурного построения, центральными звеньями которых выступает соответствующий тип гидроксилсодержащего соединения, боковые -мономерные звенья глицидилхлорида, терминальные группы -гидроксильные. Структура эпихлоргидриновых полимеров подтверждена методами 1 Н, 13 С ЯМР-и ИК-спектроскопии, гель-проникающей хроматографией. Установлено, что уровень молекулярно-массовых характеристик исследованных образцов слабо зависит от типа гидроксилсодержащего соединения, в то время как вязкость и энергия активации вязкого течения в значительной степени определяются центральным блоком полимера.…”

unclassified

Evaluation of the Effect of the Central Block Type on Viscosity-Temperature Characteristics of Epichlorohydrin Polymers

Bosov¹,

Суханов²,

Sukhanova³

et al. 2022

Южно-Сибирский Научный Вестник

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Методом ротационной вискозиметрии исследовано влияние типа центрального блока на вязкостно-температурные характеристики эпихлоргидриновых полимеров. Объекты исследования синтезированы методом катионной полимеризации эпихлоргидрина с использованием в качестве инициаторов гидроксилсодержащих соединений различного типа, отличающихся длиной углеродного скелета, строением, химической природой и функциональностью по гидроксилам. Полимеризация обеспечивает образование полимеров блочного структурного построения, центральными звеньями которых выступает соответствующий тип гидроксилсодержащего соединения, боковые – мономерные звенья глицидилхлорида, терминальные группы – гидроксильные. Структура эпихлоргидриновых полимеров подтверждена методами 1Н, 13С ЯМР- и ИК-спектроскопии, гель-проникающей хроматографией. Установлено, что уровень молекулярно-массовых характеристик исследованных образцов слабо зависит от типа гидроксилсодержащего соединения, в то время как вязкость и энергия активации вязкого течения в значительной степени определяются центральным блоком полимера. Показана возможность целенаправленного регулирования вязкостно-температурных характеристик путем использования различного типа инициатора (гидроксилсодержащего соединения) в процессе получения эпихлоргидриновых полимеров, являющихся привлекательными стартовыми макромолекулами для получения новых функциональных полимерных материалов. Here, we examined how the central block type influences the viscosity-temperature characteristics of epichlorohydrin polymers by the rotational viscometry method. The substrates for the study were synthesized by cationic polymerization of epichlorohydrin using hydroxyl-bearing compounds of different type as the initiators distinct in the carbon skeleton length, structure, chemical nature and functionality with respect to hydroxyls. The polymerization warrants the formation of polymers having a block-type structural constitution, in which the corresponding type of the hydroxyl-bearing compound serves as central units, epichlorohydrin monomeric units as the side groups and hydroxyls as the terminal groups. The structures of the epichlorohydrin polymers were confirmed by 1H, 13C, NMR and IR spectroscopies and gel-permeation chromatography. The level of the molecular-weight characteristics of the test compounds was found to be little dependent on the type of the hydroxyl-bearing compound, whereas the viscosity and activation energy of the viscous flow are largely governed by the central block of the polymer. We showed herein that the targeted control of the viscosity-temperature characteristics is possible through the use of a different-type initiator (hydroxyl-bearing compound) in the synthesis of epichlorohydrin polymers that are attractive starting macromolecules for the preparation of new functional polymeric materials.

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Synthesis and Investigation of the New Derivatives of Poly(Epichlorohydrin) Containing Energetic Groups

Cited by 7 publications

References 47 publications

MXene reinforced microporous bacterial cellulose/sodium alginate dual crosslinked cryogel for bone tissue engineering

MXene reinforced microporous bacterial cellulose/sodium alginate dual crosslinked cryogel for bone tissue engineering

The crystal structure of 3-chloro-1-hydrazino-2,4,6-trinitrobenzene, C₆H₄ClN₅O₆

Evaluation of the Effect of the Central Block Type on Viscosity-Temperature Characteristics of Epichlorohydrin Polymers

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Synthesis and Investigation of the New Derivatives of Poly(Epichlorohydrin) Containing Energetic Groups

Cited by 7 publications

References 47 publications

MXene reinforced microporous bacterial cellulose/sodium alginate dual crosslinked cryogel for bone tissue engineering

MXene reinforced microporous bacterial cellulose/sodium alginate dual crosslinked cryogel for bone tissue engineering

The crystal structure of 3-chloro-1-hydrazino-2,4,6-trinitrobenzene, C6H4ClN5O6

Evaluation of the Effect of the Central Block Type on Viscosity-Temperature Characteristics of Epichlorohydrin Polymers

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The crystal structure of 3-chloro-1-hydrazino-2,4,6-trinitrobenzene, C₆H₄ClN₅O₆