Synthesis and Study of Molecular Assemblies Formed by 4,6-<i>O</i>-(2-Phenylethylidene)-Functionalized <scp>d</scp>-Glucosamine Derivatives

Chen, Anji; Adhikari, Surya; Mays, Kellie; Wang, Guijun

doi:10.1021/acs.langmuir.7b01592

Cited by 17 publications

(37 citation statements)

References 39 publications

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“…d -glucosamine has also been used as a natural resource by Chen et al [70] for preparation of several 4,6- O -benzylidene- and alkylidene-protected amides, and their corresponding urea analogs ( 8 and 9 , Figure 7). These could gelate toluene, EtOH, iPrOH, ethylene glycol, and aqua-organic solvents.…”

Section: Carbohydrate Derived Low Molecular Weight Gelatorsmentioning

confidence: 99%

“…Of the 4,6- O -benzylidene/alkylidene protected glucosamine derivatives ( 8 and 9 , Figure 7), Chen et al tested one gel in DMSO/H 2 O, formed by the 4,6- O -alkylidene protected amide containing cyclohexoyl group on the nitrogen atom ( 8 with R = C 6 H 13 ), for drug encapsulation and sustained release of chloramphenicol; the gelator concentration and gel strength have a large effect on the sustained release of the drug [70].…”

Section: Applicationsmentioning

confidence: 99%

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Carbohydrate Derived Organogelators and the Corresponding Functional Gels Developed in Recent Time

Basu¹,

Chakraborty

Ghosh

2018

Gels

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Owing to their multifarious applicability, studies of molecular and supramolecular gelators and their corresponding gels have gained momentum, particularly in the last two decades. Hydrophobic-hydrophilic balance, different solvent parameters, gelator-gelator and gelator-solvent interactions, including different noncovalent intermolecular interactive forces like H-bonding, ionic interactions, π-π interactions, van der Waals interactions, etc., cause the supramolecular gel assembly of micro and nano scales with different types of morphologies, depending on the gelator, solvent, and condition of gelation. These gel structures can be utilized for making template inorganic superstructures for potential application in separation, generation of nanocomposite materials, and other applications like self-healing, controlled drug encapsulation, release and delivery, as structuring agents, oil-spill recovery, for preparation of semi-conducting fabrics, and in many other fields. Sugars, being easily available, inexpensive, and nontoxic natural resources with multi functionality and well-defined chirality are attractive starting materials for the preparation of sugar-based gelators. This review will focus on compilation of sugar derived organogelators and the corresponding gels, along with the potential applications that have been

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Section: Carbohydrate Derived Low Molecular Weight Gelatorsmentioning

confidence: 99%

Section: Applicationsmentioning

confidence: 99%

Carbohydrate Derived Organogelators and the Corresponding Functional Gels Developed in Recent Time

Basu¹,

Chakraborty

Ghosh

2018

Gels

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“…Several free -OH containing or partially protected monoand oligosaccharides as well as the fully unprotected N-Fmoca,b-d-glucosamine have been shownt of orm hydrogels. [2,[17][18][19][20][21] An ovel class of supramolecular hydrogelsw as thus established, wheret he self-association of hydrophobic( aromatic) and hydrophilic (free -OH) molecularf ragments make up the amphiphilic system in which CH-p interactions were proposed to take over the role of more conventional p-p stacking and hydrogen-bond driven associations. [17] High-resolution NMR and X-ray crystallographic data wouldhave been needed, however,t oe laborate this promisingc oncept further.…”

Section: Introductionmentioning

confidence: 99%

Configuration‐Controlled Crystal and/or Gel Formation of Protected d‐Glucosamines Supported by Promiscuous Interaction Surfaces and a Conformationally Heterogeneous Solution State

Kapros

Balázs

Harmat

et al. 2020

Chemistry A European J

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The configuration‐dependent self‐association mode of the two anomers of O‐Ac,N‐Fmoc‐d‐glucosamine, a foldamer building block, leading to gel and/or single crystal formation is described. The β‐anomer of the sugar amino acid (2) forms a gel from various solvents (confirmed by SEM, rheology measurements, NMR, and ECD spectroscopy), whereas the α‐anomer (1) does not form a gel with any solvent tested. Transition from the solution state to a gel is coupled to a concurrent shift of the Fmoc‐groups: from a freely rotating (almost symmetrical) to a specific, asymmetric orientation. Whereas the crystal structure of the α‐anomer is built as an evenly packed 3D system, the β‐anomer forms a looser superstructure of well‐packed 2D layers. Modeling indicates that in the lowest energy, but scarcely sampled conformer of the β‐anomer, the Fmoc‐group bends above the sugar moiety, stabilized by intramolecular CH↔π interactions between the aromatic rings. It is concluded that possessing an extended and promiscuous interaction surface and a conformationally heterogeneous solution state are among the basic requirements of gel formation for a candidate molecule.

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“…Low molecular weight organogelators (LMWOs or LMOGs) are small molecules designed to form supramolecular networks on addition to oil, turning the oil into a solid gel. [1][2][3][4][5] Once gelled, the oil can then be more easily removed. This makes LMWOs of great interest in the clean-up of marine oil and fuel spills, especially close to the shoreline or on bodies of inland water.…”

mentioning

confidence: 99%

“…These urea-based LMWOs have been widely characterised and explored. [1][2][3][4] The choice of nucleophilic "tail" (amine) is critical in order to impart solubility to the LMWO whilst still allowing the self-assembled structure to form. Previously, we have demonstrated a selection of p, m and o-tolyl isocyanates forming stable oil binding gels in sea water.…”

mentioning

confidence: 99%

In situ formation of low molecular weight organogelators for slick solidification

et al. 2020

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Synthesis and Study of Molecular Assemblies Formed by 4,6-O-(2-Phenylethylidene)-Functionalized d-Glucosamine Derivatives

Cited by 17 publications

References 39 publications

Carbohydrate Derived Organogelators and the Corresponding Functional Gels Developed in Recent Time

Carbohydrate Derived Organogelators and the Corresponding Functional Gels Developed in Recent Time

Configuration‐Controlled Crystal and/or Gel Formation of Protected d‐Glucosamines Supported by Promiscuous Interaction Surfaces and a Conformationally Heterogeneous Solution State

In situ formation of low molecular weight organogelators for slick solidification

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