Chiral Recognition of Dansyl Derivatives with an Amino Acid-Based Molecular Micelle: A Molecular Dynamics Investigation

Mauro, Garcia; Black, Nathan; Billiot, Eugene; Billiot, Fereshteh; Morris, Kevin; Fang, Yayin

doi:10.4236/ojpc.2021.112004

Cited by 2 publications

(4 citation statements)

References 34 publications

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“…Instead, polymeric micelles have been studied and the interaction between analytes and the micelles could be concluded from modeling data as summarized in [18,19]. Garcia and colleagues investigated the chiral separation mechanisms of the dansyl (Dns) amino acids Dns-Leu, Dns-Nle, Dns-Trp, and Dns-Phe by the polymeric micelle system poly-sodium N-undecanoyl-(l)leucylvalinate (poly-SULV) using MD simulations [183]. The calculated binding free energy values for the interaction of the Dns amino acids with poly-SULV indicated a stronger interaction with the l-enantiomers, which was in agreement with the enantiomer migration order d-> lamino acids.…”

Section: Chiral Micellesmentioning

confidence: 99%

“…An exception was Dns‐ l ‐Phe, which established a single major hydrogen bond in pocket 3 as compared to three in the case of the d ‐enantiomer. However, the lifetime of this hydrogen bond as well as its occupancy was much longer than the three hydrogen bonds formed by the d ‐enantiomer indicating also preferential binding of Dns‐ l ‐Phe by poly‐SULV [183].…”

Section: Chiral Selectorsmentioning

confidence: 99%

“…(A) Spatial orientation of the three binding pockets in the poly‐sodium N ‐undecanoyl‐(L)‐leucylvalinate (poly‐SULV) micelle and (B) highest scoring docked positions of Dns‐ l ‐Leu (blue, top) and Dns‐ d ‐Leu (red, bottom) in binding pockets 1–3. (Reproduced with permission [183], © Scientific Research Publishing 2021).…”

Section: Chiral Selectorsmentioning

confidence: 99%

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Update on chiral recognition mechanisms in separation science

Scriba

2024

J of Separation Science

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The stereospecific analysis of chiral molecules is an important issue in many scientific fields. In separation sciences, this is achieved via the formation of transient diastereomeric complexes between a chiral selector and the selectand enantiomers driven by molecular interactions including electrostatic, ion‐dipole, dipole‐dipole, van der Waals or π‐π interactions as well as hydrogen or halogen bonds depending on the nature of selector and selectand. Nuclear magnetic resonance spectroscopy and molecular modeling methods are currently the most frequently applied techniques to understand the selector‐selectand interactions at a molecular level and to draw conclusions on the chiral separation mechanism. The present short review summarizes some of the recent achievements for the understanding of the chiral recognition of the most important chiral selectors combining separation techniques with molecular modeling and/or spectroscopic techniques dating between 2020 and early 2024. The selectors include polysaccharide derivatives, cyclodextrins, macrocyclic glycopeptides, proteins, donor‐acceptor type selectors, ion‐exchangers, crown ethers, and molecular micelles. The application of chiral ionic liquids and chiral deep eutectic solvents, as well as further selectors, are also briefly addressed. A compilation of all published literature on chiral selectors has not been attempted.

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Section: Chiral Micellesmentioning

confidence: 99%

Section: Chiral Selectorsmentioning

confidence: 99%

Section: Chiral Selectorsmentioning

confidence: 99%

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Update on chiral recognition mechanisms in separation science

Scriba

2024

J of Separation Science

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“…The interactions between biological systems and chiral surfaces typically exhibit a diastereomeric nature between enantiomeric guest molecules and homochiral biological receptors. This characteristic leads to potential diastereomeric energy differences between homochiral vs. heterochiral interactions, L-L vs. L-D for instance [21][22][23]. Such research not only helps us understand chiral response mechanisms but also promotes the applications of the chiral effects in biological systems.…”

Section: Chiral Interface For Controlling the Cell Fatementioning

confidence: 99%

Interface Chirality: From Biological Effects to Biomedical Applications

Guo

Wang

et al. 2023

Molecules

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Chiral surface is a critical mediator that significantly impacts interaction with biological systems on regulating cell behavior. To better understand how the properties of interfacial Chirality affect cell behavior and address the limitations of chiral materials for biomedical applications, in this review, we mainly focus on the recent developments of chiral bio-interfaces for the controllable and accurate guidance of chiral biomedical phenomena. In particular, we will discuss how cells or organisms sense and respond to the chiral stimulus, as well as the chirality mediating cell fate, tissue repair, and organism immune response will be reviewed. In addition, the biological applications of chirality, such as drug delivery, antibacterial, antivirus and antitumor activities, and biological signal detection, will also be reviewed. Finally, the challenges of chiral bio-interfaces for controlling biological response and the further application of interface chirality materials for biomedical will be discussed.

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Chiral Recognition of Dansyl Derivatives with an Amino Acid-Based Molecular Micelle: A Molecular Dynamics Investigation

Cited by 2 publications

References 34 publications

Update on chiral recognition mechanisms in separation science

Update on chiral recognition mechanisms in separation science

Interface Chirality: From Biological Effects to Biomedical Applications

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