Preparation and characterization of benzoyl‐hydrazide‐derivatized poly(lactic acid) and <i>γ</i>‐cyclodextrin inclusion complex and its effect on the performance of poly(lactic acid)

Li, Ya; Zhen, Weijun

doi:10.1002/pat.4031

Cited by 11 publications

(6 citation statements)

References 57 publications

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“…Target-pathway and constituent-Pathway frameworks have been assembled to reveal an overview of the interactions between targets and Alzheimer’s disease-related mechanisms. 12 , 36 , 37 …”

Section: Methodsmentioning

confidence: 99%

Identification of phytochemicals from North African plants for treating Alzheimer’s diseases and of their molecular targets by in silico network pharmacology approach

Raafat

2021

Journal of Traditional and Complementary Medicine

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Background The global social expenses of Alzheimer’s disease (AD) have been increased to US$1 trillion due to high cost, side-effects, and low efficiency of the current AD-therapies. Another reason is the lack of preventive drugs and the low-income situation of Asian and African countries. Accordingly, patients rather prefer traditional herbal remedies. Network-pharmacology has been a well-established method for the visualization and the construction of disorder target protein-drug framework. This could aid in the identification of drugs molecular-mechanisms. Aim The aim of this study is to investigate the phytochemical constituents that could target Alzheimer’s disease from the North African plants. This could be done by exploring their possible mechanisms of action through molecular network pharmacology-based approach. Experimental procedure The Phytochemical-compounds of North-African plants (NAP) have been accessed from open-databank. ADME-screening has been conducted for filtering of the NAP phytochemical-constituents utilizing Qikprop-software. The open STITCH databank has been utilized for the prediction of the phytochemical-constituents target-proteins; UniProt and TDD-DB databanks have been utilized for distinguishing AD-related proteins. Phytochemical constituent-target protein (C-T) and plant-phytochemical constituent-target protein (P-C-T) frameworks have been assembled utilizing Cytoscape to interpret the anti-Alzheimer’s disease mechanism of action of the targeted phytochemical constituents. Results The NAP 6842 phytochemical-constituents (from more than 1000 plants) have been exposed to ADME and CNS modulating filtration, generating 94 phytochemical-constituents which have been subjected to target-prediction investigation. The 94 phytochemical-constituents and the 4 AD-identified targets have been associated through 155 edges which formed the main pathways related to AD. Cuparene, alpha-selinene, beta-sesquiphellandrene, calamenene, 2-4-dimethylheptane, undecane, n -tetradecane, hexadecane, nonadecane, n -eicosane, and heneicosane have had C-T network highest combined-score, whilst the proteins MAO-B, HMG-CoA, BACE1, and GCR have been the most enriched ones by comprising the uppermost combined-scores of C-T. Hypericum perforatum, Piper nigrum, Juniperus communis, Levisticum officinale, Origanum vulgare acquired the uppermost number of P-C-Target interactions. Conclusion The phytochemical-targets prediction of NAP utilizing molecular-network pharmacology-based investigation has paved the way for networking multi-target, multi-constituent, and multi-pathway mechanisms. This may introduce potential future targets for the regulation and the management of Alzheimer’s disease. Taxonomy (classification by EVISE) Alzheimer’s disease, Network pharmacology, In-silico com...

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“…Target-pathway and constituent-Pathway frameworks have been assembled to reveal an overview of the interactions between targets and Alzheimer’s disease-related mechanisms. 12 , 36 , 37 …”

Section: Methodsmentioning

confidence: 99%

Identification of phytochemicals from North African plants for treating Alzheimer’s diseases and of their molecular targets by in silico network pharmacology approach

Raafat

2021

Journal of Traditional and Complementary Medicine

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“…β‐CD (5 g) was slowly added to H 2 O (150 ml) and obtained β‐CD solution (5 g β‐CD/150 ml H 2 O). Then, PLA solution was slowly poured into the β‐CD solution under high‐speed shear at 40°C 25 . The mixture liquid was ultrasonically stirred for 5 h and precipitated.…”

Section: Methodsmentioning

confidence: 99%

Preparation, structure, and performance of poly(lactic acid)/vermiculite‐poly(lactic acid)‐β‐cyclodextrin inclusion complex nanocomposites

Zhen

et al. 2021

Polymers for Advanced Techs

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Poly(lactic acid) (PLA)‐β‐cyclodextrin (β‐CD) inclusion complexes (PLA‐ICs) were synthesized by ultrasonic coprecipitation with β‐CD and PLA. Furthermore, vermiculite‐PLA‐ICs (VMT‐PLA‐ICs) were synthesized with VMT and PLA‐ICs by a coupling method. Orthogonal experimental analysis exhibited that the optimum preparation conditions of VMT‐PLA‐ICs were as follows: reaction temperature of 60°C, reaction time of 3 h, dosage of coupling agent of 2 wt%, and a mass ratio of VMT and PLA‐ICs of 1:6. PLA/VMT‐PLA‐ICs nanocomposites were prepared with PLA and VMT‐PLA‐ICs by melt blending. Compared with pure PLA, the tensile strength, impact strength, and elongation at break of PLA/VMT‐PLA‐ICs (0.3 wt%) nanocomposites were increased by 8.67%, 54.90%, and 25.67%, respectively. Differential scanning calorimetric curves showed that the addition of VMT‐PLA‐ICs (0.3 wt%) increased the crystallinity of PLA to 34.46% compared with the crystallinity of pure PLA (4.67%). Due to the addition of VMT‐PLA‐ICs, the creep resistance and dimensional stability of PLA/VMT‐PLA‐ICs nanocomposites were improved, and the creep recovery deformation of PLA4 reached from 4.66% to 10.31%.

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“…A poly(lactic acid) and γ-cyclodextrin inclusion complex was obtained by ultrasonic co-precipitation and used as a precursor for the preparation of its benzyl-hydrazide derivative that was subsequently applied as a nucleating agent for PLA composites [ 123 ]. PLA chains penetrated into the cavity of the γ-CD cone, which resulted in a tunnel-shaped crystalline structure.…”

Section: Pla Composites With Cyclodextrinsmentioning

confidence: 99%

Supramolecular Interactions in Hybrid Polylactide Blends—The Structures, Mechanisms and Properties

Kowalewska

Nowacka

2020

Molecules

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The conformation of polylactide (PLA) chains can be adjusted by supramolecular interactions (the formation of hydrogen bonds or host-guest complexes) with appropriate organic molecules. The structures formed due to those intermolecular interactions may act as crystal nuclei in the PLA matrix (“soft templating”). In this review, the properties of several supramolecular nucleating systems based on synthetic organic nucleators (arylamides, hydrazides, and 1,3:2,4-dibenzylidene-d-sorbitol) are compared to those achieved with biobased nucleating agents (orotic acid, humic acids, fulvic acids, nanocellulose, and cyclodextrins) that can also improve the mechanical properties of PLA. The PLA nanocomposites containing both types of nucleating agents/additives are discussed and evaluated in the context of their biomedical applicability.

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Preparation and characterization of benzoyl‐hydrazide‐derivatized poly(lactic acid) and γ‐cyclodextrin inclusion complex and its effect on the performance of poly(lactic acid)

Cited by 11 publications

References 57 publications

Identification of phytochemicals from North African plants for treating Alzheimer’s diseases and of their molecular targets by in silico network pharmacology approach

Identification of phytochemicals from North African plants for treating Alzheimer’s diseases and of their molecular targets by in silico network pharmacology approach

Preparation, structure, and performance of poly(lactic acid)/vermiculite‐poly(lactic acid)‐β‐cyclodextrin inclusion complex nanocomposites

Supramolecular Interactions in Hybrid Polylactide Blends—The Structures, Mechanisms and Properties

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