Tomás J. Madera-Santana scite author profile

The use of chitosan, a natural polymer, has recently increased due to its antimicrobial and antifungal character, null toxicity, biocompatibility and ability to form biofilms and hydrogels. The areas of application and research include biomedical, pharmaceutical, biomaterials, water treatment and haircare and skincare products. However, the applications of chitosan are limited due to the difficulty associated with modification of its structure and its poor solubility in water. Among the main chemical modifications for functionalising the chitosan structure are the N-substitution, O-substitution (with or without protecting the reactive sites of the chitosan) and cross-linking with other compounds; these chemical modifications allow improvement of its chemical and physical properties. In relation to the current importance of the use of chitosan with chemical modification, the present review attempts to explain in a simple way the main chemical reactions carried out with chitosan and its wide range of applications, and provides a future perspective.

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Surface modification and performance of jute fibers as reinforcement on polymer matrix: an overview

Burrola‐Núñez

Herrera‐Franco

Rodríguez-Félix

et al. 2018

Journal of Natural Fibers

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Partial characterization of ethanolic extract of Melipona beecheii propolis and in vitro evaluation of its antifungal activity

Ramón-Sierra

Peraza-López

Rodríguez-Borges

et al. 2019

Revista Brasileira de Farmacognosia

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Impact of the molecular weight on the size of chitosan nanoparticles: characterization and its solid-state application

et al. 2020

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Nanofibers of gelatin and polivinyl-alcohol-chitosan for wound dressing application: fabrication and characterization

et al. 2020

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Electrospun nanofibers from gelatin (G), chitosan (CS), and chitosan-polyvinyl alcohol (CS-PVA) were developed by electrospinning process. Mechanical properties were determined by the tensile test, the elastic modulus values of the nanofibers were G (15.418-34.34 MPa) and . The morphological characterization by SEM revealed that the systems with 15% G and 6% CS-PVA showed morphological homogeneity. Structural characterization by FTIR indicated an interaction among some functional groups of the component. Thermal analysis by DSC and TGA showed degradation temperatures for G (330 °C), CS (210 °C to 370 °C), and PVA (310 °C to 420 °C). The contact angles values denoted the hydrophilic nature of the material. Finally, the antimicrobial assay proved that both 15% G and 7% PVA on the CS-PVA system presented the best antimicrobial effect. The results indicate that the electrospun nanofibers fabricated with G or CS-PVA can be used as wound healing dressings.

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