A Chitosan-based Hydrogel with PLCL, ZnO NPs, and Oligoelements: A Promising Antibiotic Scaffold for Tissue Engineering / Hidrogel de Quitosano con PLCL, ZnO NPs y Oligoelementos: Un Andamio Antibacteriano Prometedor para Ingeniería de Tejidos

ABSTRACT Tissue engineering involves anchorage-dependent cells cultured on scaffolds, with growth factors added to facilitate cell proliferation. Its use in transplants implies the risk of bacterial infection. The current contribution describes the preparation and antibacterial evaluation of a chitosan-based hydrogel physically cross-linked with poly(l-lactic-coɛ-caprolactone) (PLCL) and enriched with zinc oxide nanoparticles (ZnO NPs) and trace elements (potassium and magnesium). The material was developed as a scaffold with built-in antibacterial properties. Chitosan and PLCL are biocompatible support materials applied in medicine for the repair and regeneration of damaged tissues, objectives promoted by ZnO NPs and the aforementioned trace elements. The ZnO NPs were elaborated by chemical coprecipitation. The materials were characterized by XRD, FT-IR, and SEM. Antibacterial testing was performed with strains of Escherichia coli and Staphylococcus aureus by the Kirby-Bauer method, in accordance with the NCCLS and CLSI guidelines. It was possible to obtain a homogeneous hydrogel with adequate morphology and distribution of elements. The hydrogel with 300 mM of Mg, K, and ZnO NP's showed antibacterial inhibition halos of 13 mm for S. aureus and 19 mm for E. coli. This innovative biomaterial with trace elements holds promise for tissue engineering by considering the challenge of bacterial infection.

RESUMEN La ingeniería de tejidos involucra el uso de células cultivadas en andamios con adiciones de factores de crecimiento para facilitar la proliferación celular. Su uso en trasplantes implica riesgo de infección bacteriana. La contribución actual describe la preparación y evaluación antibacteriana de un hidrogel a base de quitosano físicamente reticulado con poli (l-láctico-co-ɛ-caprolactona) (PLCL) enriquecido con nanopartículas de óxido de zinc (NP de ZnO) y oligoelementos (potasio y magnesio). El material se desarrolló como un andamio con propiedades antibacterianas. El quitosano y el PLCL son materiales de soporte biocompatibles aplicados en medicina para la reparación y regeneración de tejidos dañados, propiedades promovidas por las NP´s de ZnO y los oligoelementos antes mencionados. Las NP de ZnO se elaboraron mediante coprecipitación química. Los materiales se caracterizaron por DRX, FT-IR y SEM. Las pruebas antibacterianas se realizaron con cepas de Escherichia coli y Staphylococcus aureus por el método de KirbyBauer de acuerdo con las guías NCCLS y CLSI. Se pudo obtener un hidrogel homogéneo con adecuada morfología y distribución de elementos. El hidrogel con 300 mM de NP ZnO y oligoelementos mostró halos de inhibición antibacteriana de 13 mm para S. aureus y 19 mm para E. coli. Este biomaterial innovador con oligoelementos es prometedor para la ingeniería de tejidos al considerar el desafío de la infección bacteriana.

Bi2O3/ZnO nanocomposite:Synthesis,characterizations and its application in electrochemical detection of balofloxacin as an anti-biotic drug / 药物分析学报

In the present work,a chemically modified electrode has been fabricated utilizing Bi2O3/ZnO nano-composite.The nanocomposite was synthesized by simple sonochemical method and characterized for its structural and morphological properties by using XRD,FESEM,EDAX,HRTEM and XPS techniques.The results clearly indicated co-existence of Bi2O3 and ZnO in the nanocomposite with chemical interaction between them.Bi2O3/ZnO nanocomposite based glassy carbon electrode(GCE)was utilized for sensitive voltammetric detection of an anti-biotic drug(balofloxacin).The modification amplified the electroactive surface area of the sensor,thus providing more sites for oxidation of analyte.Cyclic and square wave voltammograms revealed that Bi2O3/ZnO modified electrode provides excellent electrocatalytic action towards balofloxacin oxidation.The current exhibited a wide linear response in concentration range of 150-1000 nM and detection limit of 40.5 nM was attained.The modified electrode offered advantages in terms of simplicity of preparation,fair stability(RSD 1.45％),appreciable reproducibility(RSD 2.03％)and selectivity.The proposed sensor was applied for determining balofloxacin in commercial pharmaceutical formulations and blood serum samples with the mean recoveries of 99.09％and 99.5％,respectively.

Evaluation of zinc-oxide nanocoating on the characteristics and antibacterial behavior of nickel-titanium alloy

ABSTRACT Objective: To investigate the effect of ZnO nanocoating on mechanical properties of NiTi orthodontic wires and antibacterial activity. Methods: 0.016 x 0.022-in NiTi orthodontic wires were coated with ZnO nanoparticles using an electrochemical deposition method with three electrodes system in 0.1M Zn(NO3)2. Mechanical properties and frictional resistance of the coated wires were investigated using an universal testing machine. Antibacterial effect of ZnO coating was also investigated. Results: A stable adhered ZnO nanocoating on NiTi wires was obtained. The coated wires have a significant antibacterial activity against S. aureus, S. pyogens and E. coli, and a reduction of frictional forces by 34%. Conclusion: ZnO nanocoating may improve the antibacterial effects of NiTi wires and reduce the frictional resistance. Coating may be implanted in orthodontic practice for faster and safer treatment.

RESUMO Objetivos: Avaliar o efeito do nanorrevestimento de óxido de zinco (ZnO) sobre as propriedades mecânicas e propriedades antibacterianas de fios ortodônticos de NiTi. Métodos: Fios 0,016" x 0,022" de NiTi foram revestidos com nanopartículas de ZnO por meio de um método de deposição eletroquímica com um sistema de três eletrodos a 0,1M Zn(NO3)2. Uma máquina universal de testes foi utilizada para avaliar as propriedades mecânicas e a resistência friccional dos fios revestidos. Além disso, também foram analisadas as propriedades antibacterianas do revestimento de ZnO. Resultados: Obteve-se uma aderência estável das nanopartículas de ZnO sobre os fios NiTi. Os fios revestidos apresentaram atividade antibacteriana significativa contra S. aureus, S. pyogens e E. coli, e apresentaram uma redução de 34% na força de atrito. Conclusão: O revestimento com nanopartículas de óxido de zinco pode melhorar as propriedades antibacterianas e reduzir a resistência friccional dos fios de NiTi. Assim, o revestimento dos fios pode ser utilizado na Ortodontia visando tratamentos mais rápidos e seguros.

Preparación de un Adhesivo Sensible a la Presión (PSA) con la Incorporación de Nanopartículas de ZnO. Estudio de sus Propiedades Fisicoquímicas y Antimicrobianas / Preparation of a Pressure Sensitive Adhesive (PSA) with the ZnO Nanoparticles Incorporation. Study of its Physicochemical and Antimicrobial Properties

Resumen Se describe el proceso para obtener un adhesivo sensible a la presión (PSA). Este PSA está formado por un copolímero de acrilato de 2-etilhexil (2-EHA) / metacrilato de metilo (MMA) en una relación 80:20 que se polimerizó mediante una técnica de polimerización en emulsión. Se añadieron nanopartículas de óxido de zinc (NPZnO) a este copolímero, que se sintetizaron previamente y se modificaron superficialmente con 3-aminopropil-3-toxisilano (APTES) y dimetilsulfóxido (DMSO) para mejorar su dispersión en la matriz de copolímero. Los nanocompuestos obtenidos se caracterizaron por espectroscopía infrarroja (FTIR), calorimetría diferencial de barrido (DSC) y pruebas de adhesión al delaminado. Además, se determinó la actividad antimicrobiana contra S. aureus y S. pyogenes, así como la citotoxicidad en células humanas (HeLa). Los resultados demostraron que la adición de las nanopartículas de NPZnO al copolímero incrementa la temperatura de transición vítrea (Tg) así como las propiedades antimicrobianas del adhesivo mejorando a su vez su adhesión superficial. Con respecto al comportamiento adhesivo, el PSA con NPZnO sin modificar mostró una mayor resistencia al delaminado, esto quiere decir que las nanopartículas incrementan la fuerza cohesiva y proporcionan resistencia a temperaturas elevadas, lo cual sería beneficioso a su aplicación final. Finalmente, los resultados de citotoxicidad mostraron que la incorporación de NPZnO al PSA disminuye la viabilidad celular, sin embargo no se considera tóxico acorde a la norma ISO 10993 test for in vitro cytotoxicity.

Abstract The process for obtaining a pressure sensitive adhesive (PSA) is described. This PSA is formed by an acrylate copolymer of 2-ethylhexyl (2-EHA) / methyl methacrylate (MMA) in an 80:20 ratio which was polymerized by emulsion polymerization technique. Zinc oxide nanoparticles (NPZnO) were added to this copolymer, which were previously synthesized, and surface modified with 3-aminopropyltretoxysilane (APTES) and dimethyl sulfoxide (DMSO) to improve its dispersion in the copolymer matrix. The obtained nanocomposites were characterized by infrared spectroscopy (FTIR), differential scanning calorimetry (DSC) and T-peel adhesion tests. In addition, the antimicrobial activity against S. aureus and S. pyogenes as well as the cytotoxicity in human cells (HeLa) were determined. The results demonstrated that the ZnO nanoparticles incorporation enhanced the glass transition temperature (Tg) and the antimicrobial activity of PSA copolymer as well as its surface adhesion. It was confirmed that NPZnO modification with APTES increased its antimicrobial activity. Regarding adhesive behavior, PSA with unmodified NPZnO showed a greater peel resistance. This indicates that these nanoparticles enhances the cohesive force and induces a better high temperature performance, which is beneficial for the final application. Finally, cytotoxicity results showed that the incorporation of NPZnO to PSA decreases the cell viability, however this PSA is not toxic according to the standard ISO 10993 test for in vitro cytotoxicity.