How Functionalized Surfaces Can Inhibit Bacterial Adhesion and Viability

Ghilini, Fiorela; Pissinis, Diego Ezequiel; Miñán, Alejandro; Schilardi, Patricia Laura; Diaz, Carolina

doi:10.1021/acsbiomaterials.9b00849

Cited by 49 publications

(47 citation statements)

References 191 publications

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“…Another important factor in bacterial adhesion to biomaterials is the morphology of surface topography. Based on the topographic analysis of the scaffolds shown in Figure 6, the narrow and sharp peaks obtained on the PCL/TrGO scaffolds surfaces contributed to the detachment of bacteria without ES [71,72]. Spherical-shaped bacteria, such as coccus, readily adhered to the soft surfaces (R sk < 0, pure PCL scaffolds) because they were less deformable and failed to adhere to surfaces with sharp peaks, such as Bacillus bacteria (E. coli) [71,72].…”

Section: Antibacterial Behavior Under Esmentioning

confidence: 99%

“…Based on the topographic analysis of the scaffolds shown in Figure 6, the narrow and sharp peaks obtained on the PCL/TrGO scaffolds surfaces contributed to the detachment of bacteria without ES [71,72]. Spherical-shaped bacteria, such as coccus, readily adhered to the soft surfaces (Rsk < 0, pure PCL scaffolds) because they were less deformable and failed to adhere to surfaces with sharp peaks, such as Bacillus bacteria (E. coli) [71,72]. The assays with 3 h of ES demonstrated the bactericidal effect of the electroactive PCL/TrGO scaffolds under 30 V (DC current ≈ 90 ± 11 µA in the scaffold) during 3 h of ES using the experimental setup reported previously [73,74].…”

Section: Antibacterial Behavior Under Esmentioning

confidence: 99%

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Electroactive 3D Printed Scaffolds Based on Percolated Composites of Polycaprolactone with Thermally Reduced Graphene Oxide for Antibacterial and Tissue Engineering Applications

et al. 2020

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Applying electrical stimulation (ES) could affect different cellular mechanisms, thereby producing a bactericidal effect and an increase in human cell viability. Despite its relevance, this bioelectric effect has been barely reported in percolated conductive biopolymers. In this context, electroactive polycaprolactone (PCL) scaffolds with conductive Thermally Reduced Graphene Oxide (TrGO) nanoparticles were obtained by a 3D printing method. Under direct current (DC) along the percolated scaffolds, a strong antibacterial effect was observed, which completely eradicated S. aureus on the surface of scaffolds. Notably, the same ES regime also produced a four-fold increase in the viability of human mesenchymal stem cells attached to the 3D conductive PCL/TrGO scaffold compared with the pure PCL scaffold. These results have widened the design of novel electroactive composite polymers that could both eliminate the bacteria adhered to the scaffold and increase human cell viability, which have great potential in tissue engineering applications.

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Section: Antibacterial Behavior Under Esmentioning

confidence: 99%

Section: Antibacterial Behavior Under Esmentioning

confidence: 99%

Electroactive 3D Printed Scaffolds Based on Percolated Composites of Polycaprolactone with Thermally Reduced Graphene Oxide for Antibacterial and Tissue Engineering Applications

et al. 2020

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“…Medical-device-associated infections have been drastically increasing in the current scenario. Surface functionalization via altering surface topography (surface roughness/wettability/surface energy), chemical modification (smart surfaces), and multifunctional surfaces (nanoform layer/antimicrobial coating using antibiotics, antimicrobial peptides: AMPs) help in combating microbial adhesion using different pathways, i.e., contact killing mechanism, electrostatic repulsion between surface and bacterial cell, rupturing cellular membrane by nanopillars, hydrophilicity block action of bacterial cell adhesins (proteins, flagella, pilli), cationic/zwitterionic moieties repel negative charge strains and bind to + ve charge strain, thus rupturing cell membrane leading to leakage of cellular matrix ( Ghilini et al, 2019 ).…”

Section: Applications Of Polydopamine As Antibacterial Agentmentioning

confidence: 99%

“…Chemical moieties used for surface modifications such as cationic polymers, antimicrobial peptides (AMPs), zwitterionic polymers, and quaternary ammonium compounds (QAC) have been employed to introduce antifouling, antimicrobial, and antibiofilm properties, and the resulting surfaces have been used for combating device-associated infections ( Ghilini et al, 2019 ). Gram-negative bacterial strains specifically adhere to cationic surfaces for longer time period, leading to penetration of bioactive molecules into the cell membrane via different transporter and porins.…”

Section: Cationic Charge Enriched Pda-fabricated Surfaces: Effect On mentioning

confidence: 99%

Recent Advances in a Polydopamine-Mediated Antimicrobial Adhesion System

et al. 2021

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The drug resistance developed by bacteria during antibiotic treatment has been a call to action for researchers and scientists across the globe, as bacteria and fungi develop ever increasing resistance to current drugs. Innovative antimicrobial/antibacterial materials and coatings to combat such infections have become a priority, as many infections are caused by indwelling implants (e.g., catheters) as well as improving postsurgical function and outcomes. Pathogenic microorganisms that can exist either in planktonic form or as biofilms in water-carrying pipelines are one of the sources responsible for causing water-borne infections. To combat this, researchers have developed nanotextured surfaces with bactericidal properties mirroring the topographical features of some natural antibacterial materials. Protein-based adhesives, secreted by marine mussels, contain a catecholic amino acid, 3,4-dihydroxyphenylalanine (DOPA), which, in the presence of lysine amino acid, empowers with the ability to anchor them to various surfaces in both wet and saline habitats. Inspired by these features, a novel coating material derived from a catechol derivative, dopamine, known as polydopamine (PDA), has been designed and developed with the ability to adhere to almost all kinds of substrates. Looking at the immense potential of PDA, this review article offers an overview of the recent growth in the field of PDA and its derivatives, especially focusing the promising applications as antibacterial nanocoatings and discussing various antimicrobial mechanisms including reactive oxygen species-mediated antimicrobial properties.

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“…Es decir, con una única superficie, combinar diferentes mecanismos de ataque antimicrobiano [118]. Por ejemplo, se han desarrollado superficies de titanio que combinan AgNPs y antibióticos, produciendo un efecto antimicrobiano en dos etapas:…”

Section: Superficies Multicomponentesunclassified

Multifuncionalización de superficies de titanio con nanopartículas de plata y biomoléculas para mejorar el desempeño de dispositivos implantables

Ghilini¹

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Cuando un material artificial se incorpora al organismo, en el primer contacto con los fluidos biológicos, las biomoléculas se adhieren al material, creando una nueva interfaz entre dicho material y el sistema vivo. Esta interfaz condiciona dos eventos posteriores: la adhesión celular, deseable en el caso de implantes que deban incorporarse de manera permanente (ortopédicos o dentales) e indeseable en el caso de materiales que deban, ser eliminados posteriormente (por ejemplo, clavos ortopédicos); y la adhesión de microorganismos, que puede originarse en bacterias ya presentes en el individuo o bacterias que hayan ingresado por contaminación del material o manipulación inapropiada durante el proceso quirúrgico. La modificación del biomaterial en la nanoescala a través de la funcionalización de su superficie con biomoléculas permitiría controlar estos eventos, asegurando el éxito del procedimiento. El objetivo de esta tesis fue diseñar estrategias de que conduzcan a obtener superficies multifuncionalizadas con biomoléculas reguladoras de la interacción célula/material y con nanopartículas de plata (AgNPs) como agente antimicrobiano, así como la caracterización fisicoquímica acabada de estos sistemas y la evaluación de su performance en el entorno biológico para las que fueron diseñadas. Se logró la inmovilización de AgNPs sobre titanio mediada por poli-L-lisina (PLL), un polímero del aminoácido L-lisina. Se analizó la capacidad antimicrobiana y la biocompatibilidad y se compararon con las de un sustrato de titanio con AgNPs sin la presencia de PLL. Se encontró que la superficie con PLL tiene un efecto antimicrobiano mayor (bactericida) que para el caso de las superficies sin PLL (bacteriostático), sin presentar citotoxicidad para células osteoblásticas. Asimismo, se lograron superficies multifuncionalizadas con AgNPs y lactoferrina (Lf), una proteína con propiedades antimicrobianas. Los resultados mostraron que estas superficies tienen capacidad antimicrobiana, a la vez que promueven una mayor adhesión y diferenciación de células osteoblásticas. Ambos sistemas se caracterizaron, además, mediante técnicas fisicoquímicas adecuadas (AFM, FTIR, XPS, SPR, técnicas electroquímicas, etc.). Por otra parte, se realizaron análisis fisicoquímicos y microbiológicos de implantes reales recubiertos con AgNPs como parte de un desarrollo tecnológico en colaboración con una empresa nacional. Los resultados de esta tesis permiten el desarrollo racional de recubrimientos antimicrobianos sobre dispositivos ortopédicos implantables de titanio con el objetivo de disminuir la incidencia de infecciones postoperatorias.

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How Functionalized Surfaces Can Inhibit Bacterial Adhesion and Viability

Cited by 49 publications

References 191 publications

Electroactive 3D Printed Scaffolds Based on Percolated Composites of Polycaprolactone with Thermally Reduced Graphene Oxide for Antibacterial and Tissue Engineering Applications

Electroactive 3D Printed Scaffolds Based on Percolated Composites of Polycaprolactone with Thermally Reduced Graphene Oxide for Antibacterial and Tissue Engineering Applications

Recent Advances in a Polydopamine-Mediated Antimicrobial Adhesion System

Multifuncionalización de superficies de titanio con nanopartículas de plata y biomoléculas para mejorar el desempeño de dispositivos implantables

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