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The use of medical devices (e.g., catheters, implants, and probes) is a common and essential part of medical care for both diagnostic and therapeutic purposes. However, these devices quite frequently lead to the incidence of infections due to the colonization of their abiotic surfaces by biofilm-growing microorganisms, which are progressively resistant to antimicrobial therapies. Several methods based on anti-infective biomaterials that repel microbes have been developed to combat device-related infections. Among these strategies, surface coating with antibiotics (e.g., beta-lactams), natural compounds (e.g., polyphenols), or inorganic elements (e.g., silver and copper nanoparticles) has been widely recognized as exhibiting broad-spectrum bactericidal or bacteriostatic activity. So, in order to achieve a better therapeutic response, it is crucial to understand how these infections are different from others. This will allow us to find new biomaterials characterized by antifouling coatings with repellent properties or low adhesion towards microorganisms, or antimicrobial coatings that are capable of killing microbes approaching the surface, improving biomaterial functionalization strategies and supporting tissues’ bio-integration.
Medicine --- Candida --- biofilms --- diabetes --- medical devices --- candidiasis --- metabolic disorder --- hyperglycemia --- infection --- Candida glabrata --- candidemia --- echinocandins --- resistance --- micafungin --- caspofungin --- in vivo --- titanium dioxide --- nanotubes --- autoclaving --- titanium alloy --- biocompatibility --- wettability --- mechanical properties --- silver nanoparticles --- titanium dioxide nanotubes --- silver ions release --- biointegration --- antimicrobial activity --- polyethylene terephthalate --- PET --- electrospinning --- nanofibers --- antimicrobial agents --- Taguchi method --- antimicrobial efficiency --- cold atmospheric-pressure plasma jet (CAPJ) --- Escherichia coli --- DNA double-strand breaks --- scanning electron microscopy --- Ti6Al4V implants --- anodization process --- XPS --- genotoxicity assessment --- anti-inflammatory properties --- oral biofilm --- infection control --- Streptococcus mutans --- Candida spp. --- natural compounds --- antimicrobial resistance --- n/a
Choose an application
The use of medical devices (e.g., catheters, implants, and probes) is a common and essential part of medical care for both diagnostic and therapeutic purposes. However, these devices quite frequently lead to the incidence of infections due to the colonization of their abiotic surfaces by biofilm-growing microorganisms, which are progressively resistant to antimicrobial therapies. Several methods based on anti-infective biomaterials that repel microbes have been developed to combat device-related infections. Among these strategies, surface coating with antibiotics (e.g., beta-lactams), natural compounds (e.g., polyphenols), or inorganic elements (e.g., silver and copper nanoparticles) has been widely recognized as exhibiting broad-spectrum bactericidal or bacteriostatic activity. So, in order to achieve a better therapeutic response, it is crucial to understand how these infections are different from others. This will allow us to find new biomaterials characterized by antifouling coatings with repellent properties or low adhesion towards microorganisms, or antimicrobial coatings that are capable of killing microbes approaching the surface, improving biomaterial functionalization strategies and supporting tissues’ bio-integration.
Candida --- biofilms --- diabetes --- medical devices --- candidiasis --- metabolic disorder --- hyperglycemia --- infection --- Candida glabrata --- candidemia --- echinocandins --- resistance --- micafungin --- caspofungin --- in vivo --- titanium dioxide --- nanotubes --- autoclaving --- titanium alloy --- biocompatibility --- wettability --- mechanical properties --- silver nanoparticles --- titanium dioxide nanotubes --- silver ions release --- biointegration --- antimicrobial activity --- polyethylene terephthalate --- PET --- electrospinning --- nanofibers --- antimicrobial agents --- Taguchi method --- antimicrobial efficiency --- cold atmospheric-pressure plasma jet (CAPJ) --- Escherichia coli --- DNA double-strand breaks --- scanning electron microscopy --- Ti6Al4V implants --- anodization process --- XPS --- genotoxicity assessment --- anti-inflammatory properties --- oral biofilm --- infection control --- Streptococcus mutans --- Candida spp. --- natural compounds --- antimicrobial resistance --- n/a
Choose an application
The use of medical devices (e.g., catheters, implants, and probes) is a common and essential part of medical care for both diagnostic and therapeutic purposes. However, these devices quite frequently lead to the incidence of infections due to the colonization of their abiotic surfaces by biofilm-growing microorganisms, which are progressively resistant to antimicrobial therapies. Several methods based on anti-infective biomaterials that repel microbes have been developed to combat device-related infections. Among these strategies, surface coating with antibiotics (e.g., beta-lactams), natural compounds (e.g., polyphenols), or inorganic elements (e.g., silver and copper nanoparticles) has been widely recognized as exhibiting broad-spectrum bactericidal or bacteriostatic activity. So, in order to achieve a better therapeutic response, it is crucial to understand how these infections are different from others. This will allow us to find new biomaterials characterized by antifouling coatings with repellent properties or low adhesion towards microorganisms, or antimicrobial coatings that are capable of killing microbes approaching the surface, improving biomaterial functionalization strategies and supporting tissues’ bio-integration.
Medicine --- Candida --- biofilms --- diabetes --- medical devices --- candidiasis --- metabolic disorder --- hyperglycemia --- infection --- Candida glabrata --- candidemia --- echinocandins --- resistance --- micafungin --- caspofungin --- in vivo --- titanium dioxide --- nanotubes --- autoclaving --- titanium alloy --- biocompatibility --- wettability --- mechanical properties --- silver nanoparticles --- titanium dioxide nanotubes --- silver ions release --- biointegration --- antimicrobial activity --- polyethylene terephthalate --- PET --- electrospinning --- nanofibers --- antimicrobial agents --- Taguchi method --- antimicrobial efficiency --- cold atmospheric-pressure plasma jet (CAPJ) --- Escherichia coli --- DNA double-strand breaks --- scanning electron microscopy --- Ti6Al4V implants --- anodization process --- XPS --- genotoxicity assessment --- anti-inflammatory properties --- oral biofilm --- infection control --- Streptococcus mutans --- Candida spp. --- natural compounds --- antimicrobial resistance --- Candida --- biofilms --- diabetes --- medical devices --- candidiasis --- metabolic disorder --- hyperglycemia --- infection --- Candida glabrata --- candidemia --- echinocandins --- resistance --- micafungin --- caspofungin --- in vivo --- titanium dioxide --- nanotubes --- autoclaving --- titanium alloy --- biocompatibility --- wettability --- mechanical properties --- silver nanoparticles --- titanium dioxide nanotubes --- silver ions release --- biointegration --- antimicrobial activity --- polyethylene terephthalate --- PET --- electrospinning --- nanofibers --- antimicrobial agents --- Taguchi method --- antimicrobial efficiency --- cold atmospheric-pressure plasma jet (CAPJ) --- Escherichia coli --- DNA double-strand breaks --- scanning electron microscopy --- Ti6Al4V implants --- anodization process --- XPS --- genotoxicity assessment --- anti-inflammatory properties --- oral biofilm --- infection control --- Streptococcus mutans --- Candida spp. --- natural compounds --- antimicrobial resistance
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