How functionalized surfaces can inhibit bacterial adhesion and viability.

MIÑÁN, ALEJANDRO GUILLERMO; GHILINI, FIORELA; SCHILARDI, PATRICIA LAURA; PISSINIS, DIEGO EZEQUIEL; DÍAZ, CAROLINA; MIÑÁN, ALEJANDRO GUILLERMO; GHILINI, FIORELA; SCHILARDI, PATRICIA LAURA; PISSINIS, DIEGO EZEQUIEL; DÍAZ, CAROLINA

ACS Biomaterials Science & Engineering

American Chemical Society

Lugar: Washington DC; Año: 2019

2373-9878

Device-associated infections (DAI) remain a serious concern in modern healthcare. Bacterial attachment to a surface is the first step in biofilm formation, which is one of the main causes of DAIs. The development of materials capable of preventing or inhibiting bacterial attachment constitutes a promising approach to deal with this problem. The multifactorial nature of biofilm maturation and antibiotic resistance directs the research for multi-targeted or combinatorial therapeutic approaches. One attractive strategy is the modification or the engineering of surfaces in order to provide antiadhesive and/or antimicrobial properties. Currently, several different approaches that involve physical and chemical surface modification, deliver some possible alternatives to achieve this goal. The engineered surfaces can be coated with molecules capable of inhibiting the bacterial adhesion or with active agents that kill microorganisms. In addition, surfaces can also be modified in order to be stimuli-responsive, responding to a particular trigger and then delivering the consequent antimicrobial outcome. Here, we review the prevailing strategies to modify surfaces in order to create an antimicrobial surface and discuss how different surface functionalization can affect bacterial adhesion and/or viability.