3 research outputs found
Nanopatterned Smart Polymer Surfaces for Controlled Attachment, Killing, and Release of Bacteria
Model
surfaces with switchable functionality based on nanopatterned,
thermoresponsive poly(<i>N</i>-isopropylacrylamide) (PNIPAAm)
brushes were fabricated using interferometric lithography combined
with surface-initiated polymerization. The temperature-triggered hydration
and conformational changes of nanopatterned PNIPAAm brushes reversibly
modulate the spatial concealment and exposure of molecules that are
immobilized in the intervals between nanopatterned brushes. A biocidal
quaternary ammonium salt (QAS) was used to demonstrate the utility
of nanopatterned PNIPAAm brushes to control biointerfacial interactions
with bacteria. QAS was integrated into polymer-free regions of the
substrate between nanopatterned PNIPAAm brushes. The biocidal efficacy
and release properties of these surfaces were tested against <i>Escherichia coli</i> K12. Above the lower critical solution
temperature (LCST) of PNIPAAm, desolvated, collapsed polymer chains
facilitate the attachment of bacteria and expose QAS moieties that
kill attached bacteria. Upon a reduction of the temperature below
the LCST, swollen PNIPAAm chains promote the release of dead bacteria.
These results demonstrate that nanopatterned PNIPAAm/QAS hybrid surfaces
are model systems that exhibit an ability to undergo noncovalent,
dynamic, and reversible changes in structure that can be used to control
the attachment, killing, and release of bacteria in response to changes
in temperature
Dynamic surface deformation of silicone elastomers for management of marine biofouling: laboratory and field studies using pneumatic actuation
<div><p>Many strategies have been developed to improve the fouling release (FR) performance of silicone coatings. However, biofilms inevitably build on these surfaces over time. Previous studies have shown that intentional deformation of silicone elastomers can be employed to detach biofouling species. In this study, inspired by the methods used in soft-robotic systems, controlled deformation of silicone elastomers <i>via</i> pneumatic actuation was employed to detach adherent biofilms. Using programmed surface deformation, it was possible to release > 90% of biofilm from surfaces in both laboratory and field environments. A higher substratum strain was required to remove biofilms accumulated in the field environment as compared with laboratory-grown biofilms. Further, the study indicated that substratum modulus influences the strain needed to de-bond biofilms. Surface deformation-based approaches have potential for use in the management of biofouling in a number of technological areas, including in niche applications where pneumatic actuation of surface deformation is feasible.</p></div
Modification of Silicone Elastomer Surfaces with Zwitterionic Polymers: Short-Term Fouling Resistance and Triggered Biofouling Release
We
present a method for dual-mode-management of biofouling by modifying
surface of silicone elastomers with zwitterionic polymeric grafts.
Poly(sulfobetaine methacrylate) was grafted from poly(vinylmethylsiloxane)
elastomer substrates using thiol−ene click chemistry and surface-initiated,
controlled radical polymerization. These surfaces exhibited both fouling
resistance and triggered fouling-release functionality. The zwitterionic
polymers exhibited fouling resistance over short-term (∼hours)
exposure to bacteria and barnacle cyprids. The biofilms that eventually
accumulated over prolonged-exposure (∼days) were easily detached
by applying mechanical strain to the elastomer substrate. Such dual-functional
surfaces may be useful in developing environmentally and biologically
friendly coatings for biofouling management on marine, industrial,
and biomedical equipment because they can obviate the use of toxic
compounds