|
Authors
|
Hannig, C. ; Helbig, R. ; Hilsenbeck, J. ; Werner, C. ; Hannig, M.
|
|
Title
|
Impact of the springtails cuticle nanotopography on bioadhesion and biofilm formation in vitro and in the oral cavity
|
|
Date
|
04.07.2018
|
|
Number
|
55561
|
|
Abstract
|
Springtails (Collembola) have a nanostructured cuticle. To evaluate and to understand anti-biofouling properties of springtail cuticles’ morphology under different conditions, springtails, shed cuticles and cuticle replicates were studied after incubation with protein solutions and bacterial cultures using common in vitro models. In a second step, they were exposed to human oral environment in situ in order to explore potential application in dentistry. In vitro, the cuticular structures were found to resist wetting by albumin solutions for up to 3·h and colonization by Staphylococcus epidermidis was inhibited. When exposed in the oral cavity, initial pellicle formation was of high heterogeneity: parts of the surface were coated by adsorbed proteins, others remained uncoated but exhibited locally attached, ‘bridging’, proteinaceous membranes spanning across cavities of the cuticle surface; this unique phenomenon was observed for the first time. Also the degree of bacterial colonization varied considerably. In conclusion, the springtail cuticle partially modulates bioadhesion in the oral cavity in a unique and specific manner, but it has no universal effect. Especially after longer exposure, the nanotextured surface of springtails is masked by the pellicle, resulting in subsequent bacterial colonization, and, thus, cannot effectively avoid bioadhesion in the oral cavity comprehensively. Nevertheless, the observed phenomena offer valuable information and new perspectives for the development of antifouling surfaces applicable in the oral cavity.
|
|
Publisher
|
Royal Society Open Science
|
|
Wikidata
|
|
|
Citation
|
Royal Society Open Science 5 (2018) ID171742
|
|
DOI
|
https://doi.org/10.1098/rsos.171742
|
|
Tags
|
|
