posted on 2015-12-16, 22:16authored byKim Öberg, Jarmo Ropponen, Jonathan Kelly, Peter Löwenhielm, Mattias Berglin, Michael Malkoch
The antibiotic resistance developed among several pathogenic
bacterial
strains has spurred interest in understanding bacterial adhesion down
to a molecular level. Consequently, analytical methods that rely on
bioactive and multivalent sensor surfaces are sought to detect and
suppress infections. To deliver functional sensor surfaces with an
optimized degree of molecular packaging, we explore a library of compact
and monodisperse dendritic scaffolds based on the nontoxic 2,2-bis(methylol)propionic
acid (bis-MPA). A self-assembled dendritic monolayer (SADM) methodology
to gold surfaces capitalizes on the design of aqueous soluble dendritic
structures that bear sulfur-containing core functionalities. The nature
of sulfur (either disulfide or thiol), the size of the dendritic framework
(generation 1–3), the distance between the sulfur and the dendritic
wedge (4 or 14 Å), and the type of functional end group (hydroxyl
or mannose) were key structural elements that were identified to affect
the packaging densities assembled on the surfaces. Both surface plasmon
resonance (SPR) and resonance-enhanced surface impedance (RESI) experiments
revealed rapid formation of homogenously covered SADMs on gold surfaces.
The array of dendritic structures enabled the fabrication of functional
gold surfaces displaying molecular covering densities of 0.33–2.2
molecules·nm–2 and functional availability
of 0.95–5.5 groups·nm–2. The cell scavenging
ability of these sensor surfaces for Escherichia coli MS7fim+ bacteria revealed 2.5 times enhanced recognition for G3-mannosylated
surfaces when compared to G3-hydroxylated SADM surfaces. This promising
methodology delivers functional gold sensor surfaces and represents
a facile route for probing surface interactions between multivalently
presented motifs and cells in a controlled surface setting.