Mannose Conjugated Polymer Targeting P. aeruginosa Biofilms.

Biofilms are one of the most challenging obstacles in bacterial infections. By providing protection against immune responses and antibiotic therapies, biofilms enable chronic colonization and the development of antibiotic resistance. As previous clinical observations and studies have shown, traditional antibiotic therapy alone cannot effectively treat and eliminate biofilm forming infections due to the protection conferred by the biofilm. A new strategy specifically targeting biofilms must be developed. Here, we specifically target and bind to the PAO1 biofilm and elucidate the molecular mechanism behind the interaction between a glycan targeted polymer and biofilm using a continuous flow biofilm model. The incubation of biofilms with fluorescent glycan targeted polymers demonstrated strong and persistent interactions with the mannose-containing polymer even after 24 h of continuous flow. To evaluate the role of major biofilm proteins LecB and CdrA, loss of function experiments with knockout variants established the dual involvement of both proteins in mannose targeted polymer retention. These results identify a persistent and specific targeting strategy to the biofilm, emphasizing its potential value as a delivery strategy and encouraging further exploration of biofilm targeted delivery.

Lamellar stack formation and degradative behaviors of hydrolytically degraded poly(ε-caprolactone) and poly(glycolide-ε-caprolactone) blended fibers.

Electrospun fibrous mats have gained popularity in bioengineering over the past decade, but few papers detail their degradative mechanisms. To address this, blends of hydrophobic poly(ε-caprolactone) (PCL) and hydrophilic PGA-PCL-PGA triblock copolymer were electrospun into aligned fibrous mats to assess the copolymers' mechanical and degradative properties. Increased hydrophilic triblock content led to enhanced morphological uniformity of fiber, tightening of fiber diameters, increased storage and Young's modulus, and decreased elongation. The corresponding decrease in hydrophobic PCL content led to faster hydrolytic degradation rate, as reflected by enhanced decrease in mass, molecular weight, and modulus loss at 25, 37, and 45°C. The activation energy for hydrolytic degradation for 15:85 PCL: triblock copolymer was approximately half that of 85:15 PCL: triblock copolymer. Detailed examination of fiber morphology and crystallinity revealed initial surface erosion followed by the evolution of crystalline lamellar stacks and bulk degradation at 37°C. Because of the high surface to volume and short diffusion length scale of the small diameter fibers, surface and bulk degradation may both contribute to the hydrolytic degradative behavior of these electrospun fibrous mats. Electrospun mats' distinct architecture that embodies high specific surface to volume and interfiber porous ultrastructures that lead to their unique degradative behaviors hold much potential for significant impact in the field of tissue engineering and controlled drug delivery.