Effect of nanosilver surfaces on peptide reactivity towards reactive oxygen species

Ultrashort Peptides as Stabilizing Agents for Colloidal Nanogold

Ultrashort peptides hold immense potential as structural tools for enhancing the colloidal stability of nanomaterials, such as nanogold. However, such applications have been largely unexplored in part due to the inherent complexity in designing, synthesizing, and testing short peptides as colloidal nanoparticle stabilizers. In this work, we use a motif-function-guided process for peptide synthesis and high throughput screening to evaluate the colloidal stability of spherical nanogold solutions and pentapeptides. We have successfully built a library of peptides capable of stabilizing colloidal nanogold at peptide concentrations of ≤1.0 μM. This represents a 50-100-fold reduction in the concentration required for stability compared to other small molecules used as capping agents, which illustrates the potential of using short peptide sequences as colloidal nanogold stabilizers. Our findings could significantly impact the future development of high-affinity surface modifiers for the custom engineering of nanogold by providing a deeper understanding of the complex interactions between nanoparticles and peptides.

Thermodynamics of the physisorption of capping agents on silver nanoparticles

Nanoscale silver particles have growing applications in biomedical and other technologies due to their unique antibacterial, optical, and electrical properties. The preparation of metal nanoparticles requires the action of a capping agent, such as thiol-containing compounds, to provide colloidal stability, prevent agglomeration, stop uncontrolled growth, and attenuate oxidative damage. However, despite the extensive use of these thiol-based capping agents, the structure of the capping agent layers on the metal surface and the thermodynamics of the formation of these layers remains poorly understood. Here, we leverage molecular dynamics simulations and free energy calculation techniques, to study the behavior of citrate and four thiol-containing capping agents commonly used to protect silver nanoparticles from oxidation. We have studied the single-molecule adsorption of these capping agents to the metal-water interface, their coalescence into clusters, and the formation of complete monolayers covering the metal nanoparticle. At sufficiently high concentrations, we find that allylmercaptan, lipoic acid, and mercaptohexanol spontaneously self-assemble into ordered layers with the thiol group in contact with the metal surface. The high density and ordered structure is presumably responsible for their improved protective characteristics relative to the other compounds studied.

Multifunctional Nano and Collagen-Based Therapeutic Materials for Skin Repair

A novel strategy is needed for treating nonhealing wounds, which is able to simultaneously eradicate pathogenic bacteria and promote tissue regeneration. This would improve patient outcome and reduce the number of lower limb amputations. In this work, we present a multifunctional therapeutic approach able to control bacterial infections, provide a protective barrier to a full-thickness wound, and improve wound healing in a clinically relevant animal model. Our approach uses a nanoengineered antimicrobial nanoparticle for creating a sprayable layer onto the wound bed that prevents bacterial proliferation and also eradicates preformed biofilms. As a protective barrier for the wound, we developed a thermoresponsive collagen-based matrix that has prohealing properties and is able to fill wounds independent of their geometries. Our results indicate that using a combination of the matrix with full-thickness microscopic skin tissue columns synergistically contributed to faster and superior skin regeneration in a nonhealing wound model in diabetic mice.

Nanoparticle Concentration vs Surface Area in the Interaction of Thiol-Containing Molecules: Toward a Rational Nanoarchitectural Design of Hybrid Materials

The effect of accounting for the total surface in the association of thiol-containing molecules to nanosilver was assessed using isothermal titration calorimetry, along with a new open access algorithm that calculates the total surface area for samples of different polydispersity. Further, we used advanced molecular dynamic calculations to explore the underlying mechanisms for the interaction of the studied molecules in the presence of a nanosilver surface in the form of flat surfaces or as three-dimensional pseudospherical nanostructures. Our data indicate that not only is the total surface area available for binding but also the supramolecular arrangements of the molecules in the near proximity of the nanosilver surface strongly affects the affinity of thiol-containing molecules to nanosilver surfaces.