Michael J. Monteiro

Nanoparticle-induced unfolding of fibrinogen promotes Mac-1 receptor activation and inflammation

The chemical composition, size, shape and surface characteristics of nanoparticles affect the way proteins bind to these particles, and this in turn influences the way in which nanoparticles interact with cells and tissues. Nanomaterials bound with proteins can result in physiological and pathological changes, including macrophage uptake, blood coagulation, protein aggregation and complement activation, but the mechanisms that lead to these changes remain poorly understood. Here, we show that negatively charged poly(acrylic acid)-conjugated gold nanoparticles bind to and induce unfolding of fibrinogen, which promotes interaction with the integrin receptor, Mac-1. Activation of this receptor increases the NF-κB signalling pathway, resulting in the release of inflammatory cytokines. However, not all nanoparticles that bind to fibrinogen demonstrated this effect. Our results show that the binding of certain nanoparticles to fibrinogen in plasma offers an alternative mechanism to the more commonly described role of oxidative stress in the inflammatory response to nanomaterials.

Polyacrylate Dendrimer Nanoparticles: A Self‐Adjuvanting Vaccine Delivery System

(Figure Presented) Special delivery: An effective group A streptococci vaccine is formed from a delivery device consisting of well-defined dendritic structures with nanoscale dimensions (see picture). The structures are designed to display multiple copies of the minimal B-cell epitopes, which were in the optimal conformation on the surface of the nanoparticles. The nanoparticles can be administered without the aid of an adjuvant.

Controlled radical copolymerization of styrene and maleic anhydride and the synthesis of novel polyolefin-based block copolymers by reversible addition-fragmentation chain-transfer (RAFT) polymerization

Reversible addition–fragmentation chain transfer (RAFT) was applied to the copolymerization of styrene and maleic anhydride. The product had a low polydispersity and a predetermined molar mass. Novel, well-defined polyolefin-based block copolymers were prepared with a macromolecular RAFT agent prepared from a commercially available polyolefin (Kraton L-1203). The second block consisted of either polystyrene or poly(styrene-co-maleic anhydride). Furthermore, the colored, labile dithioester moiety in the product of the RAFT polymerizations could be removed from the polymer chain by UV irradiation.

Cellular Uptake of Densely Packed Polymer Coatings on Gold Nanoparticles

A variety of functional polymer chains prepared by RAFT were directly grafted onto 5, 10, and 20 nm gold nanoparticles (AuNPs). The polymer shell coating the AuNPs was densely packed because of the strong binding between the trithioester groups on the polymer chain-ends and gold. It was found that due to the densely packed nature of the shell the polymer chains were significantly stretched compared to their usual Gaussian coil conformation in water. This was even evident for polymer chains where ionic repulsion between neighboring chains should be significant. Therefore, with such high grafting densities the surface properties and size of the hybrid nanoparticles should be the only contributing factors in cellular uptake in epithelial Caco-2 cells. This study has provided valuable insight into the effects of charge and size of NPs for the application of NPs in the delivery of therapeutic agents across the intestine. Our results showed that the negatively charged AuNPs were taken up by the cells with greater efficiency than the neutral AuNPs, most probably due to binding with membrane proteins. The positively charged AuNPs as expected gave the greatest uptake efficiency. Interestingly, the uptake for PNIPAM-AuNPs (hydrophobic coating at 37 degrees C) increased from approximately 2% efficiency after a 30 min incubation to 8% after 2 h, and was much greater than the negative or neutral AuNPs. We believe that this was due to the interplay between the hydrophobic nature of the NPs and their increased size.

The influence of RAFT on the rates and molecular weight distributions of styrene in seeded emulsion polymerizations

Seeded emulsion polymerizations of styrene in the presence of two reversible addition-fragmentation chain-transfer (RAFT) agents were studied. We designed the seed to be small to observe the effects of exit and, we made the seed of poly(methyl methacrylate) so that the molecular weight distributions of poly(styrene) by gel permeation chromatography could be obtained independently by UV detection. The rates were significantly retarded by the presence of a RAFT agent, with the retardation being greater with an EMA RAFT agent [2-(ethoxycarbonyl)propyl-2-yl dithiobenzoate] than with a cumyl RAFT agent (2-phenylprop-2-yl dithiobenzoate). We propose that exit from the particles after fragmentation was the main cause of retardation. In addition, the number-average molecular weight and polydispersities (broad) did not resemble the characteristic living behavior found in bulk or solution. This was a result of the continuous transportation of RAFT agent into the particles during interval II and the transportation of a small amount during interval III. A conspicuous red layer was also observed at the beginning of the polymerization. The red layer consisted of low molecular weight dormant species swollen with monomer. Once the switch from interval II to interval III occurred, the low molecular weight species coalesced to form a red coagulant.

Contact lens sensors in ocular diagnostics.

Contact lenses as a minimally invasive platform for diagnostics and drug delivery have emerged in recent years. Contact lens sensors have been developed for analyzing the glucose composition of tears as a surrogate for blood glucose monitoring and for the diagnosis of glaucoma by measuring intraocular pressure. However, the eye offers a wider diagnostic potential as a sensing site and therefore contact lens sensors have the potential to improve the diagnosis and treatment of many diseases and conditions. With advances in polymer synthesis, electronics and micro/nanofabrication, contact lens sensors can be produced to quantify the concentrations of many biomolecules in ocular fluids. Non- or minimally invasive contact lens sensors can be used directly in a clinical or point-of-care setting to monitor a disease state continuously. This article reviews the state-of-the-art in contact lens sensor fabrication, their detection, wireless powering, and readout mechanisms, and integration with mobile devices and smartphones. High-volume manufacturing considerations of contact lenses are also covered and a case study of an intraocular pressure contact lens sensor is provided as an example of a successful product. This Review further analyzes the contact lens market and the FDA regulatory requirements for commercialization of contact lens sensors.

A comparative study of the SET-LRP of oligo(ethylene oxide) methyl ether acrylate in DMSO and in H2O

A comparative analysis of the SET-LRP of oligo(ethylene oxide) methyl ether acrylate (OEOMEA) in DMSO and in H2O at 25 °C is reported. Both the catalysis with activated Cu(0) wire/Me6-TREN and with mimics of “nascent” Cu(0) nanoparticles/Me6-TREN resulted in a higher rate of polymerization in water than in DMSO. This result is consistent with the acceleration expected for SET-LRP by a more polar reaction solvent, and with the difference between the equilibrium constants of disproportionation of CuBr in DMSO (Kd = 1.4–4.4) and in water (Kd = 106 to 107), both much higher in the presence of Me6-TREN. The inefficient access of the Cu(0) catalyst to the hydrophobic reactive centers of the monomer and initiator assembled in micellar structures explains the induction time observed in the SET-LRP of OEOMEA in water. This induction period is longer for Cu(0) wire. The use of “nascent” Cu(0) nanoparticles prepared by the disproportionation of CuBr in DMSO, in combination with 5 mol% CuBr2, led to an extremely efficient SET-LRP of OEOMEA in water. This SET-LRP in water is fast and follows first order kinetics to complete monomer conversion with linear dependence of experimental Mn on conversion, and narrow molecular weight distribution. Under the polymerization conditions investigated in both water and DMSO, no reduction in the absorbance of CuBr2/Me6-TREN was observed by online UV-vis spectroscopy. This excludes the formation of CuBr by reduction of CuBr2 by Cu(0) during the SET-LRP in DMSO and in water.

Molecular Interaction of Poly(acrylic acid) Gold Nanoparticles with Human Fibrinogen

The binding of fibrinogen to various nanoparticles can result in protein unfolding and exposure of cryptic epitopes that subsequently interact with cell surface receptors. This response is dependent on the size, charge, and concentration of the nanoparticle. Here we examine the binding kinetics of human fibrinogen to negatively charged poly(acrylic acid)-coated gold nanoparticles ranging in size from 7 to 22 nm. These particles have previously been shown to elicit an inflammatory response in human cells. The larger nanoparticles bound fibrinogen with increasing affinity and a slower dissociation rate. Each fibrinogen molecule could accommodate two 7 nm nanoparticles but only one when the diameter increased to 10 nm. Nanoparticles larger than 12 nm bound multiple fibrinogen molecules in a positively cooperative manner. However, in the presence of excess nanoparticle, fibrinogen induced aggregation of the larger particles that could bind more than one protein molecule. This is consistent with interparticle bridging by the fibrinogen. Taken together, these results demonstrate that subtle changes in nanoparticle size can influence protein binding both with the surface of the nanoparticle and within the protein corona.

Facile Fabrication of Core–Shell‐Structured Ag@Carbon and Mesoporous Yolk–Shell‐Structured Ag@Carbon@Silica by an Extended Stöber Method

Layer upon layer: A facile extended Stober method has been developed for the synthesis of diverse metal-carbon spheres, which includes core-shell-structured Ag@carbon, rattle-type Ag,AgBr@meso-SiO, and yolk-shell-structured Ag@carbon@meso-SiO (see figure).

Various polystyrene topologies built from tailored cyclic polystyrene via CuAAC reactions

Rapid CuAAC cross-coupling reactions catalyzed by CuBr/PMDETA in toluene afforded complex architectures from functional polymeric cyclic blocks. Various topologies (from paddle-like to 3-arm stars) rapidly formed with high conversion at 25 °C. Remarkably, this approach overcame significant steric hindrance linking polymeric cyclic structures with high coupling efficiency.