Mark A. Ruegsegger

Biomimetic engineering of non-adhesive glycocalyx-like surfaces using oligosaccharide surfactant polymers

The external region of a cell membrane, known as the glycocalyx, is dominated by glycosylated molecules which direct specific interactions such as cell–cell recognition and contribute to the steric repulsion that prevents undesirable non-specific adhesion of other molecules and cells. Mimicking the non-adhesive properties of a glycocalyx provides a potential solution to the clinical problems, such as thrombosis, that are associated with implantable devices owing to non-specific adsorption of plasma proteins. Here we describe a biomimetic surface modification of graphite using oligosaccharide surfactant polymers, which, like a glycocalyx, provides a dense and confluent layer of oligosaccharides. The surfactant polymers consist of a flexible poly(vinyl amine) with dextran and alkanoyl side chains. We show that alkanoyl side chains assemble on graphite through hydrophobic interaction and epitaxial adsorption. This constrains the polymer backbone to lie parallel to the substrate, with solvated dextran side chains protruding into the aqueous phase, creating a glycocalyx-like coating. The resulting biomimetic surface is effective in suppressing protein adsorption from human plasma protein solution.

Reduced protein adsorption and platelet adhesion by controlled variation of oligomaltose surfactant polymer coatings.

A series of oligomaltose surfactant polymers were prepared by the simultaneous coupling of hydrophilic maltolactone [of 2(M2), 7(M7), or 15(M15) glucose units] and hydrophobic N-(hexanoyloxy)succinimide (Hex) groups to the amino groups of a poly(vinyl amine) backbone. The surfactants were characterized by FTIR and 1H-NMR spectroscopies for purity and composition. Contact-angle and AFM measurements confirmed full monolayer adsorption for all surfactants on a model surface, highly oriented pyrolitic graphite, while full coverage was observed on polyethylene only for PVAm (M7:Hex) due to the optimal M7:Hex ratio and Hex chain density. On graphite, protein resistance increased with increasing coating thickness from 81.4 to 85.8 to 95.8% for the M2, M7, and M15 surfactants, respectively. Additionally, static platelet adhesion on all three surfactants dropped substantially to 15% (M2), 17% (M7), and 16% (M15)compared to glass (adhesion normalized to 100%) and a polyurethane (24%) surface. Protein- and platelet-resistant properties of the controlled oligomaltose layers are discussed by analysis of molecular modeling, oligomaltose and hexanoyl chain densities, and surfactant stability.

Integrin-Dependent Interaction of Human Vascular Endothelial Cells on Biomimetic Peptide Surfactant Polymers

Biomimetic surfactant polymers designed by molecular grafting of pendant RGD peptides (Pep) and dextran oligosaccharides (Dex) in different ratios onto the backbone of poly(vinyl amine) (PVAm) were examined for their ability to promote endothelial cell (EC) growth. Adhesion, formation of focal contacts, and expression of integrin receptors were examined in EC seeded onto a series of novel surfactants containing 100% dextran (PVAm[Pep (0%)]) to 100% peptide (PVAm[Pep (100%)]) compared to fibronectin control. Interaction of EC on polymer was specific, as soluble GRGDSP, but not GRGESP, was able to inhibit both adhesion and spreading of EC. At three hours, EC attachment and spreading were rapid and comparable on fibronectin and PVAm[Pep (100%)], rounded on PVAm[Pep (0%)], and intermediate on PVAm[Pep (25%)], (PVAm[Pep (50%)], and PVAm[Pep (75%)], with increasing peptide ratio favoring more spreading, although all the substrates had similar hydrophilicity. Cells that spread well on fibronectin and PVAm[Pep (100%)] had sharp spikes of vinculin localized at the termination point of actin stress fibers. Formation of stress fibers and focal adhesions on other substrates were correlated with spreading pattern of EC and the peptide content. EC seeded on fibronectin expressed f 5 g 1 integrins all along the stress fibers and throughout the entire cytoskeleton, but this distribution pattern was less prominent on PVAm[Pep (100%)]. However, expression and distribution of vitronectin receptors ( f v g 3 ) were similar on both fibronectin and PVAm[Pep (100%)], suggesting a strong cell adhesion on PVAm[Pep (100%)]. Viability of EC was also comparable on both fibronectin and PVAm[Pep (100%)] at 24 h. Substrates with high proportion of dextran limited cell adhesion, probably by decreasing protein adsorption. These results suggest that it may be possible to engineer substrates that promote cell adhesion in a receptor-dependent manner while blocking nonspecific protein adsorption, which may have potential as interface materials for prostheses used in cardiovascular system.

Nanodevices in Biomedical Applications

In the early 21st century, nanotechnology is a field in rapid flux and development, and definition of its boundaries can be elusive. Aspects of multiple disciplines, ranging from physics to computer science to biotechnology, legitimately contribute to the endeavor. This breadth of field allows many interested parties to contribute to nanotechnology, but the same ambiguity can effectively render the field indistinct. The precise definition of nanotechnology remains debatable, so consideration of the present scope of the field may be useful.

Quantum confined peptide assemblies with tunable visible to near-infrared spectral range

Quantum confined materials have been extensively studied for photoluminescent applications. Due to intrinsic limitations of low biocompatibility and challenging modulation, the utilization of conventional inorganic quantum confined photoluminescent materials in bio-imaging and bio-machine interface faces critical restrictions. Here, we present aromatic cyclo-dipeptides that dimerize into quantum dots, which serve as building blocks to further self-assemble into quantum confined supramolecular structures with diverse morphologies and photoluminescence properties. Especially, the emission can be tuned from the visible region to the near-infrared region (420 nm to 820 nm) by modulating the self-assembly process. Moreover, no obvious cytotoxic effect is observed for these nanostructures, and their utilization for in vivo imaging and as phosphors for light-emitting diodes is demonstrated. The data reveal that the morphologies and optical properties of the aromatic cyclo-dipeptide self-assemblies can be tuned, making them potential candidates for supramolecular quantum confined materials providing biocompatible alternatives for broad biomedical and opto-electric applications.Quantum confined (QC) materials have favorable photoluminescent properties, yet are less bioavailable. Here, the authors developed aromatic cyclo-dipeptides that assemble into quantum dots and organize into biocompatible QC supramolecular structures suitable for in vivo imaging and optoelectronics.

Structural, Chemical, and Mechanical Properties of Pressure Garments as a Function of Simulated Use and Repeated Laundering

Pressure garments are widely employed for management of postburn scarring. Although pressure magnitude has been linked to efficacy, maintenance of uniform pressure delivery is challenging. An understanding of garment fabric properties is needed to optimize pressure delivery for the duration of garment use. To address this issue, compression vests were manufactured using two commonly used fabrics, Powernet or Dri-Tek Tricot, to achieve 10% reduction in circumference for a child-sized mannequin. Applied pressure was tracked on five anatomical sites over 23 hours, before laundering or after one and five laundering cycles. Load relaxation and fatigue of fabrics were tested before laundering or after one and five laundering cycles, and structural analysis via scanning electron microscopy was performed. Prior to laundering, pressure vests fabricated using Powernet or Dri-Tek Tricot generated a maximum pressure on the mannequin of 20 and 23 mm Hg, respectively. With both fabrics, pressure decreased during daily wear. Following five laundering cycles, Dri-Tek Tricot vests delivered a maximum of 7 vs 15 mm Hg pressure for Powernet at the same site. In cyclic tensile and load relaxation tests, exerted force correlated with fabric weave orientation with greatest force measured parallel to a fabrics long axis. The results demonstrate that Powernet exhibited the greatest applied force with the least garment fatigue. Fabric orientation with respect to the primary direction of tension was a critical factor in pressure generation and maintenance. This study suggests that fabrication of garments using Powernet with its long axis parallel to patients body part circumference may enhance the magnitude and maintenance of pressure delivery.