Project description:Blood-contacting medical implants made of Nitinol and other titanium alloys, such as neurovascular flow diverters and peripheral stents, have the disadvantage of being highly thrombogenic. This makes the use of systemic (dual) anti platelet / anticoagulant therapies inevitable with related risks of device thrombosis, bleeding and other complications. Meeting the urgent clinical demand for a less thrombogenic Nitinol surface, we describe here a treatment of standard, commercially available Nitinol that renders its surface ultra-hydrophilic and functionalized with phosphate ions. The efficacy of this treatment was assessed by comparing standard and surface-treated Nitinol disks and braids, equivalent to flow diverters. Static and dynamic (Chandler loop) blood incubation tests showed a drastic reduction of thrombus formation on treated devices. Surface chemistry and proteomic analysis indicated a key role of phosphate and calcium ions in steering blood protein adsorption and avoiding coagulation cascade activation and platelet adhesion. A good endothelialization of the surface confirmed the biocompatibility of the treated surface.

Project description:LubriShieldTM - a novel permanent coating was invented, and evenly applied to both the internal and external surfaces of indwelling urinary Foley catheters. Without releasing active substances, it effectively prevented pathogens from producing biofilm. The coating was superhydrophilic and incorporated a proprietary anti-fouling ligand, which created a surface that significantly inhibited up to 99% of colonizing uropathogens from forming biofilm for the duration of use without any microbial killing (p< 0.001).RNA-seq analysis revealed that gene expression associated with microbial extracellular polymeric substances formation was significantly downregulated on the coated surfaces. Additionally, microorganisms adhering to LubriShieldTM coated catheters were 78% more susceptible to antibiotics compared to those on uncoated silicone catheters (p=0.004).

Project description:Despite advances in the design and protocols for maintaining the skin/device interface around percutaneous devices (PDs), no current strategy ensures the permanent attachment of peri-implant epithelial tissue to the device surface. Based on preliminary data, we hypothesized that PDs coated with keratin nanomaterials could provide a biochemically mediated surface that enhances epidermal cell adhesion and downgrowth. To test this hypothesis, fifteen Yucatan miniature pigs were each implanted with six percutaneous titanium devices, comprising three porous and three smooth devices, both with and without keratin coatings (Kerateine [iKNT] and Keratose [gKOS]). The pigs were sacrificed at 4, 8, and 16 weeks post-implantation. The devices and surrounding tissues were harvested and analyzed using histological and RNA sequencing techniques. Compared to smooth peri-implant tissue, porous peri-implant tissue showed a significant decrease in epithelial downgrowth, fibrous capsule thickness, and infections, alongside a significant upregulation of multiple immune marker genes, including IL12B. At the 16-week period, gKOS-coated surfaces demonstrated a more favorable wound healing response than iKTN-coated devices, with a reduction in granulation tissue area and a significant upregulation of several keratin genes related to differentiation. Among the combinations of surface types and coatings studied, the porous gKOS-coated device produced the most favorable wound healing response.

Project description:Gold nanoparticles (Au NPs) are uniquely suited for various biomedical applications due to the combination of their optical properties with their easily functionalized surfaces. The Au NP surface can be tailored to improve biocompatibility while also attaching targeting ligands or drugs. However, information on how these tailored surface chemistries may affect cell gene expression is scarce. Using two model human cells line, human dermal fibroblasts and prostate cancer cells, microarray experiments measured gene expression over 27,000 human genes. Each of the cell lines was exposed to four related types of surface-modified Au NPs at two different concentrations, and the microarray data was analyzed by weighted gene correlation network analysis and gene functional annotation. Au NPs were shown to affect genes associated with a variety of cellular functions, and surface charge and chemistry were linked with the types of parthways changed and the degree of which those changes occured. Nanoparticle induced gene expression in PC3 and HDF cells was measured after 24 hour exposure to nanoparticles of four different surface coating types. RNA from three separate culture samples were used for each nanoparticle-cell combinations, along with three control samples not exposed to nanoparticles at all.

Project description:Hydroxyapatite (HA) coating on orthopedic implants is known to enhance osteogenesis and bone-implant integration. However its molecular basis remains to be investiagated. In this study, we performed transcriptome analysis of osteoblasts on nano-HA-coated surfaces.

Project description:Clinical use of intraoperative auto-transfusion requires the removal of platelets and plasma proteins due to the pump-based suction and water-soluble anticoagulant administration, which causes dilutional coagulopathy. Herein, we develop a carboxylated and sulfonated heparin-mimetic polymer-modified sponge that could spontaneously adsorb blood (1.149 kg/m-2 s-1/2) along with instantaneous anticoagulation. We demonstrate that intrinsic coagulation factors (especially XI) are inactivated by adsorption to the sponge surface, while inactivation of thrombin in the sponge-treated plasma effectively inhibits the common coagulation pathway. Benefiting from the multiple inhibitory effects of sponge on coagulation enzymes and calcium depletion, the whole blood auto-transfusion in trauma-induced hemorrhage is unprecedentedly realized. The transfusion of collected blood favors faster recovery of hemostasis compared to traditional heparinized blood in an animal model. Our work not only develops a safe and convenient approach for whole blood auto-transfusion, but also provides the mechanism of action of self-anticoagulant heparin-mimetic polymer-modified surfaces.

Project description:A genomic expression comparison was done among neural progenitor cells cultured on 2D substrates, 3D porous polystyrene scaffolds, and as 3D neural spheres (in vivo surrogate), with the goal of assessing the feasibility of establishing the meaning of 3D and associated physiological relevance at the molecular level Neural progenitor cells were cultured on 2D surfaces, in 3D scaffolds and as 3D neural spheres. Chemical cues are controlled by coating. Only spacial properties of the culture systems were compared.

Project description:We examined effects of surface-coating (BPEI, CIT, PEG) of silver nanoparticles and time (6h, 12h, 24h) on gene expression in human liver cancer cells (HepG2)

Project description:Salmonella spp. biofilms have been implicated in persistence in the environment and plant surfaces. In addition, Salmonella is able to form biofilms on the surface on cholesterol gallstones. The ability of Salmonella spp. on these surfaces is superior to biofilm formation on surfaces on glass or plastic. Thus, we hypothesized that Salmonella gene expression is specific during biofilm development on cholesterol surfaces.

Project description:In this study the gene expression differences between two titanium surfaces produced at Maastricht University were investigated. These two surfaces were: flat titanium-coated polystyrene and a titanium-coated polystyrene surface imprinted with a pattern selected from an earlier screening study (Ti1018). This pattern was selected based on the osteoinductive properties observed. As a positive control cells on the flat surface were treated with dexamethasone.