Azide photochemistry for facile modification of graphitic surfaces: preparation of DNA-coated carbon nanotubes for biosensing.

A facile, two-step method for chemically attaching single-stranded DNA to graphitic surfaces, represented here by carbon nanotubes, is reported. In the first step, an azide-containing compound, N-5-azido-nitrobenzoyloxy succinimide (ANB-NOS), is used to form photo-adducts on the graphitic surfaces in a solid-state photochemical reaction, resulting in active ester groups being oriented for the subsequent reactions. In the second step, pre-synthesized DNA strands bearing a terminal amine group are coupled in an aqueous solution with the active esters on the photo-adducts. The versatility of the method is demonstrated by attaching pre-synthesized DNA to surfaces of carbon nanotubes in two platforms-as vertically-aligned multi-walled carbon nanotubes on a solid support and as tangled single-walled carbon nanotubes in mats. The reaction products at various stages were characterized by x-ray photoelectron spectroscopy. Two different assays were used to check that the DNA strands attached to the carbon nanotubes were able to bind their partner strands with complementary base sequences. The first assay, using partner DNA strands tethered to gold nanoparticles, enabled the sites of DNA attachment to the carbon nanotubes to be identified in TEM images. The second assay, using radioactively labelled partner DNA strands, quantified the density of functional DNA strands attached to the carbon nanotubes. The diversity of potential applications for these DNA-modified carbon-nanotube platforms is exemplified here by the successful use of a DNA-modified single-walled carbon-nanotube mat as an electrode for the specific detection of metal ions.

Two-year preclinical testing of perfluoropolyether polymer as a corneal inlay.

PURPOSE: To assess the long-term biocompatibility and optical clarity of a perfluoropolyether (PFPE) polymer as a corneal inlay. METHODS: A 4-mm-diameter PFPE inlay was implanted under a microkeratome flap in the corneas of rabbits (n = 16) and maintained for predetermined time points of 6, 12, or 24 months. These were compared with normal (n = 3) and time-matched sham-wounded rabbit corneas (n = 8). All corneas were monitored clinically with a slit lamp. Histology was performed on all eyes on termination to assess the tissue response. RESULTS: Some sham and implanted animals were discontinued from study 1 to 2 days after surgery because of flap dislodgement. Ten animals with PFPE inlays remained in the study, and 7 of these were maintained to their predetermined time point for up to 2 years (3 were discontinued because of peripheral corneal defects). The corneas of these 7 animals remained clear and healthy, tear film remained normal, and there were no signs of inflammation, neovascularization, or increased conjunctival redness. All inlays remained centered and optically clear (clarity 85% or greater). Histology showed PFPE was biostable. The epithelia of operated corneas were stratified but slightly thinned compared with those of normal corneas. Stromal tissue anterior and posterior to each inlay appeared normal. Keratocytes in the vicinity of the inlay were normal in distribution but showed increased vacuolation, indicating tissue repair after the surgery. CONCLUSIONS: The PFPE polymer maintained a high level of optical clarity and showed long-term biocompatibility for up to 2 years when implanted as an inlay in the rabbit cornea.

Progress in the development of a synthetic corneal onlay.

PURPOSE: This study evaluated an improved perfluoropolyether polymer formulation designed for use as a corneal onlay to correct refractive error. METHODS: Collagen I coated perfluoropolyether lenticules were implanted in feline corneas exposing a 6-mm diameter area of lenticule surface for epithelial growth. A parallel series of sham-wounded corneas were also studied. All corneas were monitored clinically for 4 or 8 weeks after surgery when animals were terminated and corneas used for histology with light and electron microscopy. RESULTS: Postoperative epithelial growth began on days 1 and 2. Lenticule surfaces were fully epithelialized by days 5 to 11. Corneas remained clear, and the lenticules maintained epithelial cover until the designated time points. Histology of the implanted corneas showed that the lenticules were well tolerated by the cornea. Each lenticule was fully covered by a multilayered epithelium with microvilli, desmosomes, and a differentiated basal cell layer. Epithelial adhesive structures (basal lamina, hemidesmosomes, and anchoring fibrils) had assembled at the tissue-lenticule interface. CONCLUSIONS: Collagen coated perfluoropolyether lenticules implanted in the feline cornea supported the growth of a stable stratified squamous epithelium. These encouraging results are a step further in the development of a corneal onlay for correction of refractive error.

Isolation of conjunctival mucin and differential interaction with Pseudomonas aeruginosa strains of varied pathogenic potential.

The purpose of the study was to investigate the adhesion of Pseudomonas aeruginosa strains with varying pathogenic potential to purified ocular mucin. Bovine conjunctival mucin was purified by three sequential density gradient centrifugation steps. Immobilised mucin was probed with biotin-labelled bacteria isolated from different contact lens events and quantified by densitometry. Bacterial pili were identified by electron microscopy. The results indicate that purified ocular mucin consisted of a polydisperse high molecular weight population containing at least one species of goblet cell origin and was associated with a 97 kDa mucin-associated protein. Three pathogenic P. aeruginosa strains, Paer1 (57.5 +/- 10.8x10(6) CFU ml(-1); contact lens induced acute red eye (CLARE)), 6294 (127.0 +/- 4.7x10(6) CFU ml(-1); microbial keratitis) and Paer25 (60.5 +/- 11.3x10(6) CFU ml(-1); CLARE) exhibited a significantly higher level of adhesion to mucin than the negative control, E. coli (14.3 +/- 9.6x10(6) CFU ml(-1)) (p<0.005). The remaining P. aeruginosa isolates, Paer3 (asymptomatic patient), Paer12 (microbial keratitis) and ATCC 15442 (standard environmental strain) did not significantly differ in their mucin adhesion from the negative control. The majority of bacterial strains tested contained pili; thus differences in mucin adhesion observed could not be solely explained by pili status. In conclusion, P. aeruginosa isolates exhibit differential adhesion patterns to purified ocular mucin. It is proposed that more avid mucin-adhering strains are given the opportunity to adhere and subsequently penetrate the mucous layer of the tear film to initiate pathogenesis.