Surface Modification of Bare-Metal Stents for Preventing Restenosis (Part 2)

Лотков, А. И.; Матвеева, В. Г.; Антонова, Л. В.; Кашин, О. А.; Kudryashov, A. N.

doi:10.17802/2306-1278-2017-6-3-131-142

Cited by 3 publications

(1 citation statement)

References 37 publications

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“…Stents [5,6] and metal plates [7,8] are the most commonly used metal implants. To investigate biocompatibility of promising metal alloys (for example, titanium nickelide), it is required to implant medical device prototypes made of the above alloys into laboratory animals, which is followed by assessment of connective tissue capsule formation, infiltration by immunocompetent cells and neovascularization [9,10].…”

Section: Introductionmentioning

confidence: 99%

A Novel Technique for Preparation, Staining, and Visualization of Tissue with Metal Implants and Extraskeletal Calcification Areas

Mukhamadiyarov¹,

Богданов²,

Мишинов³

et al. 2020

Sovrem Tehnol Med

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The aim of the study was to evaluate the efficacy of a novel technique for preparation, staining, and visualization of tissues containing extra-skeletal mineralization areas, all-metal implants or their prototypes for their subsequent examination using scanning electron microscopy in the backscattered electron mode. Materials and Methods. After fixation in 10% formalin (24 h), the biomaterial (a titanium nickelide plate with the surrounding tissues after subcutaneous implantation, patented titanium alloy plates with the surrounding tissues after cranioplasty, primary and secondary calcified atherosclerotic plaques) were fixed with 1% osmium tetroxide (12 h) and then stained with 2% aqueous solution of osmium tetroxide (48 h). The samples were further stained with 2% alcoholic uranyl acetate (5 h), dehydrated with isopropanol (5 h) and acetone (1 h), impregnated with a mixture of acetone and epoxy resin Epon (1:1, 6 h) and then embedded into a fresh portion of epoxy resin (24 h), which was followed by polymerization at 60°C. After grinding and polishing, epoxy blocks were counterstained with lead citrate (7 min) and sputter-coated with carbon, then the samples were visualized by scanning electron microscopy in the backscattered electron mode. The elemental composition was studied using X-ray microanalysis. Results. The developed technique allows obtaining high-quality images at five thousand-fold magnifications, provides the possibility to identify the shape and structure of intact metal and mineral inclusions, and to type the surrounding cells, distinguishing mesenchymal and immunocompetent cells by shape and cytoplasmic content. Apart from connective tissue capsule thickness and leukocyte infiltration, this technique makes it possible to estimate the number and area of newly formed small-caliber vessels representing a surrogate marker of inflammation. Conclusion. The proposed technique provides the possibility to investigate adequately the structure of samples when their sectioning is impossible or significantly complicated, with image quality remarkably higher than that obtained by light microscopy.

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