In situ optical coherence tomography of percutaneous implant-tissue interfaces in a murine model

Abstract: Novel surface coatings of percutaneous implants need to be tested in biocompatibility studies. The use of animal models for testing usually involves numerous lethal biopsies for the analysis of the implant-tissue interface. In this study, optical coherence tomo graphy (OCT) was used to monitor the reaction of the skin to a percutaneous implant in an animal model of hairless but immunocompetent mice. In vivo optical biopsies with OCT were taken at days 7 and 21 after implantation and post mortem on the day of n… Show more

“…To measure the geometry of the crystalline lens, spectraldomain OCT (see Fig. 2), which has been described in detail by Donner et al, 41 was used. In brief, the light of a broadband superluminescent diode (SLD) (Superlum Diodes, Ltd., Carrigtwohill, Ireland) is transmitted through a single mode fiber into a Michelson interferometer with an 80:20 nonpolarizing beam splitter (NPBS).…”

Measurement of Ex Vivo Porcine Lens Shape During Simulated Accommodation, Before and After fs-Laser Treatment

“…To measure the geometry of the crystalline lens, spectraldomain OCT (see Fig. 2), which has been described in detail by Donner et al, 41 was used. In brief, the light of a broadband superluminescent diode (SLD) (Superlum Diodes, Ltd., Carrigtwohill, Ireland) is transmitted through a single mode fiber into a Michelson interferometer with an 80:20 nonpolarizing beam splitter (NPBS).…”

Measurement of Ex Vivo Porcine Lens Shape During Simulated Accommodation, Before and After fs-Laser Treatment

“…This presented a valuable non-destructive option of imaging and material characterization since x-ray-based techniques are not suitable due to the low contrast in hydrogels and aqueous systems. Recently, OCT has gained more and more interest for the field of biomaterials by allowing observation of implants after in situ placement [47], or with additional image processing for automated assessment of the outer geometry and channel networks of bioprinted gelatin/alginate fibers [48] offering the option of a direct feedback during printing [49]. The contrast for cell visualization/tracking, in addition to the applied MTT staining of viable cells, can be enhanced by magnetic labelling of cells prior to application as shown for agar scaffolds [50] or by leveraging the dynamics of living cells.…”

Core–shell bioprinting as a strategy to apply differentiation factors in a spatially defined manner inside osteochondral tissue substitutes