This work assessed wound healing response in rabbit oral lesions grafted with autologous artificial connective tissue or acellular collagen scaffolds. Autologous artificial oral connective tissue (AACT) was produced using rabbit fibroblasts and collagen I scaffolds. Before implantation, AACT grafts were assayed to demonstrate the presence of fibroblasts and extracellular matrix components, as well as the expression of characteristic genes and secretion of chemokines, cytokines, and growth factors. AACT grafts were tested in the rabbits from which the fibroblasts were obtained, whereas acellular collagen type I scaffolds (CS) were evaluated in a separate group of rabbits. In both cases, contralateral wounds closed by secondary intention were used as controls. In a separate experiment, AACT-grafted wounds were directly compared with contralateral CS-grafted wounds in the same animals. Wound contraction and histological parameters were examined to evaluate closure differences between the treatments in the three animal experiments performed. Contraction of wounds grafted with AACT and CS was significantly lower than in their controls (p < 0.05). Additionally, AACT significantly lowered wound contraction when compared with CS (p < 0.05). Intriguingly, it was observed that AACT-grafted wounds initially displayed a significantly higher (p < 0.05)-albeit transient-inflammatory response than seen in CS-grafted wounds and secondary healed wounds. This suggests that an early inflammatory component may contribute to tissue regeneration. Altogether, the results suggest that AACT- and CS-grafted wounds favor regeneration of oral mucosa.
The data found suggest that the P. peruviana fruit juice anti-pterygium effect described in traditional medicine may be related to its inhibiting fibroblast growth. The present study contributes to the pharmacologic knowledge regarding a remedy commonly used in Colombian traditional medicine.
Arrestin was identified in ciliary photoreceptors of Pecten irradians, and its role in terminating the light response was established electrophysiologically. Downstream effectors in these unusual visual cells diverge from both microvillar photoreceptors and rods and cones; the finding that key regulatory mechanisms of the early steps of visual excitation are conserved across such distant lineages of photoreceptors underscores that a common blueprint for phototransduction exists across metazoa. Arrestin was detected by Western blot analysis of retinal lysates, and localized in ciliary photoreceptors by immunostaining of whole-eye cryosections and dissociated cells. Two arrestin isoforms were molecularly identified by PCR; these present the canonical N-and C-arrestin domains, and are identical at the nucleotide level over much of their sequence. A high degree of homology to various -arrestins (up to 70% amino acid identity) was found. In situ hybridization localized the two transcripts within the retina, but failed to reveal finer spatial segregation, possibly because of insufficient differences between the riboprobes. Intracellular dialysis of anti arrestin antibodies into voltage-clamped ciliary photoreceptors produced a gradual slow-down of the photocurrent falling phase, leaving a tail that decayed over many seconds after light termination. The antibodies also caused spectrally neutral flashes to elicit prolonged aftercurrents in the absence of large metarhodopsin accumulation; such aftercurrents could be quenched by chromatic illumination that photoconverts metarhodopsin back to rhodopsin. These observations indicate that the antibodies depleted functionally available arrestin, and implicate this molecule in the deactivation of the photoresponse at the rhodopsin level.
Several studies have evaluated proteins secreted by fibroblasts comprising skin substitutes, finding that they are secreted in combinations and concentrations that promote wound healing. However, assessment of proteins secreted by oral fibroblasts forming a part of oral substitutes is scarce. In our previous work, collagen type-I scaffolds (CSs) and autologous artificial connective tissue (AACT) were produced and implanted in rabbit oral lesions, evidencing that AACT outperforms CS. The present work determined the secreted factor profile of AACT in the time of grafting as well as that of the AACT embedded in the clot. It also evaluated the proliferation and viability of AACT fibroblasts to establish the dwell time of these cells in the grafted area. Finally, it assessed whether CS, AACT, and clot-embedded AACT increase fibroblast recruitment induced by a fibrin clot, because the cell migratory response has been associated with the wound-healing outcome. We found that some of the factors secreted by AACT fibroblasts are significantly different from those secreted by clot-embedded AACT fibroblasts. Also, that the profile of proteins secreted by AACT fibroblasts and clot-embedded AACT fibroblasts is different from already reported protein secretion profiles of other engineered tissues used in treating oral mucosa wounds. It was also found that AACT fibroblasts are viable when grafted and remain in the treated area for almost 2 weeks, and that the migratory response of fibroblasts to tissue-substitute stimulus is significantly less than the migratory response induced by the clot alone. Overall, data suggest that AACT secretion of proteins is modulated by three-dimensionality and environment factors. This bioactivity and the fact that AACT does not increase fibroblast migration can be held accountable for AACT's good performance as a graft.
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