Cirrhotic Liver Sustains In Situ Regeneration of Acellular Liver Scaffolds after Transplantation into G-CSF-Treated Animals.

Acellular liver scaffolds (ALS) produced by decellularization have been successfully explored for distinct regenerative purposes. To date, it is unknown whether transplanted ALSs are affected by cirrhotic livers, either becoming cirrhotic themselves or instead remaining as a robust template for healthy cell growth after transplantation into cirrhotic rats. Moreover, little is known about the clinical course of recipient cirrhotic livers after ALS transplantation. To address these questions, we transplanted ALSs into cirrhotic rats previously treated with the granulocyte colony-stimulating factor. Here, we report successful cellular engraftment within the transplanted ALSs at 7, 15, and 30 days after transplantation. Recellularization was orchestrated by liver tissue cell activation, resident hepatocytes and bile duct proliferation, and an immune response mediated by the granulocyte components. Furthermore, we showed that transplanted ALSs ensured a pro-regenerative and anti-inflammatory microenvironment, attracted vessels from the host cirrhotic tissue, and promoted progenitor cell recruitment. ALS transplantation induced cirrhotic liver regeneration and extracellular matrix remodeling. Moreover, the transplanted ALS sustained blood circulation and attenuated alterations in the ultrasonographic and biochemical parameters in cirrhotic rats. Taken together, our results confirm that transplanted ALSs are not affected by cirrhotic livers and remain a robust template for healthy cell growth and stimulated cirrhotic liver regeneration.

Central nervous system regeneration in ascidians: cell migration and differentiation.

Adult ascidians have the capacity to regenerate the central nervous system (CNS) and are therefore excellent models for studies on neuroregeneration. The possibility that undifferentiated blood cells are involved in adult neuroregeneration merits investigation. We analyzed the migration, circulation, and role of hemocytes of the ascidian Styela plicata in neuroregeneration. Hemocytes were removed and incubated with superparamagnetic iron oxide nanoparticles (SPION), and these SPION-labeled hemocytes were injected back into the animals (autologous transplant), followed by neurodegeneration with the neurotoxin 3-acetylpyridine (3AP). Magnetic resonance imaging showed that 1, 5, and 10 days after injury, hemocytes migrated to the intestinal region, siphons, and CNS. Immunohistochemistry revealed that the hemocytes that migrated to the CNS were putative stem cells (P-element-induced wimpy testis + or PIWI + cells). In the cortex of the neural ganglion, migrated hemocytes started to lose their PIWI labeling 5 days after injury, and 10 days later started to show ß-III tubulin labeling. In the neural gland, however, the hemocytes remained undifferentiated during the entire experimental period. Transmission electron microscopy revealed regions in the neural gland with characteristics of neurogenic niches, not previously reported in ascidians. These results showed that migration of hemocytes to the hematopoietic tissue and to the 3AP-neurodegenerated region is central to the complex mechanism of neuroregeneration.

Culture of neural cells of the eyestalk of a mangrove crab is optimized on poly-L-ornithine substrate.

Although there is a considerable demand for cell culture protocols from invertebrates for both basic and applied research, few attempts have been made to culture neural cells of crustaceans. We describe an in vitro method that permits the proliferation, growth and characterization of neural cells from the visual system of an adult decapod crustacean. We explain the coating of the culture plates with different adhesive substrates, and the adaptation of the medium to maintain viable neural cells for up to 7 days. Scanning electron microscopy allowed us to monitor the conditioned culture medium to assess cell morphology and cell damage. We quantified cells in the different substrates and performed statistical analyses. Of the most commonly used substrates, poly-L-ornithine was found to be the best for maintaining neural cells for 7 days. We characterized glial cells and neurons, and observed cell proliferation using immunocytochemical reactions with specific markers. This protocol was designed to aid in conducting investigations of adult crustacean neural cells in culture. We believe that an advantage of this method is the potential for adaptation to neural cells from other arthropods and even other groups of invertebrates.

Vascular endothelial growth factor-like and its receptor in a crustacean optic ganglia: a role in neuronal differentiation?

The neural system appears before the vascular system in the phylogenetic tree. During evolution, vascular system generation takes advantage of the pre-existing vascular endothelial growth factor (VEGF) in order to form its networks. Nevertheless, the role of VEGF in neuronal and glial cells is not yet completely understood. In order to support the hypothesis of a neural role for VEGF, we searched for VEGF- and VEGF receptor (VEGFR)-like immunoreactivities (immunohisto/cytochemistry and Western blotting) in the eyestalk of the invertebrate Ucides cordatus (Crustacea, Brachyura, Ucididae). Our results showed that both neurons and glial cells expressed VEGF-immunoreactivity, and that VEGFR was evidenced in neural cells. This is the first report about the VEGF/VEGFR-like immunoreactivities in the nervous tissue of a crustacean, and enables U. cordatus to be included in the repertoire of animal models used for ascertaining the role of VEGF in the nervous system.

Estudo morfológico e histoquímico em nível ultra-estrutural da corda tendínea de coraçöes de rato albino / Morphological and histochemical study in structural pattern of chordae tendinae of hearts from albino rat

Fragmentos de cordas tendíneas dos complexos valores mitral e tricúspide de ratos albinos foram observados ao microscópio eletrônico de transmissäo com o objetivo de estudar os componentes da matriz extracelulair. Foram utilizados dois tipos de fixador, um contendo ácido tânico para demonstrar a presença de fibras dos sistemas colágeno e elástico, e outro contendo vermelho de rutênio para a visualizaçäo de proteuglicans. Alguns fragmentos foram tratados previamente pela colagenase ou pela tripisina antes de serem fixados pelo glutaraldeído com vermelho de rutênio. Foi observado que as cordas tendíneas de rato säo revestidas por um endotélio contínuo que repousa sobre uma camada de conjuntivo contendo fibroblastos e esparsas fibras de colágeno, compondo a zona esponjosa. Tal camada circunda uma zona central (zaza fibrosa) constituída de grossos feixes de colágeno onde se encontram vários fibroblastos. Tanto na zona esponjosa como na fibrosa foram detectadas inúmeras fibras com padräo ultra-estrutural de fibras elaunínicas, os quais, juntamente com o colágeno, desempenham funçöes de resistência mecânica ao transmitirem as forças de traçäo exercidas pelo músculo papilar às bordas das válvulas. Adicionalmente, foram observadas as relaçöes morfológicas entre proteoglicans, fibrilas de colágeno e microfibrilas elaunínicas, tendo sido enfatizada a importância do equilíbrio de funçöes entre os diversos componentes da matriz extracelular concorrendo para o perfeito funcionamento deste complexo morfofuncional na fisiologia da corda tendínea.