Browsing by Subject "Decellularization"

Now showing 1 - 3 of 3
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    A modified chemical protocol of decellularization of rat sciatic nerve and its recellularization with mesenchymal differentiated Schwann-Like cells: Morphological and functional assessments
    (Universidad de Murcia. Departamento de Biología Celular e Histología, 2017) García Pérez, M.M.; Martínez Rodríguez, H.G.; López Guerra, G.G.; Soto Domínguez, A.; Said Fernández, S.L.; Morales Ávalos, R.; Elizondo Omaña, R.E.; Montes de Oca Luna, R.; Guzmán López, S.; Castillo Galván, M.L.; Mendoza Lemus, O.F.; Vílchez Cavazos, F.
    The functional reconstruction of large neural defects usually requires the use of peripheral nerve autografts, though these have certain limitations. As a result, interest in new alternatives for autograft development has risen. The acellular peripheral nerve graft is an alternative for peripheral nerve injury repair, but to date there is not a standardized chemical decellularization method widely accepted. The objective of this study was to propose a modified chemical protocol of decellularization of rat sciatic nerve and its recellularization in vitro with mesenchymal differentiated Schwann-like cells. After the transplantation, an evaluation of its regeneration was performed using morphological and functional tests. The study consisted of two phases; in phase 1, different concentrations and times of exposure of rat sciatic nerves to detergents were tested, to establish a modified chemical protocol for nerve decellularization. The chemical treatment with 3% triton X-100 and 4% sodium deoxycholate for 15 days allowed a complete decellularization whilst conserving the extracellular matrix of the harvested nerve. In phase 2, the decellularized and recellularized alografts were compared against autografts. The morphological analysis showed a higher positivity to specific myelin antibodies in the recellularized group compared to the autograft. There were no differences in this parameter between the control limb and the experimental limb (recellularized group). The functional analysis showed no statistical differences at week 15 in the Sciatic Function Index in the autograft group vs the other groups. This study sets the morphological and functional bases for posterior studies about nerve defects regeneration in humans.
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    Development of decellularization protocols for female cat reproductive organs
    (Elsevier, 2024-06) Sanguansook, P; Martínez-López, Cristina; López-Orozco, Marina; Chatdarong, K; García-Vázquez, FA; Martínez Cáceres, Carlos Manuel; Izquierdo Rico, María José; Biología Celular e Histología
    Decellularization is an innovative method to create natural scaffolds by removing all cellular materials while preserving the composition and three-dimensional ultrastructure of the extracellular matrix (ECM). The obtention of decellularized reproductive organs in cats might facilitate the development of assisted reproductive techniques not only in this species but also in other felids. The aim was to compare the efficiency of three decellularization protocols on reproductive organs (ovary, oviduct, and uterine horn) in domestic cats. The decellularization protocol involved 0.1% sodium dodecyl sulfate and 1%Triton X-100. Protocol 1 (P1) entailed 2- cycles of decellularization using these detergents. Protocol 2 (P2) was like P1 but included 3-cycles. Protocol 3 (P3) was similar to P2, with the addition of deoxyribonuclease incubation. Reproductive organs from nine cats were separated into two sides. One side served as the control (non-decellularized organ) while the contralateral side was the treated group (decellularized organ). The treated organs were subdivided into 3 groups (n = 3 per group) for each protocol. Both control and treated samples were analyzed for DNA content, histology (nuclear and ECM (collagen, elastin, and glycosaminoglycans (GAGs)) density), ultrastructure by electron microscopy, and cytotoxicity. The results of the study showed that P3 was the only protocol that displayed no nucleus residue and significantly reduced DNA content in decellularized samples (in all the studied organs) compared to the control (P < 0.05). The ECM content in the ovaries remained similar across all protocols compared with controls (P > 0.05). However, elastic fibers and GAGs decreased in decellularized oviducts (P < 0.05), while collagen levels remained unchanged (P > 0.05). Regarding the uterus, the ECM content decreased in decellularized uterine horns from P3 (P < 0.05). Electron microscopy revealed that the microarchitecture of the decellularized samples was maintained compared to controls. The decellularized tissues, upon being washed for 24 h, showed cytocompatibility following co-incubation with sperm. In conclusion, when comparing different decellularization methods, P3 proved to be the most efficient in removing nuclear material from reproductive organs compared to P1 and P2. P3 demonstrated its success in decellularizing ovarian samples by significantly decreasing DNA content while maintaining ECM components and tissue microarchitecture. However, P3 was less effective in maintaining ECM contents in decellularized oviducts and uterine horns.
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    Engineering vascular grafts from decellularized plants: Advances and challenges
    (Universidad de Murcia, Departamento de Histología e Histopatología, 2025) Merna Nick; Biología Celular e Histología
    Small-caliber vascular grafts (<6 mm diameter) are critical for coronary and peripheral bypass surgeries, yet developing functional substitutes remains challenging. Autologous vessels are ideal but often unavailable or of poor quality. Synthetic grafts, such as expanded polytetrafluoroethylene (ePTFE) and Dacron, have high failure rates at small diameters due to thrombosis, intimal hyperplasia, and compliance mismatch. Tissue-engineered vascular grafts (TEVGs) aim to overcome these issues by providing a biocompatible scaffold with an endothelial lining. Decellularized plant tissues have recently gained attention as natural scaffolds for TEVGs due to their structural similarity to human vasculature. Leaves and stems provide an extracellular matrix (ECM) primarily composed of cellulose, which is biocompatible, porous, and non-thrombogenic. These scaffolds are cost-effective, scalable, and ethically uncontroversial. Decellularized parsley stems or leatherleaf leaves, for instance, can be recellularized with endothelial and smooth muscle cells (SMCs) to create small-diameter grafts that support endothelialization and withstand physiological pressures. Perfusion bioreactors further enhance the functionality of plant-based grafts by simulating physiological conditions. Pulsatile flow and pressure stimulate endothelial cell alignment, reducing thromb-ogenicity, while mechanical stimulation promotes SMC maturation and ECM deposition, improving graft strength and compliance. This review summarizes recent advances in plant-based vascular grafts and perfusion bioreactor conditioning, compares their performance to conven-tional grafts, and highlights remaining challenges. Decellularized plant scaffolds, with their inherent vascular architecture and biocompatibility, show promise as natural templates for small-caliber vascular grafts. However, further research is needed to address key challenges such as standardization, mechanical optimization, and long-term in vivo validation to facilitate their clinical application