Wound healing is a complex process of repair that involves the interaction between different cell types and involves coordinated interactions between intracellular and extracellular signaling. Bone Marrow Mesenchymal Stem Cells (BMSCs) based and acellular amniotic membrane (AM) therapeutic strategies with the potential for treatment and regeneration of tissue. We aimed to evaluate the involvement of paracrine effects in tissue repair after the flap skin lesion rat model. In the full-thickness flap skin experiment of forty Wistar rats: A total of 40 male Wistar rats were randomized into four groups: group I: control (C; n = 10), with full-thickness lesions on the back, without (BMSCs) or AM (n = 10); group II: injected (BMSCs; n = 10); group III: covered by AM; group IV–injected (AM + BMSCs; n = 10). Cytokine levels, IL-1, and IL-10 assay kits, superoxide dismutase (SOD), glutathione reductase (GRs) and carbonyl activity levels were measured by ELISA 28th day, and TGF-β was evaluated by immunohistochemical, the expression collagen expression was evaluated by Picrosirius staining. Our results showed that the IL-1 interleukin was higher in the control group, and the IL-10 presented a higher mean when compared to the control group. The groups with BMSCs and AM showed the lowest expression levels of TGF-β. SOD, GRs, and carbonyl activity analysis showed a predominance in groups that received treatment from 80%. The collagen fiber type I was predominant in all groups; however, the AM + BMSCs group obtained a higher average when compared to the control group. Our findings suggest that the AM+ BMSCs promote skin wound healing, probably owing to their paracrine effect attributed to the promotion of new collagen for tissue repair.
The use of Wharton's Jelly (WJ) as a biomaterial is currently undergoing an appearance in the regenerative medicine field. The biomaterials applications focus on the aspects of cellular growth or delivery of proteins capable of stimulating cellular response. However, the basic knowledge about Wharton jelly and decellularization processing technology combined with understanding the physical-chemical properties of this biomaterial is necessary for proper application in regenerative medicine. This mini-review article summarizes information on the composition of WJ, application of drug delivery, in medicine and discusses recent HIGHLIGHTS • Wharton's Jelly (WJ) can stimulate cellular response.• WJ promotes cell proliferation, adhesion, differentiation, and migration.• WJ 3D printing scaffold can increase the healing tissue potential.• WJ contains a variety of growth factors that promote tissue regeneration.• developments with a special focus on its use for regenerative medicine. The most successful and stimulating applications are studies in regenerative medicine and tissue engineering, for wound healing to treat burns, tumor treatment, nanoparticle carriers, and drug delivery systems.
To investigate the effect of transplantation of stem cells from the bone marrow mononuclear cells (BMMC) associated with 15d-PGJ2-loaded nanoparticles in a rat model of chronic MI. Chronic myocardial infarction (MI) was induced by the ligation of the left anterior descending artery in 40 male Wistar rats. After surgery, we transplanted bone marrow associated with 15d-PGJ2-loaded nanoparticle by intramyocardial injection (106 cells/per injection) seven days post-MI. Myocardial infarction was confirmed by echocardiography, and histological analyses of infarct morphology, gap junctions, and angiogenesis were obtained. Our results from immunohistochemical analyses demonstrated the presence of angiogenesis identified in the transplanted region and that there was significant expression of connexin-43 gap junctions, showing a more effective electrical and mechanical integration of the host myocardium. This study suggests that the application of nanoparticle technology in the prevention and treatment of MI is an emerging field and can be a strategy for cardiac repair.
The use of biopolymers and platelet-rich fibrin (PRF) is currently investigated as an excellent application biomaterial in the tissue engineering field. Natural biomaterials with application potential in tissue engineering and regenerative medicine are due to their characteristics in biocompatibility, biodegradability, and mechanical characteristic. Though, the basic knowledge of three-dimensional fibrin scaffold and chitosan/alginate processing technology combined with an understanding of the physical-chemical properties of this natural biomaterial is necessary for proper application in regenerative medicine and tissue engineering. This mini review summarizes the information on the composition of chitosan/alginate and PRF in medical HIGHLIGHTS• Alginate/Chitosan is the second most abundant polysaccharide on earth.• PRF (platelet-rich fibrin) potential to play adjunct roles in regenerative medicine.• 3D printing grafts can increase wound healing capacity.• Prospective of combining PRF with different biomaterials promotes tissue regeneration.
In the current scenario of medical education, a trend of using models and simulators to train operational skills, especially in the practice of basic orthopedic techniques, is growing. This form of teaching allows academics to maximize learning opportunities and contributes to improving the quality of care for their future patients. However, the realistic simulation has high costs as a major limitation. Objective: To develop a low-cost orthopedic simulator for practicing pediatric forearm reduction skills in the preclinical setting. Methods: A model of an arm and forearm with a fracture in the middle third was developed. Orthopedists, residents, and medical students evaluated the simulator’s ability to reproduce fracture reduction. Results: The simulator had a significantly lower cost than the others in the literature. The participants agreed that the model had a good performance, and that the manipulation was consistent with the reality of reducing closed pediatric forearm fracture. Conclusion: The results suggest that this model can be used to teach orthopedic residents and medical students the skill of closed reduction of fractures in the middle third of the forearm. Level of Evidence III, Case Control Study.
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