Regulation of Oxygen Tension as a Strategy to Control Chondrocytic Phenotype for Cartilage Tissue Engineering and Regeneration

Lammi, Mikko J.; Qu, Chengjuan

doi:10.3390/bioengineering11030211

Cited by 2 publications

References 155 publications

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Exosomes derived from SOX9 overexpressing human umbilical cord mesenchymal stem cells ameliorate osteoarthritis by potentially activating autophagy

Qin,

Zhang,

Liu

et al. 2024

Preprint

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The exosomes derived from modified mesenchymal stem cells are a promising treatment for osteoarthritis (OA). The aim of this study was to explore the therapeutic effects of SOX9-overexpressing human umbilical cord mesenchymal stem cells (hucMSCs) exosomes on OA and their potential mechanisms. SOX9 was overexpressed in hucMSCs, and the exosomes derived from these modified hucMSCs were isolated (ExosSOX9). An IL-1β-stimulated OA chondrocytes model and a surgically induced OA rat model were established. These models were subsequently treated with the prepared exosomes. Western blot results indicated that the ExosSOX9 markedly enhanced the synthesis of cartilage extracellular matrix and inhibited its degradation in vitro. Histological, imaging, immunohistochemical, and chip analysis demonstrated that the ExosSOX9 markedly alleviated OA progression and decreased serum inflammatory markers in OA rats. Furthermore, the autophagy/Wnt signaling axis served as a potential target pathway for the ExosSOX9 in both in vivo and in vitro studies. Consequently, the ExosSOX9 may alleviate OA by simultaneously inhibiting the Wnt pathway and inducing autophagy. The findings indicate that the ExosSOX9 may represente a promising approach for cell-free therapy in OA.

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Exosomes derived from SOX9 overexpressing human umbilical cord mesenchymal stem cells ameliorate osteoarthritis by potentially activating autophagy

Qin,

Zhang,

Liu

et al. 2024

Preprint

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Exploring New Horizons: Advancements in Cartilage Tissue Engineering Under Space Microgravity

Jeyaraman,

Ramasubramanian,

Yadav

et al. 2024

Cureus

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Novel investigations of how microgravity affects cellular and tissue development have recently been made possible by the multidisciplinary fusion of tissue engineering and space science. This review examines the intersection of cartilage tissue engineering (CTE) and space science, focusing on how microgravity affects cartilage development. Space microgravity induces distinct physiological changes in chondrocytes, including a 20-30% increase in cell diameter, a 1.5- to 2-fold increase in proliferation rates, and up to 3-fold increases in chondrogenic markers such as SOX9 and collagen type II. These cellular alterations impact extracellular matrix composition and tissue structure. Space-optimized bioreactors using dynamic culture methods replicate physiological conditions and enhance tissue growth, but the absence of gravity raises concerns about the mechanical properties of engineered cartilage. Key research areas include the role of growth factors in cartilage development under microgravity, biocompatibility and degradation of scaffold materials in space, and in situ experiments on space stations. This review highlights the opportunities and challenges in leveraging microgravity for CTE advancements, emphasizing the need for continued research to harness space environments for therapeutic applications in cartilage regeneration. The multidisciplinary fusion of tissue engineering and space science opens novel avenues for understanding and improving cartilage tissue engineering, with significant implications for the future of biomedical applications in space and on Earth.

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Regulation of Oxygen Tension as a Strategy to Control Chondrocytic Phenotype for Cartilage Tissue Engineering and Regeneration

Cited by 2 publications

References 155 publications

Exosomes derived from SOX9 overexpressing human umbilical cord mesenchymal stem cells ameliorate osteoarthritis by potentially activating autophagy

Exosomes derived from SOX9 overexpressing human umbilical cord mesenchymal stem cells ameliorate osteoarthritis by potentially activating autophagy

Exploring New Horizons: Advancements in Cartilage Tissue Engineering Under Space Microgravity

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