Search results for: Fanglin Lu

Authors: Yixuan Zhou, Ming Zhang, Liang Qin, Fanglin Lu

Abstract:

Wound healing is a vital physiological process that supports the body’s ability to repair itself. Impaired healing can lead to complications such as infections, chronic ulcers, or tissue damage. Understanding the pathogenesis of wound healing is essential for developing targeted interventions to promote optimal healing outcomes and prevent complications associated with impaired wound healing. However, the underlying mechanism remains elusive. Macrophages play a crucial role in wound healing, and their function varies with the healing stage. Two main phenotypes of macrophages, known as M1 and M2, have been identified, each with distinct functions. The transition from M1 to M2 macrophages is a process that occurs during the healing of an injury. Dysregulation of macrophage polarization can impair wound healing and lead to chronic wounds. Therefore, understanding the roles of M1 and M2 macrophages and their regulation in the wound microenvironment is important for developing therapeutic strategies to promote optimal wound healing. We evaluated the efficacy of conditioned cell-free media from mouse bone marrow macrophages (BMMs) to improve wound healing in mouse models. M1 or M2 polarizations of BMMs are assessed in vitro post-stimulations using published protocols. In vivo, efficacies are assessed in a mouse model of wound healing. Macroscopy and histological data show a consistent effect of daily treatments with cell-free media from M2 BMMs on the healing of wounds in mice. These results are illustrated by a smaller wound area size, fewer inflammatory infiltrations, and enhanced angiogenesis in the healing stage. This multi-modal investigation suggests the potential of M2 macrophages for the healing of dermal injuries.

Keywords: wound healing, bone marrow macrophages, mouse model, polarization

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Authors: Xiping Guo, Fanglin Ge, Ping Guan

Abstract:

Refractory high entropy alloys are alternative materials expected to be employed at high temperatures. The comprehensive changes of microstructure and properties of NbTiZrCrAl refractory high entropy alloys are systematically studied by adjusting Al content. Five kinds of button alloy ingots with different contents of Al in NbTiZrCrAlX (X=0, 0.2, 0.5, 0.75, 1.0) were prepared by vacuum non-consumable arc melting technology. The microstructure analysis results show that the five alloys are composed of BCC solid solution phase rich in Nb and Ti and Laves phase rich in Cr, Zr, and Al. The addition of Al changes the structure from hypoeutectic to hypereutectic, increases the proportion of Laves phase, and changes the structure from cubic C15 to hexagonal C14. The hardness and fracture toughness of the five alloys were tested at room temperature, and the compressive mechanical properties were tested at 1000℃. The results showed that the addition of Al increased the proportion of Laves phase and decreased the proportion of the BCC phase, thus increasing the hardness and decreasing the fracture toughness at room temperature. However, at 1000℃, the strength of 0.5Al and 0.75Al alloys whose composition is close to the eutectic point is the best, which indicates that the eutectic structure is of great significance for the improvement of high temperature strength of NbTiZrCrAl refractory high entropy alloys. The five alloys were oxidized for 1 h and 20 h in static air at 1000℃. The results show that only the oxide film of 0Al alloy falls off after oxidizing for 1 h at 1000℃. After 20h, the oxide film of all the alloys fell off, but the oxide film of alloys containing Al was more dense and complete. By producing protective oxide Al₂O₃, inhibiting the preferential oxidation of Zr, promoting the preferential oxidation of Ti, and combination of Cr₂O₃ and Nb₂O₅ to form CrNbO₄, Al significantly improves the high temperature oxidation resistance of NbTiZrCrAl refractory high entropy alloys.

Keywords: NbTiZrCrAl, refractory high entropy alloy, al content, microstructural evolution, room temperature mechanical properties, high temperature compressive strength, oxidation resistance

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