Your search keyword '"Fan, Zhenlin"' showing total 3 results

1. Sustained Release of Hydrogen and Magnesium Ions Mediated by a Foamed Gelatin-Methacryloyl Hydrogel for the Repair of Bone Defects in Diabetes.

Author

Pei M, Li P, Guo X, Wen M, Gong Y, Wang P, Fan Z, Wang L, Wang X, and Ren W

Subjects

Animals, Mice, Bone Regeneration drug effects, Methacrylates chemistry, Delayed-Action Preparations chemistry, Macrophages drug effects, Macrophages metabolism, Polylactic Acid-Polyglycolic Acid Copolymer chemistry, Tissue Scaffolds chemistry, Reactive Oxygen Species metabolism, RAW 264.7 Cells, Diabetes Mellitus, Experimental drug therapy, Male, Oxidative Stress drug effects, Gelatin chemistry, Magnesium chemistry, Hydrogen chemistry, Hydrogen pharmacology, Hydrogen therapeutic use, Hydrogen administration & dosage, Hydrogels chemistry, Hydrogels pharmacology

Abstract

Diabetic bone defects, exacerbated by hyperglycemia-induced inflammation and oxidative stress, present significant therapeutic challenges. This study introduces a novel injectable scaffold, MgH 2 @PLGA/F-GM, consisting of foamed gelatin-methacryloyl (GelMA) and magnesium hydride (MgH 2 ) microspheres encapsulated in poly(lactic- co -glycolic acid) (PLGA). This scaffold is uniquely suited for diabetic bone defects, conforming to complex shapes and fostering an environment conducive to tissue regeneration. As it degrades, Mg(OH) 2 is released and dissolved by PLGA's acidic byproducts, releasing therapeutic Mg 2+ ions. These ions are instrumental in macrophage phenotype modulation, inflammation reduction, and angiogenesis promotion, all vital for diabetic bone healing. Additionally, hydrogen (H 2 ) released during degradation mitigates oxidative stress by diminishing reactive oxygen species (ROS). This multifaceted approach not only reduces ROS and inflammation but also enhances M 2 macrophage polarization and cell migration, culminating in improved angiogenesis and bone repair. This scaffold presents an innovative strategy for addressing the complexities of diabetic bone defect treatment.

Published

2024

2. Subcutaneously Engineered Decalcified Bone Matrix Xenografts Promote Bone Repair by Regulating the Immune Microenvironment, Prevascularization, and Stem Cell Homing.

Author

Pan Q, Zhang P, Xue F, Zhang J, Fan Z, Chang Z, Liang Z, Zhou G, and Ren W

Subjects

Humans, Rats, Animals, Heterografts, Stem Cells, Anti-Inflammatory Agents metabolism, Osteogenesis, Bone Matrix metabolism, Bone Matrix transplantation

Abstract

Immunoregulatory and vascularized microenvironments play an important role in bone regeneration; however, the precise regulation for vascularization and inflammatory reactions remains elusive during bone repair. In this study, by means of subcutaneous preimplantation, we successfully constructed demineralized bone matrix (DBM) grafts with immunoregulatory and vascularized microenvironments. According to the current results, at the early time points (days 1 and 3), subcutaneously implanted DBM grafts recruited a large number of pro-inflammatory M1 macrophages with positive expression of CD68 and iNOS, while at the later time points (days 7 and 14), these inflammatory cells gradually subsided, accompanying increased presence of anti-inflammatory M2 macrophages with positive expression of CD206 and Arg-1, indicating a gradually enhanced anti-inflammatory microenvironment. At the same time, the gradually increased angiogenesis was observed in the DBM grafts with implantation time. In addition, the positive cells of CD105, CD73, and CD90 were observed in the inner region of the DBM grafts, implying the homing of mesenchymal stem cells. The repair results of cranial bone defects in a rat model further confirmed that the subcutaneous DBM xenografts at 7 days significantly improved bone regeneration. In summary, we developed a simple and novel strategy for bone regeneration mediated by anti-inflammatory microenvironment, prevascularization, and endogenous stem cell homing.

Published

2024

3. Regeneration of Mechanically Enhanced Tissue-Engineered Cartilage Based on the Decalcified Bone Matrix Framework.

Author

Yu M, Song D, Guo X, Hu G, Pei M, Fan Z, Xi L, Wen M, Ci Z, Zhou G, and Ren W

Subjects

Mice, Swine, Humans, Animals, Gelatin pharmacology, Gelatin chemistry, Mice, Nude, Cartilage, Tissue Scaffolds chemistry, Bone Matrix

Abstract

Human decalcified bone matrix (HDBM) is a framework with a porous structure and good biocompatibility. Nevertheless, its oversized pores lead to massive cell loss when seeding chondrocytes directly over it. Gelatin (GT) is a type of protein obtained by partial hydrolysis of collagen. The GT scaffold can be prepared from the GT solution through freeze-drying. More importantly, the pore size of the GT scaffold can be controlled by optimizing the concentration of the GT solution. Similarly, when different concentrations of gelatin are combined with HDBM and then freeze-dried, the pore size of the HDBM can be modified to different degrees. In this study, the HDBM framework was modified with 0.3, 0.6, and 0.9%GT, resulting in an improved pore size and adhesion rate. Results showed that the HDBM framework with 0.6%GT (HDBM-0.6%GT) had an average pore size of 200 μm, which was more suitable for chondrocyte seeding. Additionally, our study validated that porcine decalcified bone matrix (PDBM) had a proper pore structure. Chondrocytes were in vitro seeded on the three frameworks for 4 weeks and then implanted in nude mice and autologous goats, respectively. The in vivo cartilage regeneration results showed that HDBM-0.6%GT and PDBM frameworks compensated for the oversized pores of the HDBM framework. Moreover, they showed successfully regenerated more mature cartilage tissue with a certain shape in animals.

Published

2023