Department of Orthopedic Surgery, Shanghai Sixth People's Hospital, Shanghai Jiaotong University, Shanghai 200233, People's Republic of China.
School of Materials Science and Engineering, Tongji University, Shanghai 200092, People's Republic of China.
Biomaterials. 2015;53:379-91. doi: 10.1016/j.biomaterials.2015.02.112. Epub 2015 Mar 19.
There is a need for better wound dressings that possess the requisite angiogenic capacity for rapid in situ healing of full-thickness skin wounds. Borate bioactive glass microfibers are showing a remarkable ability to heal soft tissue wounds but little is known about the process and mechanisms of healing. In the present study, wound dressings composed of borate bioactive glass microfibers (diameter = 0.4-1.2 μm; composition 6Na2O, 8K2O, 8MgO, 22CaO, 54B2O3, 2P2O5; mol%) doped with 0-3.0 wt.% CuO were created and evaluated in vitro and in vivo. When immersed in simulated body fluid, the fibers degraded and converted to hydroxyapatite within ∼7 days, releasing ions such as Ca, B and Cu into the medium. In vitro cell culture showed that the ionic dissolution product of the fibers was not toxic to human umbilical vein endothelial cells (HUVECs) and fibroblasts, promoted HUVEC migration, tubule formation and secretion of vascular endothelial growth factor (VEGF), and stimulated the expression of angiogenic-related genes of the fibroblasts. When used to treat full-thickness skin defects in rodents, the Cu-doped fibers (3.0 wt.% CuO) showed a significantly better capacity to stimulate angiogenesis than the undoped fibers and the untreated defects (control) at 7 and 14 days post-surgery. The defects treated with the Cu-doped and undoped fibers showed improved collagen deposition, maturity and orientation when compared to the untreated defects, the improvement shown by the Cu-doped fibers was not markedly better than the undoped fibers at 14 days post-surgery. These results indicate that the Cu-doped borate glass microfibers have a promising capacity to stimulate angiogenesis and heal full-thickness skin defects. They also provide valuable data for understanding the role of the microfibers in healing soft tissue wounds.
需要更好的伤口敷料,这些敷料应具有快速原位愈合全层皮肤伤口的必要血管生成能力。硼酸生物活性玻璃微纤维在愈合软组织伤口方面表现出了显著的能力,但对于愈合过程和机制知之甚少。在本研究中,制备了由硼酸生物活性玻璃微纤维(直径=0.4-1.2μm;组成 6Na2O,8K2O,8MgO,22CaO,54B2O3,2P2O5;mol%)组成的伤口敷料,并对其进行了体外和体内评价。当浸泡在模拟体液中时,纤维在大约 7 天内降解并转化为羟基磷灰石,将 Ca、B 和 Cu 等离子释放到介质中。体外细胞培养表明,纤维的离子溶解产物对人脐静脉内皮细胞(HUVEC)和成纤维细胞无毒,促进 HUVEC 迁移、管腔形成和血管内皮生长因子(VEGF)的分泌,并刺激成纤维细胞的血管生成相关基因的表达。当用于治疗啮齿动物的全层皮肤缺损时,与未掺杂纤维和未治疗缺陷(对照)相比,掺杂 3.0wt.%CuO 的 Cu 掺杂纤维在术后 7 和 14 天表现出明显更好的刺激血管生成能力。与未治疗的缺陷相比,用掺杂和未掺杂纤维治疗的缺陷显示出改善的胶原沉积、成熟度和取向,在术后 14 天时,掺杂 Cu 的纤维的改善程度并不明显优于未掺杂纤维。这些结果表明,掺杂 Cu 的硼酸玻璃微纤维具有刺激血管生成和愈合全层皮肤缺损的潜力。它们还为理解微纤维在愈合软组织伤口中的作用提供了有价值的数据。
