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一种聚氨酯微孔薄膜医用补片表层材料的制备及其性能研究

Preparation and Performance of a Novel Polyurethane Microporous Film on Polypropylene Medical Mesh Surface

  • 摘要:
    目的 本研究拟制备一种具有微孔结构的聚氨酯(polyurethane, PU)薄膜的医用补片表层材料,并对PU微孔薄膜的材料学特性和生物学性能进行评价,以期提升盆底修复补片材料的临床适用性。
    方法 采用PU预聚体发泡技术制备表面具有微孔结构的PU薄膜,通过调节最佳PU预聚体异氰酸根指数(R值)和发泡环境相对湿度(relative humidity, RH),制备PU微孔薄膜。采用扫描电子显微镜观察PU微孔薄膜表面形貌,利用红外光谱、拉曼光谱和水接触角分析PU微孔薄膜的化学结构亲水性;体外评价PU微孔薄膜浸提液对L929小鼠成纤维细胞增殖的影响,并观察PU微孔薄膜对L929小鼠成纤维细胞黏附和形态的影响和对RAW264.7小鼠单核巨噬细胞的影响;使用Sprague Dawley(SD)大鼠评价PU微孔薄膜的体内免疫反应和组织再生。
    结果 PU预聚体R值=1.5,发泡环境RH=70%时PU薄膜形成明显的微孔,且均匀致密;与PU薄膜相比较,PU微孔薄膜的化学结构无明显改变,其水接触角〔(55.7±1.5)°〕低于PU薄膜〔(69.5±1.7)°〕和聚丙烯(polypropylene, PP)的水接触角〔(104.3±2.2)°〕(P<0.05),显示出较强的亲水性;PU微孔薄膜浸提液具有良好体外生物相容性,可促进L929小鼠成纤维细胞增殖,同时PU微孔薄膜表面形态有利于L929小鼠成纤维细胞的黏附,细胞呈铺展生长,其表面形貌可以抑制RAW264.7小鼠单核巨噬细胞肿瘤坏死因子-α(tumor necrosis factor-α, TNF-α)、白细胞介素(interleukin, IL)-1β分泌,促进IL-10、IL-4分泌,与24 h相比较,培养72 h时PU薄膜组和PU微孔薄膜组TNF-α、IL-1β表达水平降低,且低于PP薄膜组(P<0.05);其中,PU微孔薄膜组TNF-α和IL-10表达水平降低最明显;而IL-10、IL-4表达水平增加,且高于PP薄膜组(P<0.01),其中,PU微孔薄膜组IL-4表达水平增加最显著。PU微孔薄膜植入体内后植入微环境炎症较轻,未见明显的纤维囊形成,植入后60 d, PU微孔薄膜部分降解,膜中央出现大量的胶原纤维生长和肌肉形成。
    结论 PU微孔薄膜具有良好的亲水性和生物相容性,其表面形貌可调节增加细胞的黏附、调控RAW264.7小鼠单核巨噬细胞的功能以及促进组织修复,为女性盆底修复重建补片材料的设计提供了新思路。

     

    Abstract:
    Objective This study aims to develop a medical patch surface material featuring a microporous polyurethane (PU) membrane and to assess the material's properties and biological performance. The goal is to enhance the clinical applicability of pelvic floor repair patch materials.
    Methods PU films with a microporous surface were prepared using PU prepolymer foaming technology. The films were produced by optimizing the PU prepolymer isocyanate index (R value) and the relative humidity (RH) of the foaming environment. The surface morphology of the PU microporous films was observed by scanning electron microscopy, and the chemical properties of the PU microporous films, including hydrophilicity, were analyzed using infrared spectroscopy, Raman spectroscopy, and water contact angle measurements. In vitro evaluations included testing the effects of PU microporous film extracts on the proliferation of L929 mouse fibroblasts and observing the adhesion and morphology of these fibroblasts. Additionally, the effect of the PU microporous films on RAW264.7 mouse macrophages was studied. Immune response and tissue regeneration were assessed in vivo using Sprague Dawley (SD) rats.
    Results The PU films exhibited a well-defined and uniform microporous structure when the R value of PU prepolymer=1.5 and the foaming environment RH=70%. The chemical structure of the PU microporous films was not significantly altered compared to the PU films, with a significantly lower water contact angle (55.7±1.5° ) compared to PU films (69.5±1.7° ) and polypropylene (PP) ( 104.3±2.5°), indicating superior hydrophilicity. The extracts from PU microporous films demonstrated good in vitro biocompatibility, promoting the proliferation of L929 mouse fibroblasts. The surface morphology of the PU microporous films facilitated fibroblast adhesion and spreading. The films also inhibited the secretion of tumor necrosis factor-α (TNF-α) and interleukin (IL)-1β by RAW264.7 macrophages while enhancing IL-10 and IL-4 secretion. Compared to 24 hours, after 72 hours of culture, the expression levels of TNF-α and IL-1β were reduced in both the PU film and PU microporous film groups and were significantly lower than those in the PP film group (P<0.05), with the most notable decreases observed in the PU microporous film group. IL-10 and IL-4 levels increased significantly in the PU microporous film group, surpassing those in the PP film group (P<0.01), with the most pronounced increase in IL-4. The PU microporous film induced mild inflammation with no significant fibrous capsule formation in vivo. After 60 days of implantation, the film partially degraded, showing extensive collagen fiber growth and muscle formation in its central region.
    Conclusion The PU microporous film exhibits good hydrophilicity and biocompatibility. Its surface morphology enhances cell adhesion, regulates the function of RAW264.7 macrophages, and promotes tissue repair, offering new insights for the design of pelvic floor repair and reconstruction patch materials.

     

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