PTFE涂层抗粘附电极切割效率和抗粘附性能的时变性研究

电外科手术过程中高频电刀手术电极表面的组织粘附会导致电极变“钝”、变粗,切割效率和操作精度降低。近年来,低表面能的PTFE涂层电极被临床用作抗粘附手术电极,然而,这种抗粘附电极的切割效率和抗组织粘附耐久性尚不清楚。因此,利用摩擦学手段实时测量电切割离体猪肝脏组织试验过程中PTFE涂层电极-组织界面的切割阻力,结合微观形貌和组织切片分析,研究了PTFE涂层电极切割效率和抗粘附性能的时变性。结果表明,PTFE涂层电极的切割效率与抗粘附能力呈负相关。在切割初期,电极表面的PTFE涂层完整涂覆,抗组织粘附效果明显,组织热损伤轻,但切割阻力大,切割效率低;随着切割时间增加,PTFE涂层变薄、局部被电弧烧蚀击穿,切割阻力显著减小,但电极的抗粘附性能急剧下降,组织热损伤加重;随着切割时间继续增加,PTFE涂层完全破坏,抗粘附效果丧失,切割阻力降低到最低值。增大高频电刀输出功率能提高PTFE涂层抗粘附手术电极的切割效率,但涂层破坏加剧,涂层的有效抗粘附时间缩短,组织损伤也显著加剧。可见,在复杂的电外科手术工况下,PTFE涂层电极的切割效率低,抗组织粘附耐久性差。

35钢表面微纳米化蒸发镀铝复合处理后的抗粘附性能

为提高35钢表面的抗粘附性能,采用机械喷丸方式在其表面实现微纳米化,并真空蒸发镀上一层纯铝基薄膜形成微纳结构镀铝复合层。通过激光共聚焦显微镜和SEM对表面微纳米结构3D形貌进行观察和分析,通过锉削试验、骤冷骤热试验定性表征铝膜层与钢基体的结合性能,使用WS-2005涂层附着力自动划痕机测试复合层的附着力,EDS和SEM表征硫化表面的成分及形貌,结果表明,采用低的喷丸压力和小喷丸直径工艺实现35钢表面的微纳米化,由于存在大量的晶界、位错、空位等缺陷,为铝原子提供了更多的扩散通道,使铝膜与基体紧固结合;表面铝膜层自钝化形成一层致密的氧化铝膜,能阻止钢中铁元素与胶料中硫化物产生化学反应;表面微纳米结构有效减少实际接触面积,相应的减少粘附力,喷丸镀铝试样表面的硫化物粘附量远小于未处理的硫化物粘附量。

血液相容生医材料的合成研究15 苯乙烯型磺酸铵内盐单体的合成及其聚合物的抗血小板粘附性能

A kind of sulfobetaine, N,N-dimethyl-N-(3- sulfopropyl )-4-ethen yl-benzenemethanaminium inner salt was synthesized from tertiary amine and propanesultone and characterized by IR a nd 1 H NMR . The blood compatibilities of the polymers were evaluate d by platelet adhesion method. No platelet adhesion in platelet rich plasma(PRP) was observed for two hours.

聚氨酯表面构建磺铵两性离子结构及其抗血小板粘附性的研究

通过己二异氰酸酯(HDI)在聚醚氨酯(PU)表面构建磺铵两性离子结构,以改善其不凝血性能,首先用HDI活化PU表面,生成PU-NCO衍生物;然后通过N,N-二甲基乙醇胺(DMEEA)中的—OH和PU表面的—NCO反应生成PU-N(CH_3)_2;最后用丙磺酸内酯(PS)进行开环.生成磺铵两性离子结构,用ATR-IR表征了各步反应,对构建前后材料的抗血小板粘附性能进行了比较,结果表明,磺铵两性离子结构具有优异的抗血小板粘附性。

Construction and evaluation of nitric oxide generating vascular graft material loaded with organoselenium catalyst via layer-by-layer self-assembly

A new biomimetic material for artificial blood vessel with in situ catalytic generation of nitric oxide(NO) was prepared in this study. Organoselenium immobilized polyethyleneimine as NO donor catalyst and sodium alginate were alternately loaded onto the surface of electrospun polycaprolactone matrix via electrostatic layer-by-layer self-assembly. This material revealed significant NO generation when contacting NO donor S-nitrosoglutathione(GSNO). Adhesion and spreading of smooth muscle cells were inhibited on this material in the presence of GSNO, while proliferation of endothelial cells was promoted. In vitro platelet adhesion and arteriovenous shunt experiments demonstrated good antithrombotic properties of this material, with inhibited platelet activation and aggregation, and prevention of acute thrombosis. This study may provide a new method of improving cellular function and antithrombotic property of vascular grafts.