国产多孔钽材料修复兔胫骨缺损的实验研究

摘要 目的：研究国产多孔钽材料能否在兔胫骨缺损模型中顺利实现骨长入,用于修复胫骨缺损。方法：在36只新西兰大白兔双侧胫骨骨干处建立骨缺损模型,每只动物左右侧缺损随机分组,分别进入实验组(植入多孔坦材料)和对照组（不植入多孔坦材料）。植入后4周、8周和12周取材,通过X线检测以及硬组织切片苏木精伊红染色,检测多孔钽材料与骨界面的骨整合情况。采用推出实验检测多孔钽材料与骨界面的结合强度。结果：将术后不同时间点取得的胫骨标本作X射线拍片分析,4周时,骨缺损端与材料结合部位有骨质生成,在8周时材料表面有骨形成现象,逐渐完全覆盖材料表面,在12周时骨量继续增加,形成覆盖材料并桥接骨缺损断端的骨痂。样本行硬组织切片并行HE染色后检测,植入4周后实验组材料两端被新生骨所覆盖,材料深部的孔隙中也可见少量骨组织长入;植入8周后发现实验组材料与骨组织生长良好,多孔钽材料表面和两端材料孔隙内均有骨组织长入,材料孔隙与组织紧密连接,有骨小梁长入;植入12周时两端骨组织长入深度没有明显变化,但材料表面骨组织继续长入,并完全嵌入圆柱体材料内。材料植入后4周与8周比较差异无统计学意义（P＞0.05）,材料植入后8周与12周比较差异有统计学意义（P<0.05）。将植入4周、8周和12周后含材料样本置于动态疲劳试验机上进行推出实验,随时间延长所需推出力明显增加,植入后4周和8周相比,虽然后者所需推力较大,但两者比较差异无统计学意义（P＞0.05）,而8周和12周比较则差异有统计学意义（P<0.05）。结论：国产多孔坦材料能在胫骨缺损中实现与骨整合,能用于皮质骨缺损修复。     

多孔自凝固磷酸钙/纤维蛋白1∶1比例血管化的分析研究

目的:观察复合纤维蛋白的多孔自凝固磷酸钙的理学性能及体内血管化情况,探讨其各组份对材料生物学特性的影响,为其临床应用提供实验数据.方法:1)采用凝固时间测定和电镜观察材料表面和断面等方法对复合支架材料构造和理学性能进行分析;2)将24只新西兰白兔随机分为3组,每组8只,分别在每只实验兔腰背筋膜下植入1:1、CPC两种比例材料各一枚.术后2、4、8周进行取材,对材料及其周围组织进行组织学观察、微血管情况定量分析.结果:1)CPC/FG复合支架材料以1∶1(g/ml)混合后,与单纯的CPC相比,初凝时间延长,而终凝时间没有明显的统计学差异;电镜观察发现多孔自凝固磷酸钙复合了纤维蛋白胶之后,纤维蛋白胶分布均匀贯穿多孔自凝固磷酸钙晶体之间,并将其紧密相连;2)术后2周材料外周可见幼稚的微血管.1∶1组高于CPC组(P＜0.05).4周微血管密度达到高峰,相对于2周时有明显差异.1∶1组高于CPC组(P＜0.05).8周时微血管密度相对4周没有显著差异.各组微血管密度与4周时没有明显变化(P＞0.05).结论:复合支架材料具有合适的凝固时间和较好的结构,纤维蛋白胶及其降解产物影响复合材料在体内的微血管密度,使复合材料血管化能力提高,其可作为细胞载体和骨缺损修复支架材料应用于临床和实验中.     

丹参对冻融入胎儿卵巢组织异种移植早期血管生成的影响

目的：研究冻融人胎儿卵巢组织移植早期血管生成过程中微血管形态和密度的改变以及血管生成相关基因mRNA的表达;探讨丹参注射液对移植物血管生成的影响。方法：冻融胎儿卵巢组织异种移植至裸鼠肾被膜下,按给药不同分为对照组（生理盐水）和丹参组（丹参注射液每只0．09g／d）,分别于移植后48h、7d和28d回收移植物。结果：移植后两组卵巢组织微血管密度均明显增多;对照组移植后7d血管密度达峰,丹参组血管密度在移植后48h即已显著上升,此后两个时间段保持相对平稳。Angiopoietin-2mRNA表达在移植后48h两组均显著升高,丹参组上升幅度大于对照组（P〈0．05）。结论：冻融人胎儿卵巢组织新血管生成开始于异种移植后48h内,移植后7d组织内微血管密度达峰。丹参在移植早期应用可以促进移植后血管生成,其机制可能与它增加了血管生成相关因子Ang-2mRNA的表达有关。     

多孔自凝固磷酸钙/纤维蛋白1：1比例血管化的分析研究

目的：观察复合纤维蛋白的多孔自凝固磷酸钙的理学性能及体内血管化情况,探讨其各组份对材料生物学特性的影响,为其临床应用提供实验数据。方法：1）采用凝固时间测定和电镜观察材料表面和断面等方法对复合支架材料构造和理学性能进行分析;2）将24只新西兰白兔随机分为3组,每组8只,分别在每只实验兔腰背筋膜下植入1：1、CPC两种比例材料各一枚。术后2、4、8周进行取材,对材料及其周围组织进行组织学观察、微血管情况定量分析。结果：1）CPC/FG复合支架材料以1：1（g/ml）混合后,与单纯的CPC相比,初凝时间延长,而终凝时间没有明显的统计学差异;电镜观察发现多孔自凝固磷酸钙复合了纤维蛋白胶之后,纤维蛋白胶分布均匀贯穿多孔自凝固磷酸钙晶体之间,并将其紧密相连;2）术后2周材料外周可见幼稚的微血管。1：1组高于CPC组（P〈0.05）。4周微血管密度达到高峰,相对于2周时有明显差异。1：1组高于CPC组（P〈0.05）。8周时微血管密度相对4周没有显著差异。各组微血管密度与4周时没有明显变化（P〉0.05）。结论：复合支架材料具有合适的凝固时间和较好的结构,纤维蛋白胶及其降解产物影响复合材料在体内的微血管密度,使复合材料血管化能力提高,其可作为细胞载体和骨缺损修复支架材料应用于临床和实验中。     

自蔓延高温合成镍钛形状记忆合金的生物医学基础研究——第二部分 组织内植入实验

目的:研究自蔓延高温合成钛镍形状记忆合金(SHS SMA)生物学组织相容性。材料和方法:将SHS NiTi SMA多孔体制成薄片,植入大白鼠体内,观察埋植材料与组织的结合情况及对组织的影响,周围组织对埋植材料的反应,并用常规锻制的镍钛记忆合金作对照。结果:肉眼观察,SHS NiTi SMA多孔材料与周围组织结合紧密,而NiTi SMA光滑材料与周围组织结合疏松;光镜观察,两和埋植材料在实验初期,周围组织均有轻度的炎症反应;SHS NiTi SMA有孔材料在一月后材料周围纤维组织增生,并有乳头状突起;NiTi SMA光滑材料一月后材料周围呈包膜样改变。电镜观察,有孔材料的孔隙内有组织长入,并随相通的孔隙长入材料的内部。而光滑材料周围呈纤维组织包裹。结论:两种材料均有良好的组织相容性,SHSNiTi SMA的孔隙有利于组织的长入和结合。     

应力对大段骨缺损修复影响的实验兔模型探讨

目的 建立用于研究应力对大段骨缺损修复作用的实验兔动物模型.方法 选用20只健康成年大耳白兔,随机分成两组,在右侧肱骨中下段制造13 mm的大段骨缺损后植入泡沫碳化硅人工骨,实验组选用具有固定和持续轴向加压双重作用的镍钛记忆合金接骨器,对照组选用同种材料和规格的仅有固定作用的接骨器,术后常规护理,待取材观察.结果 20只实验兔中,7只在苏醒后当天,10只术后1～3 d,3只术后4～7 d,出现植入体从植入部位脱出游离至皮下现象.结论 用于研究应力对大段骨缺损修复作用的实验兔动物模型未成功建立,镍钛记忆合金接骨器对兔肱骨大段骨缺损处人工骨的固定和持续加载,在实验兔肱骨难以实现.     

胎盘脱细胞基质作为组织修复材料的初步研究

目的 制备胎盘脱细胞基质并评价其生物相容性，探讨其作为组织修复材料的可行性。方法 利用分娩废弃物胎盘组织，进行病毒灭活、脱细胞处理、冷冻干燥得到胎盘脱细胞海绵状基质材料，HE染色观察脱细胞效果及扫描电镜观察材料微观结构。同时，选取健康雄性SD大鼠39只，体质量120～150 g，随机分为实验1组、实验2组及对照组。对构建的基质材料进行大鼠皮下植入实验，实验1组植入基质材料，实验2组植入基质材料及脐带间充质干细胞，对照组为假手术组。于手术后第3、5、7天进行动物血常规检测，分析淋巴细胞、粒细胞等炎性细胞数量；于手术后第1、2、4、8、9周取材料植入处及周围组织样本进行HE染色分析。结果 构建的胎盘脱细胞基质肉眼观呈乳白色海绵状，HE染色未见细胞残留，电镜观察材料内部空隙比较明显，材料交联度较好，总孔隙率为（77.54±2.53）%。皮下植入之后，切口处愈合良好，血常规结果未见明显的炎性细胞增多；术后7 d植入材料切片HE染色即可见血管形成，且脐带间充质干细胞的加入能够加快材料与机体的融合，促进细胞的深入生长及血管化。结论 胎盘脱细胞海绵基质材料具有良好的生物相容性，可作为组织工程材料的理想来源。     

微弧氧化和碱处理技术在多孔钽修复兔颅骨缺损中的应用

目的观察微弧氧化和碱处理对多孔钽表面性状、生物相容性和成骨能力的影响。方法微弧氧化和碱处理多孔钽片后,扫描电镜观察表面微孔数量、表面钙磷沉积和接触角。植入钽片修复兔颅骨缺损模型,在4周和12周观察骨愈合情况。结果扫描电镜显示处理组表面有更多的微孔和钙磷沉积以及更小的接触角(P<0.05)。植入多孔钽片后,所有动物均生长良好,伤口愈合佳。CT观察多孔钽片和周围骨组织耦合良好;钙黄绿素标记检测显示12周时有新生骨长入多空钽材料内部;扫描电镜观察发现4周时多空钽材料内部有新生血管,12周时有骨小梁长入材料内部。结论微弧氧化和碱处理能改变多孔钽材料表面形状,处理后多孔钽片具有良好的生物相容性和成骨能力。     

多孔钛合金不同孔径大小对新骨长入的影响

目的:评价不同孔径多孔钛合金植入物在骨缺损区对新骨长入的影响。方法:采用电子束熔融(EBM)技术制备三种不同孔径(孔径分别为1.0 mm,2.0 mm,3.0 mm)的多孔钛合金材料,其孔隙率依次为73%,79%,86%。将18只家犬随机分为1.0 mm孔径材料组,2.0 mm孔径材料组,3.0 mm孔径材料组,每组6只。制备家犬双侧股骨外侧髁缺损模型,然后植入各孔径组材料,于术后4周,8周,12周分别行大体标本观察,X线片观察,组织形态学观察三组不同孔径材料与周围骨的整合情况及孔隙中的新骨长入情况。结果:通过大体标本观察和X线片观察显示,12周后三组材料均与周围紧密骨连接。其中1.0 mm孔径组材料中心明显成骨,2.0 mm孔径组和3.0 mm孔径组中心仍为较多白色组织填充。组织学观察显示,12周时2.0 mm孔径组和3.0 mm孔径组材料周围有骨质包绕,但中心空洞,基本无骨质形成。1.0 mm孔径组材料周围骨质包绕紧密,孔中新生骨形成较多,且有大量纤维母细胞和软骨细胞形成。各时间点1.0 mm孔径组新生骨面积百分比明显高于2.0 mm孔径组和3.0 mm孔径组,P<0.01,差异具有统计学意义。2.0 mm孔径组和3.0 mm孔径组相比,P>0.05,无显著差异。结论:孔径大小影响多孔钛合金材料的骨长入,适当孔径的设计将更有利于材料的传导成骨。     

两种壳聚糖仿生复合材料对家兔桡骨骨缺损修复的实验研究

目的:评价壳聚糖/碳酸钙三维复合材料(CS/CaCO3)和壳聚糖/羟基磷灰石复合材料(CS/HA)用于骨缺损修复的可行性.方法:家兔24只,随机分为对照、CS/CaCO3、CS/HA三组.左前肢去毛后,2%巴比妥钠(30mg/kg,iv)麻醉,距桡骨远端3cm处截骨1cm,形成骨缺损,分别植入相应材料.术后4w、8w、12w分别处死动物,X线摄片后,取骨缺损标本,进行大体与组织学观察.结果:术后4周植入块颜色变红,周围有较多量的新生骨样组织包裹,骨痂增多,向植入块内移行;术后8周,植入块周围有明显新骨生成,将材料分隔包围,新骨中央区可见材料呈蜂窝状残留.术后12周缺损区大部分编织骨被成熟的板层骨组织替代,并形成髓腔.结论:CS/CaCO3和CS/HA两种仿生复合材料能明显促进兔桡骨骨缺损修复,诱导骨痂生成.     

一种可止血的富血小板血浆壳聚糖/丝素蛋白多孔伤口敷料的制备及性能表征

为了进一步提高伤口敷料的止血性能,文中在生物相容性良好的壳聚糖溶液中引入含有多种生长因子的人源性富血小板血浆(Humanplatelet-richplasma,hPRP),并加入不同体积比例(1∶1、1∶3、3∶1、1∶0)的丝素蛋白溶液以提高材料的多孔性与止血性,通过冷冻干燥法制备不同配比的hPRP-壳聚糖/丝素蛋白敷料,并将纯壳聚糖敷料作为对照组,研究hPRP和丝素蛋白对敷料的止血性能的影响以及丝素蛋白对PRP中生长因子控制释放的影响。结果表明,在壳聚糖敷料中引入hPRP对敷料的止血性有所提高,但对敷料的多孔结构及吸水率无明显改善,若在hPRP-壳聚糖溶液中按照体积比为1∶1的比例加入丝素蛋白溶液,会得到具有较为均匀的多孔结构的敷料,敷料的孔隙率与吸水率分别可达到86.83%±3.84%与1 474%±114%,且该比例的敷料在快速止血性能上表现优异。此外,加入丝素蛋白与壳聚糖比例为1∶1的PRP敷料能有效减少PRP中生长因子在初始阶段的爆裂释放。因此,含hPRP的壳聚糖/丝素蛋白复合敷料有望成为一种能快速止血且能促进伤口愈合的新型伤口敷料。     

Role of Phosphate and Kinetic Characteristics of Complete Iron Release from Native Pig Spleen Ferritin-Fe

The kinetics for complete iron release showing biphasic behavior from pig spleen ferritin-Fe (PSFF) was measured by spectrophotometry. The native core within the PSFF shell consisted of 1682 hydroxide Fe³⁺ and 13 phosphate molecules. Inhibition kinetics for complete iron release was measure by differential spectrophotometry in the presence of phosphate; the process was clearly divided into two phases involving a first-order reaction at an increasing rate of 46.5 Fe³⁺/PSFF/min on the surface of the iron core and a zero-order reaction at a decreasing rate of 6.67 Fe³⁺/PSFF/min inside the core. The kinetic equation [C(PSFF-Fe³⁺)_max – C(PSFF-Fe³⁺) _t ]^1/2 = T _max –T _t gives the transition time between the two rates and represents the complex kinetic characteristics. The rate was directly accelerated twofold by a mixed reducer of dithionite and ascorbic acid. These results suggest that the channel of the PSFF shell may carry out multiple functions for iron metabolism and storage and that the phosphate strongly affects the rate of iron release.     

Porous Silk Scaffolds for Delivery of Growth Factors and Stem Cells to Enhance Bone Regeneration

Stem cell-based tissue engineering shows promise for bone regeneration and requires artificial microenvironments to enhance the survival, proliferation and differentiation of the seeded cells. Silk fibroin, as a natural protein polymer, has unique properties for tissue regeneration. The present study aimed to evaluate the influence of porous silk scaffolds on rat bone marrow stem cells (BMSCs) by lenti-GFP tracking both in vitro and in vivo in cranial bone defects. The number of cells seeded within silk scaffolds in rat cranial bone defects increased from 2 days to 2 weeks after implantation, followed by a decrease at eight weeks. Importantly, the implanted cells survived for 8 weeks in vivo and some of the cells might differentiate into endothelial cells and osteoblasts induced by the presence of VEGF and BMP-2 in the scaffolds to promote angiogenesis and osteogenesis. The results demonstrate that porous silk scaffolds provide a suitable niche to maintain long survival and function of the implanted cells for bone regeneration.     

Hydrothermal production and characterization of protein and amino acids from silk waste

Non-catalytic hydrothermal decomposition of sericin and fibroin from silk waste into useful protein and amino acids was examined in a closed batch reactor at various temperatures, reaction times, and silk to water ratios to examine their effects on protein and amino acid yields. For the decomposition of sericin, the highest protein yield was found to be 0.466 mg protein/mg raw silk, obtained after 10 min hydrothermal reaction of silk waste at 1:100 silk to water ratio at 120 degrees C. The highest amino acid yield was found to be 0.203 mg amino acids/mg raw silk, obtained after 60 min of hydrothermal reaction of silk waste at 1:20 silk to water ratio at 160 degrees C. For the hydrothermal decomposition of fibroin, the highest protein yield was 0.455 mg protein/mg silk fibroin (1:100, 220 degrees C, 10 min) and that of amino acids was 0.755 mg amino acids/mg silk fibroin (1:50, 220 degrees C, 60 min). The rate of silk fibroin decomposition could be described by surface reaction kinetics. The soluble reaction products were freeze-dried to obtain sericin and fibroin particles, whose conformation and crystal structure of the particles were shown to differ from the original silk materials, particularly in the case of fibroin, in which the change from beta-sheet conformation to alpha-helix/random coil was observed.     

New process to form a silk fibroin porous 3-D structure

A new process to form fibroin spongy porous 3-D structure is reported herein. The process involves freezing and thawing fibroin aqueous solution in the presence of a small amount of an organic solvent. The process requires no freeze-drying, chemical cross-linking, or the aid of other polymeric materials. The solvent concentration, fibroin concentration, freezing temperature, and freezing duration affect the sponge formation, its porous structure, and its mechanical properties. Measurements by XRD and FTIR indicate that silk I and silk II crystalline structures exist in the fibroin sponge and that the secondary structure of fibroin is transformed to a beta-sheet from a random coil during this process. The tensile strength decreased slightly, but the fibroin sponge showed no deformation after autoclaving. Therefore, the fibroin sponge was sterilized using an autoclave. For 3 weeks, MC3T3 cells proliferated in the sterilized fibroin sponge. The fibroin sponge formed by this new process is applicable as a tissue-engineering scaffold because it is formed from biocompatible pure silk fibroin and offers both porous structure and mechanical properties that are suitable for cell growth and handling.     

酪氨酸酶催化氧化对丝素蛋白结构与性能的影响

采用酪氨酸酶对丝素蛋白催化氧化,考察了酶促氧化反应对丝素蛋白结构及丝素膜性能的影响。研究结果表明,酪氨酸酶可催化氧化丝素蛋白中酪氨酸残基生成多巴和多巴醌结构衍生物,并且两者含量随催化反应时间延长呈波动性变化;酶促反应后丝素蛋白中游离氨基含量下降,丝素风干膜断裂强度增加,表明酶促氧化中丝素大分子间发生自交联。XRD结果表明酪氨酸酶催化氧化对丝素蛋白二级结构有一定影响;SEM显示酶促改性可能影响丝素蛋白冷冻干燥膜多孔形态结构。     

Slit 2N与丝素蛋白混合物诱导大鼠海马神经元迁移的体外模型建立

目的：利用Slit排斥导向迁移和丝素蛋白,探索建立简便可行、经济实惠、作用持久的神经元导向迁移模型新方法。方法：提取SD新生鼠海马组织,以专用细胞培养片体外培养神经元,分为空白对照组、单纯丝素蛋白、单纯Slit 2N和Slit 2N与丝素蛋白混合物组（以下简称混合物组）,分别随机选择不同视野下50个神经元,用显微镜拍照记录胞体坐标及突起状态,除空白对照组外,其他3组均距每个神经元100 μm处添加相应诱导物,共观察30 min,再次记录后,用免疫荧光染色法鉴定细胞性质及其阳性率。结果：单纯Slit 2N组和混合物组均可见突起向浓度低处迁移或弯曲,且长度有所缩短,空白对照组和单纯丝素蛋白组未见明显变化。突起变化的平均持续时间及平均长度差从大到小依次为混合物组、单纯Slit 2N组、单纯丝素蛋白组（P<0.05）,单纯丝素蛋白组和空白对照组间无明显变化（P>0.05）。四组神经元MAP-2阳性率均达到90%以上。结论：丝素蛋白对Slit 2N诱导大鼠海马神经元迁移作用无明显影响,可有效减缓Slit 2N扩散速度,使作用时间延长,为治疗中枢神经系统疾病建立三维神经定向修复提供有利的体外实验构建基础。     

Structure and properties of silk fibroin-poly(vinyl alcohol) gel

A series of porous silk fibroin-poly(vinyl alcohol) blend gels were prepared from corresponding aqueous mixtures by freeze- or air-drying, and their structure and mechanical properties were examined. The air-dried gels had higher crystallinity and much greater strengths than the freeze-dried gels, and therefore are suitable for mechanical uses. The freeze-dried gels had characteristic porous structure potentially useful as cell culture substrate. Its structure could be systematically varied by changing freezing temperature and freeze-thaw pretreatments before drying.     

Engineering cartilage-like tissue using human mesenchymal stem cells and silk protein scaffolds

Human mesenchymal stem cells (hMSC) derived from bone marrow aspirates can form the basis for the in vitro cultivation of autologous tissue grafts and help alleviate the problems of immunorejection and disease transmission associated with the use of allografts. We explored the utility of hMSC cultured on protein scaffolds for tissue engineering of cartilage. hMSC were isolated, expanded in culture, characterized with respect to the expression of surface markers and ability for chondrogenic and osteogenic differentiation, and seeded on scaffolds. Four different scaffolds were tested, formed as a highly porous sponge made of: 1) collagen, 2) cross-linked collagen, 3) silk, and 4) RGD-coupled silk. Cell-seeded scaffolds were cultured for up to 4 weeks in either control medium (DMEM supplemented with 10% fetal bovine serum) or chondrogenic medium (control medium supplemented with chondrogenic factors). hMSC attachment, proliferation, and metabolic activity were markedly better on slowly degrading silk than on fast-degrading collagen scaffolds. In chondrogenic medium, hMSC formed cartilaginous tissues on all scaffolds, but the extent of chondrogenesis was substantially higher for hMSC cultured on silk as compared to collagen scaffolds. The deposition of glycosaminoglycan (GAG) and type II collagen and the expression of type II collagen mRNA were all higher for hMSC cultured on silk than on collagen scaffolds. Taken together, these results suggest that silk scaffolds are particularly suitable for tissue engineering of cartilage starting from hMSC, presumably due to their high porosity, slow biodegradation, and structural integrity.     

Silk scaffolds connected with different naturally occurring biomaterials for prostate cancer cell cultivation in 3D

In the present work, different biopolymer blend scaffolds based on the silk protein fibroin from Bombyx mori (BM) were prepared via freeze‐drying method. The chemical, structural, and mechanical properties of the three dimensional (3D) porous silk fibroin (SF) composite scaffolds of gelatin, collagen, and chitosan as well as SF from Antheraea pernyi (AP) and the recombinant spider silk protein spidroin (SSP1) have been systematically investigated, followed by cell culture experiments with epithelial prostate cancer cells (LNCaP) up to 14 days. Compared to the pure SF scaffold of BM, the blend scaffolds differ in porous morphology, elasticity, swelling behavior, and biochemical composition. The new composite scaffold with SSP1 showed an increased swelling degree and soft tissue like elastic properties. Whereas, in vitro cultivation of LNCaP cells demonstrated an increased growth behavior and spheroid formation within chitosan blended scaffolds based on its remarkable porosity, which supports nutrient supply matrix. Results of this study suggest that silk fibroin matrices are sufficient and certain SF composite scaffolds even improve 3D cell cultivation for prostate cancer research compared to matrices based on pure biomaterials or synthetic polymers.