壳聚糖-海藻酸钠靛玉红自微乳缓释微囊制备、评价及体外释放的研究

以靛玉红自微乳为囊心物,壳聚糖和海藻酸钠为囊材,采用复凝聚法制备壳聚糖-海藻酸钠靛玉红自乳化缓释微囊,通过正交实验和单因素考察确定壳聚糖-海藻酸钠靛玉红缓释微囊的最佳制备工艺。并以载药量、包封率为评价指标对其进行质量评价,同时以体外释放度评价其释药性能。壳聚糖-海藻酸钠靛玉红缓释微囊的最佳工艺是海藻酸钠的浓度为1.5%,靛玉红自微乳体积、海藻酸钠体积、壳聚糖质量三者比例为1∶1∶0.5,氯化钙浓度的最佳浓度为2.0%。采用该工艺制备的微囊载药量为0.0416%、包封率为79.2%,体外释放24 h累积释放率为(97.1±2.68)%。该微囊的释放符合Higuchi方程和一级释药模型,具有较好的缓释作用。     

快速膨胀片层多孔壳聚糖止血海绵的制备及生物相容性研究

目的:探索快速膨胀片层多孔壳聚糖止血海绵的制备工艺,评价止血海绵的理化性能及生物相容性,并探讨原料脱乙酰度对止血海绵性能的影响。方法:考察止血海绵的理化性质,包括扫描电子显微镜(SEM)观察表观形貌,检测力学性能、吸水率、快速吸水膨胀时间和膨胀率,研究其体内外的生物相容性,包括体外细胞毒性实验、动物皮内刺激实验和皮下植入实验。结果:确定了止血海绵的制备工艺,采用该工艺制备的止血海绵均具有片层多孔结构,且具有较高的力学强度和快速膨胀的特点。证实高脱乙酰度原料(DD=95.14%)制备的止血海绵力学性能、吸水率、膨胀率均优于低脱乙酰度原料(DD=69.70%)制备的止血海绵。脱乙酰度69.70%和脱乙酰度95.14%的壳聚糖止血海绵,拉伸强度分别为10.1 N和15.4 N,吸水率分别为1904%和2131%,吸水膨胀时间分别为13.4 s和14.0 s,膨胀率分别为8.4倍和10.8倍。体外细胞毒性实验表明脱乙酰度为95.14%的壳聚糖止血海绵更有利于细胞的增殖,皮内刺激和皮下植入实验结果表明脱乙酰度为95.14%的壳聚糖海止血海绵表现出更小的组织炎性反应。结论:脱乙酰度为95.14%的壳聚糖止血海绵具有优良的力学性能、优异的吸水膨胀能力以及良好的生物相容性,在临床止血特别是腔隙止血方面具有广阔的应用前景。     

丝素蛋白/羟基磷灰石复合物对磷酸钙骨水泥性能的影响

目的：磷酸钙骨水泥（Calcium phosphate cement,CPC）以其诸多优点正得到了越来越多的应用,但其较差的力学性能表现也限制了它的使用范围。本研究目的在于改善磷酸钙骨水泥的力学性能,同时评估改性后的磷酸钙骨水泥的其他性能。方法：通过丝素蛋白（Silk fibroin,SF）的矿化自组装方法制备丝素蛋白／羟基磷灰石复合物（silk fibroin/hydroxyapitite composite, SF/HA）。按照1％、2％、3％、4％的质量分数加入磷酸钙骨水泥中,与磷酸钙骨水泥组对比。比较内容包括力学强度、抗渍散性能及细胞毒性。结果：以丝素蛋白溶液为液相组的磷酸钙骨水泥强度大约为35MPa。随后随着添加丝素蛋白／羟基磷灰石复合物的质量分数从1％增至3％,磷酸钙骨水泥的强度逐渐增加（P〈0．05）,最高约至45MPa。而当丝素蛋白／羟基磷灰石的质量分数达到4％时,磷酸钙骨水泥的强度较质量分数3％组小幅度下降至43MPa（P〈0．05）。以丝素蛋白溶液作为液相时,磷酸钙骨水泥的抗溃散能力也得到了加强。在MTT法测定细胞活力的对照实验中,无论是加入丝素蛋白溶液或丝素蛋白／羟基磷灰石复合物,都未观察到细胞毒性。结论：在磷酸钙骨水泥中加入3％质量分数的丝素蛋白／羟基磷灰石复合物,能显著提高磷酸钙骨水泥的抗压强度。而丝素蛋白溶液作为液相可改善磷酸钙骨水泥的抗溃散能力。同时,丝素蛋白和丝素蛋白／羟基磷灰石复合物都不表现出细胞毒性。更理想的力学强度和更强的抗溃散能力,大大扩展了磷酸钙骨水泥的应用范围。     

人工软骨支架中TGF-β1缓释壳聚糖微球对ATDC-5细胞生长的促进作用

为了提高本课题组前期构建的Ⅱ型胶原蛋白-透明质酸-硫酸软骨素的人工三维软骨支架对软骨细胞生长的促进作用,采用乳化交联法以壳聚糖为原料,加入细胞转化生长因子TGF-β1,并通过真空冷冻干燥技术制备了包裹TGF-β1的壳聚糖微球。然后分别将其与空白壳聚糖微球整合进软骨支架中,并接种小鼠软骨细胞ATDC-5,通过观察细胞生长状态来评价缓释微球在人工软骨支架中对软骨细胞生长是否具有促进作用。结果显示所制得的壳聚糖微球球体表面光滑,分散均匀,直径在100 nm左右,吸水率良好可达983.73%±4.38%,抗酶解作用较强,第28天时降解率仅达到51.0%±1.8%。由TGF-β1累积释放曲线可知TGF-β1在开始的24 h内释放最快,之后逐渐减慢,在120 h之后进入平台期,具有缓释效果。MTT试验以及荧光染色试验充分表明,由Ⅱ型胶原蛋白、透明质酸以及硫酸软骨素构建的三维软骨支架适合ATDC-5细胞的生长增殖,并且壳聚糖微球对TGF-β1的缓释能够显著促进细胞的生长。     

类人胶原蛋白-丝素蛋白血管支架的制备及性能表征

为了提高血管支架的力学性能,将生物相容性良好的新型生物材料类人胶原蛋白(基因工程技术、高密度发酵生产)与丝素蛋白以质量比9:1、7:3、5:5复合,采用真空冷冻方法制备管状血管支架。研究了不同配比血管支架材料的表面结构、表面元素组成、力学性能、降解和生物相容性。结果表明:当类人胶原蛋白与丝素蛋白的质量比为7:3混合时,类人胶原蛋白-丝素蛋白管状支架具有均匀的多孔结构,孔径为(60±5)μm,孔隙率达到85%以上;获得了较理想的力学性能:应变为50%±5%,应力为(332±16)kPa;具有相对慢的降解速率;提高了细胞的黏附与增殖,具有良好的生物相容性。     

丝素蛋白材料在皮肤创伤愈合中的研究进展

摘要：丝素蛋白是一种天然的高分子纤维蛋白,其结构的特殊性决定了较好的机械性能,再因其优良的生物相容性、降解产物无毒等特点,被广泛用于各种材料的研究。通过各种化学修饰和负载生长因子等,使丝素蛋白在体内外具有促进成纤维细胞增殖分化的作用,拥有诱导创面愈合的功能,同时其可部分降解,具有缓释性能好,柔韧性强,透气以及透水等较好的理化性质不但在皮肤组织工程学中的广泛的应用,并且在敷料领域的研究也显示了其治疗烧烫伤、创伤达到抑制疤痕、促进伤口快速愈合的治疗效果。总之,通过改良丝素蛋白材料的加工方法,通过化学修饰、其他物质复合等手段得到适合于皮肤修复的具有优良性能的各种材料,是具有很大潜力的极具临床价值的皮肤修复材料。本文旨在综述国内及国外学者的各种关于丝素蛋白生物材料治疗皮肤损伤的研究最新进展。     

壳聚糖-三聚磷酸钠纳米粒对于肝组织严重出血模型的止血效果

目的:建立SD大鼠肝脏严重出血模型,考察壳聚糖-三聚磷酸钠(TPP)纳米粒的止血效果对于实质性器官严重出血的止血效果。方法:24只SD大鼠各分3组,每组8只,分为阴性对照组、壳聚糖-TPP组(NP组)和正常组,其中阴性对照组和NP组的大鼠建立肝脏严重出血模型。NP组,将壳聚糖-TPP纳米粒喷射到伤口,直至将整个伤口覆盖。阴性对照组,不使用任何止血材料处理创面。术后15天,用SEM和TEM观察NP组和阴性对照组的肝组织的微观结构。结果:通过组织学检查发现壳聚糖-TPP纳米粒在治疗严重伤口时能加速肉芽和大量胶原蛋白的生成,这正是伤口愈合初期的标志。结论:壳聚糖-TPP纳米粒对于严重出血的实质器官可发挥优良的止血性能,并能促使伤口愈合。     

壳聚糖/ 魔芋葡甘露聚糖复合膜体内外促创面愈合研究

目的:制备壳聚糖/魔芋葡甘露聚糖复合膜,研究其促创面愈合作用。方法:壳聚糖溶液和魔芋葡甘露聚糖溶液混合后冷冻干燥制成复合膜。扫描电镜观察膜的形态和孔径,并研究比较膜的吸水率,水蒸气透过率,拉伸强度,断裂伸长率和体外降解率。建立大鼠皮肤损伤模型,敷以复合膜治疗,比较创面愈合率,观察创面组织染色结果,评价复合膜的促创面愈合作用。结果:壳聚糖/魔芋葡甘露聚糖复合膜具有三维网状结构,壳聚糖复合魔芋葡甘露聚糖后,膜的吸水率、拉伸强度和断裂伸长率提高,体外降解加速,水蒸气透过率改善。愈合实验表明壳聚糖/魔芋葡甘露聚糖膜具有促进创面愈合作用。结论:壳聚糖/魔芋葡甘露聚糖复合膜制备工艺简单,能有效促进创面愈合,具有成为创伤敷料的潜力。     

壳聚糖复合KGF 2突变体温敏敷料联合简易负压吸引法对压力性损伤的疗效

目的探究壳聚糖复合角质细胞生长因子(keratinocyte growth factor-2,KGF-2)突变体温敏敷料联合简易负压吸引法对长期卧床老年患者大面积压力性损伤的治疗效果。方法选择2016年1月至2018年12月我院普外科收治的90名大面积压力性损伤患者,随机分为对照组与观察组,各45例。对照组患者采用简易负压吸引联合传统泡沫敷料治疗,观察组患者在此基础上联合壳聚糖复合KGF-2突变体温敏敷料填充。比较两组患者的伤口愈合效果以及创面细菌检出率。结果观察组患者的伤口愈合总有效率(93.3%)明显高于对照组(75.6%),差异有统计学意义(χ~2=5.41,P=0.003)。观察组患者细菌检出率(8.89%)显著低于对照组(35.56%),差异有统计学意义(χ~2=3.02,P=0.003)。结论壳聚糖复合KGF-2突变体温敏敷料联合简易负压吸引法能显著促进长期卧床老年患者大面积压力性损伤创面愈合,降低交叉感染的风险,具有较好的临床应用效果。     

不同钙-醇溶解体系丝素蛋白的制备及表征研究

采用 ４种中性盐溶液 Ｃａ（ＮＯ３）２４Ｈ２Ｏ 甲醇、Ｃａ（ＮＯ３）２４Ｈ２Ｏ 乙醇、ＣａＣｌ２ 甲醇 水和 ＣａＣｌ２ 乙醇 水（摩尔比分别为 １∶２、１∶２、１∶２∶８、１∶２∶８）处理蚕丝纤维,透析后经冷冻干燥制成固体,利用ＳＤＳ ＰＡＧＥ、电镜扫描和红外光谱对制得的固体进行表征。ＳＤＳ ＰＡＧＥ结果表明：Ｃａ（ＮＯ３）２４Ｈ２Ｏ 醇体系降解丝素蛋白较 ＣａＣｌ２ 醇 水体系降解程度高;电镜扫描的结果表明 Ｃａ（ＮＯ３）２４Ｈ２Ｏ 甲醇和 ＣａＣｌ２ 乙醇 水溶解体系处理的丝素蛋白溶解比较完全,Ｃａ（ＮＯ３）２４Ｈ２Ｏ 甲醇处理的丝素蛋白冻干后为颗粒状,而 ＣａＣｌ２ 乙醇 水处理的丝素蛋白冻干后为片状。红外光谱的结果表明：４种溶液处理后的丝素蛋白构象均介于 β折叠和无规则卷曲之间,从而为丝素蛋白在药物缓释载体领域的应用提供了一定的理论依据。     

Wound dressings for a proteolytic-rich environment

Wound dressings have experienced continuous and significant changes over the years based on the knowledge of the biochemical events associated with chronic wounds. The development goes from natural materials used to just cover and conceal the wound to interactive materials that can facilitate the healing process, addressing specific issues in non-healing wounds. These new types of dressings often relate with the proteolytic wound environment and the bacteria load to enhance the healing. Recently, the wound dressing research is focusing on the replacement of synthetic polymers by natural protein materials to delivery bioactive agents to the wounds. This article provides an overview on the novel protein-based wound dressings such as silk fibroin keratin and elastin. The improved properties of these dressings, like the release of antibiotics and growth factors, are discussed. The different types of wounds and the effective parameters of healing process will be reviewed.     

Promotive effects of a silk film on epidermal recovery from full-thickness skin wounds

We examined the effects of the transparent fibroin film (silk film) on full-thickness skin wounds. Full-thickness dermatotomies (15 mm x 9 mm) were prepared on the dorsal wall of CRJ:CD-1 nu/nu (ICR nu/nu) mice. The area of the wounds dressed with silk film was reduced to 10% of that made by the dermatotomy 14 days after the dermatotomy and were covered with regenerated epidermis 21 days after the dermatotomy. In contrast, less recovery and epidermal regeneration were found 14 days after dermatotomy in the wounds dressed with a conventional hydrocolloid dressing (Duro Active). Furthermore, only partial incomplete epidemal growth was obtained 21 days after dermatotomy. Most importantly, the healing time of wounds dressed with silk film was 7 days shorter than those dressed with DuoActive dressing. The silk film showed an almost similar or slightly better promotive effect as the lyophilized porcine dermis (Alloask D), which is used as a dressing for burns, ulcers, and decubitis. Histologic findings revealed that there was greater collagen regeneration and less inflammation and neutrophil-lymphocyte infiltration of the wounds dressed with silk film than with DuoActive dressing. It is clear that regeneration of the epidermis and dermis of the wound beds covered with silk film was faster than with DuoActive dressing. Finally, silk film is easily obtainable, sterilizable, and transparent, and it allows easy observation of tissue recovery. Therefore, silk film offers advantages over other dressings and may be clinically useful for wound treatment.     

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.     

GNPs-CS/KGM as Hemostatic First Aid Wound Dressing with Antibiotic Effect: In Vitro and In Vivo Study

Ideal wound dressing materials should create a good healing environment, with immediate hemostatic effects and antimicrobial activity. In this study, chitosan/konjac glucomannan (CS/KGM) films embedded with gentamicin-loaded poly(dex-GMA/AAc) nanoparticles (giving GNP-CS/KGM films) were prepared as novel wound dressings. The results revealed that the modified CS/KGM films could be used as effective wound dressings and had significant hemostatic effects. With their microporous structure, the films could effectively absorb water from blood and trap blood cells. The gentamicinloaded poly(dex-GMA/AAc) nanoparticles (GNPs) also further promoted blood clotting, with their favorable water uptake capacity. Thus, the GNP-CS/KGM films had wound healing and synergistic effects that helped to stop bleeding from injuries, and also showed good antibiotic abilities by addition of gentamicin to the NPs. These GNPCS/KGM films can be considered as promising novel biodegradable and biocompatible wound dressings with hemostatic capabilities and antibiotic effects for treatment of external bleeding injuries.     

Chitins and chitosans for the repair of wounded skin,nerve, cartilage and bone

This review provides a balanced integration of the most recent chemical, biochemical and medical information on the unique characteristics of chitins and chitosans in the area of animal/human tissue regeneration. Hemostasis is immediately obtained after application of most of the commercial chitin-based dressings to traumatic and surgical wounds: platelets are activated by chitin with redundant effects and superior performances compared with known hemostatic materials. To promote angiogenesis, necessary to support physiologically ordered tissue formation, the production of the vascular endothelial growth factor is strongly up-regulated in wound healing when macrophages are activated by chitin/chitosan. The inhibition of activation and expression of matrix metalloproteinases in primary human dermal fibroblasts by low MW chitosans prevents or solves problems caused by metalloproteinase-2 such as the hydrolysis of the basement membrane collagen IV. Experimental biocompatible wound dressings derived from chitin are today available in the form of hydrogels, xerogels, powders, composites, films and scaffolds: the latter are easily colonized by human cells in view of the restoration of tissue defects, with the advantage of avoiding retractive scar formation. The growth of nerve tissue has been guided with chitin tubes covalently coated with oligopeptides derived from laminin. The regeneration of cartilage is also feasible because chitosan maintains the correct morphology of chondrocytes and preserves their capacity to synthesize cell-specific extracellular matrix: chitosan scaffolds incorporating growth factors and morphogenetic proteins have been developed. Impressive advances have been made with osteogenic chitosan composites in treating bone defects, particularly with osteoblasts from mesenchymal stem cells in porous hydroxyapatite-chitin matrices. The introduction of azido functions in chitosan has provided photo-sensitive hydrogels that crosslink in a matter of seconds, thus paving the way to cytocompatible hydrogels for surgical use as coatings, scaffolds, drug carriers and implants capable to deliver cells and growth factors. The peculiar biochemical properties of chitins and chitosans remain unmatched by other polysaccharides.     

High-efficient and synergetic antibacterial nanocomposite hydrogel with quaternized chitosan/Ag nanoparticles prepared by one-pot UV photochemical synthesis

Hydrogel dressings have significant advantages such as absorption of tissue exudate, maintenance of proper moist environment, and promotion of cell proliferation. However, facile preparation method and high-efficient antibacterial hydrogel dressings are still a great challenge. In this study, a facile approach to prepare antibacterial nanocomposite hydrogel dressing to accelerate healing was explored. The hydrogels consisted of quaternized chitosan and chemically cross-linked polyacrylamide, as well as silver nanoparticles (AgNPs) stabilized by chitosan. The synthesis of the hydrogels including the formation of AgNPs and polymerization of acrylamide was accomplished simultaneously under UV irradiation in 1 hour without adding initiator. The hydrogels showed favorable tensile strength of ∼100 kPa with elongation at break over 1000% and shear modulus of ∼10⁴ Pa as well as suitable swelling ratio, which were appropriate for wound dressing. The combination of quaternized chitosan and AgNPs exhibited high-efficient and synergetic antibacterial performance with low cytotoxicity. In vivo animal experiments showed that the hydrogel can effectively prevent wound infection and promote wound healing. This study provides a facile method to produce antibacterial hydrogel wound dressing materials.     

静电纺丝用作难愈合伤口敷料的研究进展

静电纺丝伤口敷料作为一种新型功能性敷料,具有较大的比表面积、可调控的孔隙率和良好的生物性能,既有益于细胞呼吸,又 可抑制细菌感染伤口,并能促进细胞增殖和加速创面愈合,是未来伤口敷料研发领域发展的新方向。介绍静电纺丝纳米纤维的原理、特点, 重点阐述各类聚合物、生物活性物质在静电纺丝伤口敷料制备中的应用进展。     

Cytotoxicity testing of wound-dressing materials

A method was developed for testing the cytotoxicity of various bandage-like wound dressings and gel wound dressings. In this method, the ability of human polymorphonuclear neutrophils (PMNs) to initiate a respiratory burst after exposure to the various wound dressings is used as a marker of cytotoxicity. Luminol-amplified chemiluminescence stimulated with opsonised zymosan or phorbol 12-myristate 13-acetate (PMA) is used to measure the degree of activation of the respiratory burst, i.e. the NADPH oxidase activity, after exposure to wound dressings. Opsonised zymosan (material from yeast cell walls) is a phagocytic stimulus that activates the NADPH oxidase by binding to FC-receptors and complement receptors, and functions as an artificial bacterium, whereas PMA activates the NADPH oxidase by direct activation of protein kinase C. NADPH oxidase activity was inhibited by several wound dressings. The down-regulation of the respiratory burst is detrimental to the bactericial effect of PMNs, and can be used as a marker for the cytotoxicity of wound dressing materials.     

THE CONTROL OF WIREWORM BY GAMMA BENZENE HEXACHLORIDE: THE DEVELOPMENT OF A SEED DRESSING FOR CEREALS

Gamma benzene hexachloride has been used successfully as a seed dressing in field trials for wireworm control. For application to cereals at 2 oz./bushel, the optimum concentration of γ-isomer was 20–30 % in a dressing which advantageously included an organomercurial seed disinfectant.
Risks to germination and plant growth were thoroughly explored in the field. The 20 and 30 % dressings were safe; over-strength dressings containing 50 or 70 %γ-B.H.C. did not reduce grain yields significantly.
Seed dressed with 20 or 30 %γ-B.H.C. germinated normally after storage for 12 months. When seed was dressed at 4 oz./bushel with 35 %γ-B.H.C. and 1 % mercury as organomercurial, germination was delayed but total emergence was not affected.