奥得福尔制剂的药效学研究与临床

对奥得福尔制剂的药效学定量杀菌试验、抗病毒试验及临床应用的结果表明： 得福尔制剂原液,１：１稀释液及１：５稀释液对大肠杆菌、金黄色葡萄球菌和白色念珠菌作用１０ｍｉｎ,杀灭率均可达９９．９％以上;消毒液放置室温下稳定,有机物的存在对杀灭作用有轻度影响,但杀灭率仍可达９９．９％以上;体外抗病毒试验结果表明,该制剂的主要抗病毒功效成分－黄精多糖,对单纯疱疹病毒的空斑抑制率达到１００％;稳定性试验表明,该     

Meta分析及其在生态学上的应用

１Ｍｅｔａ分析的概念和它的发展应用Ｍｅｔａ分析（Ｍｅｔａ－Ａｎａｌｙｓｉｓ）是一种定量综合研究结果的方法．这种方法的思想起源于本世纪３０年代,６０年代用于教育、心理等社会科学领域,１９７６年由Ｇｌａｓ命名为术语“Ｍｅｔａ－Ａｎａｌｙｓｉｓ”［１］。Ｇ...     

广西姑婆山及邻近地区大型真菌物种多样性

姑婆山紧邻南岭生物多样性保护优先区，孕育了丰富的生物资源。为了解该区域大型真菌物种多样性，该文采用随机踏查法对广西姑婆山自治区级自然保护区(以下简称姑婆山)及邻近地区大型真菌资源进行调查采集，并结合形态学和分子生物学方法进行物种鉴定。结果表明：(1)共发现348种大型真菌，隶属于2门6纲17目69科175属，其中包含食用菌40种、药用菌42种、毒菌7种。(2)对该区的物种组成分析表明，优势科为蘑菇科(Agaricaceae)、牛肝菌科(Boletaceae)、粉褶蕈科(Entolomataceae)和锈革菌科(Hymenochaetaceae)等9科；优势属为鹅膏属(Amanita)、靴耳属(Crepidotus)、毛皮伞属(Crinipellis)和粉褶蕈属(Entoloma)等11属。(3)共发现2个中国特有属，即脆孔菌属(Fragiliporia)和臧氏牛肝菌属(Zangia);11个中国特有种，即厚集毛菌(Coltricia crassa)、魏氏集毛菌(C.weii)、丛生粉褶蕈(Entoloma caespitosum)、极细粉褶蕈(E.praegracile)、近薄囊粉褶蕈...     

真菌鞘糖脂的生物学功能及应用研究进展

丝状真菌作为一类重要的微生物，被广泛应用于发酵食品、工业酶和次生代谢物等工业生产中。真菌鞘糖脂主要由鞘氨醇、脂肪酸链和特殊的极性基团组成，根据极性基团的不同，分为中性鞘糖脂和酸性鞘糖脂两大类。鞘糖脂不仅参与真菌生长、细胞分化、增殖、细胞凋亡、逆境胁迫等重要生理活动，中性鞘糖脂还可作为功能性医药用品、化妆品和保健食品的重要活性组分。本文论述了真菌鞘糖脂的主要种类、结构、生物合成途径和及其参与丝状真菌生长、分化和响应逆境胁迫的生物学功能；探讨了真菌中性鞘糖脂作为抗菌肽的靶点和酸性鞘糖脂在开发抗真菌药物中的应用；同时还综述了中性鞘糖脂作为化妆品的保湿成分或保健食品的功能成分，在改善皮肤屏障功能和预防特应性皮炎中的重要作用的相关研究进展，尤其是来源于曲霉的中性鞘糖脂，可显著增强皮肤屏障功能，并可作为益生元预防肠道损伤；另外还探讨了曲霉尤其是米曲霉作为开发中性鞘糖脂生物资源的优势。     

当归抗抑郁作用及配伍应用

旨在探讨当归在抑郁症治疗中发挥的作用。通过分析相关文献,结合当归的临床功效和抑郁症的疾病特点,概括当归抗抑郁作用规律。当归在抑郁症治疗中具有补血以养肝体、活血以通心脉、通便以利肠腑的作用,以其为主药的抗抑郁复方临床应用广泛。当归的抗抑郁作用值得进一步深入研究。     

Fe3O4/ 生物可降解复合材料研究

磁性氧化铁纳米粒子因具有尺寸小、低毒性和超顺磁性等特点,已经引起了生物化工、医药工业领域的广泛关注。生物可降解高分子材料是生物医用高分子研究中最活跃的领域之一,已广泛用于外科手术缝合线,植入体材料及药物释放载体等。将Fe3O4和生物可降解高分子材料进行复合,可以扩大两者的应用范围,达到理想的治疗效果,并有望开创临床治疗的新时代。本文介绍了磁性四氧化三铁粒子的化学制备方法,包括共沉淀法、溶胶-凝胶法、微乳液法,并对各种方法的优缺点进行了比较;重点阐述了磁性壳聚糖,磁性聚乳酸,磁性PEG,磁性PCL复合材料的制备,及它们在酶的固定化、磁靶向药物及基因载体等医学领域的应用,显示了Fe3O4/生物可降解复合材料在医学领域的广阔应用前景;最后对复合材料走向临床应用所面临的问题及发展前景进行了讨论。     

The significance of arbutin and its derivatives in therapy and cosmetics

The ongoing studies on biological activity of arbutin and its derivatives show a wide range of their possible applications. Arbutin containing plant substances are used mostly in the treatment of urinary tract infections (UTI). However, several in vitro and in vivo studies revealed anti-melanogenic activity of arbutin, which can be useful in hyperpigmentation therapy. Moreover, it was found that the modifications in arbutin structure lead to an increase of the above-mentioned activity. The lack of significant adverse effects of arbutin and its derivatives makes them a valuable alternative to hydroquinone. Therefore, an increasing interest in arbutin and its derivatives is observed especially in the cosmetics industry.The scope of biological activity covered by the findings of in vivo and in vitro studies on arbutin and its derivatives are discussed.     

The Physiological,Biochemical and Molecular Roles of Brassinosteroids and Salicylic Acid in Plant Processes and Salt Tolerance

Plant hormones regulate plant growth and development by affecting an array of cellular, physiological, and developmental processes, including, but not limited to, cell division and elongation, stomatal regulation, photosynthesis, transpiration, ion uptake and transport, initiation of leaf, flower and fruit development, and senescence. Environmental factors such as salinity, drought, and extreme temperatures may cause a reduction in plant growth and productivity by altering the endogenous levels of plant hormones, sensitivity to plant hormones, and/or signaling pathways. Molecular and physiological studies have determined that plant hormones and abiotic stresses have interactive effects on a number of basic biochemical and physiological processes, leading to reduced plant growth and development. Various strategies have been considered or employed to maximize plant growth and productivity under environmental stresses such as salt-stress. A fundamental approach is to develop salt-tolerant plants through genetic means. Breeding for salt tolerance, however, is a long-term endeavor with its own complexities and inherent difficulties. The success of this approach depends, among others, on the availability of genetic sources of tolerance and reliable screening techniques, identification and successful transfer of genetic components of tolerance to desired genetic backgrounds, and development of elite breeding lines and cultivars with salt tolerance and other desirable agricultural characteristics. Such extensive processes have delayed development of successful salt-tolerant cultivars in most crop species. An alternative and technically simpler approach is to induce salt tolerance through exogenous application of certain plant growth–regulating compounds. This approach has gained significant interest during the past decade, when a wealth of new knowledge has become available on the beneficial roles of the six classes of plant hormones (auxins, gibberellins, cytokinins, abscisic acid, ethylene, and brassinosteroids) as well as several other plant growth–regulating substances (jasmonates, salicylates, polyamines, triacontanol, ascorbic acid, and tocopherols) on plant stress tolerance. Among these, brassinosteroids (BRs) and salicylic acid (SA) have been studied most extensively. Both BRs and SA are ubiquitous in the plant kingdom, affecting plant growth and development in many different ways, and are known to improve plant stress tolerance. In this article, we review and discuss the current knowledge and possible applications of BRs and SA that could be used to mitigate the harmful effects of salt-stress in plants. We also discuss the roles of exogenous applications of BRs and SA in the regulation of various biochemical and physiological processes leading to improved salt tolerance in plants.     

A link between the accumulation of DNA damage and loss of multi‐potency of human mesenchymal stromal cells

Human mesenchymal stromal cells (hMSCs) represent an attractive cell source for clinic applications. Besides being multi‐potent, recent clinical trials suggest that they secrete both trophic and immunomodulatory factors, allowing allogenic MSCs to be used in a wider variety of clinical situations. The yield of prospective isolation is however very low, making expansion a required step toward clinical applications. Unfortunately, this leads to a significant decrease in their stemness. To identify the mechanism behind loss of multi‐potency, hMSCs were expanded until replicative senescence and the concomitant molecular changes were characterized at regular intervals. We observed that, with time of culture, loss of multi‐potency was associated with both the accumulation of DNA damage and the respective activation of the DNA damage response pathway, suggesting a correlation between both phenomena. Indeed, exposing hMSCs to DNA damage agents led to a significant decrease in the differentiation potential. We also showed that hMSCs are susceptible to accumulate DNA damage upon in vitro expansion, and that although hMSCs maintained an effective nucleotide excision repair activity, there was a progressive accumulation of DNA damage. We propose a model in which DNA damage accumulation contributes to the loss of differentiation potential of hMSCs, which might not only compromise their potential for clinical applications but also contribute to the characteristics of tissue ageing.