细菌纤维素是当今国内外生物材料研究的热点之一。
Bacterial Cellulose is one of the bio-material research hotspot in the world.
对静态发酵生产细菌纤维素的动力学模型进行了研究。
The dynamical model of static fermentation of Bacterial Cellulose was studied and established.
研究结果表明该菌所产凝胶膜的主要成分是细菌纤维素。
The findings indicated that the principal constituent of this strain producing gelatinous membrane is bacterial cellulose.
胡伟立,陈仕艳,王华平细菌纤维素模板合成研究进展。
Hu W. -l., Chen S. -y., Wang H. -p. Template synthesis based on bacterial cellulose.
制备细菌纤维素,观察纳米细菌纤维素的超微结构特点。
To prepare the biomaterial bacterial cellulose (BC) and observe the characteristic of its ultra-structure.
海伦·芬克及其同事已对细菌纤维素进行修复,以便于这些细胞粘附得更好。
Helen Fink and her colleagues have modified the bacterial cellulose so that these cells adhere better.
细菌纤维素作为一种新型的生物材料,逐渐成为近年来的研究热点。
As one of the newest biomaterials, bacterial cellulose is turning to be the hotspot.
简要概述了细菌纤维素的培养条件及后续处理过程对其性能的影响。
Effects of culturing conditions and the subsequent treatment on the properties of bacterial cellulose were summarized.
我们使用含糖的绿茶了解决,增加了细菌纤维素,其中也包含酵母菌和其他生物。
We use a sugary green tea solution to which is added a bacterial cellulose culture, which also contains yeasts and other organisms.
细菌纤维素是一种新型生物合成原料,它有许多优于植物纤维的特点。
Bacterial cellulose is a new kind of biologic compound material and it has many advantages more excellent than foliage fiber.
同时,拥有自己优化的醋酸杆菌菌种库及生物发酵法生产细菌纤维素的核心技术。
It is holding a self-optimized culture bank of Acetobacter and its core patented technology (ZL96100534.3) to produce bacterial cellulose with biological fermentation.
细菌纤维素的改性方法包括细菌发酵时的生物改性及纤维素提纯之后的化学改性。
Modification of bacterial cellulose includes bio-modification during fermentation and chemical modification after purification.
把细菌纤维素添加到鲜奶中进行发酵,采用正交实验设计确定乳酸菌发酵的最佳条件。
Adding bacterial cellulose to fresh milk to ferment, the optimum fermented condition was studied by orthogonal experiment.
细菌纤维素作为一种新型的生物材料,由于其独特的功能性正受到科学界的广泛关注。
Bacterial cellulose, as a new biological material with unique functions, is attracting the interest of the scientists.
本文主要介绍了细菌纤维素的独特性质、合成和分泌过程,及细菌纤维素的商业用途。
This article mainly introduced bacterial cellulose unique nature, synthesis and secretion process, and bacterial cellulose commercial applications.
选用玉米浸出液为培养料生产细菌纤维素,可以降低原料成本,提高细菌纤维素产量。
The material cost of bacterium cellulose production can be reduced and the output of bacterium cellulose can be increased by choosing corn soaking water as the cultivation medium.
细菌纤维素框架由于卓越的机械特性和生物相容性BC表明对组织工程应用是良好候选物。
Due to outstanding mechanical properties and biocompatibility the BC appears a favourable candidate for tissue engineering applications.
扫描电镜下可见细菌纤维素膜呈疏松的网状结构,纤维素微纤丝从菌体胞壁小孔中分泌出来;
The surface of BC membranes was porous network structure observed by SEM, and the micro-fibrils of BC were secreted from the eyelet of cell wall.
目前已经发现有九个菌属可以产生细菌纤维素,其中以醋酸杆菌属的木醋杆菌产纤维素能力最强。
It was found that nine bacterial can produce bacterial cellulose, among them the wood acid bacilli cellulose has the most effective produtivity.
对细菌纤维素的结构、性质、生产和应用进行了介绍,指出细菌纤维素是一种有广阔前景的产品。
The structure and performance of bacterial cellulose is presented. The production and application is also recommended. It is expected that in the future bacterial cellulose is a promising product.
生产出的细菌纤维素酸奶和普通酸奶相比较,凝固状态、质地、口感以及功能性都有了很大的改善。
Comparing bacterial cellulose yogurt to common yogurt, the result showed the concretionary state, texture, oral feel and function of bacterial cellulose yogurt could improve greatly.
对静态发酵生产细菌纤维素的动力学模型进行了研究,初步建立了细菌纤维素静态发酵生产的动力学模型。
The paper mainly studied the dynamical model of the static fermentation of Bacterial Cellulose(BC). Thus the dynamical model of BC in static fermentation was established.
结果表明:新鲜制备的细菌纤维素膜为无色透明胶冻状膜,表面光滑;经预处理后呈乳白色半透明胶冻状;
Results showed that BC membranes that fresh prepared was smooth, colorless and jel alike and it showed translucence after pre-disposal treatment.
将其添加到新鲜牛奶中进行乳酸菌发酵,采用正交实验设计确定乳酸菌的最佳发酵条件,研制出细菌纤维素酸奶。
After bacterial cellulose was added to fresh milk to ferment, the optimum fermented condition was studied by orthogonal experiment.
合成细菌纤维素时向培养基中添加了海藻酸钠、羧甲基纤维素、 羧甲基壳聚糖等多糖,制备出了性能更优异的改性细菌纤维素。
The modified bacterial cellulose was synthesized by the addition of polysaccharide such as sodium alginate, carboxymethye cellulose and carboxymethye chitosan to the culture medium.
在静态培养的基础上,分析了细菌纤维素膜的X -衍射图谱、渗透性能和持水性等,为细菌纤维素在医学上的应用积累了重要的基础数据。
Based on the static fermentation, this paper analyzed X-ray diffraction patterns, permeability and holding water capacity. The important data could apply to medical application.
虽然那些组成植物茎干纤维素和木质素的分子不能为酵母所消化,但是某些细菌和其他种类的真菌可以完成这项任务。
Although yeast cannot digest cellulose or lignin, the molecules that form a plant's skeleton, some bacteria and other species of fungi are able to do the job.
旋转的细菌,在表面形成一层受约束的纤维素线。
The bacteria spin cellulose threads, which bind on the surface forming a layer.
旋转的细菌,在表面形成一层受约束的纤维素线。
The bacteria spin cellulose threads, which bind on the surface forming a layer.
应用推荐