综述了近年来微生物纤维素酶和动物纤维素酶分子结构和降解机制方面的研究进展。
The research advances of molecular structure and the degradation mechanism of cellulases separated horn microorganism and animal west summarized.
微生物纤维素生产的羧甲基纤维素的存在可能造成重大知道那些在许多技术手段先进的干燥。
Microbial cellulose produced in the presence of carboxymethyl cellulose may be substantially dried by many means known to those skilled in the art.
开发在微生物细胞外部能稳定存在的纤维素酶使真菌和酵母在纤维素水解产物上培养有了可能。
Development of celluloses that are stable outside the cells of microorganisms enables the culturing of fungi and with yeasts on cellulose hydrolyzates.
这个新发现的菌株可以利用任何来源的纤维素,不只是纸。事实上这种微生物是从动物粪便里发现的。
The newly discovered strain can be used to make fuel from any source of cellulose, not just paper. TU-103 was discovered in animal feces.
纤维素醋酸酯反渗透膜不用时必须贮存在一种溶液中,以防微生物生长。
Cellulose acetate reverse-osmosis membranes must be stored, when NOT in use, in a solution (sodium metabisulfite) that prevents microorganism growth.
纤维素的生物降解已经研究了很长的时间,到目前为止,还没有找到一种高效的酶或微生物来充分利用这种生物量。
Biodegradation of cellulose has been studied for a long time, but no enzyme or microorganism has been found to utilize cellulose efficiently.
如果微生物容器泄漏或是被摔倒并且破损,用纤维素覆盖这个地方并用大量消毒液冲洗。
If microorganism culture will be released or a culture container fall down and is breaking, you have to cover this place with cellulose and to disinfect with a lot of disinfection liquid.
纤维素和木质素是潜在的可再生资源,近年来,利用微生物对它们进行降解已成为研究的热点。
Lignin and cellulose are potential resources for being recycled. The investigation of biodegradation of lignin and cellulose by microorganisms has been more and more active in recent years.
纤维素分解菌作为发酵微生物菌群的一个重要组成部分,在畜禽粪便的资源化过程中得到了广泛应用。
Cellulose decomposing microorganisms, as an important part of them, were found to be very useful in the utilization of livestock and poultry manure.
本发明提供的复合微生物菌剂,对各类纤维素、蛋白质以及脂肪类大分子具有很强的消化能力。
The compound microbial bacterial preparation provided by the invention has strong digestion power for various types of cellulose, proteins and fat macromolecules.
研究了添加黄孢原毛平革菌胞外酶对农业废物堆肥中木质纤维素降解及微生物群落演替的影响。
The effect of extracellular enzymes of Phanerochaete Chrysosporium on the lignocellulose degradation and the succession of microbial community in agricultural waste composts were studied.
生物油优选采用含纤维素作为主要的碳源的原料,由一种或多种微生物经异养发酵进行制备。
The biological oils are preferably produced by heterotrophic fermentation of one or more microorganisms using cellulose-containing feedstock as a main source of carbon.
一个新成立的微生物产生的纤维素可以变成乙醇和其他生物燃料。
A newly created microbe produces cellulose that can be turned into ethanol and other biofuels.
微生物纯培养技术一直没有解决天然木质纤维素的分解难题。
Technique of microbial pure culture can not resolve the puzzle of lignocellulose degradation.
通过纤维素刚果红培养基初筛,滤纸失重实验复筛,35种微生物中有4株表现出较高的纤维素酶活力。
In advantage of cellulose-congo red medium and weight losing test of the filter paper, 4 out of the above-mentioned 35 strains showed higher enzyme activities.
在纤维素稀酸水解发酵制乙醇的过程中,由于弱酸、呋喃衍生物和苯系化合物对微生物的影响,乙醇的产量和产率都不高。
In hydrolysis of lignocellulosic materials, a lot of compounds which are inhibitory to microorganisms can be formed such as: weak acids, furan derivatives, and phenolic compounds.
能够产生纤维素酶的微生物的产酶能力低下,且所产生的酶的组分不全或不平衡。
Microorganism that can produce cellulase has low ability to produce enzyme, and the components of the produced enzyme are incomplete or unbalanced.
已有的研究表明,低等木食性白蚁对木质纤维素等植物源食物的消化主要与其肠道共生微生物有关。
It has been shown that the symbiotic gut microbiota in wood-feeding lower termites plays an important role in the digestion of different plant components.
最后,研究了胞外酶对农业废物堆肥中木质纤维素降解及微生物群落演替的影响。
The effects of extracellular enzymes on the lignocellulose degradation and the succession of microbial community in agricultural waste composts were studied.
哺乳动物(包括人)不能消化它,但草食性动物以纤维素为食,食入后在其消化道内停留的时间很长,这样生活于其消化道内的微生物便得以将它消化。
Mammals (including humans) cannot digest cellulose, but bacteria in the rumens of cattle and other ruminants and protozoans in the gut of termites produce enzymes that can break it down.
利用微生物将木质纤维素转化成乙醇已成为当前研究的热点。
For the conversion of lignocellulose into fuel ethanol by microorganisms is being studied intensively.
木质纤维素组分结构复杂,未处理的木质纤维素很难直接被微生物和酶降解。
Due to the special structure, untreated lignocellulosic was not able to be degraded directly by microbial and enzyme.
结果表明:微生物酶使木粉的玻璃化温度降低,纤维素的结晶度提高,综纤维素含量以及纤维素聚合度降低;
The result indicates:handled by enzyme, the wood's glass transition temperature, holo-cellulose content and degree of polymerization increased, crystallinity increased;
结果表明:微生物酶使木粉的玻璃化温度降低,纤维素的结晶度提高,综纤维素含量以及纤维素聚合度降低;
The result indicates:handled by enzyme, the wood's glass transition temperature, holo-cellulose content and degree of polymerization increased, crystallinity increased;
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