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有机酸是含有一种或多种低分子量酸性基团(如羧基、磺酸基)的可生物合成的有机化合物,广泛应用于食品、农业、医药、生物基材料工业等领域。酵母菌具有生物安全、抗逆性强、底物谱广泛、方便遗传改造,以及大规模培养技术成熟等独特优点,因此利用酵母菌生产有机酸的研究日益受到国内外学者的关注。目前利用酵母生产有机酸还存在浓度低、副产物多,以及发酵效率低等缺陷。随着酵母菌代谢工程和合成生物学技术的发展,利用酵母菌生产有机酸取得了快速进展。本文总结了利用酵母合成11种有机酸的研究,包括内源和异源合成的大宗羧酸和高价值有机酸,并对该领域的未来研究方向进行了展望。 相似文献
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本文对2022年《生物工程学报》发表的与合成生物制造相关的综述和研究论文进行了评述,重点讨论了DNA测序、DNA合成、DNA编辑、基因表达调控和数学细胞模型等底层技术,酶的设计、改造和应用技术,化学品生物催化、氨基酸及其衍生物、有机酸、天然化合物、抗生素与活性肽、功能多糖、功能蛋白质等重要产品的生物制造技术,一碳化合物和生物质原料利用技术以及合成微生物组技术,以帮助读者从一个侧面了解合成生物制造相关技术和产业的发展情况。 相似文献
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This paper examined the biodegradability of a new aliphatic polyester, polyethylene succinate (PES), at a high incubation temperature of 50°C. The distribution and population of total colonies and of PES degrading micro organisms on polymer-emulsified agar plates were determined using the plate count and clear zone methods. The PES-decomposers were present in six of 10 soil samples and the total number ranged from 2.0×104 to 2.2×106 c.f.u./g of samples. Degrading microorganisms constituted between 20 and 80% of the total colonies on PES–agar plates. A single PES-degrading strain, TT96, was isolated and tested for its biodegrading capacity on PES powder and on other aliphatic polyesters: poly(beta-hydroxybutyrate) (PHB), polycaprolactone (PCL), poly(butylene succinate) (PBS), and poly(L-lactide) (PLA). Degraded films of PES and PBS were presented and compared using scanning electron microscopy. Strain TT96 was able to create clear zones on all the polymers used, except on PHB-agar plates. Liquid culture test after 2 weeks showed that TT96 completely degraded PCL powder but had very little activity on other samples. Scanning electron micrograph confirmed the microbial attack of TT96 on PES and PBS films. PES film surfaces were degraded more uniformly compared to PBS films which were decomposed only in some parts. 相似文献
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Nyland Cecilia Askham Modahl Ingunn Saur Raadal Hanne Lerche Hanssen Ole Jørgen 《The International Journal of Life Cycle Assessment》2003,8(6):331-336
Aim, Scope and Background When materials are recycled they are made available for use for several future life cycles and can therefore replace virgin
material more than just once. In order to analyse the optimal waste management system for a given material, the authors have
analysed the material flows in a life cycle perspective. It is important to distinguish this approach for material flow analysis
for a given material from life cycle analysis of products. A product life cycle analysis analyses the product system from
cradle to grave, but uses some form of allocation in order to separate the life cycle of one product from another in cases
where component materials are recycled. This paper does not address allocation of burdens between different product systems,
but rather focuses on methodology for decision making for waste management systems where the optimal waste management system
for a given material is analysed. The focus here is the flow of the given material from cradle (raw material extraction) to
grave (the material, or its inherent energy, is no longer available for use). The limitation on the number of times materials
can be recycled is set by either the recycling rate, or the technical properties of the recycled material.
Main Features This article describes a mathematical geometric progression approach that can be used to expand the system boundaries and
allow for recycling a given number of times. Case studies for polyethylene and paperboard are used to illustrate the importance
of including these aspects when part of the Goal and Scope for the LCA study is to identify which waste management treatment
options are best for a given material. The results and discussion examine the different conclusions that can be reached about
which waste management option is most environmentally beneficial when the higher burdens and benefits of recycling several
times are taken into account.
Results In order to assess the complete picture of the burdens and benefits arising from recycling the system boundaries must be expanded
to allow for recycling many times. A mathematical geometric progression approach manages to take into account the higher burdens
and benefits arising from recycling several times. If one compares different waste management systems, e.g. energy recovery
with recycling, without expanding the system to include the complete effects of material recycling one can reach a different
conclusion about which waste management option is preferred.
Conclusions When the purpose of the study is to compare different waste management options, it is important that the system boundaries
are expanded in order to include several recycling loops where this is a physical reality. The equations given in this article
can be used to include these recycling loops. The error introduced by not expanding the system boundaries can be significant.
This error can be large enough to change the conclusions of a comparative study, such that material recycling followed by
incineration is a much better option than waste incineration directly.
Recommendations and Outlook When comparing waste management solutions, where material recycling is a feasible option, it is important to include the relevant
number of recycling loops to ensure that the benefits of material recycling are not underestimated. The methodology presented
in this article should be used in future comparative studies for strategic decision-making for waste management. The approach
should not be used for LCAs for product systems without due care, as this could lead to double counting of the benefits of
recycling (depending on the goal and scope of the analysis). For materials where the material cycle is more of a closed loop
and one cannot truly say that recycled materials replace virgin materials, a more sophisticated approach will be required,
taking into account the fact that recycled materials will only replace a certain proportion of virgin materials. 相似文献
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塑料作为一种重要的基础材料,给人类的生产和生活带来极大的便利的同时,由于其难以降解的特性,也给人类的生存环境造成灾难性的污染。为此,生物塑料应运而生。本文综述了发展生物塑料的缘由,生物塑料的定义和分类,开发生物塑料的现状,并展望了未来发展的趋势。 相似文献
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[目的] 农用地膜主要成分为聚乙烯(polyethylene,PE),因其难以被降解,其废弃物常造成“白色污染”,本研究从常年覆盖农用地膜的土壤中筛选PE降解菌,并探究其对PE制品的降解效能。[方法] 采集的土壤样品用PE为唯一碳源的无机盐培养基进行富集,筛选、纯化PE降解菌,分离菌通过形态染色、生理生化特征、16S rRNA基因序列分析进行鉴定,检测其在不同PE浓度(0%、0.05%、0.10%、0.25%、0.50%、1.00%、2.00%、3.00%)的无机盐培养基中的生长曲线,最后通过扫描电镜、光镜观察,检测分离菌对农用地膜的降解效能。[结果] 从土壤中筛选获得一株能够降解PE的分离菌株(命名为SW1),初步鉴定其为放线菌的诺卡氏菌属Nocardia sp.。SW1的生长对PE具有明显浓度依赖,在含2% PE的无机盐培养基中生长最快,在培养的第48 h菌液浓度开始明显增加,第60 h达到最大,而在不含PE的无机盐培养基中未见生长。形态生理学观察表明,35℃培养15 d后,扫描电镜观察可见有大量菌嵌入膜内或附于膜表面生长,膜表面粗糙,并开始出现破损;培养60 d后,光镜观察可见膜大面积破损,并出现空洞。[结论] 从土壤中筛选获得了一株能够有效降解PE制品的放线菌菌株Nocardia sp. SW1。该研究丰富了PE制品降解微生物的菌种资源,为PE塑料废弃物的生物降解提供了科学数据与参考。 相似文献
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【背景】废旧塑料聚乙烯因具有较高的化学惰性,不易被自然降解而形成长期污染。【目的】探究聚乙烯泡沫塑料对大麦虫生长发育的影响,为大麦虫作为降解聚乙烯泡沫塑料的昆虫推广提供理论依据。【方法】以大麦虫幼虫为研究对象,选用常见的泡沫塑料(聚乙烯),采用4种不同的饲喂方式T1 (麦麸)、T2 (泡沫塑料)、T3 (泡沫塑料+麦麸)、T4 (不饲喂)进行驯化,处理30 d后对大麦虫进行解剖,取肠道内容物于LB培养基中进行富集培养,将富集培养后的菌液加入以聚乙烯(polyethylene,PE)为唯一碳源的LCFBM培养基进行选择性培养,从中筛选分离得到对PE塑料有降解能力的菌株。【结果】取食泡沫塑料30d后,与单一饲喂PE相比,麦麸和PE混合饲喂后大麦虫幼虫的存活率为76%。采用傅里叶变换红外光谱检测发现虫粪组分中主要官能团中峰值明显变化,表明PE长链有断裂现象,并从肠道中分离得到3株可以对PE薄膜边缘造成明显侵蚀的菌株。【结论】大麦虫可取食并消化PE塑料,其肠道内的微生物对PE塑料的降解起到关键作用,研究结果为塑料污染的生物降解提供了科学证据。 相似文献