CN106190850B - 高油脂含量微藻体的培养方法 - Google Patents

高油脂含量微藻体的培养方法 Download PDF

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CN106190850B
CN106190850B CN201610535230.7A CN201610535230A CN106190850B CN 106190850 B CN106190850 B CN 106190850B CN 201610535230 A CN201610535230 A CN 201610535230A CN 106190850 B CN106190850 B CN 106190850B
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isochrysis galbana
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胡玉才
苏延明
付晚涛
白亚乡
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Dalian Ocean University
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Abstract

本发明公开了一种高油脂含量微藻体的培养方法,其特征在于:所述的方法按照以下步骤进行:选取球等鞭金藻作为培养主体,将球等鞭金藻置于电场强度为1×106‑2×106V/m的匀强电场环境下10‑20min,然后将球等鞭金藻置于磁感应强度为50‑100mT的匀强磁场环境下15‑20min,之后按照以下参数进行培养:葡萄糖碳源4‑6g/L,温度19‑26℃,盐度33‑34,pH值8.2‑8.4,光照强度3000‑3500lux,培养期间连续充气,连续培养10‑14d,即可获得高油脂含量的微藻体。这是一种成本低廉,操作简便,能够获得油脂含量相对较高的微藻体的培养方法。

Description

高油脂含量微藻体的培养方法
技术领域
本发明涉及一种强电场磁场提高微藻含油量的方法,特别是一种高油脂含量微藻体的培养方法。
背景技术
微藻是一类在陆地、海洋分布广泛,营养丰富、光合利用度高的自养植物,其细胞代谢能够产生多糖、蛋白质、色素等,使其在食品、医药、基因工程、液体燃料等领域具有很好的开发前景。它利用光能,以CO2和H2O合成有机物质进行细胞生长,其体内的油脂不但可作为营养保健品,且可作为生物柴油的重要油料来源。受能源危机的影响,利用微藻制提生物柴油的技术和相关研究已经在世界范围内得到广泛关注,科技工作者做了大量的研究与实验,但远未能产业化,其中一个主要原因是成本问题。
在利用微藻制提生物柴油的过程中,微藻的规模化培养是技术关键,而规模化培养的关键点则在于如何提高其生长速度和含油量。如果能够有效提高微藻的生长速度和含油量,则能够大大降低微藻的培育成本,进而让微藻制提生物柴油这一技术获得坚实的基础。
发明内容
本发明是为了解决现有技术所存在的上述不足,提出一种成本低廉,操作简便,能够获得油脂含量相对较高的微藻体的培养方法。
本发明的技术解决方案是:一种高油脂含量微藻体的培养方法,其特征在于:所述的方法按照以下步骤进行:
选取球等鞭金藻作为培养主体,将球等鞭金藻置于电场强度为1×106-2×106V/m的匀强电场环境下10-20min,然后将球等鞭金藻置于磁感应强度为50-100mT的匀强磁场环境下15-20min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度19-26℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养10-14d,即可获得高油脂含量的微藻体。
所述的球等鞭金藻为球等鞭金藻8701或球等鞭金藻3011。
选取球等鞭金藻8701作为培养主体,将球等鞭金藻8701置于电场强度为1×106V/m的匀强电场环境下20min,然后将球等鞭金藻8701置于磁感应强度为100mT的匀强磁场环境下15min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度20±1℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养10-14d,即可获得高油脂含量的微藻体。
选取球等鞭金藻3011作为培养主体,将球等鞭金藻3011置于电场强度为2×106V/m的匀强电场环境下10min,然后将球等鞭金藻3011置于磁感应强度为50mT的匀强磁场环境下20min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度25±1℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养10-14d,即可获得高油脂含量的微藻体。
本发明同现有技术相比,具有如下优点:
本发明所公开的培养方法,以特定浓度的葡萄糖碳源配以适宜的温度、盐度、pH值以及养殖水温,来进行微藻体的培养,并且它在培养前将微藻体依次置于特定条件的匀强电场和匀强磁场环境下进行处理,利用该方法所培养出的微藻体,其油脂含量可达40%以上,其油脂含量为传统方法下培养出的微藻体的油脂含量的1.8倍以上。该方法本利用了电场环境和磁场环境的正向叠加效应,能够有效提高微藻的含油量。
具体实施方式
下面将说明本发明的具体实施方式。
一种高油脂含量微藻体的培养方法,按照以下步骤进行:
选取球球等鞭金藻8701或球等鞭金藻3011作为培养主体,将球等鞭金藻置于电场强度为1×106-2×106V/m的匀强电场环境下10-20min,然后将球等鞭金藻置于磁感应强度为50-100mT的匀强磁场环境下15-20min,之后按照以下参数进行培养:葡萄糖碳源4-6g/L,温度19-26℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
在培养期间保持连续充气,连续培养10-14d后,即可获得高油脂含量的微藻体。
实施例一:
选取球等鞭金藻8701作为培养主体,将球等鞭金藻8701置于电场强度为1×106V/m的电场环境下20min,然后将球等鞭金藻8701置于磁感应强度为100mT的磁场环境下15min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度20±1℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养,培养至第10天可得到最高细胞密度值的微藻体,其最高细胞密度值可达常规培养方法条件下所获得的微藻体的最高细胞密度值的1.2倍左右;培养至第12天可得到最高油脂含量的微藻体,其油脂含量可达42.1%,为常规培养方法条件下所获得的微藻体的最高油脂含量的1.83倍。
实施例二:
选取球等鞭金藻3011作为培养主体,将球等鞭金藻3011置于电场强度为2×106V/m的电场环境下10min,然后将球等鞭金藻3011置于磁感应强度为50mT的磁场环境下20min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度25±1℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养,培养至第12天其油脂含量可达41.6%,为常规培养方法条件下所获得的微藻体的最高油脂含量的1.81倍。

Claims (4)

1.一种高油脂含量微藻体的培养方法,其特征在于:所述的方法按照以下步骤进行:
选取球等鞭金藻作为培养主体,将球等鞭金藻置于电场强度为1×106-2×106V/m的匀强电场环境下10-20min,然后将球等鞭金藻置于磁感应强度为50-100mT的匀强磁场环境下15-20min,之后按照以下参数进行培养:葡萄糖碳源4-6g/L,温度19-26℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,培养期间连续充气,连续培养10-14d,即可获得高油脂含量的微藻体。
2.根据权利要求1所述的高油脂含量微藻体的培养方法,其特征在于:所述的球等鞭金藻为球等鞭金藻8701或球等鞭金藻3011。
3.根据权利要求2所述的高油脂含量微藻体的培养方法,其特征在于:选取球等鞭金藻8701作为培养主体,将球等鞭金藻8701置于电场强度为1×106V/m的匀强电场环境下20min,然后将球等鞭金藻8701置于磁感应强度为100mT的匀强磁场环境下15min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度20±1℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养10-14d,即可获得高油脂含量的微藻体。
4.根据权利要求2所述的高油脂含量微藻体的培养方法,其特征在于:选取球等鞭金藻3011作为培养主体,将球等鞭金藻3011置于电场强度为2×106V/m的匀强电场环境下10min,然后将球等鞭金藻3011置于磁感应强度为50mT的匀强磁场环境下20min,之后按照以下参数进行培养:
葡萄糖碳源4-6g/L,温度25±1℃,盐度33-34,pH值8.2-8.4,光照强度3000-3500lux,
培养期间连续充气,连续培养10-14d,即可获得高油脂含量的微藻体。
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Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
ES2334478A1 (es) * 2007-07-20 2010-03-10 Biofuel Systems, S.L. Sistema de captacion de radiacion solar y co2 para su conversion a energia quimica en continuo.
CN102453682A (zh) * 2010-10-15 2012-05-16 中国科学院海洋研究所 一种海洋微藻及其培养方法和应用

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
ES2334478A1 (es) * 2007-07-20 2010-03-10 Biofuel Systems, S.L. Sistema de captacion de radiacion solar y co2 para su conversion a energia quimica en continuo.
CN102453682A (zh) * 2010-10-15 2012-05-16 中国科学院海洋研究所 一种海洋微藻及其培养方法和应用

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
等鞭金藻的电转化体系;李海东等;《海洋环境科学》;20121031;第31卷(第5期);第677-681页 *

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