Removal of Cadmium (II) from Aqueous Solution Using Galdieria sulphuraria CCMEE 5587.1.

IF 2.7 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
BioTech Pub Date : 2024-08-01 DOI:10.3390/biotech13030028
Hari Lal Kharel, Lina Jha, Melissa Tan, Thinesh Selvaratnam
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引用次数: 0

Abstract

The release of cadmium into the environment is a significant global concern due to its toxicity, non-biodegradability, and persistence in nature. There is an urgent need for effective, eco-friendly, and cost-effective systems for removing Cd because of the many drawbacks of conventional physicochemical techniques. This study investigated the ability of the extremophile red microalgal strain Galdieria sulphuraria CCMEE 5587.1 to tolerate and remove Cd (II) ions at acidic pH in a controlled laboratory environment. Three distinct concentrations of Cd (1.5 mg L-1, 3 mg L-1, and 6 mg L-1) were introduced to the cyanidium medium, and G. sulphuraria cells were introduced in the medium and grown for ten days. Four distinct aspects were identified regarding Cd removal: time course Cd removal, total Cd removal, extracellular Cd removal, and intracellular Cd removal. The inhibitory effects of Cd on G. sulphuraria growth were observed using a daily growth profile. Initial incubation days showed an inhibition of G. sulphuraria growth. In addition, increasing the Cd concentration in the medium decreased the growth rate of G. sulphuraria. Rapid Cd removal occurred on the first day of the experiment, followed by a steady removal of Cd until the last day. The highest total removal efficiency occurred in a medium containing 3 mg L-1 of Cd ions, which was 30%. In contrast, the highest sorption capacity occurred in a medium containing 6 mg L-1 of Cd ions, which was 1.59 mg g-1 of dry biomass. In all media compositions, a major fraction (>80%) of Cd removal occurred via adsorption on the cell surface (extracellular). These results showed that G. sulphuraria cells can remove Cd ions from aqueous solution, which makes them a potential bioremediation option for heavy metal removal.

利用 Galdieria sulphuraria 去除水溶液中的镉(II) CCMEE 5587.1.
由于镉的毒性、不可生物降解性和在自然界中的持久性,镉排放到环境中是一个全球关注的重大问题。由于传统的物理化学技术存在诸多弊端,因此迫切需要有效、生态友好且具有成本效益的系统来去除镉。本研究调查了嗜极端红色微藻菌株 Galdieria sulphuraria CCMEE 5587.1 在受控实验室环境中酸性 pH 下耐受和去除镉(II)离子的能力。在蓝藻培养基中引入三种不同浓度的镉(1.5 毫克/升、3 毫克/升和 6 毫克/升),并将 G. sulphuraria 细胞引入培养基并生长 10 天。在镉的去除方面,发现了四个不同的方面:镉去除的时间过程、镉去除总量、细胞外镉去除量和细胞内镉去除量。利用每日生长曲线观察了镉对硫磺藻生长的抑制作用。最初的培养天数显示出对 G. sulphuraria 生长的抑制作用。此外,增加培养基中的镉浓度也会降低硫化球藻的生长速度。实验第一天镉的去除速度很快,随后直到最后一天镉的去除都很稳定。在镉离子含量为 3 mg L-1 的培养基中,总去除率最高,达到 30%。相比之下,镉离子含量为 6 mg L-1 的培养基的吸附能力最高,为 1.59 mg g-1 干生物质。在所有培养基成分中,大部分(大于 80%)镉的去除都是通过细胞表面(胞外)的吸附作用实现的。这些结果表明,G. sulphuraria 细胞可以去除水溶液中的镉离子,这使它们成为去除重金属的潜在生物修复选择。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
BioTech
BioTech Immunology and Microbiology-Applied Microbiology and Biotechnology
CiteScore
3.70
自引率
0.00%
发文量
51
审稿时长
11 weeks
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