Pressurized extraction of unsaturated fatty acids and carotenoids from wet Chlorella vulgaris and Phaeodactylum tricornutum biomass using subcritical liquids

The objective of this study was to investigate the extraction of lipids, for example, mono‐ and polyunsaturated fatty acids (PUFA) as well as carotenoids, from wet microalgae biomass using pressurized subcritical extraction solvents, which meet the requirements of food and feed applications. To demonstrate the effect of the solvent and temperature on the lipid yield, we chose two microalgae species, viz. Chlorella vulgaris and Phaeodactylum tricornutum, differing in their biochemical composition fundamentally. In case of P. tricornutum, ethanol showed the highest fatty acid yield of 85.9% w/w. In addition to eicosapentaenoic acid (EPA), the ethanolic extracts contained exceptional amounts of fucoxanthin (up to 26.1 mg/g d. w.), which can be beneficial to protect unsaturated fatty acids from oxidation processes and in terms of human nutrition. For C. vulgaris, a fatty acid yield of 76.5% w/w was achieved from wet biomass using ethyl acetate at 150°C. In general, an increase in the extraction temperature up to 150°C was found to be important in terms of fatty acid yield when extracting wet microalgae biomass. The results suggest that it is possible to efficiently extract both fatty acids and carotenoids from wet microalgae by selecting suitable solvents and thus circumvent energy‐intensive drying of the biomass.     

Solvent effects on focused microwave assisted extraction of polyphenolic acids from Eucommia ulmodies

An open microwave-assisted extraction system was used to extract gallic acid, protocatechuic acid, chlorogenic acid and caffeic acid from Eucommia ulmodies. The effect of extraction variables, especially solvent, on the recoveries of these polyphenolic compounds was investigated using factorial design. As extracting solvent for these compounds, methanol produced a higher recovery than pure water. For straight chain alcohol solvents, the lower the carbon number, the higher the recoveries of the polyphenolic acids. The optimal ratio of methanol:water:glacial acetic acid in the solvent mixture used in microwave-assisted extraction was 2:8:0.3 (v/v) and this solvent could be directly used as the mobile phase in HPLC separation without additional intermittent treatment as reported in literature. The extraction under the condition of 50% microwave power and 30 s irradiation at a solvent:sample ratio of 10 (mL/g) was found to be the most advantageous. The repeatability test of extraction and chromatographic analysis was satisfactory for the analysis of these polyphenolic compounds.     

紫芝中三萜化合物标准化提取方法研究

为了更好地发挥紫芝的药用功效,本文优选了紫芝子实体三萜类化合物的提取条件。采用L9(34)正交实验设计,以提取溶媒、提取方法、提取时间和提取次数四因素三水平的提取工艺优选。各因素重要性依次为提取溶媒>提取次数>提取方法>提取时间。本文确定了以氯仿或丙酮为提取溶剂提取紫芝中三萜类物质的标准化方法。在提取过程中如果采用甲醇、乙醇或水作为提取溶媒,虽然提取效率高,但含糖、氨基酸等其它非三萜成分多,三萜类物质提取不全。     

A New Method for Rapid Extraction of High Quality RNA from Recalcitrant Tissues of Grapevine

A quick, inexpensive, and reliable protocol for the extraction of RNA from grapevine berry skins containing large quantities of polyphenols, procyanidins, and polysaccharides is described. The method involves an extraction step in the presence of ribonuclease inhibitors and compounds that compete with vacuolar contaminants for binding to RNA. After extraction with organic solvents, RNA is bound to a fibrous cellulose matrix and processed to eliminate the remaining contaminants and ribonucleases. Following this method, highly stable RNA, sufficiently pure for northern hybridizations and enzymatic processing, may be obtained from as little as 200 mg of starting amounts of fresh material and without multiple, time consuming precipitations or ultracentrifugation steps. This procedure may also prove useful for extracting RNA from recalcitrant tissues of other plant species. Abbreviations: ATA, aurintricarboxylic acid; CF11, cellulose fibrous medium (type 11); PVPP, polyvinylpolypyrrolidone; RT room temperature; VRC, vanadyl ribonucleoside complex.     

Optimizing a continuous flow lipid extraction system (CFLES) used for extracting microalgal lipids

A laboratory‐made continuous flow lipid extraction system (CFLES) was devised to extract lipids from microalgae Nannochloropsis sp., a potential feedstock for biodiesel fuel, with a focus to assess the workable temperatures and pressures for future industrial applications. Using conventional solvents, the CFLES recovered 100% of the lipids extracted with conventional Soxhlet extraction. The optimum temperature and pressure were found to be 100 °C and 50 psi, respectively; conditions significantly lower than those normally used in pressurized liquid extractions requiring specialized equipment. Approximately 87% of the extracted oil was successfully transesterified into biodiesel fuel (fatty acid methyl esters). Preliminary calculations based on the tested lab‐scale system indicated savings in energy, solvent consumption, and extraction time as 96%, 80%, and more than 90%, respectively, as compared to Soxhlet extraction. However, the true cost savings can only be assessed at scaled up level. Energy efficiency of CFLES was calculated as 48.9%. Residual water (~70%) in the biomass had no effect on the extraction performance of CFLES, which is expected to help the process economics at scaled up application. The effect of temperature and pressure on the fatty acids profile of Nannochloropsis sp. is also discussed. Based on the existing literature, the authors believe that a pressurized liquid extraction system with continuous solvent flow has not been reported for lipid extraction from Nannochloropsis sp.     

Multi-step Preparation Technique to Recover Multiple Metabolite Compound Classes for In-depth and Informative Metabolomic Analysis

Metabolomics is an emerging field which enables profiling of samples from living organisms in order to obtain insight into biological processes. A vital aspect of metabolomics is sample preparation whereby inconsistent techniques generate unreliable results. This technique encompasses protein precipitation, liquid-liquid extraction, and solid-phase extraction as a means of fractionating metabolites into four distinct classes. Improved enrichment of low abundance molecules with a resulting increase in sensitivity is obtained, and ultimately results in more confident identification of molecules. This technique has been applied to plasma, bronchoalveolar lavage fluid, and cerebrospinal fluid samples with volumes as low as 50 µl.  Samples can be used for multiple downstream applications; for example, the pellet resulting from protein precipitation can be stored for later analysis. The supernatant from that step undergoes liquid-liquid extraction using water and strong organic solvent to separate the hydrophilic and hydrophobic compounds. Once fractionated, the hydrophilic layer can be processed for later analysis or discarded if not needed. The hydrophobic fraction is further treated with a series of solvents during three solid-phase extraction steps to separate it into fatty acids, neutral lipids, and phospholipids. This allows the technician the flexibility to choose which class of compounds is preferred for analysis. It also aids in more reliable metabolite identification since some knowledge of chemical class exists.     

Lipid extraction of tissues with a low-toxicity solvent

An improved method for extracting the lipids from tissues consists of the use of hexane:isopropanol, followed by a wash of the extract with aqueous sodium sulfate to remove nonlipid contaminants. This method has a number of advantages over the common usage of chloroform:methanol. The solvents are somewhat less toxic, interference in processing by proteolipid protein contamination is avoided, the two phase separate rapidly during the washing step, the solvent density is low enough to permit centrifugation of the homogenate as an alternative to filtration, the solvents are cheaper, and the washed extract can be applied to a chromatographic column with continuous monitoring of the elution in the far ultraviolet region. The new extraction method is inefficient for the extraction of gangliosides.     

High-efficient extraction of principal medicinal components from fresh Phellodendron bark (cortex phellodendri)

There are three key medicinal components (phellodendrine, berberine and palmatine) in the extracts of Phellodendron bark, as one of the fundamental herbs of traditional Chinese medicine. Different extraction methods and solvent combinations were investigated to obtain the optimal technologies for high-efficient extraction of these medicinal components. Results: The results showed that combined solvents have higher extracting effect of phellodendrine, berberine and palmatine than single solvent, and the effect of ultrasonic extraction is distinctly better than those of distillation and soxhlet extraction. Conclusion: The hydrochloric acid/methanol-ultrasonic extraction has the best effect for three medicinal components of fresh Phellodendron bark, providing an extraction yield of 103.12 mg/g berberine, 24.41 mg/g phellodendrine, 1.25 mg/g palmatine.     

Increase of lipid yields from some algae by acid extraction

The amounts of total lipids extracted from some but not all the algae examined were increased significantly by adding HCl to the usual chloroform—methanol extraction mixture. The Yield of phospholipid fraction relative to the glycolipids and neutral lipids increased significantly with acid extraction. Acid extraction also increased the yield of phosphatidyl serine, fatty acids, chlorophyll (or its derivatives) and several unknown compounds.     

Biodiesel production by simultaneous extraction and conversion of total lipids from microalgae, cyanobacteria, and wild mixed-cultures

Microalgae have been identified as a potential biodiesel feedstock due to their high lipid productivity and potential for cultivation on marginal land. One of the challenges in utilizing microalgae to make biodiesel is the complexities of extracting the lipids using organic solvents followed by transesterification of the extracts to biodiesel. In the present work, reaction conditions were optimized that allow a single step extraction and conversion to biodiesel in high yield from microalgae. From the optimized conditions, it is demonstrated that quantitative conversion of triglycerides from several different microalgae and cyanobacteria could be achieved, including from mixed microbial biomass collected from a municipal wastewater lagoon. Evidence is presented that for some samples, significantly more biodiesel can be produced than would be expected from available triglycerides, indicating conversion of fatty acids contained in other molecules (e.g., phospholipids) using this approach. The effectiveness of the approach on wet algae is also reported.     

A rapid separation technique for overcoming suppression of triacylglycerols by phosphatidylcholine using MALDI-TOF MS

Phospholipids and triacylglycerols (TAGs) are important classes of lipids in biological systems. Rapid methods have been developed for their characterization in crude samples, including MALDI time-of-flight MS. For mixtures, MALDI often selectively shows only some components. For example, phosphatidylcholine (PC) suppresses detection of other lipids. Most rapid MS methods detect either TAGs or phospholipids but not both. Herein, we demonstrate a simple approach to rapidly screen mixtures containing multiple lipid classes. To validate this approach, reference lipids [PC, tripalmitin (PPP), and phosphatidyl-ethanolamine (PE)] and real samples (beef, egg yolk) were used. In a binary mixture with a strong suppressor (PC), PPP was greatly suppressed. After a simple separation, suppression was virtually eliminated. A mixture of nominally nonsuppressing lipids (PE and PPP) was not adversely affected by separation. Ground beef and egg yolk were used to demonstrate detection of known lipid compositions where other methods have missed one or more lipids or lipid classes. Separation was performed using solid phase extraction with a PrepSep florisil column. A 10 min separation allows rapid screening for lipids and changes in lipids. It is sufficient to clearly detect all lipids and overcome suppression effects in complex lipid mixtures.     

发酵液中多拉菌素的提取和萃取条件研究

采用单因素实验,分别研究提取试剂、发酵液放置时间、pH值和温度对发酵液中多拉菌素提取效果的影响;然后以乙酸乙酯为萃取试剂,研究萃取次数及萃取体积对多拉菌素萃取效果的影响。结果显示,甲醇为最佳提取试剂;发酵液在pH为3～11、温度为20～80℃的条件下放置144 h,多拉菌素均能稳定存在,提取得到的多拉菌素的质量浓度没有显著变化;浓缩提取液液经2倍体积乙酸乙酯萃取2次即可。该条件下多拉菌素的质量浓度和萃取率分别为151.78μg/mL和98.00%。     

Decomposition of aquatic biota and sediment formation: bound lipids in algal detritus and lake sediments

SUMMARY. Organic detritus resulting from microbial attack on algal material contains lipids directly extractable by organic solvents and also contains bound lipids, obtained by solvent extraction following acid hydrolysis. Differences between the composition of bound and extractable n-alkanes, n- and branched/cyclic alkanoic acids from each source are attributed to a major bacterial input to these bound lipid classes. Similarities in composition between bound lipid classes of algal detritus and corresponding classes in a lake sediment support earlier suggestions of a considerable bacterially-derived contribution to sedimentary bound lipids.     

Comparative assessment of solvents and lignocellulolytic enzymes affiliated extraction of polyphenols from the various lignocellulosic agro-residues: identification and their antioxidant properties

Abstract

The present investigation was aimed to utilize lignocellulosic agro-residues and compare the extraction of polyphenols utilizing lignocellulolytic enzymes secreted by Sphingobacterium sp. ksn and with that of the solvents (ethanol, methanol) affiliated methods. The maximum amount of polyphenols, flavonoids and tannins were 94.29, 11.36, and 79.21?g 100?g^?1 respectively, found in the extracts obtained by enzymes affiliated extraction of coffee cherry husk (CCH). The phenolics namely, gallic acid, caffeic acid, coumaric acid, 1-hydroxybenzoic acid, 2,5-dihydroxybenzoic acid, p-hydroxybenzaldehyde were commonly found whereas syringic acid, quercetin, kaempferol, and epicatechin were hardly found in the extracts of agro-residues. The extracts of CCH shown maximum antioxidant properties for DPPH, ABTS, and FRAP. The present study reports that the affiliation of enzymes for the extraction of polyphenols from agro-residues is more efficient than that of the solvents affiliation and CCH as the good source of polyphenols.     

基于天然低共熔溶剂的甜叶菊中甜菊糖绿色提取方法及优化

尝试利用天然低共熔溶剂(NADES)提取甜叶菊(Stevia rebaudiana)中的甜菊糖, 探索一种高效、绿色和环保的甜菊糖提取新方法。以甜叶菊干叶为原料, 对照传统提取溶剂水, 以甜菊糖中甜菊苷和莱鲍迪苷A的提取浓度作为指标, 筛选出最优的NADES提取配方, 然后通过Box-Behnken响应面法对NADES提取甜叶菊中甜菊糖的工艺条件进行筛选优化。结果表明, 提取效率最高的NADES配方为1,2-丙二醇:甘油:水=8:1:1 (v/v/v), 提取的甜菊苷浓度为2.59 mg∙mL^-1, 比水提取高16.40%, 提取的莱鲍迪苷A浓度为1.06 mg∙mL^-1, 比水提取高12.62%; 通过响应面法得到最优提取条件: 提取时间90分钟, 提取温度60°C, 超声功率为80 J∙s^-1, 预测甜菊苷提取浓度为3.49 mg∙mL^-1, 莱鲍迪苷A提取浓度为1.43 mg∙mL^-1, 与实验验证值(甜菊苷浓度为3.48 mg∙mL^-1, 莱鲍迪苷A浓度为1.42 mg∙mL^-1)接近。在最优条件下, 甜菊苷提取浓度比初始条件提高了34.36%, 莱鲍迪甘A提取浓度比初始条件提高了33.96%。NADES绿色环保, 且提取效率高于传统溶剂, 可用于甜叶菊中甜菊糖的绿色提取; 同时, 该提取方法可为后续推广至其它大宗经济植物类天然产物的绿色工业生产提供参考。     

Effective recovery of poly‐β‐hydroxybutyrate (PHB) biopolymer from Cupriavidus necator using a novel and environmentally friendly solvent system

This work demonstrates a significant advance in bioprocessing for a high‐melting lipid polymer. A novel and environmental friendly solvent mixture, acetone/ethanol/propylene carbonate (A/E/P, 1:1:1 v/v/v) was identified for extracting poly‐hydroxybutyrate (PHB), a high‐value biopolymer, from Cupriavidus necator. A set of solubility curves of PHB in various solvents was established. PHB recovery of 85% and purity of 92% were obtained from defatted dry biomass (DDB) using A/E/P. This solvent mixture is compatible with water, and from non‐defatted wet biomass, PHB recovery of 83% and purity of 90% were achieved. Water and hexane were evaluated as anti‐solvents to assist PHB precipitation, and hexane improved recovery of PHB from biomass to 92% and the purity to 93%. A scale‐up extraction and separation reactor was designed, built and successfully tested. Properties of PHB recovered were not significantly affected by the extraction solvent and conditions, as shown by average molecular weight (1.4 × 10⁶) and melting point (175.2°C) not being different from PHB extracted using chloroform. Therefore, this biorenewable solvent system was effective and versatile for extracting PHB biopolymers. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:678–685, 2016     

Pulsed electric field (PEF) as an intensification pretreatment for greener solvent lipid extraction from microalgae

Microalgae, with their high lipid content, are a promising feedstock for renewable fuels. Traditionally, human and environmentally toxic solvents have been used to extract these lipids, diminishing the sustainability of this process. Herein, pulsed electric field technology was utilized as a process intensification strategy to enhance lipid extraction from Ankistrodesmus falcatus wet biomass using the green solvent, ethyl acetate. The extraction efficiency for ethyl acetate without PEF was lower (83–88%) than chloroform. In addition, the ethyl acetate exhibited a 2‐h induction period, while the chloroform showed no time dependence. Utilizing PEF technology resulted in 90% of the cells being lysed and a significant enhancement in the rate of lipid recovery using ethyl acetate. The increase in lipid recovery was due to the presence of the electric field and not due to temperature effects. The PEF technology uses less energy than other PEF systems reported in the literature. Biotechnol. Bioeng. 2013; 110: 1605–1615. © 2013 Wiley Periodicals, Inc.     

一种快速提取小麦叶片总RNA的方法

从植物组织中提取高质量的RNA是进行植物分子生物学研究的必要前提和关键.同种植物不同器官的组织由于组成分的差异,提取RNA的方法也存在不同的难点.在苯酚法和氯化锂沉淀法的基础上,改进并提出了一种适合小麦叶片总RNA的快速提取方法,消除了蛋白质、DNA、多糖、多酚等污染.该方法提取的小麦叶片总RNA,完整性好、纯度高,可用于RT-PCR、N orthern杂交、RACE等实验操作,而且简单经济、快速、实验结果稳定,重复性好,还适合富含多糖和脂质的植物组织总RNA的提取.     

海洋野生鱼酶解提取鱼油的工艺分析

海洋野生鱼与养殖鱼比较, 其鱼油中含更多的二十碳五烯酸（EPA）、二十二碳六烯酸（DHA）、脂溶性维生素等活性成分。为提高海洋野生鱼的利用价值, 以野生小带鱼为原料进行酶法提油工艺研究。分析了不同的温度, 时间, pH值等影响因素下的提取、萃取以及离心效果, 以响应面法确定了最佳的酶解工艺条件: 液固比为6、pH7.3、酶量1000 u/g原料、搅拌速度200 r/min、45oC酶解90 min; 最优萃取条件: 萃取剂100 mL(每20 g鱼糜原料)、pH4.0、40oC萃取25 min; 离心条件: 离心速度3000 r/min (1865 g)、离心时间10 min。上述工艺条件下提油率为79.90%。改进了传统的鱼油提取工艺, 在活性成分保护上有较大改善。     

海洋野生鱼酶解提取鱼油的工艺分析

海洋野生鱼与养殖鱼比较, 其鱼油中含更多的二十碳五烯酸（EPA）、二十二碳六烯酸（DHA）、脂溶性维生素等活性成分。为提高海洋野生鱼的利用价值, 以野生小带鱼为原料进行酶法提油工艺研究。分析了不同的温度, 时间, pH值等影响因素下的提取、萃取以及离心效果, 以响应面法确定了最佳的酶解工艺条件: 液固比为6、pH7.3、酶量1000 u/g原料、搅拌速度200 r/min、45oC酶解90 min; 最优萃取条件: 萃取剂100 mL(每20 g鱼糜原料)、pH4.0、40oC萃取25 min; 离心条件: 离心速度3000 r/min (1865 g)、离心时间10 min。上述工艺条件下提油率为79.90%。改进了传统的鱼油提取工艺, 在活性成分保护上有较大改善。