Lipid sovent systems are not equivalent for analysis of lipid classes in the microeukaryotic green alga,Chlorella

A comparison of three lipid solvent system indicated that they are not equivalent for the analysis of lipid classes in the green alga, Chlorella. Soxhlet extraction (methylene chloride/methanol, 3 h refulx) recovers more neutral lipid than the other methods but is equivalent to the room-temperature Bligh and Dyer (chloroform/methanol/water) extraction modified with phosphate buffer in glycolipid and polar lipid recovery. The Soxhlet method, however, gave a significantly lower recovery of many polyunsaturated fatty acids. The hexane/isopropanol method is selective for algal neutral lipids with poor recovery of membrane lipids (glyco- and polar lipids). Although this selectivity may have some useful applications, for biochemical studies of lipid synthesis in Chlorella, the modified Bligh and Dyer provides the most quantitative and reproducible recovery of all Chlorella lipid classes while minimizing artifacts due to the extraction procedure.     

Evaluation of a hexane/isopropanol lipid solvent system for analysis of bacterial analysis of bacterial phospholipids and application to chloroform-soluble Nuclepore (polycarbonate) membranes with retained bacteria

The recovery of phospholipid, ester-linked fatty acids and phospholipid phosphate from the eubacterium Pseudomonas atlantica was shown to be equivalent for the modified Bligh ad Dyer (chloroform/methanol/water) procedure and hexane/isopropanol (HIP) lipid extraction. In addition to its previously suggested lower toxicity, the HIP solvent system allows lipid analyses to be routinely done on chloroform-soluble materials such as Nuclepore polycarbonates, useful for well-defined size fractionation studies of bacterioplankton communities.     

A comparison of five lipid extraction solvent systems for lipidomic studies of human LDL

Lipidome profile of fluids and tissues is a growing field as the role of lipids as signaling molecules is increasingly understood, relying on an effective and representative extraction of the lipids present. A number of solvent systems suitable for lipid extraction are commonly in use, though no comprehensive investigation of their effectiveness across multiple lipid classes has been carried out. To address this, human LDL from normolipidemic volunteers was used to evaluate five different solvent extraction protocols [Folch, Bligh and Dyer, acidified Bligh and Dyer, methanol (MeOH)-tert-butyl methyl ether (TBME), and hexane-isopropanol] and the extracted lipids were analyzed by LC-MS in a high-resolution instrument equipped with polarity switching. Overall, more than 350 different lipid species from 19 lipid subclasses were identified. Solvent composition had a small effect on the extraction of predominant lipid classes (triacylglycerides, cholesterol esters, and phosphatidylcholines). In contrast, extraction of less abundant lipids (phosphatidylinositols, lyso-lipids, ceramides, and cholesterol sulfates) was greatly influenced by the solvent system used. Overall, the Folch method was most effective for the extraction of a broad range of lipid classes in LDL, although the hexane-isopropanol method was best for apolar lipids and the MeOH-TBME method was suitable for lactosyl ceramides.     

Comparison of methods for the extraction of plant lipids

The ability of a number of different solvent systems to extract lipid from a range of plant tissues was compared by measurement of phospholipid, glycolipid, sterol lipid and total acyl lipid content. A chloroform-methanol extraction method based upon the principles of Bligh and Dyer was considered to be the most efficient system for use with the majority of plant tissues. Cereal seeds were anomalous in that water saturated n- butanol was the preferred solvent system due to its superior ability to extract bound lysophospholipids present in large amounts in the endosperm portion of the tissue.     

Lipid extraction by methyl-tert-butyl ether for high-throughput lipidomics

Accurate profiling of lipidomes relies upon the quantitative and unbiased recovery of lipid species from analyzed cells, fluids, or tissues and is usually achieved by two-phase extraction with chloroform. We demonstrated that methyl-tert-butyl ether (MTBE) extraction allows faster and cleaner lipid recovery and is well suited for automated shotgun profiling. Because of MTBE's low density, lipid-containing organic phase forms the upper layer during phase separation, which simplifies its collection and minimizes dripping losses. Nonextractable matrix forms a dense pellet at the bottom of the extraction tube and is easily removed by centrifugation. Rigorous testing demonstrated that the MTBE protocol delivers similar or better recoveries of species of most all major lipid classes compared with the "gold-standard" Folch or Bligh and Dyer recipes.     

The acyl lipid composition of wheat leaves and moss protonemata using a new, non-carcinogenic extraction solvent system

As chloroform has proved to be carcinogenic we were looking for an alternative solvent system for chloroform:methanol widely used in plant lipid investigations. The lipids from leaves of wheat ( Triticum aestivum L. cv. Vakka) and from protonemata of the moss Ceratodon purpureus (Hedw.) Brid. were extracted with two petroleum ether:methanol solvent systems. The polar lipids were separated by two-dimensional thin-layer chromatography and the amounts of each lipid class were compared with those obtained from chloroform:methanol (2:1, v/v) extractions. The significantly higher amounts of phosphatidylinositol observed in petroleum ether:methanol (1:1, v/v) extraction suggest that the small amounts reported earlier in plants may be an artefact relating to the solvent system used. As petroleum ether:methanol (1:1, v/v) proved to be at least as good a solvent system as chloroform:methanol (2:1, v/v) we propose it as an alternative extractant for plant polar lipids.     

Comparative evaluation and selection of a method for lipid and fatty acid extraction from macroalgae

A comparative evaluation of Bligh and Dyer, Folch, and Cequier-Sánchez methods for quantitative determination of total lipids (TLs) and fatty acids (FAs) was accomplished in selective green (Ulva fasciata), red (Gracilaria corticata), and brown algae (Sargassum tenerrimum) using a full factorial categorical design. Applications of sonication and buffer individually on lipid extraction solvent systems were also evaluated. The FA recoveries obtained from the aforementioned methods were compared with those of direct transesterification (DT) methods to identify the best extraction methods. The experimental design showed that macroalgal matrix, extraction method, and buffer were key determinants for TL and FA recoveries (P ? 0.05), exhibiting significant interactions. But sonication gave erratic results with no interaction with any of the factors investigated. The buffered solvent system of Folch rendered the highest TL yield in U. fasciata and G. corticata while the buffered system of Bligh and Dyer gave the highest yield in S. tenerrimum. DT methods were more convenient and accurate for FA quantification and rendered 1.5–2 times higher yields when compared with the best conventional method, minimizing the use of chlorinated solvents, their cost of analysis, and disposal. The buffered solvent system was found to be the most appropriate for lipid research in macroalgae.     

A monophasic extraction strategy for the simultaneous lipidome analysis of polar and nonpolar retina lipids

Lipid extraction using a monophasic chloroform/methanol/water mixture, coupled with functional group selective derivatization and direct infusion nano-ESI-high-resolution/accurate MS, is shown to facilitate the simultaneous analysis of both highly polar and nonpolar lipids from a single retina lipid extract, including low abundance highly polar ganglioside lipids, nonpolar sphingolipids, and abundant glycerophospholipids. Quantitative comparison showed that the monophasic lipid extraction method yielded similar lipid distributions to those obtained from established “gold standard” biphasic lipid extraction methods known to enrich for either highly polar gangliosides or nonpolar lipids, respectively, with only modest relative ion suppression effects. This improved lipid extraction and analysis strategy therefore enables detailed lipidome analyses of lipid species across a broad range of polarities and abundances, from minimal amounts of biological samples and without need for multiple lipid class-specific extractions or chromatographic separation prior to analysis.     

Evaluation of metabolite extraction strategies from tissue samples using NMR metabolomics

Metabolomic analysis of tissue samples can be applied across multiple fields including medicine, toxicology, and environmental sciences. A thorough evaluation of several metabolite extraction procedures from tissues is therefore warranted. This has been achieved at two research laboratories using muscle and liver tissues from fish. Multiple replicates of homogenous tissues were extracted using the following solvent systems of varying polarities: perchloric acid, acetonitrile/water, methanol/water, and methanol/chloroform/water. Extraction of metabolites from ground wet tissue, ground dry tissue, and homogenized wet tissue was also compared. The hydrophilic metabolites were analyzed using 1-dimensional (1D) ¹H nuclear magnetic resonance (NMR) spectroscopy and projections of 2-dimensional J-resolved (p-JRES) NMR, and the spectra evaluated using principal components analysis. Yield, reproducibility, ease, and speed were the criteria for assessing the quality of an extraction protocol for metabolomics. Both laboratories observed that the yields of low molecular weight metabolites were similar among the solvent extractions; however, acetonitrile-based extractions provided poorer fractionation and extracted lipids and macromolecules into the polar solvent. Extraction using perchloric acid produced the greatest variation between replicates due to peak shifts in the spectra, while acetonitrile-based extraction produced highest reproducibility. Spectra from extraction of ground wet tissues generated more macromolecules and lower reproducibility compared with other tissue disruption methods. The p-JRES NMR approach reduced peak congestion and yielded flatter baselines, and subsequently separated the metabolic fingerprints of different samples more clearly than by 1D NMR. Overall, single organic solvent extractions are quick and easy and produce reasonable results. However, considering both yield and reproducibility of the hydrophilic metabolites as well as recovery of the hydrophobic metabolites, we conclude that the methanol/chloroform/water extraction is the preferred method. C. Y. Lin and H. Wu contributed equally.     

Isolation and enzymic assay of choline and phosphocholine present in cell extracts with picomole sensitivity.

Increasing interest in receptor-regulated phospholipase C and phospholipase D hydrolysis of cellular phosphatidylcholine motivates the development of a sensitive and simple assay for the water-soluble hydrolytic products of these reactions, phosphocholine and choline respectively. Choline was partially purified from the methanol/water upper phase of a Bligh & Dyer extract by ion-pair extraction using sodium tetraphenylboron, and the mass of choline was determined by a radioenzymic assay using choline kinase and [32P]ATP. After removal of choline from the upper phase, the mass of residual phosphocholine was determined by converting it into choline by using alkaline phosphatase, followed by radioactive phosphorylation. In addition to excellent sensitivity (5 pmol for choline and 10 pmol for phosphocholine), these assays demonstrated little mutual interference (phosphocholine----choline = 0%; choline----phosphocholine = 5%), were extremely reproducible (average S.E.M. of 3.5% for choline and 2.9% for phosphocholine), and were simple to perform with instrumentation typically available in most laboratories. In addition, the ability to apply the extraction technique to the upper phase of Bligh & Dyer extracts permitted simple analysis not only of choline and phosphocholine, but also of phosphatidylcholine and lipid products of phospholipase C and phospholipase D activity (1,2-diacylglycerol and phosphatidic acid respectively) from the same cell or tissue sample.     

Sequential one-step extraction and analysis of triacylglycerols and fatty acids in plant tissues

A method for plant tissue digestion and triacylglycerol (TAG) extraction followed by transmethylation of TAGs to produce the fatty acid methyl esters (FAMEs) from small storage tissue samples is presented. The method allows the analysis of both TAGs and FAMEs from the same sample. Several reagent mixtures and different experimental conditions were tested on sliced sunflower seeds. The best results were obtained using a mixture that was 33.3% a solution of NaCl (0.17 M) in methanol and 66.6% heptane by volume. The TAGs in the heptane solution were transmethylated with a mixture containing methanol:toluene:dimethoxypropane:H(4)SO(2) (39:20:5:2, by vol). The method was also tested on other oil seed storage tissue (soybean) and fruit tissues from olive and acorn. In all cases, sunflower, soybean, olive, and acorn, the TAGs and FAMEs composition data obtained by this method were quite similar to data from a standard analysis method. In samples with high protein content, such as soybean and sunflower seeds, the TAG extraction was incomplete. The water content of fruit samples did not interfere with TAG extraction obtained by this method.     

Comparison of three detergent-free protein extraction protocols for white adipose tissue

A comparative study of three detergent-free protein extraction protocols—a differential centrifugal fractionation, a delipidation protocol based on the Bligh and Dyer method, and the trifluoroethanol addition as cosolvent to an aqueous buffer—was performed on white adipose tissue. The performance of the protocols directly compatible with liquid chromatography–electrospray ionization–mass spectrometry (LC–ESI–MS) was evaluated based on the total protein extraction yield and the protein recovery from different functional and cellular compartments. The most suitable method for the extraction of white adipose tissue proteins from a wide range of cellular and structural compartments was the delipidation protocol based on the Bligh and Dyer method.     

An integrated procedure for the extraction of bacterial isoprenoid quinones and polar lipids

A simple small-scale procedure for the sequential extraction of isoprenoid quinones and polar lipids from bacterial cells was developed. Extraction with a biphasic mixture of petroleum ether (b.p. 60–80°C) and methanolic saline gave an upper phase containing isoprenoid quinones. The lower phase, containing the partially extracted organisms, was processed according to the Bligh and Dyer extraction method to give a polar lipid extract. As examples of the procedure, the isoprenoid quinones and polar lipids of Bacillus subtilis, Mycobacterium avium, Pseudomonas diminuta and Streptomyces griseus were extracted and analyzed.     

Acaricidal activities of extracts of Kochia scoparia against Tetranychus urticae, Tetranychus cinnabarinus, and Tetranychus viennensis (Acari: Tetranychidae)

Extracts of an annual herbaceous plant, Kochia scoparia (L.) Schrad (Macrophomina), were bioassayed to determine their acaricidal activities against Tetranychus urticae Koch, Tetranychus cinnabarinus (Boisduval), and Tetranychus viennensis Zacher (Acari: Tetranychidae) in the laboratory. Extracts had both contact and systemic toxicity to these mites. Three solvents were tested for preparing crude extracts: petroleum ether, chloroform, and methanol. Methanol was the most effective solvent, extracting 3.11-4.53% of the acaricide. Petroleum ether was the least effective solvent, extracting 1.25-1.54%. However, extracts with chloroform resulted in the highest mite mortality (78.86%), and ultrasound-assisted extraction required the least time (10 min). Concentrated extracts were prepared using chloroform, methyl acetate, or distilled water as a solvent. Mite mortalities from the concentrated extracts by methyl acetate or distilled water were significantly lower than those by chloroform. The mean lethal concentrations (LC50) of the extracts by chloroform, methyl acetate, and distilled water to the mites were 0.71 +/- 0.06, 2.08 +/- 0.16 and 8.75 +/- 0.062 mg/ml, respectively. After liquid chromatography and thin layer chromatography, the concentrated extracts by chloroform were separated into seven groups of isolated fractions and tested for acaricidal activity.     

Delipidization of membrane glycoproteins solubilized in acidified chloroform/methanol. Preparation of N-retinylidene opsin in a water soluble form without-detergent

Bovine retina membrane proteins and glycoproteins were insoluble in chloroform/methanol (2:1, v/v) unless the membrane suspension was precipitated with trichloroacetic acid and the organic solvent mixture added to the precipitated membranes. The presence of millimolar amount of trichloroacetic acid in the organic solvent led to the total solubilization of membranes. The glycoproteins precipitated at the interphase after partition of the acidified chloroform/methanol solution with water and were resolubilized from the interphase with chloroform/methanol/water (1:1:0.3, by vol). The solubility properties of the membrane glycoproteins in the acidified organic solvent mixtures allow to remove the bulk of membrane lipids and to recover from the chloroform/methanol/water solution the glycoprotein of rod outer segment membranes, rhodopsin, as protonated N-retinylidene opsin in a water soluble form.     

Supercritical carbon dioxide extraction of astaxanthin from Haematococcus pluvialis with vegetable oils as co-solvent

Soybean oil and olive oil were investigated as continuous co-solvents for supercritical carbon dioxide (SC-CO₂) extraction of astaxanthin from Haematococcus pluvialis. Without co-solvents, only 25.40 ± 0.79% efficiency was achieved with SC-CO₂ extraction at 70 °C and 40 MPa at a continuous flow rate of 3 mL min⁻¹ for 5 h. In the presence of soybean oil or olive oil as a co-solvent, the extraction efficiency was enhanced, with the most appropriate level of soybean oil in the solvent mixture being 10% by volume. At this concentration and the above extraction conditions, the highest extraction efficiency of 36.36 ± 0.79% was obtained for soybean oil, a 30% increase in extraction efficiency compared with SC-CO₂ extraction without soybean oil, whereas the 10% olive oil increased the extraction efficiency further to 51.03 ± 1.08%, which was comparable to that obtained using ethanol as co-solvent.     

A Mass Spectrometric Study for Comparative Analysis and Evaluation of Metabolite Recovery from Plasma by Various Solvent Systems

A solvent system that extracts a maximum number of metabolites belonging to diverse chemical classes from complex biofluids, such as plasma, may offer useful inputs to understand the metabolic and physiological state of an individual. The present study compared seven solvent systems for extraction of metabolites from plasma. The extracts were analyzed by mass spectrometry (MS) and MS/MS (MS2) using a quadrupole time-of-flight liquid chromatography/MS system in positive and negative modes of ionization. Metabolites with molecular mass below 400 were identified using Human Metabolome Database MS2 and MS search interfaces. The acetone/isopropanol (2:1) system yielded promising results in positive ionization mode, as the maximum number of MS and MS2 features was detected in the extract. It was found to be superior in extraction of various classes of metabolites, especially organic acids, nucleosides and nucleoside derivatives, and heterocyclic molecules. Glycerophosphocholines in the mass range of 400–700 were found to be efficiently extracted by the methanol/chloroform/water (8:1:1) system. In negative mode as well, the maximum number of MS2 features was detected in methanol/chloroform/water and acetone/isopropanol extracts. The fingerprints of molecular features obtained in the negative and positive modes differed from each other to a significant extent.     

一种简便的肌醇磷脂微量分析方法

分析磷脂酰肌醇循环(PI cycle)的磷脂组分常采用双向薄层层析法．建立了一个简单快速的单向薄层层析分离肌醇磷脂方法．首先采用不同的有机溶剂体系分别提取非多磷酸肌醇磷脂和多磷酸肌醇磷脂,然后用不同的层析展开体系,对两部分磷脂进行单向薄层层析分离．采用无载体 ³²P标记实验对该方法分离效果进行了观察．此法适用于同位素标记和非标记样品中肌醇磷脂组分的比较分析及多磷酸肌醇磷脂的提取、纯化和定量．     

Microwave-assisted extraction of homoharringtonine from <Emphasis Type="Italic">Cephalotaxus koreana</Emphasis>

An efficient method using microwave energy was developed to extract homoharringtonine (HHT), an alkaloid component effective in the treatment of leukemia, from Cephalotaxus koreana. The effects of major process parameters on extraction efficiency were also investigated. Using a fixed biomass-to-methanol ratio of 1:8 (w/v), an extraction temperature of 30°C, an extraction time of 20 min, and a stirrer velocity of 250 rpm, a 25% higher yield of HHT was achieved using microwave-assisted extraction (MAE) than using conventional solvent extraction. It was possible to recover more than 95% of the HHT by extracting twice using MAE. In addition, the HHT yield increased as the extraction temperature increased, but the content of plant-derived tar and waxy compounds increased as well. Removal of these impurities and of the pigments from extracts was most effectively accomplished at a mixing ratio of biomass-to-sylopute of 1:1.5 (w/w). The effects of using different organic solvents (acetone, chloroform, ethanol, or methanol) for MAE were also assessed; the highest extraction efficiency was obtained using methanol. When the agitation speed was altered, most of the HHT (> 99%) was recovered at 250 rpm. A mixing ratio of biomass-to-methanol of 1:6 (w/v) at an extraction temperature of 40°C and an extraction time of 10 min proved to be the most effective for reducing processing time and organic solvent usage while enabling nearly all of the HHT (> 99%) to be recovered.     

Selection of Xenobiotic-Degrading Microorganisms in a Biphasic Aqueous-Organic System

Microbial selection on mixtures of chlorinated and nonchlorinated compounds that are poorly soluble in water and/or toxic to growing microbial cells was examined in both biphasic aqueous-organic and monophasic aqueous systems. A biphasic system in which silicone oil was used as the organic phase permitted the acceleration of acclimation, leading to rapid selection and to an increase in xenobiotic compound degradation. In contrast, acclimation, selection, and degradation were very slow in the monophasic aqueous system. The variation in microbial growth rate with the degree of dispersion (i.e., dispersion at different silicone oil concentrations and agitation rates), and cell adhesion to the silicone oil indicate that the performance of the biphasic aqueous-organic system is dependent on the interfacial area between the two phases and that microbial activity is important at this interface. Therefore, the biphasic water-silicone oil system could be used for microbial selection in the presence of xenobiotic compounds that are toxic and have low water solubility.