Analysis of picogram quantities of protein in subnanoliter-size samples

The ability to measure protein concentration in subnanoliter volumes would be helpful in many biological studies. A microassay for measuring nanogram protein quantities in nanoliter-size samples and an ultramicroassay for measuring picogram quantities in picoliter samples were developed to measure lymphatic protein concentration. Aliquots of a sample solution were mixed with an o-phthalaldehyde mercaptoethanol reagent using micropipetting techniques. Reaction product fluorescence was measured using a modified Leitz MPV-1 microscope as a microfluorometer. Fluorescence varied linearly with albumin concentrations between 1 and 8 g/100 ml. A typical microassay measuring albumin standards at 0.0, 1.0, 2.0, and 4.0 g/100 ml yielded a linear regression of y = 207x + 60 (r = 0.99). Minimum detectable protein concentration was 0.125 g/100 ml. The SE for the albumin standards varied from 0.02 to 0.17 g/100 ml. An ultramicroassay measuring similar standards yielded a linear regression of y = 1180x + 109 (r = 0.96). Minimum detectable protein concentration was 0.028 g/100 ml. The SE for the standards varied from 0.01 to 0.32 g/100 ml.     

The determination of nicotine in biological fluids at picogram levels by selected ion recording.

Using a combined gas chromatographic-mass spectrometric-selected ion recording technique it has been possible to achieve detection, identification, and quantitation of nicotine in biological fluids in amounts as low as 25 pg. Employing the deuterated variant nicotine-5′,5′-d₂ both as an internal standard and as a carrier in an inverse isotope dilution method, an accurate, sensitive, and specific method for picogram level quantitation of nicotine is obtained. Careful precautions were necessary to prevent positive “blank” values at low levels due to extraneous nicotine, which were found to arise both from the solvents used in the extractions and from airborne sources.     

Bile acids: analysis in biological fluids and tissues

The formation of bile acids/bile alcohols is of major importance for the maintenance of cholesterol homeostasis. Besides their functions in lipid absorption, bile acids/bile alcohols are regulatory molecules for a number of metabolic processes. Their effects are structure-dependent, and numerous metabolic conversions result in a complex mixture of biologically active and inactive forms. Advanced methods are required to characterize and quantify individual bile acids in these mixtures. A combination of such analyses with analyses of the proteome will be required for a better understanding of mechanisms of action and nature of endogenous ligands. Mass spectrometry is the basic detection technique for effluents from chromatographic columns. Capillary liquid chromatography-mass spectrometry with electrospray ionization provides the highest sensitivity in metabolome analysis. Classical gas chromatography-mass spectrometry is less sensitive but offers extensive structure-dependent fragmentation increasing the specificity in analyses of isobaric isomers of unconjugated bile acids. Depending on the nature of the bile acid/bile alcohol mixture and the range of concentration of individuals, different sample preparation sequences, from simple extractions to group separations and derivatizations, are applicable. We review the methods currently available for the analysis of bile acids in biological fluids and tissues, with emphasis on the combination of liquid and gas phase chromatography with mass spectrometry.     

Measurement of inorganic pyrophosphate in biological fluids and bone tissues

A simple and rapid technique of measuring pyrophosphates in plasma, urine, and bone tissue is described, using the UDPG-pyrophosphorylase reaction and fluorimetrical determination of NADPH formed in a combined system of phosphorylation and reduction. This very specific method avoids the separation of Pi² by column chromatography, and its very great sensitivity enables measurement on a final sample corresponding to 0.2 ml of plasma, with a precision of about 3%.The mean plasma PPi concentration (±SE of mean) was 3.53 ± 0.19 μmoles/liter (SE=0.93), or 0.207 ± 0.006 mg Pi/liter. The normal range for this population (99% confidence limit) is therefore between 1.10 and 5.90 μmoles/liter or 0.068 – 0.366 mg Pi/liter. Analysis of the variation of the duplicate measurements shows a very small divergence of 3.4% or ±0.12 μm.Normal 24 hr urinary excretion is 53.0 ± 6.8 μmoles with 99% confidence limits of 10.0 and 96.0 μmoles.The average PPi concentration in calvaria of 20 10-day-old rats is 3.685 ± 0.16 nmoles/mg fresh weight.     

Determination of quassin in picogram quantities by an enzyme-linked immunosorbent assay

A double-antibody, enzyme-linked immunosorbent assay has been developed for the detection of quassin, neoquassin and 18-hydroxyquassin, the bitter natural products of Quassia amara and related species. Antiserum was raised in rabbits using 18-hydroxyquassin-bovine serum albumin as immunogen. The assay described is able to detect these closely related seco-triterpenes at concentrations as low as 5 pg per 0.1 ml sample, and the antiserum shows little cross-reactivity with other quassinoids. The distribution of quassin within small plants of Q. amara, Q. indica and Picrasma quassioides is described.     

Highly sensitive method for quantitative determination of bilirubin in biological fluids and tissues

Unconjugated bilirubin (UCB) exhibits potent antioxidant and cytoprotective properties, but causes apoptosis and cytotoxicity at pathologically elevated concentrations. Accurate measurement of UCB concentrations in cells, fluids and tissues is needed to evaluate its role in redox regulation, prevention of atherosclerotic and malignant diseases, and bilirubin encephalopathy. In the present study, we developed and validated a highly sensitive method for tissue UCB determinations. UCB was extracted from rat organs with chloroform/methanol/hexane at pH 6.2 and then partitioned into a minute volume of alkaline buffer that was subjected to HPLC using an octyl reverse phase (RP) column. Addition of mesobilirubin as an internal standard corrected for losses of UCB during extraction. Recoveries averaged 75+/-5%. The detection limit was 10pmol UCB/g wet tissue. Variance was +/-2.5%. When used to measure UCB concentrations in tissues of jaundiced Gunn rats, this procedure yielded UCB levels directly comparable to published methods, and accurately determined very low tissue bilirubin concentrations (相似文献   

Determination of cholesterol in sub-nanomolar quantities in biological fluids by high-performance liquid chromatography

A highly sensitive method for the determination of cholesterol in biological fluids is described. Unsaponifiable lipids from rat serum and thoracic duct lymph chylomicron samples were treated with cholesterol oxidase. The product of the enzymatic reaction, Δ⁴-cholestenone, was analysed by normal-phase high-performance liquid chromatography (HPLC) using hexane—isopropanol (95:5, v/v) as a mobile phase and detected with a UV spectrophotometer at 240 nm. When the standard samples containing varying amounts of cholesterol (0.15–3 nmol) were treated with cholesterol oxidase and analysed by HPLC (injected amounts 0.09–1.8 nmol of cholesterol), the peak areas increased proportionally with the amounts of authentic cholesterol with a correlation coefficient of 0.996. The values in these biological fluids determined by the HPLC method were identical to those obtained by enzymatic—colorimetric or gas chromatographic methods. Moreover, the detection limit (0.09 nmol) of the present method (0.15 nmol are required for the sample preparation) is lower than those of conventional methods (approximately 30 nmol). Because of the excellent sensitivity and reproducibility, this method is well suited for the determination of cholesterol in biological fluids where cholesterol concentration is low.     

Non-protein-bound iron detection in small samples of biological fluids and tissues

Interest in the pro-oxidative nature of non-protein-bound-iron (NPBI) led to the development of an assay for its detection. The aim was to set up a reliable method of detecting NPBI in small samples of biological fluids and tissue. The method was based on preferential chelation of NPBI by a large excess of the low-affinity ligand nitrilotriacetic acid. To separate NPBI, a two-step filtration procedure was used. All glassware and plasticware were treated to minimize iron contamination. Measurements were performed in plasma, amniotic fluid, bronchoalveolar lavage, and brain tissues. The analytic system detected iron as ferric nitrate standard down to a concentration of 0.01 μM. The 1,2-dimethyl-3-hydroxy-4(1H)-pyridone-Fe(DHP-Fe) complex eluted with a retention time of about 2.6 min. The standard curve for the DHP-Fe complex was linear between 0.01 and 400 μM in water as well as in plasma, bronchoalveolar lavage, brain tissue, and amniotic fluid. The detection limit was 0.01 μM for all biological fluids and brain tissue. The data show that reliable measurements of NPBI are possible in studies on oxidative stress under experimental and clinical conditions. The possibility of investigating NPBI involvement in free-radical injury might be useful in all human diseases in which oxidative stress occur.     

Trans-diamminedichlorplatinum (II)-modified probes for detection of picogram quantities of DNA.

A novel simple nonradioactive method for detection of specific nucleotide sequences has been developed. This method consists of the hybridization of a target DNA with a DNA probe modified with trans-diamminedichlorplatinum(II) (trans-DDP) followed by detection of DNA/DNA hybrids with affinity-isolated anti-DNA-trans-DDP antibodies and poly-horseradish peroxidase-protein A conjugate. Major advantages of this approach are the low cost and the extreme simplicity of the labeling procedure, which involves only mixing of the reagents. The sensitivity of the proposed technique is sufficient to detect 0.8 pg of DNA in Southern blot hybridization and 25 fg in dot hybridization and permits colony screening.     

Simple method for analysis of diquat in biological fluids and tissues by high-performance liquid chromatography

A simple HPLC method has been described to quantify diquat in biological fluids and tissues. This method permits separation and quantification of diquat from blood, bile, urine, liver and kidney. It does not require special pretreatment of the samples prior to analysis, nor a specially prepared analytical column. Various concentrations of diquat were added (10–300 nmol/ml or g) to fluids or tissues. Analysis of blank samples revealed no substrates that interfere with diquat elution. Excellent recovery (95–105%) was obtained. Diquat (120 μmol/kg, i.v.) was injected to rats and quantified in bile, blood and liver. Concentration of diquat was higher in blood and bile than liver. Therefore, this method is applicable for quantification of diquat in toxicological samples, and may be used to determine structurally similar compounds such as paraquat.     

A simplified microassay for serotonin: Modification of the enzymatic isotopic assay

A simplification of the enzymatic isotopic assay for serotonin is described, Serotonin is converted to [³H]melatonin by a two-step reaction: N-acetylation of serotonin using acetic anhydride, followed by O-methylation with the enzyme hydroxyindole O-methyltransferase (EC 2.1,1.4) and S-adenosyl- -[methyl-³H]methionine as methyl donor. The present assay avoids the use of unstable acetylating enzyme, rat liver N-acetyltransferase (EC2.3,1.5). Blank values are lowered considerably and the sensitivity is doubly increased. Two-tenths micromole of serotonin per 30 μl of sample in tissue homogenates can be measured.