Use of deuterated water for measurement of short-term cholesterol synthesis in humans

Previous methods for measurement of cholesterol synthesis de novo in humans have either required extended measurement periods or been indirect. Recently, a technique based on the rate of incorporation of deuterium from D2O into the plasma cholesterol pool has been developed. Following oral ingestion of D2O, deuterium enrichment over time in free plasma cholesterol after combustion and reduction was determined using isotope ratio mass spectrometry. This methodology enabled direct measurement of plasma cholesterol synthesis over intervals as short as 4 h. The technique has been used to demonstrate changes in synthetic rate in response to feeding conditions and genetic influences. Fasting over 36 h resulted in markedly reduced deuterium uptake into cholesterol in healthy males. Diurnal variations in synthetic rate have also been identified, with elevated synthesis observed during nocturnal periods in both fed and fasted subjects. In addition, the influence of apolipoprotein E phenotype on cholesterol synthesis has been shown using this technique. Individuals carrying the apoprotein epsilon 2 allele demonstrated lower synthesis compared with those possessing the epsilon 4 allele. Thus, the deuterium incorporation technique for measuring cholesterol synthesis demonstrates potential as a valuable stable isotope method for human nutrition studies.     

Steroid 21-hydroxylation by human preovulatory follicles from stimulated cycles: a mass spectrometrical study of deoxycorticosterone, 21-hydroxypregnenolone and 11-deoxycortisol in follicular fluid

A highly specific technique based on gas chromatography-mass spectrometry associated with stable isotope dilution was applied to the analysis of follicular fluid aspirated from preovulatory follicles of women under ovarian stimulation prior to in vitro fertilization. Deoxycorticosterone, 21-hydroxypregnenolone and 11-deoxycortisol have been identified and quantified in the nanomolar concentration range. Significant positive correlations were found between these 21-hydroxy-steroids and their immediate precursors, thus indicating a probable common cellular origin. Corticosterone was tentatively identified and cortisol was evidenced at concentrations lower than peripheral plasma levels. The occurrence in human follicular fluid of cortisol, together with different high concentration intermediates, constitutes evidence for ovarian intra-follicular 21-hydroxylase activity, and probably also for 11 beta-hydroxylation enzyme activity.     

Trace determination and isotopic analysis of the elements in life sciences by mass spectrometry

The main ionization methods in a mass spectrometer for isotope ratio determinations of the elements are discussed in this review. These methods are thermal ionization, spark source, electron impact, inductively coupled plasma and field desorption. As concerns thermal ionization, electron impact and field desorption, a survey of the possibilities of isotope analyses in the periodic table of the elements is given. Besides kinetic studies, trace element determination by isotope dilution technique is the main application for isotope ratio measurements of the elements. The definitive method, isotope dilution mass spectrometry, is discussed as a potential tool for achieving accurate and precise trace analyses. Using field desorption mass spectrometry, one example of calcium kinetics in man and one example of thallium trace determination in an animal tissue are given. Other metal trace analyses with the isotope dilution technique are presented for biological and medical samples using positive thermal ionization mass spectrometry. Negative thermal ions are formed for the mass spectrometric analysis of non-metals and non-metal compounds in food samples, e.g. for iodine and nitrate in milk powder. Preliminary results with the isotope dilution technique are presented for a new quadrupole thermal ionization mass spectrometer which is a low-cost instrument and can be easily handled.     

Determination of selenium stable isotopes by gas chromatography–mass spectrometry with negative chemical ionisation

A gas chromatography mass spectrometric method using negative chemical ionisation was developed for the determination of stable isotopes of selenium for evaluation of selenium absorption and retention from foods in humans. The method involves an acid digestion to convert all selenium into selenite, which subsequently reacts with 4-nitro-o-phenylene-diamine to form a volatile piazselenole. The piazselenole, after extraction into an organic solvent, was analysed for its isotopic selenium composition by gas chromatography mass spectrometry. Negative chemical ionisation is reported for the first time for the determination of selenium stable isotopes and its analytical characteristics were compared to those of electron impact mass spectrometric ionisation, classically used for the determination of selenium. The negative chemical ionisation technique allowed accurate determination of total selenium by isotope dilution and of selenium isotope ratios in biological samples. The repeatability for total selenium and for stable isotope ratios was good (R.S.D.≤10%) within the range of 50 to 250 ng selenium. The detection limit for the investigated selenium isotopes was approximately 1 pg (signal to noise ratio at 3). The applicability of the developed stable isotope methodology was demonstrated by the determination of the selenium absorption and retention from foods in a pilot study using one human adult.     

Determination of chlorpromazine and its major metabolites by gas chromatography/mass spectrometry: application to biological fluids

A method for the quantitative determination of chlorpromazine and five of its major metabolites in a single sample of biological fluid in the ng/ml range has been developed utilizing gas chromatography/mass spectrometry with selected ion recording. The assay is highly specific and quantification is accomplished by an inverse stable isotope dilution technique, using deuterium-labeled variants of the compounds as internal standards. In this way the concentrations of chlorpromazine and five of its major metabolites (the sulfoxide, the N-oxide, the monodemethylated, the didemethylated, and the 7-hydroxylated compounds) can be determined in biological fluids. Levels in humans have been measured both in plasma and in red blood cells and are compared to those found in related in vitro studies.     

Pharmacokinetic studies of methionine in rats using deuterium-labeled methionine quantitative assessment of remethylation

The pharmacokinetics of methionine has been studied in rats by means of stable isotope methodology. After the i.v. bolus injection of [2H7]methionine (5 mg/kg body wt.), the plasma concentrations of [2H7]methionine, demethylated [2H4]homocysteine and remethylated [2H4]methionine were determined simultaneously with endogenous methionine and homocysteine by gas chromatography-mass spectrometry. The half-life for [2H7]methionine were 35.0 +/- 6.9 min. The appearance of the metabolites, [2H4]homocysteine and [2H4]methionine, in the plasma was very rapid. The fraction of [2H7]methionine that remethylated to [2H4]methionine through [2H4]homocysteine were 0.185 +/- 0.028. The administered [2H7]methionine did not influence the plasma levels of endogenous methionine and homocysteine. The present stable isotope methodology has made it possible to evaluate the pharmacokinetics of methionine, including the estimation of remethylation.     

Stable isotope methodology in the pharmacokinetic studies of androgenic steroids in humans

The use of stable isotopically labeled steroids combined with gas chromatography/mass spectrometry (GC/MS) has found a broad application in pharmacologic studies. Initially, stable isotopically labeled steroids served as the ideal analytic internal standard for GC/MS analysis; however, their in vivo use has expanded and has proven to be a powerful pharmacokinetic tool. We have successfully used stable isotope methodology to study the pharmacokinetic/bioavailability of androgens. The primary advantage of the technique is that endogenous and exogenous steroids with the same basic structure can be differentiated by using stable isotopically labeled analogs. The method was used to examine the pharmacokinetics of testosterone and testosterone propionate, and to clarify the influence of endogenous testosterone. Another advantage of the isotope methods is that steroidal drugs can be administered concomitantly in two formulations (e.g., solution and solid dosage). A single set of blood samples serves to describe the time course of the formulations being compared. This stable isotope coadministration technique was used to estimate the relative bioavailability of 17 alpha-methyltestosterone.     

Isotope ratio determination in boron analysis

Traditionally, boron (B) isotope ratios have been determined using thermal ionization mass spectrometry (TIMS) and, to some extent, secondary ion mass spectrometry (SIMS). Both TIMS and SIMS use a high-resolution mass analyzer, but differ in analyte ionization methods. TIMS uses electrons from a hot filament, whereas SIMS employs an energetic primary ion beam of Ga+, Cs+, or O- for analyte ionization. TIMS can be used in negative or positive ion modes with high sensitivity and precision of B isotope ratio determination. However, isobaric interferences may be a problem, if the sample is not well purified and/or memory of the previous sample is not removed. Time-consuming sample preparation, analyte (B) purification, and sample determination processes limit the applications of TIMS for routine analyses. SIMS can determine B and its isotope ratio in intact solid samples without destroying them, but has poorer resolution and sensitivity than TIMS, and is difficult to standardize for biological samples. Development of plasma-source mass spectrometry (MS) enabled the determination of B concentration and isotope ratio without requiring sample purification. Commonly used plasma-source MS uses an Ar inductively coupled plasma (ICP) as an ionization device interfaced to a low-resolution quadrupole mass analyzer. The quadrupole ICP-MS is less precise than TIMS and SIMS, but is a popular method for B isotope ratio determination because of its speed and convenience. B determination by ICP-MS suffers no spectroscopic interferences. However, sample matrices, memory effects, and some instrument parameters may affect the accuracy and precision of B isotope ratio determination if adequate precautions are not taken. New generations of plasma-source MS instruments using high-resolution mass analyzers provide better sensitivity and precision than the currently used quadrupole ICP-MS. Because of the convenience and high sample throughput, the high-resolution ICP-MS is expected to be the method of choice for B isotope ratio determination. The current state of instrumental capabilities is adequate for B isotope determination. However, precision and accuracy are primarily limited by sample preparation, introduction, and analytical methodology, including 1. Analyte loss and isotope fractionation during sample preparation. 2. The precision of B isotope determination in small samples, especially those containing low concentrations. 3. Difficult matrices. 4. Memory effects. Sample preparation by alkali fusion allows rapid and complete decomposition of hard-to-digest samples, but high-salt environments of the fused materials require extensive sample purification for B ratio determination. The alternative wet-ashing sample decomposition with HF also results in B loss and isotopic fractionation owing to the high volatility of BF3. Open-vessel dry- or wet-ashing methods usually do not work well for animal samples, and are also prone to B loss and contamination. Closed-vessel microwave digestion overcomes these problems, but the digests of biological materials have high C contents, which cause spectral interference on 11B and affect 11B/10B ratios. Exchange separation/preconcentration of B using exchange (cation or anion exchange, B-specific resin, e.g., Amberlite IRA-743) tend to cause B isotope fractionation, and C eluting from these resin columns may interfere with B isotope ratio determination. Memory effects of B that occur during sample determination may cause serious errors in B isotope ratio determination, especially when samples varying in B concentrations and/or isotope composition are analyzed together. Although the utilization of high-resolution plasma-source MS will undoubtedly improve analytical precision, it is the sample preparation, sample introduction, and analytical methodology that represent the primary limitation to accurate and precise B isotope ratio determination.     

Techniques for boron determination and their application to the analysis of plant and soil samples

This paper reviews techniques for determining B concentration and isotopic ratio and their application to soil and plant samples. Boron concentration has been determined utilising spectrophotometry, potentiometry, chromatography, flame atomic emission and absorption spectrometry, inductively coupled plasma (ICP) optical emission (OES) and mass spectrometry (MS), and neutron activation analysis using neutron radiography and prompt- activation analysis. Isotopic ratios of B have been measured by ICP–MS, thermal ionisation mass spectrometry (TIMS) and secondary ion mass spectrometry (SIMS). For isotopic measurements, TIMS and SIMS are more sensitive and provide higher degrees of accuracy and resolution than ICP–MS, however, extensive sample preparation and purification, and time-consuming measurements limit their usefulness for routine analyses.While the spectrophotometric technique using a colorimetric reaction of B with azomethine-H has been the most extensively applied B determination method for soil and plant samples, colorimetric methods, in general, suffer from numerous interferences and have poor sensitivity and precision. The prompt- method can determine B concentration in intact samples which enables this method to be especially useful for some applications in agriculture. Research involving B behaviour in plant and soil environments would benefit from this technology. In recent years, the use of ICP–OES and ICP–MS for B determination in plant and soil samples has grown tremendously. The application of ICP–OES brought a significant improvement in B analysis because of its simplicity, sensitivity and multielement detection capability. However, besides matrix interferences, the two most sensitive emission lines for B suffer strong spectral interference from Fe. The ICP–OES is not adequately sensitive for some nutritional work involving low B concentrations and B translocation studies using the isotope tracer technique.Plasma is one of the most effective analyte ionisers and MS is the most sensitive ion detector. Coupling of plasma with MS resulted in the development of plasma source MS technology (ICP–MS) which has outperformed all previous analytical methods for trace element determination. Boron determination by ICP–MS suffers no spectroscopic interferences, and is considered the most practical and convenient technique for B isotope determination. The ability of ICP–MS to measure isotopic ratios as well as B concentration enables: (1) B concentration determination by the isotope dilution method, (2) verification of B concentration by isotope fingerprinting in routine analysis and (3) determination of total B concentration as well as B isotope ratio in the same run for biological tracer studies. Therefore, ICP–MS is the method of choice among the present-day technologies for determining B concentration and a convenient method for B isotope determination. In recent years, new generations of plasma-source MS instruments have been developed using alternative plasma generation methods and high-resolution mass spectrometers. These instruments are expected to bring further improvements in accuracy, sensitivity and precision of B determination.     

Cortisol production rate measurement by stable isotope dilution using gas chromatography-negative ion chemical ionization mass spectrometry.

Presented here is a stable isotope dilution technique for determining cortisol production rate (CPR). The method involves extraction and derivatization of cortisol isoforms from serum (0.5 ml), separation of derivatives by gas chromatography, and detection by using negative ion chemical ionization mass spectrometry. This method provides 50-100-fold greater sensitivity than positive ion mass spectrometry and allows for estimations of cortisol production rate with the use of small amounts of pooled serum, even in the presence of high concentrations of lipophilic contaminants. The area under the curve for the total selected ion chromatogram of fluoroacyl derivatives of cortisol (d0, m/z 782) and deuterated cortisol (d3, m/z 785) were used to determine the isotopic dilution ratio in three types of samples: 1) standards: d0/d3 ratios ranging from 1 to 8%; 2) controls: d3-cortisol added to serum with known cortisol concentration; 3) subjects: 24-h pooled serum samples (q 30 min over 24 h) from healthy children (male 10-13 years; female 7-11 years) receiving continuous infusions of d3-cortisol at 2-4% of their estimated CPR. Recovery after the solid phase extraction and derivatization process was >90%, as determined by thin-layer chromatography. Expected versus measured ratios for d3/d0 in standards and serum controls were highly correlated (r2(standard) = 0.99; r2(control) = 0.99) over a wide range of d3-cortisol enrichment (1.0-10.0%). Mean 24-h CPRs were 4.8 +/- 0.6 mg/m2/24 h (mean +/- SEM, n = 7) in male children and 4.4 +/- 0.5 mg/m2/24 h in female children (n = 4). These CPR values are lower than those derived by radio tracer methods, but are in agreement with previous isotopic dilution studies. This technique is an important tool for assessing CPRs in a wide range of disease states affecting cortisol production.     

Determination of the acylcoenzyme A cholesterol acyltransferase inhibitor 447C88 in plasma using gas chromatography-mass spectrometry and liquid chromatography atmospheric pressure chemical ionisation tandem mass spectrometry

Two mass spectrometry-based methods are described for the determination of 447C88 (I), a novel inhibitor of acylcoenzyme A cholesterol acyltransferase (ACAT), in rat, dog and human plasma. The first method uses gas chromatography-mass spectrometry (GC-MS) with electron ionisation and selected-ion monitoring. The method employs solid-phase extraction of I from plasma and requires alkylation of I using iodoethane. The second method uses liquid chromatography-tandem mass spectrometry (LC-MS-MS) with atmospheric-pressure chemical-ionisation and selected-reaction monitoring. The LC-MS-MS method uses a simplified version of the extraction procedure used for GC-MS and does not require derivatisation of I. While both methods provide the necessary limit of quantitation of 0.5 ng/ml in human, dog and rat plasma with the required precision and accuracy, the LC-MS-MS assay offers increased sensitivity, selectivity and speed over the GC-MS assay. This allows a same day turn round of results for in excess of 100 samples, including sample preparation and data acquisition and processing.     

Gas chromatography-mass spectrometry profiling of steroids in times of molecular biology.

This review's aim is to outline the potential of gas chromatography-mass spectrometry profiling of steroids in the diagnosis of endogenous human steroid disorders. Mass spectrometry currently provides the highest specificity in clinical steroid analysis. The non-invasive and non-selective GC-MS urinary steroid profiling technique enables diagnosis of almost any adrenal enzyme defects in steroid biosynthesis. While enzymatic defects can be diagnosed from spot urine samples in most cases, analysis of 24-hr urinary samples permits determination of hormonal excretion rates or enables diagnostic or therapeutic monitoring of steroid related diseases. Profiling plasma steroids by isotope dilution/GC-MS is particularly suitable where only minimal plasma samples are available and/or the highest specificity is required; therefore, GC-MS steroid profiling presents a complementary analytical technique whenever highest specificity is required. Clinical GC-MS profiling of steroids is also highly recommended as a reasonable initial diagnostic approach--especially in unclear situations--avoiding uncritical and expensive attempts at molecular diagnostic testing.     

The use of deuterium-labeled cortisol for in vivo evaluation of renal 11beta-HSD activity in man: urinary excretion of cortisol, cortisone and their A-ring reduced metabolites

This study describes a new approach using stable isotope methodology in evaluating 11beta-HSD activities in vivo based on urinary excretion of cortisol, cortisone, and their A-ring reduced metabolites. The method involved the measurement of deuterium-labeled cortisol and its deuterium-labeled metabolites by GC/MS simultaneously with endogenous cortisol, cortisone, and their A-ring reduced metabolites after oral administration of deuterium-labeled cortisol to normal human subjects. This stable isotope approach offered unique advantages in assessing the appropriateness of measuring unconjugated and total (unconjugated + conjugated) cortisol, cortisone, and their A-ring reduced metabolites in urine as indices of renal 11beta-HSD2 activity in man. Our results strongly support that the measurement of urinary unconjugated cortisol and cortisone is a significant advance in assessing 11beta-HSD2 activity.     

Determination of sucrose in equine serum using liquid chromatography-mass spectrometry (LC/MS)

Mucosal integrity may be objectively assessed by determination of the absorption of exogenous substances such as sucrose. Gas chromatography-mass spectrometry (GC/MS) and liquid chromatography-mass spectrometry (LC/MS) have been reported for the accurate quantification of low concentrations of sucrose in serum. LC/MS offered the advantage of high sensitivity and mass selectivity without the need for extensive sample derivatization required for GC/MS methods. However, the high polarity and non-volatile nature of the sucrose molecule renders LC/MS techniques challenging. Previously published reports lacked sufficient detail to permit replication of methodology. Problems encountered with existing protocols included poor peak resolution and weak fragmentation of the parent molecule. This communication describes a LC/MS protocol developed to provide improved resolution and product detection.     

Quantification of corticosteroids in human plasma by liquid chromatography–thermospray mass spectrometry using stable isotope dilution

Liquid chromatography–thermospray mass spectrometry (LC–TSP-MS) using isotope dilution was investigated for quantitative analysis of cortisol, cortisone, prednisolone and prednisone in human plasma. Complete separation attained by a LiChroCART Supersupher reversed-phase column and elution with 0.05 M ammonium formate–tetrahydrofuran–methanol (180:53:17, v/v/v) resulted in a significantly large isotope effect of the deuterium-labeled analogs on the HPLC behavior and caused difficulty in quantification. Reduction of the isotope effect on the retention times using 0.05 M ammonium formate–acetonitrile (65:35, v/v) permitted accurate quantification of cortisol and cortisone by the isotope dilution LC–TSP-MS, although separation between cortisol and prednisone was incomplete.     

The measurement of stable isotope natural abundance variations

Precise stable isotope natural abundance analysis of the elements of organic matter, yields a wealth of information for the biologist. Robust sample preparation methodology and analytical instrumentation is necessary to achieve precise results. Basic principles of isotope ratio mass spectrometry (IRMS) are detailed, with particular regard to sample size, gas production and transfer into the IRMS ion source. Gas preparation methods developed to give quantitative yields of pure simple gases from organic and inorganic materials include vacuum line combustion, ampoule combustion and automated elemental analysers used off and on-line. The new technique of GC-C-IRMS, where individual volatile organic compounds are separated by GC, combusted and analysed on-line by IRMS, is also described. The conventional dual batch inlet developed by geochemists for the most precise analysis of stable isotopes, is contrasted with continuous flow-IRMS analysis. The needs of the biological scientist for rapid throughput of small samples are discussed in this context. It is argued that the development of new instrumental approaches will permit many new applications of stable isotope methodology in the biological sciences.     

定量蛋白质组学中的同位素标记技术

定量蛋白质组学的目的是对复杂的混合体系中所有的蛋白质进行鉴定,并对蛋白质的量及量的变化进行准确的测定,是当前系统生物科学研究的重要内容。近年来,由于质谱技术和生物信息学的进步,定量蛋白质组学在分析蛋白质组或亚蛋白质组方面已取得了令人瞩目的成就,但其最显著的成就应该归功于稳定同位素标记技术的应用。该技术使用针对某一类蛋白具有特异性的化学探针来标记目的蛋白质或肽段,同时化学探针要求含有用以精确定量的稳定同位素信号。在此基础上,实现了对表达的蛋白质差异和翻译后修饰的蛋白质差异进行精确定量分析。综述了在定量蛋白质组学中使用的各种同位素标记技术及其应用。     

Development of a stable isotope approach for the inductively coupled plasma-mass spectrometry determination of oxidized metallothionein in biological materials

The use of isotope dilution analysis (IDA) with inductively coupled plasma-mass spectrometry (ICP-MS) for the determination of oxidized metallothionein (MT) by a Cd-saturation method is investigated. The method developed here is a modification of an earlier methodology which used a radioactive Cd isotope ((109)Cd). While retaining the many advantages of this previous approach, the procedure presented here uses stable isotope ratio measurements ((114)Cd/(111)Cd) for the determination of MT. Experimental parameters governing the instrumental precision and accuracy for isotope ratio measurements of Cd by ICP-MS were characterized. Systematic errors, including mass bias, detector dead time, and spectroscopic interferences, could be easily corrected. The isotope dilution ICP-MS method was validated by the determination of very low levels of cadmium in biological certified reference materials (NIST SRM 2670 freeze-dried urine, IAEA H-8 horse kidney, and BCR TP-25 lichens). Finally, the IDA procedure was evaluated for the determination of oxidized MT by a Cd-saturation method previously developed using radioactive (109)Cd. The final procedure was applied to the quantification of MT in Long-Evans Cinnamon rat liver cytosol samples and the results were compared with data obtained for the same samples using the reference (109)Cd methodology. A good agreement between the analytical values obtained by both methods was observed.     

Stable isotope dilution gas chromatography/mass spectrometry of prostaglandins and leukotrienes

The group of arachidonic acid metabolites comprising the prostaglandins, thromboxanes, and leukotrienes (eicosanoids) are extremely potent, biologically active compounds. Their properties include proaggregatory anti-aggregatory activity for platelets, chemotactic activity for neutrophils, vasoactive activity, and contractile activity to smooth muscle. In order to determine the role of these substances in pathophysiological conditions, it is essential to have highly sensitive methods available for their analysis. It is generally accepted that combined gas chromatography/mass spectrometry is the most specific technique available for the quantitative analysis of eicosanoids. However, methods based on electron impact ionization and positive ion chemical ionization are relatively insensitive, and many investigators have preferred the use of less specific but more sensitive methods based on radioimmunoassay. We have explored the use of negative ion chemical ionization mass spectrometry to improve sensitivity coupled with capillary column chromatography to maximize specificity. Conversion of the terminal carboxyl group (present in all eicosanoids) to the pentafluorobenzyl ester derivative confers excellent electron capturing properties to the molecule. The derivative undergoes highly efficient thermal electron capture in the gas phase, and any fragmentation that occurs subsequently is directed almost entirely away from the analyte molecule. The stabilized carboxylate anion that results carries at least 30% of the total ion current. Using selected ion monitoring techniques it is possible to detect eicosanoids in the range 1–8 pg on column. This methodology has been applied to the development of stable isotope dilution assays for plasma 6-oxo-prostaglandin (PG) F_1α (1) and for the simultaneous analysis of six biologically important PGs in biological fluids (2). In addition, stable isotope dilution techniques have been developed for the analysis of serum thromboxane B₂ and serum leukotriene B₄ (3). The application of this technology to understanding the role of arachidonic acid metabolism in humans will be discussed.