Simple method for the determination of choline and acetylcholine by pyrolysis gas chromatography

An improved purification procedure is described for the simultaneous assay of endogenous choline and acetylcholine by pyrolysis gas chromatography, particularly for providing a simple and effective method for propionylation of choline in the presence of acetylcholine. The reaction was carried out in acetonitrile solution prepared by dissolving the evaporated residue of the supernatant of brain homogenate. Thus samples for propionylation were prepared without the use of ion-exchange chromatography.     

Determination of picomole quantities of acetylcholine and choline in physiologic salt solutions

An assay capable of detecting tens-of-picomole quantities of choline and acetylcholine in milliliter volumes of a physiological salt solution has been developed. Silica column chromatography was used to bind and separate 10–3000 pmol [¹⁴C]choline and [¹⁴C]acetylcholine standards made up in 3 ml of a bicarbonate-buffered Krebs-Ringer solution. The silica columns bound 95–98% of both choline and acetylcholine. Of the bound choline 84–87% was eluted in 1.5 ml of 0.075 n HCl, whereas 95–98% of the bound acetylcholine was eluted in a subsequent wash with 1.5 ml of 0.030 n HCl in 10% 2-butanone. Vacuum centrifugation of the eluants yielded small white pellets with losses of choline and acetylcholine of only 1%. Dried pellets of unlabeled choline and acetylcholine standards were assayed radioenzymatically using [γ-³²P]ATP, choline kinase, and acetylcholinesterase. The net disintegrations per minute of choline[³²P]phosphate product was proportional to both the acetylcholine (10–3000 pmol) and choline (30–3000 pmol) standards. The “limit sensitivity” was 8.5 pmol for acetylcholine and 11.4 pmol for choline. Cross-contamination of the choline assay by acetylcholine averaged 1.3%, whereas contamination of the acetylcholine assay by choline averaged 3.1%.     

Measurement of choline and choline metabolite concentrations using high-pressure liquid chromatography and gas chromatography-mass spectrometry

We have developed a reproducible and sensitive procedure for the isolation and measurement of choline, phosphocholine, glycerophosphocholine, phosphatidylcholine, lysophosphatidylcholine and acetylcholine in a single 100-mg sample of biological tissue. Tissues were spiked with 14C-methyl- and 2H-methyl- or 15N-choline labeled internal standards for each compound. They were extracted with chloroform/methanol/water and the aqueous and organic phases were dried. The organic phase was resuspended in chloroform/methanol (1/1, v/v) and an aliquot was applied to a silica-gel thin-layer chromatography plate. The plate was developed in chloroform/methanol/water (65/30/4, v/v). Segments which cochromatographed with external standards of phosphatidylcholine and lysophosphatidylcholine were stained, scraped, and hydrolyzed in 6 M methanolic-HCl at 80 degrees C for 60 min, liberating free choline. The aqueous phase was resuspended in methanol/water and injected onto a silica HPLC column. Choline and its metabolites were eluted using a binary nonlinear gradient of acetonitrile/ethanol/acetic acid/1 M ammonium acetate/water/0.1 M sodium phosphate (800/68/2/3/127/10, v/v changing to 400/68/44/88/400/10, v/v). Peaks were detected with an on-line radiometric detector, collected, and dried under vacuum. Each choline ester was digested in 6 M HCl at 80 degrees C to form choline. Choline was then converted to the propionyl ester and demethylated with sodium benzenethiolate. This volatile derivative was then isolated using gas chromatography and measured with a mass selective detector. Deuterated internal standards were used to correct for variations in recovery. Choline, glycerophosphocholine, phosphocholine, phosphatidylcholine, lysophosphatidylcholine, and acetylcholine were measured in rat liver, heart, muscle, kidney, plasma, red blood cells, and brain and in human plasma.(ABSTRACT TRUNCATED AT 250 WORDS)     

The measurement of nanogram amounts of acetylcholine in tissues by pyrolysis gas chromatography

Abstract— A method previously described for measuring ACh in biological effluents has been simplified and extended for use with tissues. The tissue is homogenized in acetonitrile containing propionylcholine as the internal standard and after centrifugation the acetonitrile is removed by shaking with toluene. To the aqueous solution is added a solution of KI-I₂ to precipitate the quaternary compounds. The precipitate is dissolved in aqueous acetonitrile and then drawn through a small column of ion-exchange resin to convert the periodides of the quaternary compounds to chlorides which are then simultaneously pyrolysed and gas chromatographed. On the column the pyrolytic product of choline has a slower retention time than that of acetylcholine; under these circumstances the choline present in tissues does not obscure the measurement of acetylcholine. Specificity was demonstrated by several procedures including mass spectroscopy. The method can measure 25 ng (171 pmoles) of acetylcholine in extracts of brain, simply, and with high reproducibility. With the usual gas chromatograph, 16 samples can be run in a working day. The content of acetylcholine in rat brain was 26.4 nmol/g or almost precisely the values found with other gas chromatographic methods. The pyrolytic method was shown to be applicable to the detection of biologically interesting substances other than choline esters, including betaine, carnitine and the non- quaternary compound, ?-aminobutyric acid, which is readily converted to a volatile compound (probably its methyl ester) when pyrolysed in the presence of tetramethylammonium hydroxide. Of additional general interest is the demonstration of the advantages of acetonitrile as a solvent for extracting water-soluble compounds from tissues.     

High-performance liquid chromatography of water-soluble choline metabolites

We have developed a new method for the separation of [3H]choline metabolites by high-performance liquid chromatography. Using this method it is possible to separate, in one step, all of the known major water-soluble choline metabolites present in crude acid extracts of cells that have been incubated with [3H]choline, with baseline or near-baseline resolution. We use a gradient HPLC system with a normal-phase silica column as the stationary phase, and a linear gradient of increasing polarity and ionic strength as the mobile phase. The mobile phase is composed of two buffers: Buffer A, containing acetonitrile/water/ethyl alcohol/acetic acid/0.83 M sodium acetate (800/127/68/2/3), and buffer B (400/400/68/53/79), pH 3.6. A linear gradient from 0 to 100% buffer B, with a slope of 5%/min, is started 15 min after injection. At a flow rate of 2.7 ml/min and column temperature of 45 degrees C, typical retention times for the following compounds are (in min): betaine, 10; acetylcholine, 18; choline, 22; glycerophosphocholine, 26; CDP-choline, 31; and phosphorylcholine, 40. This procedure has been applied in tracer studies of choline metabolism utilizing the neuronal NG108-15 cell line and rat hippocampal slices as model systems. While the compounds labeled in the NG108-15 cells were primarily phosphorylcholine and glycerophosphocholine, reflecting high rates of phospholipid turnover, in the hippocampal slices choline and acetylcholine were the major labeled species. Identification of individual peaks was confirmed by comparing the elution profiles of untreated cell extracts with extracts that had been treated with hydrolyzing enzymes of differing specificities. This HPLC method may be useful in studies of acetylcholine and phosphatidylcholine metabolism, and of the possible interrelationships of these compounds in cholinergic cells.     

Isolation of choline esters from aqueous solutions by extraction with sodium tetraphenylboron in organic solvents

1. The method is based on the observation that choline esters and sodium tetraphenylboron (Kalignost) form complexes that are insoluble in water but soluble in organic solvents such as nitriles, higher ketones and benzyl alcohol. 2. The extraction procedure is an example of liquid cation exchange where tetraphenylboron is the cation-exchange group. 3. The proportion of choline esters extracted depends on the type and total amount of cation in the aqueous phase and the amount of sodium tetraphenylboron in the organic solvent. 4. The proportion of choline esters extracted is independent of the choline ester concentration, the pH (between 8 and 3) and the relative volumes of the two phases. 5. The affinity of sodium tetraphenylboron for choline esters increases with an increase in the size of the acyl group. 6. The choline ester extracted can be released into an aqueous solution by treatment with strong acids, silver salts and anion-exchange resins.     

Estimation of N-amino-N,N-dimethylaminoethanol, choline and their acetate esters by gas chromatography mass spectrometry

A method is described for measurement of choline, N-aminodeanol, and their acetyl esters by gas chromatography mass spectrometry. The preparation of N-aminodeanol and its isotopic variants is also described. This method allows a thorough quantitative analysis of the replacement of true with false neurotransmitter in biological preparations.     

A method for measurement of the specific radioactivity of the choline moiety of choline phospholipids.

The specific radioactivity of a choline phospholipid has been determined by a double-isotope method. Purified phospholipid was hydrolyzed to release labeled choline, and choline kinase was employed to label the choline with ³²P from [γ-³²P]ATP. The double-labeled phosphorylcholine was purified by ion-exchange chromatography on QAE-Sephadex, and the specific radioactivity of the choline was calculated from the isotope ratio. The method is sensitive, requiring only 5 nmol of choline with a specific radioactivity of 1 μCl/μmol, and the chromatographic isolation of phosphorylcholine is simple and reproducible.     

毛豆中腈菌唑残留量的气相色谱法测定

采用气相色谱法定量分析毛豆上腈菌唑的微量残留量。样品经乙腈提取,液液分配,中性氧化铝柱层析净化后,以气相色谱电子俘获检测器法(GC-ECD)测定,DB-1701毛细管柱、氮气为载气,柱温150℃20℃/min 260℃(10 min),气化室温度240℃,检测器温度300℃,外标法定量。该方法快速、准确,在0.05~2.00 mg/L范围内线性相关系数r²=0.9998,平均回收率91.1%~99.0%,变异系数1.22%~2.94%,最小检测量1.0×10^-12 g,最低检出浓度5.0×10^-4 mg/kg。     

Analysis of microquantities of choline and its esters utilizing gas chromatography-chemical ionization mass spectrometry.

Gas chromatography-chemical ionization mass spectrometry has been applied successfully in the analysis of choline and its esters. This approach serves to extend further the potential of existing gas chromatographic procedures which are capable of the microestimation of choline esters following their N-demethylation by either chemical or physical means. Typical fragmentation patterns with ions at $\text{m}\text{e}\text{= 72}$ and $\text{m}\text{e}\text{= (M + 1)}$ were obtained for each choline ester derivative. When methane was used as the reactant gas, the above fragments were approximately of equal abundance for each ester. Use of isobutane as reactant gas yielded almost 80% of the (M + 1) fragment, and only approximately 5% of the fragment ion at $\text{m}\text{e}\text{= 72}$. Recovery of all fragments was linear for nondeuterated as well as deuterated analogs of choline ester derivatives. Recovery, as evident from the analysis of records of relative ratios of injected isotopic variants of these esters, indicated that this analysis of choline esters using chemical ionization mass spectrometry coupled with gas chromatography is quantitative and highly reproducible.     

Simultaneous analysis of choline and acetylcholine levels in rat brain by pyrolysis gas chromatography.

Gas chromatographic analysis of the tertiary amines resulting from either chemical (1,2) or heat-catalyzed (3,4) removal of a quarternary methyl group from choline esters has provided a sensitive chemical assay for acetylcholine (ACh) in various tissues. In order to study ACh turnover using precursor labeling techniques it is also necessary to measure the level of free choline in tissue. Recent publications on the level of choline in the central nervous system (5,6) and on the role its uptake plays in the regulation of ACh synthesis in cholinergic neurons have also stimulated interest in the measurement of choline. Methods for simultaneous analysis of choline and ACh employing chemical demethylation have previously been published (7). The present paper describes the modification of a previous method (4) which is necessary for simultaneous analysis of choline and ACh by pyrolysis gas chromatography. These modifications are required because endogenously occurring amounts of choline are not reproducibly precipitated as the eneiodide salt from aqueous solutions and choline cannot be quantitatively converted to its tertiary amine analog by pyrolysis. It is therefore quantitatively isolated and converted to a choline ester prior to gas chromatographic analysis.     

Measurement of acetylcholine and choline in brain by HPLC with electrochemical detection

A simple and rapid method for measuring acetylcholine and choline using high performance liquid chromatography (HPLC) with electrochemical detection is presented. Acetylcholine and choline were first separated using reverse-phase chromatography; acetylcholine was then hydrolyzed post-column to choline by acetylcholinesterase. Choline was oxidized enzymatically by choline oxidase to betaine and hydrogen peroxide, and the peroxide was detected electrochemically. Changes in methodology from previous procedures include a different mobile phase, controlled heating of chromatography column and post-column reaction coil, and a different extraction method for quaternary amines. The changes resulted in less inhibition of derivatizing enzymes by mobile phase, narrow and consistent elution of peaks, and a rapid and efficient extraction of quaternary amines. Measurement of acetylcholine and choline in brain tissue was found to be replicable, and the levels agreed with literature values.     

Purification of fatty acid ethyl esters by solid-phase extraction and high-performance liquid chromatography

We have developed a two-step method to purify fatty acid ethyl esters (FAEE) using solid-phase extraction (SPE), with a recovery of 70±3% (mean±S.E.M.) as assessed using ethyl oleate as a recovery marker from a standard lipid mixture in hexane. The first step of the SPE procedure involves application of a lipid mixture to an aminopropyl-silica column with simultaneous elution of FAEE and cholesteryl esters from the column with hexane. Gas chromatographic analysis of FAEE without interference from cholesteryl esters may be performed using the eluate from the aminopropyl-silica column, thus eliminating the need for an octadecylsily (ODS) column in this case. The FAEE can then be separated from the cholesteryl esters, if necessary, by chromatography on an ODS column and elution with isopropanol-water (5:1, v/v). Both the aminopropyl-silica and ODS columns were found to be effective for up to four uses. To permit isolation of specific FAEE species following isolation of total FAEE by the two-step SPE method, we have also developed a purification scheme for individaal FAEE by high-performance liquid chromatography (HPLC). Thus, this simple method allows for reproducible isolation of total FAEE by SPE and isolation of individual FAEE species by HPLC.     

Uptake and metabolism of choline in primary isolated neurons and glial cells in culture

The influx and metabolism of choline have been studied in primary cultures of isolated neurons and glial cells from chick embryo dissociated cerebral hemispheres. The results showed a correlation between both influx and metabolism of choline and the exogenous concentrations of choline. When neurons and glial cells were preincubated (10 min) and incubated in Krebs-Ringer phosphate solution with concentrations of choline lower (0.5 μM) or higher (150 μM) than the one present in the growth medium, the metabolism of choline, as a function of time, approached saturation following unusual kinetics. This suggests a non steady state of the endocellular concentrations of free choline. Moreover, when both neurons and glial cells were preincubated (10 min) with 50 μM choline and then incubated (2 min) with various concentrations of choline, only one uptake mechanism was measured, while the preincubation in the absence of choline followed by the incubation of the cells with various concentrations of choline showed the presence of two apparent K_m's with different affinities.The results also indicate the capacity of glial cells to incorporate choline suggesting a storage function for the cells.     

Novel isolation procedure for short-, medium-, and long-chain acyl-coenzyme A esters from tissue

A novel procedure for the quantitative isolation and purification of acyl-coenzyme A esters is presented. The procedure involves two steps: (1) tissue extraction using acetonitrile/2-propanol (3+1, v+v) followed by 0.1 M potassium phosphate, pH 6.7, and (2) purification using 2-(2-pyridyl)ethyl-functionalized silica gel. Recoveries determined by adding radiolabeled acetyl-, malonyl-, octanoyl-, oleoyl-, palmitoyl-, or arachidonyl-coenzyme A to powdered rat liver varied 93-104% for tissue extraction and 83-90% for solid-phase extraction. The procedure described allows for isolation and purification, with high recoveries, of acyl-coenzyme A esters differing widely in chain length and saturation.     

Chemiluminescent assays for choline and phospholipase-D using a flow injection system

A flow injection chemiluminescent method is described for the determination of choline. The method is based on the production of hydrogen peroxide from choline using on-line covalently bound immobilized choline oxidase column. The product is mixed downstream and detected via the cobalt catalyzed chemiluminescent oxidation of luminol. The detection limit is 1×10⁻⁷ mol/L, with rsd 1.8 to 2.8% in the range 2–10×10⁻⁵ mol/L. The sample throughput is 30 per hour. The method was applied to the determination of choline produced off-line from phosphatidylcholine using phospholipase-D isolated from cabbage. © 1997 John Wiley & Sons, Ltd.     

Separation of long-chain fatty acid esters of retinol by high-performance liquid chromatography

Individual long-chain fatty acid esters of retinol can be resolved by high-performance liquid chromatography using an octyl- or phenyl-substituted reverse-phase column and mixtures of acetonitrile with water as mobile phase. This simple procedure provides good resolution of biologically important retinyl esters including retinyl palmitate and retinyl oleate. Using an isocratic elution system, it is shown that nine synthetic esters of retinol, ranging in fatty acyl chain length from 12 to 20 carbons, each elute with a unique elution volume and produce an absorbance signal at 340 nm proportional to molar concentration. The method is suitable for analysis of various esters of retinol in biological samples including lymph chylomicrons and blood plasma. The octyl-substituted reverse-phase column can also be used to separate more polar neutral retinoids including retinol and retinaldehyde.     

Determination of choline in erythrocytes using high-resolution proton nuclear magnetic resonance spectroscopy: Comparison with a choline oxidase method

Detailed operating conditions are reported for the determination of choline in human erythrocytes using proton nuclear magnetic resonance spectroscopy in conjunction with the inversion-recovery spin-echo pulse sequence. The results of the NMR method were in excellent agreement with those obtained using an enzymatic (choline oxidase) assay; however, they were approximately three times higher than those reported using gas chromatography/mass spectrometry techniques. The differences may be partly due to the method of preparing or sampling cells since there is a distribution of choline in cells of different ages. However, choline levels were not affected by the methods used in the present study for storing or preparing cells.     

Quantitative determination of acyl chain composition of subnanomole amounts of cellular long-chain acyl-coenzyme A esters

A procedure for the quantitative determination of the acyl chain composition of cellular long-chain acyl-CoA esters in subnanomole amounts is described. The abundant cellular lipids of samples are removed by extraction with organic solvents, and the proteins are precipitated from the aqueous phase by the addition of acetonitrile. The CoA thiolesters are adsorbed on neutral aluminum oxide and reduced with sodium borohydride to the corresponding alcohols that are then converted to t-butyldimethylsilyl ethers and analyzed quantitatively by gas chromatography. Saturated and unsaturated acyl chains behaved similarly throughout the procedure, and the common lipid esters do not interfere with the analysis of the CoA esters in the final assay procedure described. This simple and relatively rapid method is suitable for analyzing a large number of samples at a time.     

A radiometric microassay for choline acetyltransferase. Some observations on the spinal cord of the chicken embryo

This paper describes cation-exchange methods for separating acetyl[³H] coenzyme A from [acetyl-³H]choline. Blanks for the routine method were approximately 0.05% of the substrate radioactivity; product recoveries were approximately 97%. The cation-exchange method was moreefficient than the standard methods using either anion-exchange chromatography or periodide precipitation. The cation-exchange method was also morespecific than either of the other two standard methods for estimating choline acetyltransferase (ChAT) activity. ChAT activity was detected in the chicken lumbar spinal cord on embryonic day (E) 2 1/4 with the cation-exchange method. This developmental stage is about 6 hours before the final mitosis of any neuroblast in the ventral horn. Total ChAT activity per lumbar spinal cord increased more than 10,000-fold between E 3 and E 18. Changes in ChAT activity in the lumbar spinal cord following limb-bud extirpation appeared to mirror (with a phase lag) the changes in the number of motoneurons in the lateral motor column.