Simple and rapid measurement of acetylcholine and choline by HPLC and enzymatic-electrochemical detection

A simple, rapid and sensitive method for the detection of acetylcholine and choline in tissue extracts is reported. Acetylcholine and choline are first separated by HPLC then react in a mini-column with acetylcholinesterase and choline oxidase immobilized on Sepharose. The resulting H₂O₂ produced by choline oxidase is then detected electrochemically. The assay is more sensitive than existing methods. We believe that the principle involved in this method namely the combination of immobilized enzymes and the high sensitivity of electrochemical detection may be applied to other substances that can be converted by immobilized enzymes into an electrochemically detectable compound.     

Internal standard method for the measurement of choline and acetylcholine by capillary electrophoresis with electrochemical detection

An internal standard method has been developed for the determination of the neurotransmitter acetylcholine and/or its metabolic precursor choline. This approach couples the high separation efficiency of capillary electrophoresis with the sensitivity and selectivity of electrochemical detection at an enzyme-modified electrode. Indirect electrochemical detection is accomplished at a 25 microm platinum electrode modified by cross-linking the enzymes choline oxidase and acetylcholinesterase with glutaraldehyde. Although in this simple form of electrode fabrication there is a gradual loss of response from the electrochemical detector with time, accurate quantitation is achieved by the addition of butyrylcholine, which is also a substrate for acetylcholinesterase, as an internal standard. A linear response is achieved between 0 and 125 microM with a limit of detection of 2 microM (25 fmol). The utility of this method was demonstrated by monitoring the kinetics of choline uptake in synaptosomal preparations.     

Enzymic radioassay for acetylcholine and choline in brain

This assay for acetylcholine (ACh) or choline in extracts of rat brain involves the isolation of the choline ester by high-voltage paper electrophoresis, alkaline hydrolysis of ACh to choline, and the quantitative enzymic conversion of choline to a radioactive derivative, P³²-phosphorylcholine. The method is specific, is applicable to large numbers of tissue samples, and has a blank value of about 3 nanograms of choline.     

Increase in rat brain acetylcholine induced by choline or deanol.

Total catecholamines, norepinephrine and small amounts of dopamine were measured in the spinal cord of rats by sensitive radiometric enzymatic assays. There was a considerable disparity between levels of NE and those of total CA suggesting the presence of significant amounts of another catecholamine in spinal cord. The demonstration of the presence of specific phenylethanolamine-N-methyl transferase activity in spinal cord suggested that the catecholamine could be epinephrine. The presence of epinephrine in spinal cord was confirmed by quantitative mass fragmentography. Pretreatment with intracisternal and intracerebroventricular 6-hydroxydopamine markedly reduced the contents of total catecholamines, no norepinephrine and dopamine-β-hydroxylase activity when compared to vehicle treated controls. In contrast, the levels of dopamine only fell to 50% of controls after 6-hydroxydopamine. Thus, in addition to descending noradrenergic tracts, adrenergic neurons appear to be present in the spinal cord.     

Quantitative determination of 5-hydroxytryptophan in dissected brain regions by on-line trace enrichment HPLC with electrochemical detection

A sensitive, specific and rapid quantitative HPLC assay for 5-hydroxytryptophan (5-HTP) in samples of brain regions of widely differing size is described. The method utilizes off-line prepurification of tissue supernatants on gravity-fed strong cation exchange columns, on-line enrichment of the entire cation exchange column eluate on short reverse phase enrichment precolumns, further separation by reverse phase chromatography on an analytical column and electrochemical detection. On-line trace enrichment permits the efficient incorporation of off-line column chromatography to maximize assay specificity without compromising assay sensitivity. A reliable, working limit of detection of 200 pg 5-HTP/sample permits the estimation of in vivo tryptophan hydroxylase activity by determining the rate of 5-HTP accumulation following L-aromatic amino acid decarboxylase inhibition in small discrete brain regions or larger tissue samples only poorly innervated by 5-HT terminals.     

The source of choline for acetylcholine synthesis in brain

More is known about the synthesis and metabolism of acetylcholine (ACh) than other choline (Ch) containing compounds in the brain in spite of the fact that ACh represents only a small fraction of the total Ch esters. This review will attempt to summarize the evidence for the source of Ch in the brain and its relation to the turnover of ACh. Ch is a precursor not only for ACh but also for phosphoryl Ch and phospholipids. It appears that in the rat a bound form of Ch in the brain can produce free Ch which can leave the brain, be converted to ACh or be reutilized for phospholipid synthesis. There is evidence that one of the sources of free Ch that is utilized for ACh synthesis is outside the cholinergic nerve terminal.     

Determination of acetylcholine and choline by flow-injection with immobilized enzymes and fluorometric or luminometric detection

A method for determination of picomolar quantities of acetylcholine and choline in solutions and tissue extracts is described. The analytes are injected into a continuous stream of a simple medium flowing through a sequence of enzyme reactors containing acetylcholinesterase, choline oxidase, and peroxidase. Additional reactors with choline oxidase and catalase are used to remove endogenous choline from the tissue extracts in which the content of acetylcholine is to be measured. Reaction products are detected fluorometrically or luminometrically. The limits of sensitivity are about 10 pmol/sample with luminometric and 0.2 pmol/sample with fluorometric detection.     

Seizures increase acetylcholine and choline concentrations in rat brain regions

Seizures induced by three convulsant treatment produced differential effects on the concentration of acetylcholine in rat brain. Status epilepticus induced by (i) coadministration of lithium and pilocarpine caused massive increases in the concentration of acetylcholine in the cerebral cortex and hippocampus, (ii) a high dose of pilocarpine did not cause an increase of acetylcholine, and (iii) kainate increased acetylcholine, but the magnitude was lower than with the lithium/pilocarpine model. The finding that the acetylcholine concentration increases in two models of status epilepticus in the cortex and hippocampus is in direct contrast with manyin vitro reports in which excessive stimulation causes depletion of acetylcholine. The concentration of choline increased during seizures with all three models. This is likely to be due to calcium- and agonist-induced activation of phospholipase C and/or D activity causing cleavage of choline-containing lipids. The excessive acetylcholine present during status epilepticus induced by lithium and pilocarpine was responsive to pharmacological manipulation. Atropine tended to decrease acetylcholine, similar to its effects in controls. The N-methyl-D-aspartate (NMDA) receptor antagonist, MK-801, reduced the excessive concentration of acetylcholine, especially in the cortex. Inhibition of choline uptake by hemicholinium-3 (HC-3) administered icv reduced the acetylcholine concentration in controls and when given to rats during status epilepticus. These results demonstrate that the rat brain concentrations of acetylcholine and choline can increase during status epilepticus. The accumulated acetylcholine was not in a static, inactive compartment, but was actively turning-over and was responsive to drug treatments. Excessive concentrations of acetylcholine and/or choline may play a role in seizure maintenance and in the neuronal damage and lethality associated with status epilepticus.     

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 carvedilol in plasma by high-performance liquid chromatography with electrochemical detection

Carvedilol is a beta/alpha1-adrenoceptor blocker. A sensitive method for measuring plasma levels of carvedilol in human administrated low doses is needed since its plasma concentration is low. We measured carvedilol and carvedilol M21-aglycon using high-performance liquid chromatography (HPLC) with electrochemical detection. The amperometric detector was operated at 930 mV versus Ag/AgCl. Mean coefficients of variation (n = 5) for carvedilol and M21-aglycon were 4.0 and 7.7% (intra) and 6.1 and 6.7% (inter), respectively. The lower limit of quantification for each analyte was 0.10 ng/ml (signal-to-noise ratio = 3). This lower limit of quantification for carvedilol was sufficient for clinical use.     

Liquid chromatography with electrochemical detection for quantitation of bound choline liberated by phospholipase D hydrolysis from phospholipids containing choline in rat plasma

This report describes the optimal conditions for the determination of bound choline in rat plasma. The method used was based on the liberation of choline by phospholipase D from phospholipids containing choline in plasma, followed by high-performance liquid chromatographic analysis. Normal concentrations of total, free and bound choline in rat plasma were found to be 1278.7 ± 132.5, 11.5 ± 2.2 and 1267.2 ± 125.5 nmol/ml, respectively. The described procedure has the advantages of rapidity, specificity, excellent precision and the need for only a small amount of the sample.     

Determination of reduced glutathione in guinea pig and rat tissue by HPLC with electrochemical detection

A method using HPLC with electrochemical detection has been developed for the determination of GSH in tissue. The method is based upon the separation of GSH from other components by cation exchange chromatography coupled with the electrochemical oxidation of GSH to the corresponding disulfide. Detection limits of ca. 5 × 10^?12 moles GSH were established and the method was used to measure GSH content of rat and guinea pig brain, liver and synaptosome preparations.     

Measurement of nicotine in hair by reversed-phase high-performance liquid chromatography with electrochemical detection

We have developed an assay for nicotine in hair based on reversed-phase HPLC with electrochemical detection. The method uses a low-metal, high-purity silica reversed-phase column. We have investigated the washing, digestion and extraction procedures and discuss the important points in the HPLC method development. The assay is presented as an application in a population of exposed and non-exposed children. Analytical parameters are satisfactory with linearity, recoveries, limit of quantitation and precision all suitable for epidemiological studies involving environmental tobacco smoke exposure assessment.     

Determination of acetylcholine by on-line microdialysis coupled with pre- and post-microbore column enzyme reactors with electrochemical detection

A sensitive procedure consisting of a pre- and post-microbore column reactor sequence of a LC-electrochemical detection system coupled with on-line microdialysis system is described in the present study to measure endogenous acetylcholine concentration in freely moving rats. The pre-column packed, with immobilized choline oxidase and catalase, was used to remove choline, whereas the post-column, packed with immobilized acetylcholine oxidase and choline oxidase, was used to measure acetylcholine selectively. The detection limit of acetylcholine was found to be 5 fmol/μl (50 fmol/10 μl). The usefulness of the described methodology was evaluated by examining the change in the striatal acetylcholine concentration of freely moving rats after physostigmine (0.5 mg/kg, s.c.) administration.     

High-performance liquid chromatography followed by peroxyoxalate chemiluminescence detection of acetylcholine and choline utilizing immobilized enzymes

A sensitive and selective method for the simultaneous determination of acetylcholine (ACh) and choline (Ch) is reported. ACh and Ch were separated on a reversed-phase column, passed through an immobilized enzymes (acetylcholine esterase and choline oxidase) column, and converted to hydrogen peroxide. The generated hydrogen peroxide was detected by the peroxyoxalate chemiluminescence reaction. The linear determination ranges were from 10 pmol to 10 nmol. The detection limit for both cholines was 1 pmol.     

VI. The concurrent estimation of the major monoamine metabolites in human and non-human primate brain by HPLC with fluorescence and electrochemical detection

A simple and sensitive method for the concurrent determination of the monoamine metabolites MHPG, DOPAC, HVA and 5HIAA in brain samples is described. After solvent extraction at acid pH, the metabolites are separated by HPLC on a C₁₈ reversed phase column using phosphate buffers. Detection and quantification are achieved using fluorescence and electrochemical detection in series. The method is applied to control samples of divers areas of human and non-human primate brain, and the distribution of results agrees well with those obtained by existing methods. The concentrations found also agreed well with literature values, and, for 5HIAA and DOPAC, with results obtained on parallel samples analysed by fluorimetry and by GC. Results for HVA however are higher than those obtained by GC, but agree well with literature values obtained by fluorimetry and by GCMS.