Increased conjugated dopamine in plasma after exercise training

To evaluate the effect of endurance exercise on plasma catecholamines, we exercise trained eight dogs (group T) by treadmill running for 8 weeks. Six sedentary dogs constituted a nontrained control group (group NT). Heart rate response to a graded submaximal stress test was reduced in group T dogs (p less than 0.05), but mean resting aortic blood pressure (NT, 84 +/- 5 mm Hg; T, 82 +/- 4 mm Hg) and heart rate (NT, 87 +/- 1 bpm; T, 84 +/- 2 bpm) were unchanged by exercise, and no cardiac hypertrophy occurred after exercise. Plasma norepinephrine and epinephrine levels were reduced in group T at rest and during a fixed exercise workload. Plasma conjugated dopamine showed a marked increase in group T dogs (NT, 1398 +/- 130 pg/ml; T, 11346 +/- 1291 pg/ml; p less than 0.01) at rest, and no change in conjugated dopamine occurred in either group after short-term exercise stress. No intergroup differences were noted in resting coronary flow or coronary arteriovenous oxygen, or in myocardial oxygen consumption. The data verify previous findings of lower plasma levels of norepinephrine and epinephrine after training, and indicate that a marked rise in conjugated dopamine occurs after training. These findings suggest that norepinephrine and epinephrine metabolism is shifted toward conjugated dopamine by exercise training, thereby reducing active catecholamines in plasma, but retaining a large pool of usable metabolite.     

Distribution of free and conjugated catecholamines between plasma, platelets and erythrocytes: different effects of intravenous and oral catecholamine administrations

Plasma, platelet and erythrocyte contents of free and conjugated norepinephrine, epinephrine and dopamine were determined by radioenzymatic assay in 12 resting healthy volunteers. Mean platelet/plasma concentration ratios were 533 for free norepinephrine, 502 for free epinephrine and 149 for free dopamine. Corresponding erythrocyte/plasma ratios were 1.04, 1.13 and 4.5, respectively. The presence of conjugated catecholamines in platelets and erythrocytes could be confirmed; however, their relative proportion within these cells, particularly in platelets, was lower than that in plasma. Upon intravenous infusion of dopamine for 3 hr at 5 micrograms kg-1 min-1, concentrations of free dopamine in plasma increased rapidly (280-970-fold), whereas conjugated dopamine only reached maximal values (14-19-fold increase) at 30 to 60 min after cessation of the infusion. The relative distribution of unconjugated dopamine in whole blood between plasma, platelets and erythrocytes changed from mean values of 1:0.33:3.7 at rest to 1:1.1:0.5 at the end of the infusion. As a result of the subsequent rapid decrease of dopamine in plasma and erythrocytes, this distribution was 1:17:1 shortly thereafter and remained constant up to the end of the investigation period. The relative distribution for conjugated dopamine of 1:0.001:0.5 at rest changed to about 1:0.2:0.1 at the termination of the infusion. Oral administration of norepinephrine and dopamine led to increases in the plasma concentrations of these amines in their conjugated forms only, whereas epinephrine concentrations remained constant. These elevations were not accompanied by corresponding increases in platelet and erythrocyte norepinephrine, epinephrine and dopamine contents.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of exercise training on plasma catecholamines and haemodynamics of adolescent hypertensives during rest,submaximal exercise and orthostatic stress

Summary. Twelve adolescents with essential hypertension were studied to determine the effect of exercise training on plasma catecholamine concentrations, blood pressure and cardiovascular haemodynamics at rest and during submaximal exercise and orthostatic stress. Maximal oxygen consumption (V?O₂max) increased 13% with training while body weight and body fat did not change. Resting systolic and diastolic blood pressures decreased significantly with training, while plasma norepinephrine and epinephrine levels were unchanged. The increase in systolic blood pressure in response to standing was significantly lower after training, while the plasma catecholamine response was not significantly different. At the same absolute work rate after training, the subjects' systolic and diastolic blood pressures, heart rates, and plasma norepinephrine and epinephrine levels were significantly lower than before training. At the same relative work rate after training, the blood pressure response was the same as before training despite significantly higher plasma norepinephrine levels. Thus, the training-induced changes in resting blood pressures and blood pressure responses to orthostatic and submaximal exercise stress cannot be attributed to decreases in plasma catecholamine levels.     

Plasma dopa responses during stress: dependence on sympathoneural activity and tyrosine hydroxylation.

Dihydroxyphenylalanine (dopa), the precursor of all the endogenous catecholamines, circulates in plasma at a concentration higher than that of the sympathetic neurotransmitter, norepinephrine (NE). Sources of dopa in plasma and the meaning of plasma dopa levels in terms of sympathoneural function have been unclear. Plasma concentrations of dopa, the catecholamines NE, epinephrine and dopamine, the deaminated catechol metabolites dihydroxyphenylglycol and dihydroxyphenylacetic acid, and the O-methylated metabolites methoxyhydroxyphenylglycol and homovanillic acid were measured during immobilization stress in conscious rats. Animals were pretreated with chlorisondamine to block ganglionic neurotransmission or with alpha-methyl-para-tyrosine to inhibit tyrosine hydroxylation. Immobilization produced rapid, sustained increases in plasma levels of dopa, catecholamines and catecholamine metabolites. Chlorisondamine decreased base-line plasma dopa and NE levels and abolished the increases in plasma dopa and NE levels during immobilization. alpha-Methyl-para-tyrosine administration produced sustained decreases in plasma dopa levels and markedly attenuated immobilization-induced increases in plasma dopa levels. Bilateral adrenalectomy augmented base-line plasma levels of dopa and NE and augmented dopa and NE responses during immobilization. The results indicate that during immobilization stress, increased postganglionic sympathoneural outflow stimulates the synthesis of dopa in sympathetic neurones and enhances release of dopa into the circulation. The data generally support the view that changes in plasma dopa levels during stress reflect in vivo changes in the rate of catecholamine biosynthesis in sympathetic nerve terminals.     

What stimulates atrial natriuretic factor release during exercise?

Prior studies have shown that circulating atrial natriuretic factor (ANF) increases during short-term exercise, but the mechanism controlling ANF release, as well as the effect of exercise training on ANF release, remains unclear. Fifteen healthy mongrel dogs underwent short-term exercise testing before and after a 12-week period of exercise training (n = 8) or cage confinement (n = 7). ANF, norepinephrine, epinephrine, right atrial pressure, and heart rate were measured simultaneously at rest and during exercise at the time of each acute exercise study. Data were analyzed for all animals with normal baseline ANF values. Exercise training had no modulating effect on circulating ANF levels at rest or during exercise. Therefore, data before and after exercise training or cage confinement were grouped (n = 24) to determine the effects of short-term exercise. ANF levels increased from 49 +/- 2 pg/ml at rest to 60 +/- 4 pg/ml during exercise (p less than 0.05). Heart rate, norepinephrine, and epinephrine values also increased, but right atrial pressure actually decreased from 2.3 +/- 0.9 mm Hg at rest to -3.8 +/- 0.9 mm Hg during exercise (p less than 0.05). There was no correlation between ANF concentrations and levels of these other variables either at rest of during exercise. By demonstrating an increase in ANF with a simultaneous decrease in right atrial pressure, this study clearly shows that increased right atrial pressure is not the secretory stimulus for ANF release during exercise in the normal dog. The lack of correlation between ANF and right atrial pressure, heart rate, norepinephrine, and epinephrine levels suggests that factors other than these variables stimulate ANF release during short-term exercise.     

Free and conjugated catecholamines in patients with cirrhosis

A defect of conjugation may play a role in the elevated plasma free norepinephrine observed in patients with cirrhosis. Plasma free, sulfoconjugated, and glucuronoconjugated catecholamine concentrations were assessed in 15 patients with cirrhosis and in 15 age-matched control subjects. Plasma free norepinephrine and epinephrine levels were significantly higher in patients with cirrhosis (481 +/- 75 and 96 +/- 16 pg/ml, respectively) than in those of the control group (307 +/- 33 and 42 +/- 10 pg/ml, p less than 0.05 and p less than 0.01, respectively). Plasma free dopamine levels were similar in both groups. Sulfoconjugated catecholamines were the predominant form in plasma from both cirrhotic patients and control subjects. The ratio of conjugated to total catecholamines was similar in the two groups. Therefore, it is unlikely that a defect in conjugation of catecholamines is contributing to the excessive plasma free norepinephrine and epinephrine concentrations found in patients with cirrhosis. Moreover, in patients with cirrhosis, no significant relation was found between plasma conjugated catecholamines and the severity of liver disease. This study shows that cirrhosis does not induce alteration in conjugation of catecholamines and that hepatocellular function is not essential for conjugation of circulating catecholamines.     

Human liver and conjugation of catecholamines

To investigate the role of the liver in conjugation of catecholamines we measured the concentrations of free and conjugated norepinephrine, epinephrine, and dopamine in plasma of patients with severe liver disease who were undergoing liver transplantation. Comparisons were made with catecholamine levels in plasma of euhepatic patients who were undergoing abdominal aortic aneurysmectomy. We were also able to determine the importance of the liver in conjugation of exogenous dopamine because this compound was given to both groups of patients. The concentrations of conjugated amines were within the normal range in the patients undergoing liver transplantation, and administered dopamine was conjugated to a similar extent in the two groups of patients. The data suggest that the liver is not indispensable for the conjugation of circulating catecholamines.     

Conjugated catecholamines in human plasma: where are they coming from?

The origins of conjugated catecholamines remain poorly known. The aim of the present study was to see whether a major contribution comes from the sympathetic nervous system. We have assumed some kind of parallelism between the activity of the sympathetic nervous system, the amount of catecholamines released and taken up, and the amount of conjugated catecholamines circulating in plasma. Accordingly, an increase in sympathetic activity should be followed by an increase in the plasma level of conjugated catecholamines. The plasma levels of sulfoconjugated and glucuroconjugated catecholamines were measured in 10 patients with mental disease resistant to drug treatment, before and after electroconvulsive therapy. As expected, blood pressure, norepinephrine concentration, and epinephrine concentration in plasma were transiently increased. Neither sulfoconjugated nor glucuroconjugated catecholamines were significantly changed. Conjugated catecholamines were measured in 10 volunteers before and at the nadir of insulin-induced hypoglycemia. As expected, plasma levels of norepinephrine and epinephrine were drastically increased. Plasma levels of sulfoconjugates were decreased and glucuroconjugates increased; these were narrow but statistically significant variations. Data reported in the present article do not support a major role for the activity of the sympathetic system in fixing the level of conjugated catecholamines in human plasma. This is a negative, but nonetheless important, observation. In human subjects, currently available information suggests an important role for the intestinal wall and renal function in determining the level of circulating sulfoconjugates.     

Quantitative analysis of the contribution of pulmonary and hind limb circulation to the clearance of exogenous catecholamines

The contribution of pulmonary and hind limb circulation to the clearance of exogenous catecholamines was analyzed quantitatively. During infusion of clinical doses of norepinephrine, epinephrine and dopamine in dogs, the plasma level of catecholamine and the plasma flow were measured simultaneously. Percentage of contribution was calculated from the following equation; transorgan difference of plasma catecholamine (nanograms per milliliter) X plasma flow (milliliters per minute) X 100/dose (nanograms per minute). This value means the percentage of the amount of catecholamine cleared by an organ to the amount of catecholamine administered into the body. Small but significant transpulmonary gradients of plasma levels of norepinephrine, epinephrine and dopamine and large translimb gradients of plasma levels of these catecholamines were observed. The plasma flow of pulmonary circulation was increased by infusion of epinephrine and dopamine, whereas it remained unchanged by infusion of norepinephrine. The plasma flow of hind limb circulation showed no significant change by infusion of catecholamines. The calculated contribution values indicate that pulmonary circulation clears 35.7% of norepinephrine (at 0.2 ng X kg-1 X min-1), 27.1% of epinephrine (0.2 ng X kg-1 X min-1) and 21.5% of dopamine (10 micrograms X kg-1 X min-1) administered exogenously, and that the corresponding figures for hind limb circulation are 8.2, 7.8 and 4.5%.     

Ethanol-induced adrenomedullary catecholamine secretion in LS/Ibg and SS/Ibg mice

Ethanol, administered i.p., produced a dose-dependent increase in plasma norepinephrine and epinephrine concentrations in LS/Ibg (LS) but not in SS/Ibg (SS) lines of mice. Ethanol-induced elevations of plasma epinephrine in LS mice were approximately 10-fold greater than those observed in SS mice. Plasma epinephrine and norepinephrine attained peak concentrations at 20-min post-ethanol administration at doses ranging from 2.8 to 4.1 g/kg. Plasma catecholamines remained elevated for approximately 1 hr and returned to basal values 2 hr after ethanol administration. Significant correlations were obtained between blood ethanol (r = 0.99), plasma epinephrine (r = 0.92) and plasma glucose (r = 0.98) as a function of ethanol dose in LS mice. Chlorisondamine (3 mg/kg), a ganglionic blocker, abolished completely the ethanol-induced increase in plasma catecholamines. These results confirm previous suggestions that the response is centrally mediated through an increased sympathetic outflow rather than by a direct effect on the adrenal medulla. The increase in plasma epinephrine and associated hyperglycemia produced by ethanol was not observed with pentobarbital or halothane anesthesia. Ethanol-induced hypothermia was diminished markedly (47%) by an elevated ambient temperature (28 degrees C) without reducing the hyperglycemic response to ethanol. These results suggest that ethanol-induced hypothermia does not mediate ethanol-induced adrenomedullary catecholamine secretion and concomitant hyperglycemia. It is proposed that the differential ethanol-induced secretion of adrenomedullary catecholamines in LS and SS mice is due to differential central nervous system sensitivities to ethanol.     

Role of circulating catecholamines in the control of pancreatic polypeptide and gastrin release

The influence of circulating catecholamines on the release of pancreatic polypeptide (PP) and gastrin was studied in volunteers. Physical exercise increased plasma epinephrine by 374 +/- 123% and plasma norepinephrine by 167 +/- 30%, but plasma PP concentrations remained unchanged during standardized bicycle ergometry. Immediately after cessation of exercise catecholamine levels decreased rapidly, whereas PP concentrations increased by 55%. In a second series, epinephrine infusion (5, 25, and 75 ng.kg-1.min-1) increased epinephrine levels by 38 +/- 12, 331 +/- 69, and 1229 +/- 131%, respectively, whilst norepinephrine was unaffected. Neither during nor after catecholamine infusion PP secretion was affected. Gastrin release increased by a maximum of 85 +/- 38% (at epinephrine 75 ng.kg-1.min-1). It is concluded, that (1) changes in circulating adrenaline do not significantly influence PP secretion in man; (2) the PP increase immediately following physical exercise cannot be attributed to a rapid fall of catecholamine levels; (3) endogenous catecholamines are of minor importance in the control of gastrin secretion.     

Catecholamines in CSF, plasma, and tissue after autologous transplantation of adrenal medulla to the brain in patients with Parkinson's disease

Catecholamine concentrations were measured in tissue samples of caudate and adrenal medulla in eight patients with Parkinson's disease who were taking L-dopa and were undergoing autologous transplantation of adrenal medulla to caudate nucleus. High-performance liquid chromatography with electrochemical detection was used for the measurement of analytes. Dopamine concentrations were quite similar in the caudate and the adrenal medulla; epinephrine and norepinephrine concentrations were some 600 times and 90 times higher, respectively, than that of dopamine in adrenal medulla but were barely detectable in caudate nucleus. Catecholamines and metabolites were also measured, before and after transplantation, in lumbar cerebrospinal fluid (CSF) and plasma 1 hour after the patients' first morning dose of L-dopa. The major fractions of the catecholamines in CSF were sulfoconjugated. The concentrations of sulfoconjugated but not free dopamine were modestly increased in CSF after the transplantation, although plasma concentrations were unchanged. CSF concentrations of free and conjugated norepinephrine and epinephrine, 3-methoxy-4-hydroxyphenylglycol, and homovanillic acid were unchanged after the transplantation. The data suggest that the grafted tissue does not retain its noradrenergic or adrenergic properties after transplantation, and that dopamine formation in the brain may be modestly increased. Plasma catecholamines were unaffected after the removal of one adrenal gland for the transplant.     

Catecholamines in the plasma and urine of patients with alcoholic liver damage under resting and exercise conditions

Heart rate and plasma catecholamines were determined in 16 patients with alcoholic fatty liver and 14 patients with alcoholic cirrhosis of the liver. The measurements were performed at rest and after exercise on the bicycle ergometer, on average 11 days after admission to hospital. In comparison with a control group, the mean heart rate of the patient group was significantly increased at rest and under graduated loading. Significantly increased plasma catecholamine concentrations under resting conditions were observed in both groups of patients, the increase being more pronounced in the cirrhotics (increased with progressive liver damage, significant differences being found between the control group and each of the two groups of patients). During exercise under a load of 50 or 100 watts, the increases in adrenaline, noradrenaline and dopamine concentrations were greatest in patients with alcoholic cirrhosis. With reference to the initial values, however, the increases in concentration were identical in all three groups. In the patients, metabolism of the catecholamines remained unchanged after an average of 11 days abstinence from alcohol; they showed a significantly diminished elimination of vanillylmandelic acid in the urine and, compared with the greatly elevated plasma catecholamine levels, they showed only a moderate increase in the excretion of catecholamines. The results reported here support the assumption that changes in catecholamine metabolism compatible with an increased sympathetic activity are present in chronic alcoholics without advanced liver damage.     

Response of sympathetic nervous system activity to exercise in patients with congestive heart failure

To investigate the serial sympathetic nervous system response to exercise, plasma norepinephrine (NE) and epinephrine (E) concentrations were measured at rest, during each stage of treadmill exercise, and immediately and 5 minutes after exercise in 68 congestive heart failure (CHF) patients (NYHA functional class I 24, II 25, III 19) and 30 normal subjects. Circulatory responses of NYHA class II patients increased at early stages of exercise. Systolic blood pressure and double product at peak exercise were significantly lower in NYHA class III patients. Plasma NE response of NYHA class I patients was similar to that of normal subjects. However, plasma NE at rest, and during and after exercise were significantly higher in NYHA classes II and III patients than in normal subjects and NYHA class I patients (peak NE (pg ml-1); Normals: 547 +/- 37, I: 535 +/- 53, II: 867 +/- 87, III: 1033 +/- 157). There was no significant difference in plasma E levels among the four groups. NE response to exercise was augmented according to the severity of heart failure, which suggested compensatory activation of sympathetic nervous system activity. Circulatory responses were reduced in NYHA class III patients despite the exaggerated compensatory activation of the sympathetic nervous system. Blunted circulatory responses to increased NE concentration in NYHA class III patients might relate to a decreased cardiac responsiveness to sympathetic activity in severe CHF patients.     

Sources and significance of plasma levels of catechols and their metabolites in humans

Human plasma contains several catechols, including the catecholamines norepinephrine, epinephrine, and dopamine, their precursor, L-3,4-dihydroxyphenylalanine (L-DOPA), and their deaminated metabolites, dihydroxyphenylglycol, the main neuronal metabolite of norepinephrine, and dihydroxyphenylacetic acid, a deaminated metabolite of dopamine. Products of metabolism of catechols include 3-methoxytyrosine (from L-DOPA), homovanillic acid and dopamine sulfate (from dopamine), normetanephrine, vanillylmandelic acid, and methoxyhydroxyphenylglycol (from norepinephrine), and metanephrine (from epinephrine). Plasma levels of catechols and their metabolites have related but distinct sources and therefore reflect different functions of catecholamine systems. This article provides an update about plasma levels of catechols and their metabolites and the relevance of those levels to some issues in human health and disease.     

Plasma levels of free and total catecholamines and two deaminated metabolites in man — rapid deconjugation by heat in acid

We have described a procedure for deconjugation of plasma catecholamines, norepinephrine (NE), epinephrine (E) and dopamine (DA) and two Catecholamine metabolites 3,4-dihydroxymandelic acid (DOMA) and 3,4-dihydroxyphenylglycol (DOPEG). Heat at 100° C of the acidified specimen, pH 0.8, produced complete deconjugation of catecholamines in 7 minutes and of metabolites in 5–7 minutes. Subsequently all five products were simultaneously measured with a radioenzymatic assay. However, hydrolysis for 7 minutes produced approximately a loss of 5% in DA and E, 15% in NE and 50% in the metabolites.The percent of free compound in the plasma of 11 normotensive and healthy subjects was 23 ± 16 for NE, 20 ± 8 E, 0.8 ± 1 DA, 20 ± 7 DOMA and 42 ± 12 for DOPEG. Similar results were obtained in a random specimen of six patients with primary hypertension. In a group of four patients with pheochromocytoma free levels of NE, DOPEG and DOMA were significantly greater than in the other two groups, whereas conjugates were not.The intravenous administration of NE or the activation of sympathetic nervous system by standing combined with exercise for 15 minutes did not produce a change in the levels of plasma conjugates. These findings suggest that short changes in plasma catecholamines are better reflected in the free than the conjugated part.     

Catecholamine metabolism in recurrent hereditary polyserositis. Pathogenesis of acute inflammation: the retention—leakage hypothesis

Recurrent hereditary polyserositis (RHP), also known as familial Mediterranean fever, is a genetically-determined disease characterized by paroxysmal attacks of peritonitis, pleuritis, arthritis or inflammation of other serous membranes. We have previously suggested that the pathogenesis of this disease seems to be related to abnormal catecholamine metabolism. This study compares the plasma and urine catecholamine profile in patients with RHP during different clinical states to that in controls. In RHP there were lower plasma and higher urine dopamine levels in the asymptomatic state and during attacks, while norepinephrine levels remain unchanged. However, plasma epinephrine was significantly lower in the asymptomatic state but markedly higher during attacks. The urine epinephrine values in both situations were similar but significantly lower than in controls, suggesting abnormal renal excretion of epinephrine. The urine metanephrine was markedly elevated in the asymptomatic state compared to controls, but remained unchanged during the attacks, again suggesting defective renal clearance of metanephrine. Metaraminol infusion, which induces attacks in RHP patients, was associated with an increase in plasma dopamine and epinephrine (but not norepinephrine); yet the urinary levels of dopamine, epinephrine and metanephrine remained the same, confirming the dissociation between the plasma and urinary levels of these catecholamines, probably due to abnormalities in the renal clearance mechanism. We postulate that this dissociation leads to retention of these amines in the plasma which may subsequently leak through the serous membranes (the target organs) and incite an acute inflammatory process. Colchicine, the only known drug that protects against disease attacks, reduces the plasma levels of these amines, and thus may act by preventing retention that leads to leakage and subsequent inflammation.     

Comparative study of plasma epinephrine and norepinephrine concentrations during hemodialysis: measurement by high-performance liquid chromatography versus radioenzymatic assay

We measured epinephrine and norepinephrine levels simultaneously using two methods of detection of catecholamines in plasma--radioenzymatic assay and high-performance liquid chromatography with electrochemical detection. Measurements were made in 15 stable patients during hemodialysis. No statistical differences in intradialysis plasma concentrations were found for epinephrine or norepinephrine, and no statistical differences were found between the values of epinephrine and norepinephrine using the two different methods. No significant decrement in epinephrine or norepinephrine concentrations during the dialysis procedure was detected regardless of the method used. We conclude that the hemodialysis procedure does not affect the concentration of plasma catecholamines and that the two methods of detecting plasma catecholamines in patients with renal failure are equally accurate.     

Effect of intermediate-dose naloxone on cardiovascular and sympathoneural adjustments to exercise.

The effects of intermediate-dose naloxone on sympathetic nerve activity and cardiovascular adjustments to exercise were examined in two series of experiments. In the first series 10 normal male volunteers, mean age 28 +/- 5 (SD) years received i.v. naloxone, mean 0.28 +/- 0.6 mg/kg in 0.1 mg/kg aliquots 60-90 min after 45 min of submaximum treadmill exercise. Naloxone had no detectable effect on supine blood pressure, heart rate, plasma norepinephrine, or epinephrine concentrations or muscle sympathetic nerve burst frequency at rest or during the strain phase of the Valsalva manoeuvre, but decreased slightly sympathetic burst incidence at rest (p less than 0.05). In the second study, 8 of these subjects repeated the exercise protocol 15 to 20 min after 0.1 mg/kg i.v. naloxone. Supine blood pressure, heart rate, plasma norepinephrine and epinephrine concentrations before and 15 min after naloxone were virtually identical. A comparison of results from both study days did not reveal a naloxone effect on blood pressure during or up to 60 min after exercise, whereas the heart rate response to exercise was attenuated (p less than 0.002). Intermediate-dose naloxone has no apparent effects on blood pressure during and after exercise, attenuates the chronotropic response to exercise, and has only modest inhibitory effects on muscle sympathetic nerve activity.     

Electrochemical detection of catecholamines in urine and plasma after separation with HPLC

The catecholamines in plasma and urine were determined by electrochemical detection after separation on a HPLC column RCM 100 C 18. Linear calibration plots of epinephrine, norepinephrine and dopamine have been obtained in the range expected to appear in urine or plasma. Coefficients of variation (0.5 to 10%), recovery rates (60 to 80%) and the standard deviation were satisfactory, whereas plasma dopamine showed a greater variation (10-15%). The values ascertained by this technique were compared with those determined by the radioenzymatic assay of Da Prada et al. They showed a good correlation for norepinephrine r = 0.92, p less than 0.001 and epinephrine r = 0.80, p less than 0.01, but less for dopamine r = 0.1. Experimental details of isolation from plasma with Al2O3 adsorption and desorption with HClO4, and from urine with ion exchange chromatography on Bio-Rex 70 and elution with boric acid are described. Technical modifications which improve the method are reported. The optimized assay could reliably be employed in investigations of more than 3000 urine and plasma samples obtained from patients and athletes before and after exercise.