Occurrence of orally administered curcuminoid as glucuronide and glucuronide/sulfate conjugates in rat plasma

Curcuminoids, curcumin and its structurally related compounds, constitute the phenolic yellowish pigment of turmeric. We investigated the absorption and metabolism of orally administered curcuminoids (curcumin, demethoxycurcumin and bisdemethoxycurcumin) in rats. HPLC and LC-MS analyses after enzymatic hydrolyses showed that the predominant metabolites in plasma following administration were glucuronides and glucuronide/sulfates (conjugates with both glucuronide and sulfate) of curcuminoids. The plasma concentrations of conjugated curcuminoids reached a maximum one hour after administration. The conjugative enzyme activities for glucuronidation and sulfation of curcumin were found in liver, kidney and intestinal mucosa. These results indicate that orally administered curcuminoids are absorbed from the alimentary tract and present in the general blood circulation after largely being metabolized to the form of glucuronide and glucuronide/sulfate conjugates.     

Free and conjugated catecholamines and metabolites in cat urine after hypoxia

Catecholamine and metabolite excretion was studied in the cat after 6 h of 7.5% O2 hypoxia. Norepinephrine (NE) release from sympathetic nervous endings was strongly activated, whereas epinephrine (E) excretion was only slightly increased. A noteworthy result was the increase of dopamine (DA) and its metabolites [3-methoxytyramine (MT); 3,4-dihydroxyphenylacetic acid (DOPAC)] in urine samples. This increased release does not seem to originate from the central nervous system, but rather from peripheral dopaminergic structures; available knowledge on peripheral DA suggests that the hypoxia-induced DA release might be partly related to chemosensory or renal function. Indeed, in addition to enhanced DA and NE excretion, we observed an increase in sodium excretion that correlated with both DA and NE. Analysis of free and conjugated urinary metabolites showed that only free NE and both free and conjugated normetanephrine were increased in urine after hypoxic stress. Among DA metabolites, conjugated DOPAC was the main DA metabolite in the basal state and after hypoxia. Both the free and the conjugated forms of DA, MT, and DOPAC were increased by hypoxia.     

Gasping and autoresuscitation in the developing rat: effect of antecedent intermittent hypoxia.

Gasping is a critically important mechanism for autoresuscitation and survival during extreme tissue hypoxia. Evidence of antecedent hypoxia in sudden infant death syndrome suggests that intermittently occurring hypoxic episodes may modify gasping and autoresuscitation. To examine this issue, an intermittent hypoxia (IH) profile consisting of alternating room air and 10% O(2)-balance N(2) every 90 s was applied to pregnant Sprague-Dawley rats (IHRA; n = 50) and to pups after a normal pregnancy (RAIH; n = 50) as well as to control pups (RARA; n = 50). At postnatal day 5, pups were exposed to 95% N(2)-5% CO(2), and gasping and the ability to autoresuscitate were assessed. Compared with RARA, IHRA- and RAIH-exposed pups had a reduced number of gasps, decreased overall gasp duration, and were less likely to autoresuscitate on introduction of room air to the breathing mixture during the last phase of gasping (P < 0.001 vs. RARA). We conclude that both prenatal and early postnatal IH adversely affect gasping and related survival mechanisms.     

The effect of catecholamines and prostaglandins upon human and rat erythrocytes

Both human and rat erythrocytes respond to low doses (10⁻¹¹-10⁻⁹ M) of L-isoproterenol and Lepinephrin with an increased degree of hypotonic hemolysis and a decreased rate of filtration through standardized paper filters. The receptors in both cell types have many of the characteristics of β-receptors for catecholamines. However, hormone-receptor interaction in the human cell does not lead to an increase in intracellular cyclic AMP concentration, but in the rat cell, hormone-receptor interaction does lead to a significant increase in cylic AMP content. Thus, catecholamine-β-receptor interaction, at least in the human red cell, leads to a change in red cell properties which are not mediated by adenylate cyclase activation. Likewise, prostaglandin E₂, at 10⁻¹²-10⁻¹⁰ M, causes an increased degree of hypotonic hemolysis and a decreased rate of filtration through standardized paper filters, but it also does not increase the cyclic AMP content of the human erythrocyte but does increase that of the rat erythrocyte. Nevertheless, exogenous cyclic AMP, when added at a concentration of 10⁻⁸ M to washed human erythrocytes, increases the degree of hypotonic hemolysis. Conversely, prostaglandin E₁, at 10⁻¹²-10⁻¹⁰ M, causes a decreased degree of hypotonic hemolysis and an increased rate of filtration through a standard filter. Both prostaglandin E₂ and the catecholamines decrease the size of a rapidly exchangeable calcium pool, and prostaglandin E₁ increases it.     

Direct determination of glucuronide and sulfate of p-hydroxymethamphetamine in methamphetamine users' urine

Two conjugates of p-hydroxymethamphetamine (p-OHMA), p-OHMA-glucuronide (p-OHMA-Glu) and p-OHMA-sulfate (p-OHMA-Sul) have been identified in methamphetamine (MA) users' urine by using liquid chromatography-high resolution tandem mass spectrometry (LC-HRMS-MS). The synthesis of p-OHMA-Glu and p-OHMA-Sul, and an LC-MS procedure for the simultaneous determination of MA and its four metabolites, amphetamine (AP), p-OHMA, p-OHMA-Glu and p-OHMA-Sul, in urine have also been established. After deproteinizing urine samples with methanol, LC-MS employing a C(18) semi-micro column with a gradient elution program provided the successful separations and MS determinations of these analytes within 20 min. Based on the established method, p-OHMA-Sul was detected at higher concentrations than p-OHMA-Glu in all of the three urine samples tested. These data suggest that sulfation is a major pathway in the MA phase II metabolism.     

The effect of ascorbic acid on plasma sulfate conjugated catecholamines after eating bananas

The effects of eating bananas, a rich source of biogenic amines, on the plasma concentration of free and sulfate conjugated norepinephrine (NE) and dopamine (DA), and free epinephrine (E), were examined in normal male subjects before and after treatment with ascorbic acid, 2 g daily for 7 days. There were no significant changes in the levels of free NE or E in any subjects after eating a banana, either before or after ascorbic acid. Plasma free DA became detectable in some subjects, but the overall changes were not significant. Sulfate conjugated DA and NE increased markedly after banana ingestion, as previously demonstrated in our laboratory. After ascorbic acid treatment the rise in sulphate conjugated NE was attenuated, presumably because ascorbic acid acts as a competitive inhibitor of sulfate conjugation. In contrast, the rise in conjugated DA was potentiated after ascorbic acid treatment. This may be indicative of the higher affinity of DA for phenolsulfotransferase, an inhibitory effect of ascorbic acid on dopamine-receptor coupling or of ascorbic acid protecting DA from oxidation in the gut.     

Single doses of catecholamines in the rat: catecholaminotropic, but not hyperglycemic

1. As in two "lower" vertebrates, the lamprey and the eel, single intravascular injections of physiological doses (2.5 micrograms/kg) of epinephrine (E) into the rat immediately increased levels of plasma dopamine (DA) and norepinephrine (NE). 2. Single doses of DA (5 micrograms/kg) enhanced circulating NE and E, while NE (5 micrograms/kg) had no clear impact on the plasma levels of the other two catecholamines (CAs). 3. These data are at variance with findings in the eel, where all three CAs are mutually stimulatory; and in the lamprey, where only E stimulates release of the other two CAs. 4. It appears that E-stimulated CA release is widespread or ubiquitous among vertebrates, and that complex interactions between circulating CAs must be considered under experimental, physiological, and clinical conditions. 5. None of the injections had a significant hyperglycemic effect.     

Attenuating effect of melatonin on pyridoxal-stimulated release of adrenomedullary catecholamines in the rat

AimsTo investigate the ability of melatonin (MEL) to suppress adrenomedullary catecholamine (CAT) release in the rat, with pyridoxal (PL) being used as an adrenomedullary stimulus and liver and gastrocnemius muscle glycogenolysis acting as indices of CAT release.Main methodsMEL (1–4 mg/kg, i.p.) and PL (300 mg/kg, i.p.) were administered separately or together to male Sprague–Dawley rats (275–300 g), and blood samples for the assay of plasma glucose and CATs were periodically collected for up to 3 h after PL. Immediately thereafter, the liver and gastrocnemius muscle were surgically removed and used for the assay of glycogen. The role of adrenoceptors in PL-induced glycogenolysis was examined by parallel experiments in which idazoxan (IDX, 1 mg/kg), propranolol (PRO, 2 mg/kg) or metoprolol (MET, 2 mg/kg) were administered alongside MEL. In addition, MEL (4 mg/kg) was co-administered with taurine (TAU, 2.4 mmol/kg), a known adrenomedullary membrane stabilizer.Key findingsMEL attenuated the release of adrenomedullary CATs and accompanying liver and gastrocnemius muscle glycogenolysis due to PL in a dose-dependent manner. A co-treatment with MEL and an adrenoceptor blocker had a greater attenuating effect on PL-induced glycogenolysis and hyperglycemia than MEL but without impinging on the CAT levels seen with MEL alone. Evidence of maximal inhibitory action by MEL on PL-induced plasma CAT elevation was suggested by the about equal levels of plasma CATs after treatments with MEL and with MEL plus TAU.SignificanceThe present study demonstrates the modulatory effect of MEL of exogenous origin on adrenomedullary CAT secretion when present in supraphysiological concentrations.     

Free and conjugated catecholamines in digestive tissues of rats

Using a radioenzymatic technique, the highest concentrations of free catecholamines were found in the duodenum, and the lowest in the liver of untreated rats. When compared to the antrum, the concentration of free dopamine was higher, and that of norepinephrine lower in the fundus. As far as conjugated catecholamines are concerned, the tissue concentrations of both sulfo- and glucurono-conjugates were usually low, and often non detectable, with an exception: the concentration of glucurono-conjugated dopamine was very high in the duodenum, ileum, and liver of untreated rats.     

Profiling of 19-norandrosterone sulfate and glucuronide in human urine: Implications in athlete's drug testing

19-Norandrosterone (19-NA) as its glucuronide derivative is the target metabolite in anti-doping testing to reveal an abuse of nandrolone or nandrolone prohormone. To provide further evidence of a doping with these steroids, the sulfoconjugate form of 19-norandrosterone in human urine might be monitored as well. In the present study, the profiling of sulfate and glucuronide derivatives of 19-norandrosterone together with 19-noretiocholanolone (19-NE) were assessed in the spot urines of 8 male subjects, collected after administration of 19-nor-4-androstenedione (100 mg). An LC/MS/MS assay was employed for the direct quantification of sulfoconjugates, whereas a standard GC/MS method was applied for the assessment of glucuroconjugates in urine specimens. Although the 19-NA glucuronide derivative was always the most prominent at the excretion peak, inter-individual variability of the excretion patterns was observed for both conjugate forms of 19-NA and 19-NE. The ratio between the glucuro- and sulfoconjugate derivatives of 19-NA and 19-NE could not discriminate the endogenous versus the exogenous origin of the parent compound. However, after ingestion of 100 mg 19-nor-4-androstenedione, it was observed in the urine specimens that the sulfate conjugates of 19-NA was detectable over a longer period of time with respect to the other metabolites. These findings indicate that more interest shall be given to this type of conjugation to deter a potential doping with norsteroids.     

The effect of catecholamines and prostaglandins upon human and rat erythrocytes.

Both human and rat erythrocytes respond to low doses (10(-11)--10(-9) M) of L-isoproterenol and L-epinephrine with an increased degree of hypotonic hemolysis and a decreased rate of filtration through standardized paper filters. The receptors in both cell types have many of the characteristics of beta-receptors for catecholamines. However, hormone-receptor interaction in the human cell does not lead to an increase in intracellular cyclic AMP concentration, but in the rat cell, hormone-receptor interaction does lead to a significant increase in cyclic AMP content. Thus, catecholamine-beta-receptor interaction, at least in the human red cell, leads to a change in red cell properties which are not mediated by adenylate cyclase activation. Likewise, prostaglandin E2, at 10(-12)--10(-10) M, causes are increased degree of hypotonic hemolysis and a decreased rate of filtration through standardized paper filters, but it also does not increase the cycliC AMP content of the human erythrocyte but does increase that of the rat erythrocyte. Nevertheless, exogenous cyclic AMP, when added at a concentration of 10(-8) M to washed human erythrocytes, increases the degree of hypotonic hemolysis. Conversely, prostaglandin E1, at 10(-12)--10(-10) M, causes a decreased degree of hypotonic hemolysis and an increased rate of filtration through a standard filter. Both prostaglandin E2 and the catecholamines decrease the size of a rapidly exchangeable calcium pool, and prostaglandin E1 increases it.     

The effect of catecholamines and adenosine deaminase on the glucose transport system in rat adipocytes

2-Deoxyglucose uptake (3 min) and 3-O-methylglucose transport (2 s) was measured in rat adipocytes preincubated with 5 microM epinephrine plus adenosine deaminase as described by Green (Green, A. (1983) FEBS Lett. 152, 261-264). 2-Deoxyglucose uptake was about 95% depressed in insulin-treated, but not in 'basal', cells preincubated with epinephrine plus adenosine deaminase for 60 min in broad agreement with Green's report. However, this depression was caused by a decrease in sugar phosphorylation rather than transport. In similarly incubated cells, transport of 3-O-methylglucose, a sugar analogue not phosphorylated in the adipocytes, was not affected by catecholamine plus adenosine deaminase. However, a decrease in transport of about 60% was observed both in the absence and the presence of insulin when the albumin concentration was high enough and the cell concentration low enough to prevent accumulation of free fatty acids in the medium. In addition, the insulin sensitivity with regard to hexose transport was markedly reduced. Transport was approximately doubled in cells incubated with 5 microM epinephrine in the absence of adenosine deaminase. Thus, epinephrine at a high concentration stimulates hexose transport in the absence of adenosine deaminase (presence of adenosine) whereas it inhibits both basal and insulin-stimulated transport in the presence of adenosine deaminase (absence of adenosine).