Elucidation of (-)-epicatechin metabolites after ingestion of chocolate by healthy humans

After absorption in the gastrointestinal tract, (-)-epicatechin is extensively transformed into various conjugated metabolites. These metabolites, chemically different from the aglycone forms found in foods, are the compounds that reach the circulatory system and the target organs. Therefore, it is imperative to identify and quantify these circulating metabolites to investigate their roles in the biological effects associated with (-)-epicatechin intake. Using authentic synthetic standards of (-)-epicatechin sulfates, glucuronides, and O-methyl sulfates, a novel LC-MS/MS-MRM analytical methodology to quantify (-)-epicatechin metabolites in biological matrices was developed and validated. The optimized method was subsequently applied to the analysis of plasma and urine metabolites after consumption of dark chocolate, an (-)-epicatechin-rich food, by humans. (-)-Epicatechin-3'-β-d-glucuronide (C(max) 290±49nM), (-)-epicatechin 3'-sulfate (C(max) 233±60nM), and 3'-O-methyl epicatechin sulfates substituted in the 4', 5, and 7 positions were the most relevant (-)-epicatechin metabolites in plasma. When plasmatic metabolites were divided into their substituent groups, it was revealed that (-)-epicatechin glucuronides, sulfates, and O-methyl sulfates represented 33±4, 28±5, and 33±4% of total metabolites (AUC(0-24)(h)), respectively, after dark chocolate consumption. Similar metabolites were found in urine samples collected over 24h. The total urine excretion of (-)-epicatechin was 20±2% of the amount ingested. In conclusion, we describe the entire metabolite profile and its degree of elimination after administration of (-)-epicatechin-containing food. These results will help us understand more precisely the mechanisms and the main metabolites involved in the beneficial physiological effects of flavanols.     

The differential tissue distribution of the citrus flavanone naringenin following gastric instillation

Citrus flavonoids have been investigated for their biological activity, with both anti-inflammatory and -carcinogenic effects being reported. However, little information is known on the bioavailability of these compounds in vivo. The objectives of this study were to determine the tissue distribution of naringenin after gastric gavage of [³H]-naringenin to rats. Unlabelled naringenin was also used to quantify the levels of naringenin and its major metabolites in tissues and eliminated in the urine and faeces. Significant radioactivity was detected in the plasma as well as all tissues examined 2 h post-gavage. After 18 h, higher levels of radioactivity were retained in plasma and tissues (55% of the administered radioactivity). Investigation of the nature of metabolites, using unlabelled naringenin, revealed that the glucuronides were the major components in plasma, tissues and urine, in addition to the colonic metabolite 3-(4-hydroxyphenyl) propionic acid, detected in the urine. The aglycone was the form extensively retained in tissues after 18 h post-gavage. Total identified metabolites detected after 18 h in most tissues were only 1-5% of the levels detected after 2 h. However, the brain, lungs and heart retained 27, 20 and 11%, respectively, relative to the total metabolites detected at 2 h. While radioactive detection suggests increased levels of breakdown products of naringenin after 18 h versus 2 h, the products identified using unlabelled naringenin are not consistent with this, suggesting that a predominant proportion of the naringenin breakdown products at 18 h are retained as smaller decomposition molecules which cannot yet be identified.     

The Differential Tissue Distribution of the Citrus Flavanone Naringenin Following Gastric Instillation

Citrus flavonoids have been investigated for their biological activity, with both anti-inflammatory and -carcinogenic effects being reported. However, little information is known on the bioavailability of these compounds in vivo. The objectives of this study were to determine the tissue distribution of naringenin after gastric gavage of [³H]-naringenin to rats. Unlabelled naringenin was also used to quantify the levels of naringenin and its major metabolites in tissues and eliminated in the urine and faeces. Significant radioactivity was detected in the plasma as well as all tissues examined 2?h post-gavage. After 18?h, higher levels of radioactivity were retained in plasma and tissues (55% of the administered radioactivity). Investigation of the nature of metabolites, using unlabelled naringenin, revealed that the glucuronides were the major components in plasma, tissues and urine, in addition to the colonic metabolite 3-(4-hydroxyphenyl) propionic acid, detected in the urine. The aglycone was the form extensively retained in tissues after 18?h post-gavage. Total identified metabolites detected after 18?h in most tissues were only 1–5% of the levels detected after 2?h. However, the brain, lungs and heart retained 27, 20 and 11%, respectively, relative to the total metabolites detected at 2?h. While radioactive detection suggests increased levels of breakdown products of naringenin after 18?h versus 2?h, the products identified using unlabelled naringenin are not consistent with this, suggesting that a predominant proportion of the naringenin breakdown products at 18?h are retained as smaller decomposition molecules which cannot yet be identified.     

Metabolism of osaterone acetate in dogs and humans

Osaterone acetate (17 alpha-acetoxy-6-chloro-2-oxa-4,6-pregnadiene-3,20-dione; OA) is a steroidal antiandrogen. In order to clarify the species differences, metabolites of OA were examined in plasma, urine, and feces of dogs and humans after oral administration of OA. Eleven metabolites in plasma, urine, and feces were identified by their spectral properties and comparison to appropriate standards. The primary routes of OA metabolism involve 11 beta-, 15 beta- and 21-hydroxylation, 17 alpha-deacetylation, and dechlorination. Other metabolites arise from combinations of these pathways to form multiple oxidized metabolites. All metabolites observed in humans occurred in dogs. 11 beta-Hydroxylated metabolites (11 beta-OH OA and 11-oxo OA) were found in the plasma and urine of dogs, but there was no evidence of their presence in humans. 11 beta-Hydroxylation of exogenous steroids represents a distinctive biotransformation pathway.     

Orally administered rosmarinic acid is present as the conjugated and/or methylated forms in plasma, and is degraded and metabolized to conjugated forms of caffeic acid, ferulic acid and m-coumaric acid

Rosmarinic acid (RA) is contained in various Lamiaceae herbs used commonly as culinary herbs. Although RA has various potent physiological actions, little is known on its bioavailability. We therefore investigated the absorption and metabolism of orally administered RA in rats. After being deprived of food for 12 h, RA (50 mg/kg body weight) or deionized water was administered orally to rats. Blood samples were collected from a cannula inserted in the femoral artery before and at designated time intervals after administration of RA. Urine excreted within 0 to 8 h and 8 to 18 h post-administration was also collected. RA and its related metabolites in plasma and urine were measured by LC-MS after treatment with sulfatase and/or beta-glucuronidase. RA, mono-methylated RA (methyl-RA) and m-coumaric acid (COA) were detected in plasma, with peak concentrations being reached at 0.5, 1 and 8 h after RA administration, respectively. RA, methyl-RA, caffeic acid (CAA), ferulic acid (FA) and COA were detected in urine after RA administration. These components in plasma and urine were present predominantly as conjugated forms such as glucuronide or sulfate. The percentage of the original oral dose of RA excreted in the urine within 18 h of administration as free and conjugated forms was 0.44 +/- 0.21% for RA, 1.60 +/- 0.74% for methyl-RA, 1.06 +/- 0.35% for CAA, 1.70 +/- 0.45% for FA and 0.67 +/- 0.29% for COA. Approximately 83% of the total amount of these metabolites was excreted in the period 8 to 18 h after RA administration. These results suggest that RA was absorbed and metabolized as conjugated and/or methylated forms, and that the majority of RA absorbed was degraded into conjugated and/or methylated forms of CAA, FA and COA before being excreted gradually in the urine.     

Xanthoangelols isolated from Angelica keiskei inhibit inflammatory-induced plasminogen activator inhibitor 1 (PAI-1) production

The folk medicine Angelica keiskei (Ashitaba) exhibits antitumor, antioxidant and antidiabetic activities and it has recently attracted attention as a health food. Ashitaba is thought to have antithrombotic properties, but this has not yet been scientifically proven. The elevation of plasma plasminogen activator inhibitor 1 (PAI-1), an inhibitor of fibrinolysis results in a predisposition to the risk of thrombosis. The present study showed that Ashitaba exudates injected intraperitoneally and orally administered over long-term suppressed the lipopolysaccharide (LPS) induced PAI-1 increase in mouse plasma. We also found that xanthoangelol, xanthoangelols B and D, the components of Ashitaba exudates, significantly inhibited TNFα-induced PAI-1 production from human umbilical vein endothelial cells (HUVECs). These findings suggest that Ashitaba can decrease elevated PAI-1 production, and that daily consumption of Ashitaba product might maintain anticoagulant status by inhibiting elevations in PAI-1 under inflammatory conditions.     

新型乙酰胆碱酯酶抑制剂Bis(9)-(-)-Meptazinol的小鼠 和大鼠药代动力学研究

目的:研究新型乙酰胆碱酯酶(acetylcholinesterase,AChE)抑制剂Bis(9)-(-)-Meptazinol(B9M)在小鼠和大鼠体内的药代动力学、组织分布和排泄过程。方法:应用本课题组前期报道的大鼠血浆中B9M的LC-MS/MS定量方法:检测B9M皮下和静脉给药后小鼠血浆和脑组织中的含量,计算相应的药代动力学参数,测定B9M小鼠(1.5 mg/kg)和大鼠(1.0 mg/kg)皮下给药后不同时间点的组织分布和粪便、尿液中排泄量。结果:小鼠经皮下注射后,B9M可迅速进入血液(Tmax=0.25 h)血液中消除速度较慢(T_(1/2)=18.09h)绝对生物利用度为115.95%。皮下注射后,B9M在脑内的达峰时间和半衰期分别是8h和18.75h,生物利用度为44.67%。小鼠和大鼠皮下给药后广泛分布于各组织,以脾、肺、肾等血流量大的组织中分布最多。B9M从体内排泄迅速原型药物在小鼠和大鼠尿液和粪便中的排泄量低于3%。结论:皮下给药B9M在小鼠和大鼠体内具有易吸收、分布广泛、易排泄的特点药代动力学特征优良,是极具研发潜力的抗阿尔茨海默病(Alzheimer's disease,AD)新药。     

Cytotoxic activities and anti-tumor-promoting effects of microbial transformation products of prenylated chalcones from Angelica keiskei

Three prenylated chalcones, 4-hydroxyderricin (1), xanthoangelol (2), and xanthoangelol F (3), isolated from Angelica keiskei, were transformed by the fungus Aspergillus saitoi. These chalcones were converted to flavanones (i.e., 4, 8, and 12), and prenyl-chain-hydrated (i.e., 5, 7, 9-11, and 13) and ring-B-hydroxylated (i.e., 6) chalcones. The structures of three new metabolites, 7, 9, and 13, were established as 2″,3″-dihydro-4,3″-dihydroxyderricin, 6″,7″-dihydro-7″-hydroxyxanthoangelol, and 6″,7″-dihydro-7″-hydroxyxanthoangelol F, respectively. Upon evaluation of cytotoxic activities of compounds 1-13, the metabolite 7 exhibited potent cytotoxicity against HL60 cells, and this cell death was revealed to be mostly due to apoptosis. In addition, compounds 1-4, 7-10, 12, and 13 were examined for their inhibitory effects on the induction of Epstein-Barr virus early antigen (EBV-EA) by 12-O-tetradecanoylphorbol-13-acetate (TPA) in Raji cells. All compounds tested showed inhibitory effects against EBV-EA activation with potencies higher than that of β-carotene. Furthermore, the metabolite 13 exhibited inhibitory effect on skin tumor promotion in an in vivo two-stage mouse skin carcinogenesis test based on 7,12-dimethylbenz[a]anthracene (DMBA) as initiator, and with TPA as promoter.     

Urinary excretion of hydroxycinnamates and flavonoids after oral and intravenous administration.

The urinary recoveries of the hydroxycinnamates, ferulic acid (3-methoxy, 4-hydroxy cinnamic acid), and chlorogenic acid (the quinic acid ester of 3,4-dihydroxycinnamic acid), and three structurally related flavonoids were studied in the rat. For the latter, the aglycone quercetin was compared with its 3-glucoside (isoquercitrin) and 3-rhamnoglucoside (rutin). Doses of 50 mg/kg were administered via the oral and intravenous routes and urine collected over the subsequent 24-h period. Reverse phase HPLC with photo-diode array detection was used to analyze the unchanged compound and their metabolites excreted in the urine. Ferulic acid and isoquercitrin were orally absorbed (5.4 and 0.48% of administered dose, respectively) and are therefore bioavailable. In contrast, neither unchanged chlorogenic acid, rutin, quercetin, nor the conjugated metabolites in the form of glucuronide or sulphate were detected in the urine after oral dosing. All the flavonoids studied produced low total urinary recoveries after intravenous administration, 9.2% for quercetin-3-rhamnoglucoside, 6.7% for the 3-glucoside, and 2.4% for the aglycone, indicating that extensive metabolism to low molecular weight compounds or excretion via other routes may be occurring. Overall it can be stated that renal excretion is not a major pathway of elimination for intact flavonoids and hydroxycinnamates in the rat.     

Metabolism of echitamine and plumbagin in rats

When administered to rats, echitamine was absorbed rapidly from the tissues and was detected in circulation within 30 min. The drug level reached a maximum value by 2 h and then decreased steadily. The drug had completely disappeared from the blood in 6 h. The presence of echitamine was observed within 2 h in urine and the maximum amount of drug was excreted between 2 and 4 h. About 90% of the drug was excreted in urine in 24 h and the drug could not be detected in urine after 48 h. Along with echitamine, its metabolites were also detected in the urine. Plumbagin was not detected in blood upto 24 h when administered into rats. The drug was detected in urine within 4 h after administration; a major portion of the drug was excreted in urine by 24 h and traces of the drug were observed in the urine even after 48 h.     

New insights into the bioavailability of red raspberry anthocyanins and ellagitannins

Red raspberries, containing ellagitannins and cyanidin-based anthocyanins, were fed to volunteers and metabolites appearing in plasma and urine were analysed by UHPLC-MS. Anthocyanins were not absorbed to any extent with sub nmol/L concentrations of cyanidin-3-O-glucoside and a cyanidin-O-glucuronide appearing transiently in plasma. Anthocyanins excreted in urine corresponded to 0.007% of intake. More substantial amounts of phase II metabolites of ferulic acid and isoferulic acid, along with 4′-hydroxyhippuric acid, potentially originating from pH-mediated degradation of cyanidin in the proximal gastrointestinal tract, appeared in urine and also plasma where peak concentrations were attained 1–1.5 h after raspberry intake. Excretion of 18 anthocyanin-derived metabolites corresponded to 15.0% of intake, a figure substantially higher than obtained in other anthocyanin feeding studies. Ellagitannins pass from the small to the large intestine where the colonic microbiota mediate their conversion to urolithins A and B which appeared in plasma and were excreted almost exclusively as sulfate and glucuronide metabolites. The urolithin metabolites persisted in the circulatory system and were excreted in urine for much longer periods of time than the anthocyanin metabolites although their overall urinary recovery was lower at 7.0% of intake. It is events originating in the proximal and distal gastrointestinal tract, and subsequent phase II metabolism, that play an important role in the bioavailability of both anthocyanins and ellagitannins and it is their metabolites which appear in the circulatory system, that are key to elucidating the mode of action(s) underlying the protective effects of these compounds on human health.     

Oral absorption and excretion of icaritin, an aglycone and also active metabolite of prenylflavonoids from the Chinese medicine Herba Epimedii in rats

Icaritin (ICT) is a main aglycone and also active intestinal metabolite of prenylflavonoids from the Chinese medicine Herba Epimedii. In the present study, the oral absorption and excretion of this compound was investigated using rats for exploring its fate in the body, so as to better understanding its in vivo pharmacological activities. The free (parent) and total (parent plus conjugated metabolites) ICT concentrations in rat plasma, urine and bile, after intravenous (i.v.) and oral administration both at 5mg/kg, were determined before and after enzymatic hydrolysis with β-glucuronidase/sulphatase, respectively, by a HPLC-UV method. The results showed that free ICT plasma concentration after i.v. dose was rapidly decreased with average t(1/2, λ) of 0.43h, while the total ICT concentration was decreased slowly with t(1/2, λ) of 6.86h. The area under the curve of ICT conjugated metabolites was about 11-fold higher than that of free ICT. The majority of ICT in the body was excreted from the bile with 68.05% of dose over 8h after i.v. dosing, in which only 0.15% was in parent form. While very little amount of ICT was excreted from the urine with 3.01% of dose over 24h, in which the parent form was 0.62%. After oral administration, very little amount of parent ICT was detected only in 0.5, 1 or 2h plasma samples with the concentration less than LOQ, however, its total plasma concentration after enzymatic hydrolysis treatment was at relative high level with average maximum concentration of 0.49μg/ml achieved at 1h post dose. The oral bioavailability of ICT was 35% of dose, estimated by its total plasma drug concentrations. It is concluded that ICT can be easily absorbed into the body, and then rapidly conversed to its conjugated metabolites, and finally removed from the body mainly by biliary excretion.     

Comparative Excretion and Tissue Distribution of Selenium in Mice and Rats Following Treatment with Diphenyl Diselenide

The purpose of this study was to provide data about in vivo tissue distribution and excretion of diphenyl diselenide ((PhSe)₂) in rats and mice through determination of selenium levels in different biological samples. (PhSe)₂ (500?mg/kg, dissolved in canola oil) was administered to animals once a day per oral. After this, mice and rats were housed in metabolic cages (one animal per cage) and urine and feces were collected at specific times after treatment. Three to five animals per group (for each time-point) were anesthetized and blood samples were collected at 0 and 30?min, 24?h, at day 5, 15, and 30 after (PhSe)₂ administration. The plasma and red blood cells were separated. Brain, liver, lungs, kidneys, and adipose tissue were also collected. The determination of selenium levels was performed by inductively coupled plasma atomic emission spectrometry. The main results indicate that: (1) urine is an important route of excretion of selenium originated from (PhSe)₂ in mice and rats; (2) a large amount of (PhSe)₂ or some of its metabolites are stored in fat; (3) the content of selenium found in plasma was low; and (4) liver and kidneys are the tissues with high amounts of selenium.     

Disposition and metabolism of 16 beta-ethyl-17 beta-hydroxy-4-estern-3-one (TSAA-291), a new antiandrogen, in rats.

Matabolic fate of a new antiandrogen, 16 beta-ethyl-17 beta-hydroxy-4-estren-3-one (TSAA-291), was studied in rats. 14C-TSAA-291 intramuscularly injected as an aqueous suspension was absorbed gradually to give an increase in the plasma level which attained a plateau at 0.5 h, persisted till 8 h and then declined with an approx. half-life of 3.6 days. The drug was widely distributed in tissues, with the concns. almost equal to or higher than that in the plasma. The 14C-drug was eliminated mostly as metabolites within 10 days after dosing with higher activities found in the feces than in urine. Biliary 14C effectively underwent enterohepatic cycling. Biliary metabolites of TSAA-291 were characterized by the combined use of deuterium labeling and GLC-MS analysis. The metabolites identified were as follows: the parent drug, monohydroxy TSAA-291 having the additional hydroxy function in the steroid skeleton, 17 beta-hydroxy-16 beta-(1 xi-hydroxyethyl)-4-estren-3-one, 16 beta-ethyl-17 beta-hydroxy-5 beta-estran-3-one, 16 beta-ethyl-17 beta-hydroxy-5 alpha-estran-3-one, 16 beta-ethyl-5 beta-estrane-3 alpha, 17 beta-diol, 16 beta-ethyl-5 alpha-estrane-3 alpha, 17 beta-diol, 16 beta-ethyl-3 alpha-hydroxy-5 beta-estran-17-one and 16 beta-ethyl-3 alpha-hydroxy-5 alpha-estran-17-one. Monoketodihydroxy and/or trihydroxy metabolites were also detected in the bile.     

Six new chalcones from Angelica keiskei inducing adiponectin production in 3T3-L1 adipocytes

Angelica keiskei (Ashitaba in Japanese), a traditional herb in Japan, contains abundant prenylated chalcones. It has been reported that the chalcones from A. keiskei showed such bioactivities as anti-bacterial, anti-cancer and anti-diabetic effects. Xanthoangelol, 4-hydroxyderricin and six new chalcones were isolated in this study from an ethanol extract of A. keiskei by octadecyl silyl (ODS) and silica gel chromatography, and identified by 1D- and 2D-nuclear magnetic resonance (NMR) and high-resolution mass spectrometric analyses. The chalcones from A. keiskei markedly increased the expression of the adiponectin gene and the production of adiponectin in 3T3-L1 adipocytes. These results suggest that the chalcones from A. keiskei might be useful for preventing the metabolic syndrome.     

Rapid methods to determine procyanidins, anthocyanins, theobromine and caffeine in rat tissues by liquid chromatography-tandem mass spectrometry

Rapid, selective and sensitive methods were developed and validated to determine procyanidins, anthocyanins and alkaloids in different biological tissues, such as liver, brain, the aorta vein and adipose tissue. For this purpose, standards of procyanidins (catechin, epicatechin, and dimer B(2)), anthocyanins (cyanidin-3-glucoside and malvidin-3-glucoside) and alkaloids (theobromine, caffeine and theophylline) were used. The methods included the extraction of homogenized tissues by off-line liquid-solid extraction, and then solid-phase extraction to analyze alkaloids, or microelution solid-phase extraction plate for the analysis of procyanidins and anthocyanins. The eluted extracts were then analyzed by ultra-performance liquid chromatography-electrospray ionization-tandem mass spectrometry, using a triple quadrupole as the analyzer. The optimum extraction solution was water/methanol/phosphoric acid 4% (94/4.5/1.5, v/v/v). The extraction recoveries were higher than 81% for all the studied compounds in all the tissues, except the anthocyanins, which were between 50 and 65% in the liver and brain. In order to show the applicability of the developed methods, different rat tissues were analyzed to determine the procyanidins, anthocyanins and alkaloids and their generated metabolites. The rats had previously consumed 1g of a grape pomace extract (to analyze procyanidins and anthocyanins) or a cocoa extract (to analyze alkaloids) per kilogram of body weight. Different tissues were extracted 4h after administration of the respective extracts. The analysis of the metabolites revealed a hepatic metabolism of procyanidins. The liver was the tissue which produced a greater accumulation of these metabolites.     

Stereospecificity of flobufen metabolism in guinea pigs in vitro and in vivo: phase I of biotransformation

Flobufen (F) is an original nonsteroidal antiinflammatory drug that exists in two enantiomeric forms. Its biotransformation was investigated in male guinea pigs because of the similarities shown in a preliminary F metabolic study between guinea pig and man. Stereospecificity of the respective enzymes was studied in vitro, using microsomes and cytosol, and in vivo, in urine and feces. Rac-F, R-F, and S-F served as substrates. The amount of 4-dihydroflobufen stereoisomers (DHF) and other metabolites (M-17203 and UM-2) was determined by chiral HPLC using an R,R-ULMO column. It was observed that F reductases were distributed differently in microsomes and cytosol. The microsomal fraction showed higher activity and different stereospecificity in rac-F, R-F, and S-F reduction compared to cytosol. (2R;4S)-DHF was the principle metabolite in microsomes and (2S;4S)-DHF was the principle metabolite in cytosol. In vivo experiments revealed the excretion of a main metabolite UM-2 in addition to other metabolites M-17203 and DHF stereoisomers. UM-2 was predominantly excreted after S-F administration. Stereoselectivity of DHF stereoisomers excretion was different in urine and in feces. The absence of UM-2 and M-17203 in microsomes and cytosol and their presence in urine and feces showed that both could arise in some other extrahepatic tissue or cell compartment or that their formation depends on liver cell integrity.     

Metabolism of Hymexazol, 3-Hydroxy-5-methylisoxazole,in the Rats

Excretion, distribution and metabolism of the fungicide, hymexazol, (3-hydroxy-5-methylisoxazole), labeled with carbon-14 were examined after administration of a single oral dose to Wistar-strain rats. Hymexazol was rapidly absorbed and distributed in the tissues. During 96 hr, 97% of the total radioactivity was excreted in the urine and 0.89% in the feces, and 0.86% was found in the expired gasses for 24 hr. Two metabolites were detected in the urine, whose chemical structures were determined as 3-(β-d-glucopyranuronosyloxy)-5- methylisoxazole and 5-methyl-3-isoxazolyl sulfate.     

L-Carnitine dissimilation in the gastrointestinal tract of the rat

Results of previous studies in this laboratory and others have suggested that L-carnitine is degraded in the gastrointestinal tract of the rat, perhaps by the action of indigenous flora. L-[methyl-14C]Carnitine was administered to rats either orally or intravenously in doses of 86 nmol or 124 mumol, and expired air, 48-h urine and fecal collections, and selected tissues at 48 h after isotope administration were examined for radiolabeled carnitine and metabolites. Urine and feces of rats receiving oral L-[methyl-14C]carnitine consistently contained two radiolabeled metabolites which were identified as trimethylamine N-oxide (primarily in urine) and gamma-butyrobetaine (primarily in feces). In these rats, these metabolites accounted for up to 23% and 31% of the administered dose, respectively. By contrast, for rats receiving intravenous L-[methyl-14C]carnitine or germ-free rats receiving the isotope orally or intravenously, virtually all of the radioactivity recovered was in the form of carnitine. Analyses for 14CO2 and [14C]trimethylamine in expired air revealed little or no (less than 0.1% of dose) conversion to these compounds, regardless of size of dose or route of administration. Results of this study demonstrate conclusively that L-carnitine is degraded in the gastrointestinal tract of the rat and that indigenous flora are responsible for these transformations.     

Single and multiple dose pharmacokinetics of maritime pine bark extract (Pycnogenol) after oral administration to healthy volunteers

Background

Since plant extracts are increasingly used as phytotherapeutics or dietary supplements information on bioavailability, bioefficacy and safety are warranted. We elucidated the plasma kinetics of genuine extract components and metabolites after single and multiple ingestion of the standardized maritime pine bark extract Pycnogenol (USP quality) by human volunteers.

Methods

Eleven volunteers received a single dose of 300 mg pine bark extract, five volunteers ingested 200 mg daily for five days to reach steady state concentrations. Plasma samples were obtained before and at defined time points after intake of the extract. Samples were analyzed by HPLC with ion-pair reagents and simultaneous UV and electrochemical detection.

Results

We quantified total plasma concentrations of catechin, caffeic acid, ferulic acid, taxifolin and the metabolite M1 (δ-(3,4-dihydroxy-phenyl)-γ-valerolactone). Additionally, we describe plasma time courses and steady state appearance of ten so far unknown compounds, U1 to U10. After single ingestion, compounds derived from the extract were rapidly absorbed and the majority of them were detectable over whole experimental period of 14 h. The analysis of steady state plasma samples revealed significant phase II metabolism.

Conclusion

We present the first systematic pharmacokinetic analysis of compounds derived from maritime pine bark extract. Beyond the known constituents and metabolites we uncovered the plasma time courses of ten unknown compounds. In concert with our previous detection of anti-inflammatory bioefficacy of these plasma samples ex vivo we suggest that constituents and metabolites of Pycnogenol bear potential for disclosure of novel active principles.