Pharmacokinetic characteristics of hydroxysafflor yellow A in normal and diabetic cardiomyopathy mice.

Hydroxysafflor yellow A (HSYA), a major active water-soluble component in Carthamus tinctorius L., is considered a potential antioxidant with protective effects against myocardial injury. However, its pharmacokinetic characteristics in normal and diabetic cardiomyopathy (DCM) mice remain unknown. This study was designed to investigate the differences in the pharmacokinetics of HSYA between normal and streptozotocin-induced DCM mice. HSYA in the mouse plasma was quantified using LC-MS/MS. Compared with the normal group, the DCM group showed a significantly higher area under the curve (AUC(0-t) , AUC(0-∞) ) value and peak plasma concentration, suggesting a higher uptake of HSYA in the DCM mice, and a significantly lower plasma clearance and apparent volume of distribution, suggesting slower elimination of HSYA in the DCM mice. The levels of serum superoxide dismutase and glutathione peroxidase were significantly higher, and malondialdehyde content was significantly lower in DCM mice than in normal mice, indicating the antioxidative stress effect of HSYA. Furthermore, the correlation analysis revealed that the serum HSYA content in the DCM mice significantly positively correlated with antioxidant enzyme levels. These results showed that the pharmacokinetics of HSYA changed significantly in the DCM mice, and this may improve the antioxidative stress effect of the drug.

Plasma and cerebrospinal fluid pharmacokinetics of hydroxysafflor yellow A in patients with traumatic brain injury after intravenous administration of Xuebijing using LC-MS/MS method.

Hydroxysafflor yellow A (HSYA) is the most pharmaceutically relevant compound in Xuebijing (XBJ) for traumatic brain injury (TBI) treatment. We aimed to investigate biofluids pharmacokinetics of HSYA from XBJ to ensure the drug safety and to guide the clinical use.A sensitive, rapid and reliable liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was applied to investigate pharmacokinetics of HSYA in TBI patients after intravenous administration of XBJ. Non-compartmental methods using DAS 3.0 software were applied to analyse the pharmacokinetic parameters.A similar half-life (Plasmat1/2: 14.55 ± 3.51 h vs. CSFt1/2: 15.73 ± 3.63) was observed. HSYA reached the peak level rapidly, but exhibited a strongly slow absorption phase from blood to cerebrospinal fluid (CSF, PlasmaTmax: 0.69 ± 0.26 h vs. CSFTmax: 4.0 ± 2.62 h). HSYA exhibited much higher Cmax (PlasmaCmax: 9342.76 ± 2489.23 µg/L vs. CSFCmax: 98.08 ± 14.51 µg/L) and AUC0-t (PlasmaAUC0-t: 57490.5 ± 5560.3 µg h/L vs. CSFAUC0-t: 1851.6 ± 269.1 µg h/L), yet a shorter CL (PlasmaCL: 0.02 ± 0.002 L/h/kg vs. CSFCL: 0.55 ± 0.01 L/h/kg) in plasma than in CSF. The AUCCSF/AUCplasma of HSYA was almost 3.37%.In summary, the results demonstrate that part of HSYA come across blood-brain barrier after XBJ administration. This study provides evidence for better understanding the pharmacokinetics and potential for clinical guidance of XBJ for TBI treatment.

Comparative pharmacokinetics of nine major bioactive components in normal and ulcerative colitis rats after oral administration of Lizhong decoction extracts by UPLC-TQ-MS/MS.

Lizhong decoction (LZD), a classic formula, has been used to treat ulcerative colitis (UC) for thousands of years in clinical practice. However, the pharmacokinetic characteristics of its major bioactive components in rats under different physiological and pathological states are not clear. Thus, in this study, a rapid and sensitive analytical method, ultra-performance liquid chromatography coupled with mass spectrometry (UPLC-MS/MS) method, was developed and applied to simultaneously determine glycyrrhizic acid, liquiritin, isoliquiritin, glycyrrhizin, isoliquiritigenin, 6-gingerol, ginsenoside Rg1, ginsenoside Rb1 and ginsenoside Re in normal and UC rats after oral administration of LZD extract. A Waters BEH C18 UPLC column was used for chromatographic separation, while acetonitrile and 0.1% formic acid were selected as mobile phase. The linearity of nine analytes was >0.9920. Inter- and intra-day accuracy was ≤ 11.4% and precision was from 1.1 to 12.7%. Additionally, stable and suitable extraction recoveries were also obtained. The established method was validated and found to be specific, accurate and precise for nine analytes. Furthermore, it was successfully applied to the pharmacokinetic investigation of nine major components after oral administration of LZD extracts to normal and model rats, respectively. The results showed that the pharmacokinetic parameters (Cmax , Tmax , AUC0-t , AUC0-∞ ) in the plasma of UC rats were significantly different from those of normal rats, which could provide a reference for the clinical application of LZD.

Pharmacokinetic Study on Protocatechuic Aldehyde and Hydroxysafflor Yellow A of Danhong Injection in Rats with Hyperlipidemia.

BACKGROUND: Protocatechuic aldehyde (PAL) and hydroxysafflor yellow A (HSYA) are 2 effective ingredients of Danhong Injection, which is extensively used for the clinical treatment of cardio-cerebrovascular diseases. This study aims to investigate the pharmacokinetic differences between single and combined medication of PAL and HSYA and analyze the interaction of the above effective components in hyperlipidemia rats. METHODS: Thirty male SD rats were randomly divided into the control group (n = 6) and the model group (n = 24). The hyperlipidemia model was established by feeding with superfatted forage. The successful model rats were then randomly divided into the PAL group (16 mg/kg), the HSYA group (10 mg/kg), and the combination group (16 mg/kg + 10 mg/kg). Administration through tail-vein, and orbital blood was sampled at different time points. The mass concentration of PAL and HSYA was determined by high performance liquid chromatography (HPLC-DAD). Analysis of pharmacokinetic parameters was conducted by using DAS 3.2.6 software and SPSS 19.0 statistical analysis software. RESULTS: According to the parameters of statistical moment of non-compartmental model, there was a significant difference in plasma clearance (CL) between the PAL group and the drug combination group (p < 0.01), as well as in the area under the first moment of the plasma concentration-time curve and the elimination half-life (t1/2) between the HSYA group and the drug combination group (p < 0.01) but no obvious differences about the blood concentration time curve area, the average dwell time (MRT), and the peak concentration (Cmax; p > 0.05). CONCLUSION: The combined medication of PAL and HSYA could increase the plasma CL significantly and have a great influence on the absorption of HSYA in rats with hyperlipidemia.

The application of HPLC-MS/MS to studies of pharmacokinetics and interconversion of isoliquiritigenin and neoisoliquiritigenin in rats.

A specific and sensitive HPLC-MS/MS method was developed and validated for the simultaneously quantification of isoliquiritigenin (ISL) and neoisoliquiritin (NIS) in rat plasma by oral administration. Analytes were analyzed on an Agilent 6460 LC-MS/MS system (Agilent, USA) using an Agilent Zorbax SB-C18 column (4.6 × 150 mm, 5 µm). Gradient elution was applied for the analyte separation using a mobile phase composed of 0.1% formic acid aqueous solution and methanol at a flow rate of 1.0 mL/min with a total running time of 12 min. The calibration curves for ISL and NIS showed good linearity in the concentrations ranging from 0.001 to 4.000 µg/mL with correlation coefficients >0.998. The precision, accuracy, recovery and stability were deemed acceptable. The method was applied to the pharmacokinetics study of ISL and NIS in rats by single and combination administration. The result showed that Cmax and AUC0→t of ISL were markedly increased from 0.53 to 1.20 µg/mL, and from 69.63 to 200.74 min µg/mL by combination administration. The mean t1/2 value was also prolonged from 64.55 to 203.74 min in the combination group. These results indicated that NIS may have been metabolized to ISL which increased the absorption and extended the elimination of ISL. However, little difference was found for NIS pharmacokinetics parameters between single NIS and the combination group, which suggested that there was no significant biotransformation of ISL to NIS. Copyright © 2015 John Wiley & Sons, Ltd.

[Studies on effects of Achyranthes bidentata on tongsaimai pellets main active ingredients chlorogenic acid, isoliquiritin, harpagoside and glycyrrhizin in vivo pharmacokinetics].

To study on the effects of Achyranthes bidentata on Tongsaimai pellets main active ingredients chlorogenic acid, isoliquiritin, harpagoside and glycyrrhizin in rats in vivo pharmacokinetic behaviors, a method for the simultaneous determination of chlorogenic acid, isoliquiritin, harpagoside and liquiritigenin in rat plasma was established by UPLC-MS/MS. The analysis was performed on a waters Acquity BEH C18 column (2.1 mm x 100 mm, 1.7 microm) with the mixture of acetonitrile and 0.1% formic acid/water as mobile phase, and the gradient elution at a flow rate of 0.3 mL x min(-1). The analytes were detected by tandem mass spectrometry with the electrospray ionization (ESI) source and in the multiple reaction monitoring (MRM) mode. It turned out that the analytes of Tongsaimai pellets groups C(max) and AUC(Q-infinity) values were higher than that with A. bidentata group, and the C(max) values of chlorogenic acid had significantly difference (P < 0.05), the AUC(0-infinity) values of chlorogenic acid and glycyrrhizin had significantly difference (P < 0.05); The T(max) and CL values of two groups had no significantly difference. Results showed that the established method was specific, rapid, accurate and sensitive for the studies of Tongsaimai pellets four main active ingredients in rat in vivo pharmacokinetic, and A. bidentata have varying degrees of effects on Tongsaimai pellets four main active ingredients in rat in vivo pharmacokinetic behaviors.

A stepwise integrated multi-system to screen quality markers of Chinese classic prescription Qingzao Jiufei decoction on the treatment of acute lung injury by combining 'network pharmacology-metabolomics-PK/PD modeling'.

BACKGROUND: Previously, we have investigated the therapeutic mechanism of Qingzao Jiufei Decoction (QZJFD), a Chinese classic prescription, on acute lung injury (ALI), however, which remained to be further clarified together with the underlying efficacy related compounds for quality markers (Q-markers). HYPOTHESIS/PURPOSE: To explore Q-markers of QZJFD on ALI by integrating a stepwise multi-system with 'network pharmacology-metabolomics- pharmacokinetic (PK)/ pharmacodynamic (PD) modeling'. METHODS: First, based on in vitro and in vivo component analysis, a network pharmacology strategy was developed to identify active components and potential action mechanism of QZJFD on ALI. Next, studies of poly-pharmacology and non-targeted metabolomics were used to elaborate efficacy and verify network pharmacology results. Then, a comparative PK study on active components in network pharmacology was developed to profile their dynamic laws in vivo under ALI, suggesting Q-marker candidates. Next, quantified analytes with marked PK variations after modeling were fitted with characteristic endogenous metabolites along drug concentration-efficacy-time curve in a PK-PD modeling to verify and select primary effective compounds. Finally, Q-markers were further chosen based on representativeness among analytes through validity analysis of PK quantitation of primary effective compounds. RESULTS: In virtue of 121 and 33 compounds identified in vitro and in vivo, respectively, 33 absorbed prototype compounds were selected to construct a ternary network of '20 components-47 targets-113 pathways' related to anti-ALI of QZJFD. Predicted mechanism (leukocytes infiltration, cytokines, endogenous metabolism) were successively verified by poly-pharmacology and metabolomics. Next, 18 measurable components were retained from 20 analytes by PK comparison under ALI. Then, 15 primary effective compounds from 18 PK markers were further selected by PK-PD analysis. Finally, 9 representative Q-markers from 15 primary effective compounds attributed to principal (chlorogenic acid), ministerial (methylophiopogonanone A, methylophiopogonanone B), adjuvant (sesamin, ursolic acid, amygdalin), conductant drugs (liquiritin apioside, liquiritigenin and isoliquiritin) in QZJFD, were recognized by substitutability and relevance of plasmatic concentration at various time points. CONCLUSION: 9 Q-markers for QZJFD on ALI were identified by a stepwise integration strategy, moreover, which was a powerful tool for screening Q-makers involved with the therapeutic action of traditional Chinese medicine (TCM) prescription and promoting the process of TCM modernization and scientification.

Validated LC-MS/MS method for simultaneous quantification of seven components of Naodesheng in rat serum after oral administration and its application to a pharmacokinetic study.

A simple, precise and reliable LC-MS/MS method was developed and validated for simultaneous quantification of vitexin, notoginsenoside R1, hydroxysafflor yellow A, ginsenoside Rd, puerarin, daidzein and senkyunolide I as components of Naodesheng (NDS) in rat serum. The Linearity ranges in rat serum were 0.045-4.5 µg/mL for vitexin, 0.0476-4.76 µg/mL for notoginsenoside R1, 0.0422-4.22 µg/mL for hydroxysafflor yellow A, 0.0426-4.26 µg/mL for ginsenoside Rd, 0.0436-4.36 µg/mL for puerarin, 0.026-2.6 µg/mL for daidzein, and 0.05-5 µg/mL for senkyunolide I, with the correlation coefficients greater than 0.99. The established method was validated in terms of intra- and inter-day precision and accuracy, recovery, matrix effect and stability. Furthermore, the method was successfully applied for pharmacokinetic study of these seven components in rat serum after oral administration of NDS.

A rapid and sensitive liquid chromatography-tandem mass spectrometry (LC-MS/MS) method for the determination of hydroxysafflor yellow A in human plasma: application to a pharmacokinetic study.

A sensitive and specific liquid chromatography-tandem mass spectrometry (LC-MS/MS) method has been developed and validated for the determination of hydroxysafflor yellow A (HSYA) in human plasma. HSYA was extracted from human plasma by using solid-phase extraction technique. Puerarin was used as the internal standard. A Shim-pack VP-ODS C(18) (150mm x 4.6mm, 5 microm) column and isocratic elution system composing of methanol and 5mM ammonium acetate (80:20, v/v) provided chromatographic separation of analytes followed by detection with mass spectrometry. The mass transition ion-pair was followed as m/z 611.19-->491.19 for HSYA and m/z 415.19-->295.10 for puerarin. The proposed method has been validated with a linear range of 1-1000 ng/ml for HSYA with a correlation coefficient >/=0.999. The lower limit of quantitation was 1 ng/ml. The intra-batch and inter-batch precision and accuracy were within 10%. The average extraction recovery was 81.7%. The total run time was 5.5 min. The validated method was successfully applied to the study on pharmacokinetics of HSYA in 12 healthy volunteers after a single oral administration of safflower oral solution containing 140 mg of HSYA.

A comprehensive in vitro and in vivo metabolism study of hydroxysafflor yellow A.

As the most important marker component in Carthamus tinctorius L., hydroxysafflor yellow A (HSYA) was widely used in the prevention and treatment of cardiovascular diseases, due to its effect of improving blood supply, suppressing oxidative stress, and protecting against ischemia/reperfusion. In this paper, both an in vitro microsomal incubation and an in vivo animal experiment were conducted, along with an LC-Q-TOF/MS instrument and a 3-step protocol, to further explore the metabolism of HSYA. As a result, a total of 10 metabolites were searched and tentatively identified in plasma, urine, and feces after intravenous administration of HSYA to male rats, although no obvious biotransformation was found in the simulated rat liver microsomal system. The metabolites detected involving both phase I and phase II metabolism including dehydration, deglycosylation, methylation, and glucuronic acid conjugation. A few of the metabolites underwent more than one-step metabolic reactions, and some have not been reported before. The study would contribute to a further understanding of the metabolism of HSYA and provide scientific evidence for its pharmacodynamic mechanism research and clinical use.

Development and validation of a sensitive and fast UPLC-MS/MS method for simultaneous determination of seven bioactive compounds in rat plasma after oral administration of Guizhi-gancao decoction.

Rapid, sensitive, selective and accurate UPLC-MS/MS method was developed and fully validated for simultaneous determination of cinnamaldehyde, cinnamic acid, 2-methoxy cinnamic acid, glycyrrhizic acid, glycyrrhetinic acid, liquiritigenin and isoliquiritin in rat plasma after oral administration of Guizhi-gancao decoction. Plasma samples were processed with a simple protein precipitation technique using acetonitrile, followed by chromatographic separation using a Thermo Hypersil GOLD C18 column. A 11.0min linear gradient elution was used at a flow rate of 0.2mL/min with a mobile phase of 0.1% acetic acid containing 0.2mM ammonium acetate in water and acetonitrile. The analytes and internal standard, schisandrin, were detected using both positive and negative ion electrospray ionization in multiple reaction monitoring mode. The developed method was validated for intra-day and inter-day accuracy and precision whose values fell in the acceptable limits. Matrix effect was found to be minimal. Recovery efficiency of all the analytes was found to be >60%. Stability results showed that the analytes were stable at all the conditions. This validated method was successfully used to study the pharmacokinetics of multiple compounds in rat plasma after oral administration of Guizhi-gancao decoction.

Determination of butein in rat serum by high performance liquid chromatography.

A simple high performance liquid chromatography (HPLC) method was developed for the determination of butein in rat serum. The method involved the deproteinization followed by injection into a Luna C8 column. Butein was eluted at 3.8 min at a flow rate of 0.2 ml/min with the mobile phase of acetonitrile-ammonium formate (10mM, pH 3.0) (35:65, v/v). The standard curve was linear (r(2)=0.995) over the concentration range of 0.1-10 microg/ml. The coefficient of variation (CV) of intra- and inter-assay ranged from 2.7 to 7.5% and 6.0 to 7.5%, respectively. The limit of quantification was 0.1 microg/ml using a serum sample of 50 microl. This method was applied to a pharmacokinetic study after intravenous injection of butein (5mg/kg) to rats.

The absorption and excretion of the peripheral vasodilator 14C-mecinarone, (14C-6809 MD) in rat, dog and man.

Oral doses of the peripheral vasodilator mecinarone (6809 MD), administered as the 14C-compound, were well absorbed from the gastrointestinal tract of rats, dogs and humans. Much of the dose was excreted in 24 by rats and dogs, but more slowly by humans. In 5 days, rats, dogs and humans excreted in the urine and faeces respectively means of 3.3 and 95.9%, 13.2 and 80.3%, and 22.0 and 60.8%. The proportions of radioactivity excreted in urine and faeces after intravenous doses were similar to those after oral doses, means of 3.1 and 85.0% respectively by rats and 16.8 and 78.3% by dogs. Radioactivity present in the faeces was probably mainly excreted in bile; rats (n = 2) excreted a mean of 52.3, 19.8 and 3.9% in bile, faeces and urine after oral doses. Plasma concentrations of radioactivity after oral doses reached a maximum at 1 h in rats (mean 126 ng equiv/ml), at 1 to 2 h in dogs (mean 784 ng equiv/ml) and at 1.5 to 2 h in humans (mean 547 ng equiv/ml. Only a small proportion of this radioactivity (10-30%) represented unchanged drug. When "normalised" for dose/bodyweight differences, those levels were in the ratio 1 : 7 : 32 (rat less than dog less than man). Areas under plasma radioactivity concentration-time curves after oral doses to rats and dogs were about 25% and 53% respectively of those after corresponding intravenous doses. Only about 20% of the radioactivity in the plasma of dogs at 2 min after an intravenous dose represented unchanged drug. These data suggest that 6890 MD was probably rapidly biotransformed in rat, dog and man.

Aspects of the metabolism of the peripheral vasodilator mecinarone (14C-6809 MD) in rat, dog and man.

The major proportion of oral doses of 14C-mecinarone was excreted in the faeces by rat, dog and man, and in all species the faecal metabolites were more polar than mecinarone and the O-desmethyl reference compounds. Rat faecal extracts contained two major components each accounting for about 30-40% of the radioactivity. Dog and human faecal extracts contained some mecinarone but also three major, more polar components, two of which corresponded to the rat metabolites. Rat bile contained three major components and dog bile two components. One of the components in both bile samples was shown to be a conjugate of O-desmethyl-mecinarone. Besides mecinarone human urine contained a component corresponding to the phenol resulting from 0-demethylation in the p-methoxycinnamoyl group. The same two compounds were also detected in human plasma. The two major components in rat and dog faecal extracts gave mass spectra identical to mecinarone and the p-hydroxycinnamoyl derivative (O-desmethyl-mecinarone). It is postulated that these thermally-labile metabolites were formed by nucleophilic addition of a substituent to the alpha, beta-unsaturated ketone. It has been demonstrated in vitro that mecinarone forms a glutathione conjugate. The metabolites may be compounds of this type where the glutathione moiety has been degraded in the gastrointestinal tract.

[Study on distribution of safflor yellow A in tissues of mice].

AIM: To study the distributive character of safflor yellow A in mice. METHODS: A RP-HPLC method for the determination of safflor yellow A in tissues was established and applied to determine safflor yellow A in biological samples. RESULTS: After iv injection of Safflor yellow A in mice, the AUC of safflor yellow A was hightest in plasma, followed by kidney, liver, lung, heart, spleen. But it was not found in the brain. CONCLUSION: The distribution of safflor yellow A in the body is abroad and the speed of its process is swift.

Mechanism of enhanced oral absorption of hydrophilic drug incorporated in hydrophobic nanoparticles.

Hydroxysafflor yellow A (HSYA) is an effective ingredient of the Chinese herb Carthamus tinctorius L, which has high water solubility and low oral bioavailability. This research aims to develop a hydrophobic nanoparticle that can enhance the oral absorption of HSYA. Transmission electron microscopy and freeze-fracture replication transmission election microscopy showed that the HSYA nanoparticles have an irregular shape and a narrow size distribution. Zonula occludens 1 protein (ZO-1) labeling showed that the nanoparticles with different dilutions produced an opening in the tight junctions of Caco-2 cells without inducing cytotoxicity to the cells. Both enhanced uptake in Caco-2 cells monolayer and increased bioavailability in rats for HSYA nanoparticles indicated that the formulation could improve bioavailability of HSYA significantly after oral administration both in vitro and in vivo.

Pharmacokinetic comparisons of hydroxysafflower yellow A in normal and blood stasis syndrome rats.

ETHNOPHARMACOLOGICAL RELEVANCE: Safflower is a popular Traditional Chinese Medicine (TCM) to invigorate the blood and dispel 'blood stasis', which arises from poor blood circulation. The differences of pharmacokinetic properties between normal and blood stasis syndrome rats were seldom reported. AIM OF THE STUDY: The present study was conducted to evaluate the pharmacokinetics of hydroxysafflower yellow A (HSYA) following oral administration of hydroxysafflower yellow A and safflower extract with approximately the same dose of HSYA 100mg/kg in both normal and acute blood stasis rats. MATERIALS AND METHODS: The animals were orally administered with HYSA monomer and safflower extract. The blood samples were collected according to the time schedule. The concentrations of HSYA in rat plasma were determined by HPLC. Various pharmacokinetic parameters were estimated from the plasma concentration versus time data using non-compartmental methods. RESULTS: It was found that AUC(0-t), C(max), Vd and CL of HSYA in both HSYA monomer and safflower extract in acute blood stasis rats were with significant difference (P<0.05) comparing with that in normal rats. CONCLUSIONS: The results indicated that HSYA was with high uptake and eliminated slowly in the animals with blood stasis syndrome, suggesting that the rate and extent of drug metabolism was altered in acute blood stasis animals.

Simultaneous determination of hydroxysafflor yellow A and ferulic acid in rat plasma after oral administration of the co-extractum of Rhizoma chuanxiong and Flos Carthami by HPLC-diode array detector.

A simple, rapid and accurate HPLC method has been developed for simultaneous determination of hydroxysafflor yellow A and ferulic acid in rat plasma after oral administration of the co-extractum of Rhizoma chuanxiong and Flos Carthami. Plasma samples were deproteinized with 6% perchloric acid, and riboflavin was used as internal standard. The supernatant after centrifuge was injected into a Shimadzu C(18) (150 x 4.6 mm, i.d. 5 microm) column. Gradient elution for A:B (0 min, 90:10; 25 min, 70:30; 27 min, stop) was applied. The mobile phase was composed of 0.022 mol/L potassium dihydrogen phosphate solutions, adjusted to pH 3.0 with phosphoric acid for pump A, and 90% (v/v) acetonitrile for pump B. The assay was shown to be linear over the range 0.046-4.6 microg/mL (r(2) = 0.9995) for hydroxysafflor yellow A and 0.037-3.7 microg/mL (r(2) = 0.9998) for ferulic acid. Mean recovery was 97.5% for hydroxysafflor yellow A and 83.6% for ferulic acid. Both of the intra-day and inter-day precisions were

HPLC determination of safflor yellow A and three active isoflavones from TCM Naodesheng in rat plasma and tissues and its application to pharmacokinetic studies.

A high-performance liquid chromatographic method was developed for the simultaneous determination and pharmacokinetic studies of safflor yellow A, puerarin, 3'-methoxyl-puerarin, and puerarinapioside in the plasma and tissues of rats that had been administered with the traditional Chinese medicine (TCM) preparation Naodesheng via the caudal vein. Samples taken from rats were subjected to protein precipitation with acetone. Separation of these four compounds was accomplished on a Kromisil C18 stationary phase using a mobile phase of acetonitrile-0.1% phosphoric acid-tetrahydrofuran (8:92:2, v/v/v) at a flow-rate of 1.0 mL/min. The detection wavelength was set at 250 nm. The calibration curves of the four components were linear in the given concentration ranges. The intra- and inter-day precisions in plasma and tissues were less than 15% and the extraction recoveries were higher than 60%. The lower limits of quantitation of four components were low enough to determine the four components. These four components all exhibited kinetics that fitted a two-compartment model in rats. The elimination half-life was 1.19 h for safflor yellow A, 2.69 h for puerarin, 2.94 h for 3'-methoxyl-puerarin, and 0.87 h for puerarinapioside, respectively. Following administration of a single injection of Naodesheng, the concentration (C) of the four components in the tissues showed C(kidney) > C(lung), C(liver) > C(spleen), C(stomach), C(heart), approximately. The method is a reliable tool for performing studies of safflor yellow A and three puerarin isoflavones in different biological material.

Pharmacokinetics and excretion of hydroxysafflor yellow A, a potent neuroprotective agent from safflower, in rats and dogs.

Studies were conducted to characterize the pharmacokinetics and excretion of hydroxysafflor yellow A (HSYA) in rats and dogs after administration by intravenous injection or infusion. Plasma, urine, feces and bile concentrations of HSYA were measured using five validated mild HPLC methods. Linear pharmacokinetics of HSYA after the intravenous administrations were found at doses ranging from 3 to 24 mg/kg in rats and from 6 to 24 mg/kg in dogs. At a dose of 3 mg/kg, HSYA in urine, feces and bile was determined. For 48 h after dosing, the amount of urinary excretion accounted for 52.6 +/- 17.9 % (range: 31.1 - 78.7%, n = 6) of the dose, and the amount of fecal amount accounted for 8.4 +/- 5.3% (range 1.7 - 16.4%, n = 6) of the dose. Biliary excretion amount accounted for 1.4 +/- 1.0% (range 0.4-2.9%; n = 6) of the dose for 24 h after dosing. Percent plasma protein binding of HSYA ranged from 48.0 to 54.6% at 72 h. In summary, five mild HPLC methods for the determinations of HSYA in rat plasma, urine, feces, bile and dog plasma have been developed and successfully applied to preclinical pharmacokinetics and excretion of HSYA in rats and dogs. The results of excretion studies indicated that HSYA was rapidly excreted as unchanged drug in the urine. In view of previous pharmacological work, the concentration-dependent neuroprotective effect of HSYA in rats was defined.