Large differences in ammonia emission factors between greenhouse and open-field systems under different practices across Chinese vegetable cultivation.

Estimating ammonia (NH3) emission factors (EFs) for vegetable production can support assessment of potential atmospheric pollution risk and provide information for mitigating NH3 volatilization. The EFs in greenhouse and open-field systems under different fertilization, irrigation regimes, vegetable types and soil properties in both greenhouse and open-field vegetable production systems in China are poorly understood. An integrated analysis was performed, including 282 field measurements of NH3 volatilization from 54 field studies, to quantify ammonia EFs under different management practices and soil properties. The results showed that the mean ammonia EF across all measurements was 4.2 % (3.6 %-4.8 %). The EFs of greenhouse and open-field systems were 2.0 % (1.5 %-2.5 %) and 6.3 % (5.4 %-7.2 %), respectively. There was a power function relationship between nitrogen application rate and ammonia EF in greenhouses. No relationship was identified between nitrogen application rate and ammonia EF in the open-field system. The EFs of organic fertilizers were lower than those of both chemical fertilizers and the combination of chemical and organic fertilizers. EFs of leafy vegetables, cabbages, solanaceous vegetables and melons were 2.7 %, 2.9 %, 1.4 % and 1.4 % in the greenhouse system, and 5.2 %, 5.7 %, 7.6 % and 9.7 % in the open-field system, respectively. The EFs of the greenhouse production system increased with increasing soil organic matter. Boosted regression tree analysis showed that N application rate, pH and soil organic matter were the main driving factors of EFs in the greenhouse system. Vegetable type, pH and soil organic matter were the main driving factors in the open-field system. In this study, the EFs were evaluated and distinguished across greenhouse and open-field systems, and the results provided accurate EFs under different management practices and soil properties for vegetable production in both greenhouse and open-field systems.

Pharmacodynamic model of slow reversible binding and its applications in pharmacokinetic/pharmacodynamic modeling: review and tutorial.

Therapeutic responses of most drugs are initiated by the rate and degree of binding to their receptors or targets. The law of mass action describes the rate of drug-receptor complex association (kon) and dissociation (koff) where the ratio koff/kon is the equilibrium dissociation constant (Kd). Drugs with slow reversible binding (SRB) often demonstrate delayed onset and prolonged pharmacodynamic effects. This report reviews evidence for drugs with SRB features, describes previous pharmacokinetic/pharmacodynamic (PK/PD) modeling efforts of several such drugs, provides a tutorial on the mathematics and properties of SRB models, demonstrates applications of SRB models to additional compounds, and compares PK/PD fittings of SRB with other mechanistic models. We identified and summarized 52 drugs with in vitro-confirmed SRB from a PubMed literature search. Simulations with a SRB model and observed PK/PD profiles showed delayed and prolonged responses and that increasing doses/kon or decreasing koff led to greater expected maximum effects and a longer duration of effects. Recession slopes for return of responses to baseline after single doses were nearly linear with an inflection point that approaches a limiting value at larger doses. The SRB model newly captured literature data for the antihypertensive effects of candesartan and antiallergic effects of noberastine. Their PD profiles could also be fitted with indirect response and biophase models with minimal differences. The applicability of SRB models is probably commonplace, but underappreciated, owing to the need for in vitro confirmation of binding kinetics and the similarity of PK/PD profiles to models with other mechanistic determinants.

Doctoral Graduate Programs in the Pharmaceutical Sciences: An International Survey.

This publication represents the first to report global information on characteristics and requirements of doctoral programs in the pharmaceutical sciences in schools/colleges of Pharmacy. Survey responses (140 responses) were received from doctoral programs in 23 countries, with the greatest number of responses obtained from Japan, followed by India and the United States. Program characteristics and requirements, and student and faculty information, including graduate placement, in programs in Asia, North America, Europe, Africa and Australia were compared. Survey responses indicated differences in entrance requirements for doctoral programs with minimum requirements being a bachelor's degree, pharmacy degree or master's degree, including a M.Phil. degree. Programs differed widely in size in all geographical areas, but there was a similar emphasis on core educational learning outcomes (core competencies) and Ph.D. graduation requirements including qualifying examinations, thesis defense with internal and external reviewers and requirements for peer-reviewed publications. Additionally, three-quarters of programs indicated that there was external review of their programs every 2-4 or 5-7 years. Female students and female faculty mentors represented about 50% of students/faculty in programs in most geographical areas. Placement of students after graduation indicated that the highest percentage went into the pharmaceutical industry in Asia (predominantly India) and North America, with a lower percentage in Europe, Africa and Australia.

Master's Graduate Programs in the Pharmaceutical Sciences: An International Survey.

Information on master's programs in the pharmaceutical sciences is lacking; this manuscript addresses this gap in the literature, by reporting on the results of an international survey performed in 2021 of master's programs in the pharmaceutical sciences offered at Schools/Colleges of Pharmacy. Ninety-six responses were received from universities from 23 countries, with the greatest number of responses obtained from India, followed by the United States and Japan. Master's programs in the pharmaceutical sciences are generally full time and 2 years in duration. Only 3% of programs were reported to be examination-based, while the remaining 97% had a research component with 70% of programs having a thesis defense with external and/or internal examiners. Master's programs tended to be larger in Asia and Europe than in North America; as well, programs in North America tended to have more international students. Didactic coursework was included in 96% of master's programs in North America, but only in 38% of Asian and 58% of European programs. The predominant placement of graduates from master's programs in Asia was in the pharmaceutical industry (70%); this contrasted with programs in Europe, Africa and North America where 28-36% enter careers in the pharmaceutical industry and higher percentages enter Ph.D. programs. The major challenge identified by programs was funding of faculty and of graduate students, although decreasing career opportunities was identified as a challenge in Asia and Africa.

Untargeted metabolomics identifies the potential role of monocarboxylate transporter 6 (MCT6/SLC16A5) in lipid and amino acid metabolism pathways.

Monocarboxylate transporter 6 (MCT6; SLC16A5) is an orphan transporter protein with expression in multiple tissues. The endogenous function of MCT6 related to human health and disease remains unknown. Our previous transcriptomic and proteomic analyses in Mct6 knockout (KO) mice suggested that MCT6 may play a role in lipid and glucose homeostasis, but additional evidence is required. Thus, the objective of this study was to further explore the impact of MCT6 on metabolic function using untargeted metabolomic analysis in Mct6 KO mice. The plasma from male and female mice and livers from male mice were submitted for global metabolomics analysis to assess the relative changes in endogenous small molecules across the liver and systemic circulation associated with absence of Mct6. More than 782 compounds were detected with 101 and 51 metabolites significantly changed in plasma of male and female mice, respectively, and 100 metabolites significantly changed in the livers of male mice (p < .05). Significant perturbations in lipid metabolism were annotated in the plasma and liver metabolome, with additional alterations in the amino acid metabolism pathway in plasma samples from male and female mice. Elevated lipid diacylglycerol and altered fatty acid metabolite concentrations were found in liver and plasma samples of male Mct6 KO mice. Significant reduction of N-terminal acetylated amino acids was found in plasma samples of male and female Mct6 KO mice. In summary, the present study confirmed the significant role of MCT6 in lipid and amino acid homeostasis, suggesting its contribution in metabolic diseases.

Redistribution and chemical speciation of rare earth elements in an ion-adsorption rare earth tailing, Southern China.

Mining is an activity that will change the distribution and chemical speciation of rare earth elements (REEs), thus posing a serious threat to the natural environment. However, the distribution and chemical speciation of REEs in ion-adsorption rare earth tailings remain poorly understood. In this study, we investigated the contents and forms of REEs and associated geochemical behavior in rare earth tailings in southeast China. Total rare earth elements (TREEs) contents were lower while the ratios of light REEs (LREEs) to heavy REEs (HREEs) were higher in tailings than in an unmined area. In the unmined area, the distribution characteristics of TREEs and LREEs remained consistent, whereas HREEs differed with increasing depth. However, in the tailing area, the distribution characteristics of TREEs, LREEs and HREEs tended to be consistent, reflecting the outcomes of mining activities on vertical distribution characteristics of REEs. The REEs were dominated by residual and exchangeable forms in the unmined area, while residual and exchangeable REEs accounted for 80% and 20% of the TREEs, respectively, in the three tailings. Additionally, the exchangeable and carbonate-bound REEs increased but Fe/Mn oxide-bound and organic-bound REEs declined in the unmined area, whereas their distribution characteristics were irregular in the tailings. These results suggest that mining activity could curtail REEs contents and redistribute their chemical speciation, further altering geochemical behaviors in the tailings and posing serious risks to adjacent environments.

Drug-drug interaction between diclofenac and gamma-hydroxybutyric acid.

Gamma hydroxybutyric acid (GHB) has been approved clinically to treat excessive daytime sleepiness and cataplexy in patients with narcolepsy, alcohol and opioid withdrawal, and as an anesthetic. The use of GHB clinically is limited due to its high abuse potential. The absorption, clearance and tissue uptake of GHB is mediated by proton-dependent and sodium-coupled monocarboxylate transporters (MCTs and SMCTs) and inhibition of these transporters may result in a change in GHB pharmacokinetics and pharmacodynamics. Previous studies have reported that non-steroidal anti-inflammatory drugs (NSAIDs) may inhibit these monocarboxylate transporters. Therefore, the purpose of this work was to analyze the interaction between GHB (at a dose of 600 mg/kg i. v.) and the NSAID, diclofenac, by examining the effects of this drug on the in vivo pharmacokinetics and pharmacodynamics in rat studies. The pharmacodynamic effect evaluated was respiratory depression, a measure of toxicity observed by GHB at this dose. There was an improvement in the respiratory rate with diclofenac administration suggesting an effect of diclofenac on GHB toxicity. In vitro studies with rat blood brain endothelial cells (RBE4) that express MCT1 indicated that diclofenac can inhibit GHB transport with an IC50 of 10.6 µM at pH 7.4. In vivo studies found a decrease in brain GHB concentrations and a decrease in the brain-to-plasma concentration ratio following diclofenac treatment. With this study we can conclude that diclofenac and potentially other NSAIDs can inhibit the transport of GHB into the brain, therefore decreasing GHB's pharmacodynamic effects and toxicity.

Targeting the Choroid Plexuses for Protein Drug Delivery.

Delivery of therapeutic agents to the central nervous system is challenged by the barriers in place to regulate brain homeostasis. This is especially true for protein therapeutics. Targeting the barrier formed by the choroid plexuses at the interfaces of the systemic circulation and ventricular system may be a surrogate brain delivery strategy to circumvent the blood-brain barrier. Heterogenous cell populations located at the choroid plexuses provide diverse functions in regulating the exchange of material within the ventricular space. Receptor-mediated transcytosis may be a promising mechanism to deliver protein therapeutics across the tight junctions formed by choroid plexus epithelial cells. However, cerebrospinal fluid flow and other barriers formed by ependymal cells and perivascular spaces should also be considered for evaluation of protein therapeutic disposition. Various preclinical methods have been applied to delineate protein transport across the choroid plexuses, including imaging strategies, ventriculocisternal perfusions, and primary choroid plexus epithelial cell models. When used in combination with simultaneous measures of cerebrospinal fluid dynamics, they can yield important insight into pharmacokinetic properties within the brain. This review aims to provide an overview of the choroid plexuses and ventricular system to address their function as a barrier to pharmaceutical interventions and relevance for central nervous system drug delivery of protein therapeutics. Protein therapeutics targeting the ventricular system may provide new approaches in treating central nervous system diseases.

Identification of the in vivo relevant dissolution media for the three active components in EGb 761 tablet for better correlation with their pharmacokinetics in healthy subjects.

Although EGb 761, the standardized dry extract of Ginkgo biloba leaves, exhibited numerous pharmacological activities and widely used in Asia, European and North America, the quality control of its dosage forms such as tablet mainly relies on monitoring the contents of the active marker components, namely quercetin, kaempferol, isorhamnetin, bilobalide, ginkgolide A, ginkgolide B and ginkgolide C. So far, the in vitro dissolution profiles of EGb761 tablet were barely used to monitor its quality and how these dissolution profiles correlate with their in vivo pharmacokinetics was not known. Thus, the present study was proposed aiming to 1) develop the in vitro-in vivo correlations (IVIVCs) for the marker components in EGb 761 tablet; 2) identify the in vivo relevant dissolution media for the marker components in EGb 761 tablet based on the established IVIVCs. The content analyses of the marker components in EGb 761 tablet was first carried out. Then, the dissolution profiles were further obtained using paddle method of United States Pharmacopeia for bilobalide, ginkgolides A, and ginkgolide B, that have previously reported human plasma pharmacokinetics after EGb 761 tablet oral administrations. About seven different media including 0.1 M hydrochloric acid (HCl), acetate buffer, H2O, fasted state simulated gastric fluid (FaSSGF), fasted state simulated intestinal fluid version 2 (FaSSIF-V2), fed state simulated intestinal fluid version 2 (FeSSIF-V2), and sequential medium (0.1 M HCl for 2 h with pH adjusted to 7 for another 2 h) were tested in the current investigation. The obtained in vitro dissolution profiles of bilobalide, ginkgolides A and ginkgolide B from EGb 761 tablet were first fitted with four dissolution models, namely Weibull, Double Weibull, Hill and Makoid-Banakar, to obtain the best-fit model for each component in each medium. The human plasma concentration versus time profiles of the above three components were then inputted into the Phoenix WinNonlin IVIVC Toolkit to obtain their in vivo absorption profiles using numerical deconvolution. The best-fit dissolution profiles of each marker component in the seven studied media were further used to correlate with its obtained in vivo absorption profile by the linear correlation models to establish the corresponding IVIVCs in each studied medium. Finally, the best in vivo correlated medium for each investigated marker component was selected based on their adjusted correlation coefficients, Akaike Information Criterion (AIC) and Schwarz's Bayesian Criterion (SBC) values. As a result, the dissolution profiles of bilobalide, ginkgolide A, ginkgolide B from EGb 761 tablet in 0.1 M HCl, FaSSGF, FaSSIF-V2 demonstrated the best correlation with their in vivo absorption profiles, respectively. Our current studies for the first time applied the concept of IVIVC to EGb 761 tablet and successfully identified the in vivo relevant dissolution media for its three active marker components to improve its quality control.

Reduced systemic exposure and brain uptake of donepezil in rats with scopolamine-induced cognitive impairment.

1. Donepezil (DPZ) is an acetylcholinesterase (AchE) inhibitor used in the mild to moderately severe Alzheimer's disease. Among its major metabolites, 6-O-desmethyl DPZ (6-DDPZ), 5-O-desmethyl DPZ (5-DDPZ) and DPZ N-oxide, the anti-AchE activities of 5-DDPZ and DPZ N-oxide have never been clearly identified before. Besides, there is no report on simultaneous determination of DPZ and its three metabolites in the brain, thus their uptake in hippocampus and cortex are unknown. Therefore, the current studies are proposed aiming to: (1) investigate the anti-AchE activities and brain uptake of DPZ and its three metabolites and (2) compare their pharmacokinetics and brain uptake between normal and scopolamine-induced rats.2. DPZ and its three metabolites demonstrated anti-AchE activities with the IC50 in the order of DPZ (7.20 × 10-2 µM), 6-DDPZ (1.14 × 10-1 µM), 5-DDPZ (4.03 × 10-1 µM) and DPZ N-oxide (1.61 µM). They were also evenly distributed in the brain and retained much longer in the brain than that in plasma in normal rats.3. Compared to normal rats, Cmax, AUC0→24h and AUC0→∞ of DPZ were reduced by 52.0%, 31.2% and 30.1%, respectively; Tmax of DPZ and its three metabolites were prolonged and their brain uptake were decreased in scopolamine-induced rats, suggesting the potential reduced absorption of DPZ.

Exclusion of unsuitable CNS drug candidates based on their physicochemical properties and unbound fractions in biomatrices for brain microdialysis investigations.

Microdialysis has been the only direct method of continuously measuring the unbound drug concentrations in extracellular fluid at a specific brain region with respect to time in the same animal. However, not every compound is suitable for microdialysis system as demonstrated by their inconsistent "by gain" and "by loss" in-vitro microdialysis probe recoveries leading to over- or under- estimated in-vivo concentrations. Therefore, our current study was proposed aiming to develop simple exclusion criteria for drug candidates that are not suitable for microdialysis system investigation. Through literature research, the properties ((LogP, pKa, water solubility and unbound fraction in plasma and brain) of drugs that have been reported for microdialysis studies were summarized. The exclusion criteria were developed by evaluating the impact of such properties on the consistency of in-vitro "by gain" and "by loss" recoveries of microdialysis probe. As a result, forty-five compounds were identified from literatures, among which doxorubicin, docetaxel, omeprazole, donepezil and phenytoin were found to have inconsistent in-vitro "by gain" and "by loss" microdialysis probe recoveries and subsequently selected for the exclusion criteria analysis. It was found that compounds with limited water solubility (less than 1 g/L) and unbound fraction in plasma (fu,plasma less than 30%) and brain homogenate (fu,brain less than 10%) were more likely to have inconsistent "by gain" and "by loss" microdialysis probe recoveries. Our proposed exclusion criteria were further validated using carbamazepine (limited water solubility only), DB213 (limited fu,brain only) and piperine (both limited water solubility and limited fu,plasma, fu,brain). Our current proposed exclusion criteria will help excluding the CNS drug candidates that are highly unlikely suitable for brain microdialysis approach leading to a better success rate in brain microdialysis approach development.

Role of piperine in CNS diseases: pharmacodynamics, pharmacokinetics and drug interactions.

Introduction: Piperine, the major bioactive component from black pepper, has gained increasing attention for its beneficial effects in the central nervous system (CNS). However, its related pharmacodynamics and brain pharmacokinetics, as well as its interaction with other CNS drugs are lacking, which may hinder its therapeutic and safe use. Areas covered: The current review provides an updated summary on CNS activities of piperine, including anti-epileptic, anti-depressive and neurodegeneration protection effect. The brain pharmacokinetic properties of piperine together with the approaches to enhance its aqueous solubility were summarized. Considering the wide use of black pepper and the well-reported alteration on CYP and transporters by piperine, interactions between piperine and CNS drugs are also illustrated for the first time. Expert opinion: Although the CNS beneficial effects of piperine have been extensively studied in preclinical models, clinical evidence on its CNS application is barely available, which may be attributed to its limited aqueous solubility, unclear pharmacokinetic properties in humans and potential toxicities during long-term use at higher doses. Although beneficial interactions between piperine and certain CNS drugs were often reported in preclinical studies, more mechanistic studies with clinically relevant doses should be conducted to provide guidance on their clinical combination use.

Reduced Systemic and Brain Exposure with Inhibited Liver Metabolism of Carbamazepine After Its Long-Term Combination Treatment with Piperine for Epilepsy Control in Rats.

Carbamazepine (CBZ) with piperine, the active ingredient in black pepper, which is omnipresent in food and may be potentially used for epilepsy control owing to its anticonvulsant effects, can be coadministered to epileptic patients. Since piperine has previously demonstrated its inhibition of the CYP3A-mediated metabolism of CBZ to carbamazepine-10,11-epoxide (CBZE), the present study aimed to investigate the impact of piperine on CBZ pharmacokinetics (PKs) in rats and pharmacodynamics in zebrafish and mouse acute seizure models. Plasma and brain PKs were studied in rats after a single-dose or 2-week combined oral administration of piperine (3.5/35 mg/kg, q.d.) and CBZ (40 mg/kg, t.i.d.) by blood sampling and brain microdialysis. Although no PK change was noticed after a single coadministration, significantly decreased plasma and brain concentrations of CBZ and CBZE with inhibited rat liver Cyp3a2 were demonstrated after long-term combined administration. Our developed compartmental model for the PK characterization of CBZ and CBZE in the blood and brain further estimated that coadministration with high-dose piperine could lead to decreases of 26%, 35%, and 38% in bioavailability, metabolism, and brain uptake of CBZ, respectively. Regardless of the PK changes, a limited impact on the antiepileptic effect of CBZ was found after the coadministration of CBZ and piperine in the tested seizure models. In conclusion, single-dose cotreatment of CBZ and piperine did not result in any significant PK or pharmacodynamic interactions, whereas their long-term cotreatment could lead to inhibited liver metabolism and the markedly reduced systemic and brain exposure of CBZ and CBZE.

Piperine-loaded nanoparticles with enhanced dissolution and oral bioavailability for epilepsy control.

Piperine, an alkaloid from black pepper, has demonstrated beneficial effects in central nervous system, especially in epilepsy control. However, its therapeutic application remains limited due to the low aqueous solubility of piperine. Thus, the present study aimed to formulate piperine into a more solubilized form to enhance its oral bioavailability and facilitate its development as a potential anti-epileptic treatment. The nanoprecipitation method was applied to prepare piperine nanoparticles, which were then examined under transmission electron microscopy. A spherical nanosized particle was obtained with small particle size (average particle size 130.20 ±â€¯1.57 nm), narrow size distribution (polydispersity index 0.195 ±â€¯0.002) and efficient entrapment (entrapment efficiency 92.2 ±â€¯2.5%). Compared with the unformulated piperine, nanosized piperine had a much faster dissolution rate with 3 times higher accumulated drug release after 24 h. After oral administration at 3.5 mg/kg in rats, the nanosized piperine formulations could improve its oral bioavailability by 2.7-fold with 16 times higher concentrations in brain at 10 h postdosing. Moreover, the piperine nanoparticles exhibited effective protection against pentylenetetrazol-induced seizures in both zebrafish and mice. In summary, the present study provided a simple formulation strategy for oral administration of piperine to overcome its limitation in water solubility. The developed formulations could effectively enhance oral bioavailability of piperine with promising anti-epileptic effect, which could be applied as a potential therapy in epilepsy control.

Time-dependent inhibition of carbamazepine metabolism by piperine in anti-epileptic treatment.

AIMS: The first-line anti-epileptic agent carbamazepine has narrow therapeutic index and can potentially interact with piperine, the major component from black pepper. The present study aimed to delineate the mechanism of such interaction for safe usage of carbamazepine during epilepsy control. MATERIALS AND METHODS: The effect of piperine on carbamazepine hepatic metabolism was examined using rat or human liver microsomes. Mechanistic static model was applied to predict the extent of interaction. In addition, liver microsomal activities, mRNAs and protein expressions of genes regulating carbamazepine metabolism were evaluated after two weeks oral administrations of 3.5 and 35 mg/kg piperine in rats. Moreover, the effect of piperine on the xenobiotic receptor constitutive androstane receptor (CAR) was further accessed. KEY FINDINGS: Time-dependent inhibitory effect of piperine on carbamazepine metabolism was observed, with kinact and KI of 0.0153 min-1 and 18.34 µM for rat, and 0.0093 min-1 and 9.45 µM for human. Based on such in-vitro metabolic parameters, further estimation using mechanistic static model indicated that piperine could increase the AUC of CBZ by 7% and 11% in rat and human, respectively. Significant inhibition on rat liver microsomal activity, Cyp3a2 mRNA and protein expression, CAR mRNA were demonstrated with piperine at 35 mg/kg. Yet, no direct effect on the activity of CAR for piperine was found. SIGNIFICANCE: We have demonstrated the time-dependent inhibition by piperine on carbamazepine metabolism as the interaction mechanism. Prolonged use of piperine at high dose could increase carbamazepine concentrations through inhibiting metabolic enzyme activities and their related genes expressions.

Efficient brain uptake of piperine and its pharmacokinetics characterization after oral administration.

1. Piperine, the major biological active component in black pepper has been associated with miscellaneous pharmacological effects, especially on central nervous system. To correlate with its neurological activity, a comprehensive pharmacokinetic profile of piperine in brain, plasma and cerebrospinal fluid after oral administration in rats was investigated in this study. 2. It was noted that piperine could efficiently penetrate and homogeneously distribute into brain with similar pharmacokinetics profiles in each region. In addition, piperine concentrations in brain and plasma were found to be comparable with brain to plasma area under curve extrapolated to infinity (AUC0→∞) ratios of 0.95 and 1.10 for total concentration and unbound concentrations, respectively. Piperine also demonstrated high affinity toward brain tissue (98.4-98.5%) and plasma protein (96.2-97.8%) leading to a brain distribution volume of 36.32 ± 1.40 ml/g brain. Moreover, its efficient membrane permeability (P app values of 5.41 ± 0.40 × 10- 5 cm/s and 4.78 ± 0.16 × 10- 5 cm/s for basolateral to apical and apical to basolateral transport in Caco-2 monolayer model) and limited hepatic metabolism (Clint of 8.15 µl/min/mg) could also contribute to its quick and high extent brain exposure. 3. In summary, this study for the first time demonstrated high brain penetration potency of piperine could be resulted from its high brain tissue affinity and membrane permeability together with its limited liver metabolism.

Non-linear pharmacokinetics of piperine and its herb-drug interactions with docetaxel in Sprague-Dawley rats.

Piperine (PIP), the major alkaloid component from Piper longum L. and Piper nigrum L., could enhance the bioavailabilities of other drugs including rosuvastatin, peurarin and docetaxel (DOX) via inhibition of CYP3A and P-glycoprotein activity. Nevertheless, the effect of such drug combination usage on the in vivo exposure of PIP has not been investigated due to lack of assay for the simultaneous determination of PIP and other drugs such as DOX. Besides, the reported pharmacokinetics of PIP varied a lot without appropriate bioavailability determined from the same dose. In the current study, an LC/MS/MS method has been developed to simultaneously determine the plasma concentrations of PIP and DOX and further applied to investigate the pharmacokinetics properties of PIP after oral and intravenous administrations as well as the pharmacokinetics interactions between PIP and DOX after their co-administration. A simple protein precipitation method was employed for plasma sample treatment by adding a mixture of methanol and acetonitrile (1:1, v/v) with glibenclamide as internal standard (IS). The LC/MS/MS system consisted of Agilent 6430 series LC pumps and auto-sampler. The chromatographic separation was carried out in 15min on a Waters C18 column (150×3.9mm i.d., 4µm) with a mobile phase containing 0.2% formic acid and acetonitrile (1:1, v/v) at a flow rate of 0.4ml/min. The detection was performed using the positive ion electrospray ionization (ESI) in multiple reaction monitoring (MRM) mode with precursor-to-product ion transitions at m/z 286.1→201.1 for PIP, m/z 830.3→548.9 for DOX and m/z 494.2→369.0 for IS. The method demonstrated good linearity for both PIP and DOX over the concentration range of 2.5-1280ng/ml with LLOD at 2.5ng/ml. The intra-day and inter-day precisions were less than 13.34% and relative error (R.E.) representing accuracy was in the range of -11.38 to 3.15%. The recoveries of PIP, DOX and IS were above 75% and there was no matrix effect. PIP and DOX exhibited good stabilities under various conditions. PIP was administrated via intravenous bolus at 3.5mg/kg and via oral administration at 35mg/kg and 3.5mg/kg, while DOX was intravenously administrated at 7mg/kg to Sprague-Daley rats. The plasma concentrations of PIP and DOX were determined using the above developed and validated method. At the dose of 3.5mg/kg, the bioavailability of PIP was calculated to be 25.36%. Its AUC0→t was unproportionally increased with doses, indicating a potential non-linear pharmacokinetics profile of PIP. It was found that the AUC0→t and C0 of DOX and t1/2 of PIP were significantly increased after their combination use, suggesting potential enhanced bioavailability of not only DOX but also PIP, which may lead to the overall enhanced pharmacological effects.

Comprehensive quantitative analysis of Chinese patent drug YinHuang drop pill by ultra high-performance liquid chromatography quadrupole time of flight mass spectrometry.

YinHuang drop pill (YHDP) is a new preparation, derived from the traditional YinHuang (YH) decoction. Since drop pills are one of the newly developed forms of Chinese patent drugs, not much research has been done regarding the quality and efficacy. This study aims to establish a comprehensive quantitative analysis of the chemical profile of YHDP. ultra high-performance liquid chromatography quadrupole time of flight mass spectrometry (UHPLC-Q-TOF-MS/MS) was used to identify 34 non-sugar small molecules including 15 flavonoids, 9 phenolic acids, 5 saponins, 1 iridoid, and 4 iridoid glycosides in YHDP samples, and 26 of them were quantitatively determined. Sugar composition of YHDP in terms of fructose, glucose and sucrose was examined via a high performance liquid chromatography-evaporative light scattering detector on an amide column (HPLC-NH2P-ELSD). Macromolecules were examined by high performance gel permeation chromatography coupled with ELSD (HPGPC-ELSD). The content of the drop pill's skeleton component PEG-4000 was also quantified via ultra-high performance liquid chromatography coupled with charged aerosol detector (UHPLC-CAD). The results showed that up to 73% (w/w) of YHDP could be quantitatively determined. Small molecules accounted for approximately 5%, PEG-4000 represented 68%, while no sugars or macromolecules were found. Furthermore, YHDP showed no significant differences in terms of daily dosage, compared to YinHuang granules and YinHuang oral liquid; however, it has a higher small molecules content compared to YinHuang lozenge.

Astragalus saponins Inhibits Lipopolysaccharide-Induced Inflammation in Mouse Macrophages.

Excessive nitric oxide (NO) and pro-inflammatory cytokines are produced during the pathogenesis of inflammatory diseases and cancer. It has been demonstrated that anti-inflammation contributes Astragalus membranaceus saponins (AST)'s beneficial effects in combination of conventional anticancer drugs. However, the immunomodulating property of AST has not been well characterized. In this study, we found that AST suppressed lipopolysaccharide (LPS)-induced generation of NO without causing cytotoxicity in the mouse macrophage RAW264.7. The gene and protein overexpression of inducible NO synthase (iNOS) as well as the production of tumor necrosis factor-[Formula: see text], evoked by LPS, was consistently down-regulated by AST. AST also inhibited the phosphorylation of p38 mitogen-activated protein kinase (MAPK) and suppressed nuclear factor (NF)-[Formula: see text]B activation and the associated I[Formula: see text]B[Formula: see text] degradation during LPS insult. Furthermore, AST induced growth inhibition in promyelocytic leukemic HL-60 cells and T-lymphocyte leukemic Jurkat cells, but exerted no cytotoxic effects in normal human peripheral blood mononuclear cells (PBMC). It is known that the chemotherapeutic drug 5-FU can suppress the immune system, which can be identified by a reduced white blood cell count and decreased hematocrit, while the combination of AST and 5-FU can reverse the above hematologic toxicities. To summarize, non-cytotoxic concentrations of AST suppress LPS-induced inflammatory responses via the modulation of p38 MAPK signaling and the inhibition of NO and cytokine release. Importantly, AST can alleviate the hematologic side effects of current chemotherapeutic agents. These findings can facilitate the establishment of AST in the treatment of inflammatory diseases and inflammation-mediated tumor development.