In vitro and in silico study on consequences of combined exposure to the food-borne alkenylbenzenes estragole and safrole.

Potential consequences of combined exposure to the selected food-borne alkenylbenzenes safrole and estragole or their proximate carcinogenic 1'-hydroxy metabolites were evaluated in vitro and in silico. HepG2 cells were exposed to 1'-hydroxyestragole and 1'-hydroxysafrole individually or in equipotent combination subsequently detecting cytotoxicity and DNA adduct formation. Results indicate that concentration addition adequately describes the cytotoxic effects and no statistically significant differences were shown in the level of formation of the major DNA adducts. Furthermore, physiologically based kinetic modeling revealed that at normal dietary intake the concentration of the parent compounds and their 1'-hydroxymetabolites remain substantially below the Km values for the respective bioactivation and detoxification reactions providing further support for the fact that the simultaneous presence of the two carcinogens or of their proximate carcinogenic 1'-hydroxy metabolites may not affect their DNA adduct formation. Overall, these results point at the absence of interactions upon combined exposure to selected food-borne alkenylbenzenes at realistic dietary levels of intake.

α-Asarone, ß-asarone, and γ-asarone: Current status of toxicological evaluation.

Asarone isomers are naturally occurring in Acorus calamus Linné, Guatteria gaumeri Greenman, and Aniba hostmanniana Nees. These secondary plant metabolites belong to the class of phenylpropenes (phenylpropanoids or alkenylbenzenes). They are further chemically classified into the propenylic trans- and cis-isomers α-asarone and ß-asarone and the allylic γ-asarone. Flavoring, as well as potentially pharmacologically useful properties, enables the application of asarone isomers in fragrances, food, and traditional phytomedicine not only since their isolation in the 1950s. However, efficacy and safety in humans are still not known. Preclinical evidence has not been systematically studied, and several pharmacological effects have been reported for extracts of Acorus calamus and propenylic asarone isomers. Toxicological data are rare and not critically evaluated altogether in the 21st century yet. Therefore, within this review, available toxicological data of asarone isomers were assessed in detail. This assessment revealed that cardiotoxicity, hepatotoxicity, reproductive toxicity, and mutagenicity as well as carcinogenicity were described for propenylic asarone isomers with varying levels of reliability. The toxicodynamic profile of γ-asarone is unknown except for mutagenicity. Based on the estimated daily exposure and reported adverse effects, officials restricted or published recommendations for the use of ß-asarone and preparations of Acorus calamus. In contrast, α-asarone and γ-asarone were not directly addressed due to a limited data situation.

Estragole DNA adduct accumulation in human liver HepaRG cells upon repeated in vitro exposure.

Accumulation of N2-(trans-isoestragol-3'-yl)-2'-deoxyguanosine (E-3'-N2-dG) DNA adducts derived from the alkenylbenzene estragole upon repeated dose exposure was investigated since the repair of this adduct was previously shown to be inefficient. To this end human HepaRG cells were exposed to repeating cycles of 2 h exposure to 50 µM estragole followed by 22 h repair to mimic daily exposure. The E-3'-N2-dG DNA adduct levels were quantified by LC-MS/MS after each cycle. The results show accumulation of E-3'-N2-dG DNA adducts at a rate of 17.53 adducts/108 nts/cycle. This rate at the dose level calculated by physiologically based kinetic (PBK) modeling to result in 50 µM was converted to a rate expected at average human daily intake of estragole. The predicted time estimated to reach adduct levels reported at the BMD10 of the related alkenylbenzene methyleugenol of 10-100 adducts /108 nts upon average human daily intake of estragole amounted to 8-80 (in rat) or 6-57 years (in human). It is concluded that the persistent nature of the E-3'-N2-dG DNA adducts may contribute to accumulation of substantial levels of DNA adducts upon prolonged dietary exposure.

Lipid Nanoparticles Improve the Uptake of α-Asarone Into the Brain Parenchyma: Formulation, Characterization, In Vivo Pharmacokinetics, and Brain Delivery.

Treatment of brain-related diseases is one of the most strenuous challenges in drug delivery research due to numerous hurdles, including poor blood-brain barrier penetration, lack of specificity, and severe systemic toxicities. Our research primarily focuses on the delivery of natural therapeutic compound, α-asarone, for the treatment of brain-related diseases. However, α-asarone has poor aqueous solubility, bioavailability, and stability, all of which are critical issues that need to be addressed. This study aims at formulating a lipid nanoparticulate system of α-asarone (A-LNPs) that could be used as a brain drug delivery system. The physicochemical, solid-state properties, stability, and in vitro and in vivo studies of the A-LNPs were characterized. The release of α-asarone from the A-LNPs was prolonged and sustained. After intravenous administration of A-LNPs or free α-asarone, significantly higher levels of α-asarone from the A-LNPs were detected in murine plasma and brain parenchyma fractions, confirming the ability of A-LNPs to not only maintain a therapeutic concentration of α-asarone in the plasma, but also transport α-asarone across the blood-brain barrier. These findings confirm that lipid nanoparticulate systems enable penetration of natural therapeutic compound α-asarone through the blood-brain barrier and may be a candidate for the treatment of brain-related diseases.

Investigation of Volatiles in Cork Samples Using Chromatographic Data and the Superposing Significant Interaction Rules (SSIR) Chemometric Tool.

This study describes a new chemometric tool for the identification of relevant volatile compounds in cork by untargeted headspace solid phase microextraction and gas chromatography mass spectrometry (HS-SPME/GC-MS) analysis. The production process in cork industries commonly includes a washing procedure based on water and temperature cycles in order to reduce off-flavors and decrease the amount of trichloroanisole (TCA) in cork samples. The treatment has been demonstrated to be effective for the designed purpose, but chemical changes in the volatile fraction of the cork sample are produced, which need to be further investigated through the chemometric examination of data obtained from the headspace. Ordinary principal component analysis (PCA) based on the numerical description provided by the chromatographic area of several target compounds was inconclusive. This led us to consider a new tool, which is presented here for the first time for an application in the chromatographic field. The superposing significant interaction rules (SSIR) method is a variable selector which directly analyses the raw internal data coming from the spectrophotometer software and, combined with PCA and discriminant analysis, has been able to separate a group of 56 cork samples into two groups: treated and non-treated. This procedure revealed the presence of two compounds, furfural and 5-methylfurfural, which are increased in the case of treated samples. These compounds explain the sweet notes found in the sensory evaluation of the treated corks. The model that is obtained is robust; the overall sensitivity and specificity are 96% and 100%, respectively. Furthermore, a leave-one-out cross-validation calculation revealed that all of the samples can be correctly classified one at a time if three or more PCA descriptors are considered.

Determination of toosendanin and trans-anethole in Fructus Meliae Toosendan and Fructus Foeniculi by HPLC-MS/MS and GC-MS/MS in rat plasma and their potential herb-herb interactions.

ETHNOPHARMACOLOGICAL RELEVANCE: The objective of traditional Chinese medicine (TCM) combination theory is to "reduce toxicity and increase efficiency", especially to solve the liver toxicity of many TCMs. Fructus Meliae Toosendan (CLZ)-Fructus Foeniculi (XHX) is a typical traditional Chinese herb pair that decreases the toxicity and increases the efficiency of the herbs. Fructus Meliae Toosendan (CLZ, cold-natured) has significant liver toxicity. However, it has been widely used in combination with Fructus Foeniculi (XHX, hot-natured) for thousands of years in TCM, in which form it shows no hepatotoxicity, indicating that the combined use of XHX and CLZ can reduce the hepatotoxicity of CLZ. Herb-herb interactions could affect herb pharmacokinetics and in vivo efficacy. The herb-herb interactions between CLZ and XHX are still unknown. MATERIALS AND METHODS: This study used liquid chromatography tandem mass spectrometry (LC-MS) and gas chromatography tandem mass spectrometry (GC-MS) to establish methods for detecting toosendanin and trans-anethole, the main active substances of CLZ and XHX, respectively. Additionally, we investigated their herb-herb interactions via pharmacokinetic and pharmacodynamic studies. RESULTS: The results indicate that the established analytical methods are suitable for detecting toosendanin and trans-anethole, and the methodology meets the requirements of biological sample testing methods. Compared with the CLZ group, the pharmacokinetic parameters Cmax , AUC(0-t) , AUC(0-∞) , MRT(0-t) and MRT(0-∞) of toosendanin in the CLZ-XHX group notably decreased and the values of Vz/F remarkably increased. Compared with the XHX group, the pharmacokinetic parameters Cmax , AUC0-t , AUC0-∞, Tmax and t1/2z of trans-anethole notably increased in the CLZ-XHX group, and the values of CLz/F and Vz/F obviously decreased. CONCLUSION: The pharmacokinetic results indicate that XHX can significantly decrease the absorption and bioavailability and accelerate the elimination process of toosendanin in CLZ. XHX could decrease the risk of in vivo accumulation of the toxic constituent of CLZ, toosendanin, thus decreasing its toxicity. It has also been shown that CLZ can significantly increase absorption and bioavailability and attenuate the elimination process of trans-anethole in XHX, thus enhancing its efficacy. Hepatotoxicity studies indicate that CLZ has significant hepatotoxicity, and its combined use with XHX can decrease its liver-damaging properties.

Detection of N-Acetyl-S-[3'-(4-methoxyphenyl)allyl]-l-Cys (AMPAC) in Human Urine Samples after Controlled Exposure to Fennel Tea: A New Metabolite of Estragole and trans-Anethole.

Fennel and other herbs contain the secondary plant metabolites estragole and trans-anethole, of which estragole is carcinogenic in rodents. It is metabolically activated by cytochrome P450-catalyzed conversion to 1'-hydroxyestragole and subsequent sulfo conjugation to the genotoxic 1'-sulfoxyestragole. The current study followed the hypothesis that the reactive sulfate ester may be detoxified by glutathione conjugation, leading to the urinary excretion of a resultant mercapturic acid. We identified the assumed downstream metabolite N-acetyl-S-[3'-(4-methoxyphenyl)allyl]-l-Cys (AMPAC) in human urine samples after consumption of fennel tea. An isotope-dilution technique for its quantification by ultraperformance liquid chromatography-tandem mass spectrometry and [13C3,15N]AMPAC in urine samples was developed. The method was applied to determine the AMPAC concentration in urine samples following uptake of 500 mL of fennel tea containing 2.2 mg of estragole by 12 healthy participants (six females and six males). Before drinking the tea, the urinary AMPAC concentration was below the limit of detection. In most of the participants, the highest amounts of urinary AMPAC were found in the first-hour urine after exposure. The excretion by first-order kinetics (range of t1/2 = 0.78-1.54 h; mean ± SD: 1.13 ± 0.21 h) led to a nearly complete clearance within 8 h in all participants. The total AMPAC excreted was in the range of 93-1076 ng, reflecting pronounced interindividual variations of enzymes taking part in estragole metabolism. Importantly, AMPAC was also formed in one volunteer following oral uptake of a single dose of isolated trans-anethole, albeit to a much smaller extent compared to estragole. AMPAC may be of future use as a human biomarker for the internal exposure to the carbocation formed from either 1'-sulfoxyestragole or 3'-sulfoxyisoestragole, the reactive sulfate ester metabolites of estragole and trans-anethole, respectively.

Pharmacokinetics and tissue distribution evaluation of α-asaronol and its main metabolite in rats by HPLC method.

α-Asaronol is one of trace metabolites of α-asarone formed in vivo and in vitro and exhibits good anticonvulsant activities with low neurotoxicity. The present study was mainly to describe the pharmacokinetics and tissue distribution of α-asaronol and its metabolite E-2,4,5-trimethoxy cinnamic acid (E-2,4,5-TMCA), in rat after oral and intravenous administration of α-asaronol. The results indicate that α-asaronol can be absorbed (tmax = 5-10 min) and transformed to E-2,4,5-TMCA (tmax = 10-15 min) rapidly after oral administration. Presumably due to hepatic first-pass effect, α-asaronol shows a low bioavailability (about 25.9%). Furthermore, α-asaronol is distributed rapidly and widely in various tissues with the order of brain > heart > kidney > spleen > liver > lung, and eliminated quickly following the intravenous administration. The maximal concentration of α-asaronol in the brain is about 1.603 ± 0.221 µg/g at 5 min. In comparison, the concentrations of E-2,4,5-TMCA, except brain, are all higher than that of α-asaronol in the tested tissues with the order of kidney > liver > lung > heart ≈ spleen > brain. Current study results will contribute to interpretation and understanding preclinical PK properties of α-asaronol and its antiepileptic effects in animals.

Development of a selective and sensitive LC-MS/MS method for the quantification of α-asarone in mouse plasma and its application to pharmacokinetic studies.

A simple, sensitive and selective liquid chromatography-tandem mass spectrometric method was developed and validated for the quantification of α-asarone in mouse plasma with its application to pharmacokinetic studies. An electrospray ionization (ESI) with multiple reaction monitoring (MRM) mode was used to monitor the precursor-product ion transitions of 209.1 > 193.9 m/z for α-asarone and 157.8 > 114.0 m/z for allantoin. Chromatographic separation was acquired on a Sepax BR-C18 (5 µm, 120 Š1.0 × 100 mm) column with an isocratic mobile phase consisting of methanol and 0.1% formic acid (80:20, v/v). The developed bioanalytical method was successfully validated according to the United States Food and Drug Administration (US FDA) guidelines for linearity, selectivity, accuracy, precision, recovery, matrix effect, and stability. The validated method was successfully applied to a pharmacokinetics study of α-asarone along with a combination of pharmacokinetic techniques, including small-volume serial blood sampling in mice, reducing drug doses and the number of animals used, using a simple protein precipitation method and less solvent consumption will enable its use in further bioequivalence studies.

Experimental Study on the Postmortem Redistribution of the Substituted Phenethylamine, 25B-NBOMe.

2-(4-Bromo-2,5-dimethoxyphenyl)-N-(2-methoxybenzyl)ethanamine (25B-NBOMe) is a substituted phenethylamine, which has become highly prevalent worldwide since 2014. Recently, in an autopsy case involving fatal 25B-NBOMe intoxication, we found the postmortem increase of 25B-NBOMe concentration in the cardiac blood approximately 2 days after death. The aim of this study was to investigate the distribution of 25B-NBOMe and reproduce the postmortem redistribution using a rat model. Sprague-Dawley rats were killed 30 min after intraperitoneal injection of 25B-NBOMe (0.5 mg/kg) and left for 0, 3, 6, 9, 15, or 24 h (six rats at each time point). Postmortem 25B-NBOMe concentrations in the cardiac blood increased by more than 10-fold at 6-h postmortem. 25B-NBOMe accumulated primarily in the lung. Moreover, this postmortem redistribution occurred even in rats that had died 1 week following the 25B-NBOMe administration. These findings indicate that attention should be paid to sample collection and data interpretation in the toxicological analysis of 25B-NBOMe.

Simultaneous determination of usnic, diffractaic, evernic and barbatic acids in rat plasma by ultra-high-performance liquid chromatography-quadrupole exactive Orbitrap mass spectrometry and its application to pharmacokinetic studies.

Usnea longissima Ach. (Usnea) is used in pharmaceuticals, food and cosmetics. Evernic acid (EA), barbatic acid (BA), diffractaic acid (DA) and usnic acid (UA) are the most typical ingredients in U. longissima and exert a wide variety of biological functions. The study aimed to develop a sensitive method for simultaneous analysis of EA, BA, DA and UA in rat plasma and was applied to pharmacokinetic studies after consumption of UA and ethanol extract from U. longissima (UE). The samples were separated on a BEH C18 column by gradient elution with 0.5% formic acid in water and in methanol. The relative molecular masses of analytes were obtained in full-scan range from 50.0 to 750.0 m/z under negative ionization mode by UPLC-Q-Exactive Orbitrap MS. All validation parameters, such as lower limit of quantitation, linearity, specificity, precision, accuracy, extraction recovery, matrix effect and stability, were within acceptable ranges and the method was appropriate for biological specimen analysis. The pharmacokinetic results indicated that the absolute bioavailabilities of UA after oral administration of UA and UE reached 69.2 and 146.9%, respectively. Compared with UA in UE, the relative bioavailability of DA, BA and EA reached 103.7, 10.4 and 0.7% after oral administration of UE.

Development of an LC-MS/MS method for quantification of two isomeric phenylpropenes and the application to pharmacokinetic studies in rats.

Isomers ß-asarone and α-asarone have recently been demonstrated to have differential pharmacological activities. Here, we report an LC-MS/MS method developed using acetonitrile to extract two isomeric phenylpropenes from rat plasma. Separation was achieved using a XDB-C18 column (100 × 2.1 mm; i.d., 1.8 µm) with a mobile phase of methanol-0.1% formic acid (55:45, v/v) at a flow rate of 0.3 mL/min. Calibration curves ranging from 5.20 to 2080 ng/mL for ß-asarone and from 3.68 to 1470 ng/mL for α-asarone were linear (r2 ≥ 0.9938) with the lower limits of quantification being 5.20 and 3.68 ng/mL for both isomers. Intravenous administration of ß-asarone (2.22 mg/kg) and α-asarone (2.36 mg/kg) in rats yielded half-lives of 13.40 ± 4.11 and 28.88 ± 7.82 min with clearance values of 0.196 ± 0.062 mL/min/kg and 0.112 ± 0.012 mL/min/kg for ß-asarone and α-asarone, respectively.

Intranasal delivery of α-asarone to the brain with lactoferrin-modified mPEG-PLA nanoparticles prepared by premix membrane emulsification.

Alpha-asarone is a bioactive component of Acorus tatarincuii Schott with low bioavailability, which is often used for treatments of various brain diseases in clinical setting. This study was to formulate biodegradable methoxy polyethylene glycol-polylactic acid (mPEG-PLA) nanoparticles (NPs) surface-modified by lactoferrin (Lf), for delivering α-asarone into the brain following intranasal administration. Alpha-asarone NPs were prepared by premix membrane emulsification. The relative parameters were optimized by a Box-Behnken experimental design. The particle size, zeta potential, and dispersibility index of NPs and Lf-NPs were characterized. Their ex vivo permeation, pharmacokinetics, distribution in the brain and other tissue, brain targeting, and toxicity were investigated. Following intranasal administration, Lf-NPs had a better permeability and no significant poor bioavailability compared to NPs; the area under curve from 0 to 12 h of α-asarone in Lf-NPs of the olfactory bulb, hippocampus, olfactory bundles, and thalamus were 2.14-, 4.17-, 3.62-, and 1.96-fold of those in NP group, respectively. Lactoferrin could enhance the efficacy of brain targeting with NPs and reduce its liver accumulation. Toxicity of NPs on nasal mucosal cilia and epithelial cells was also decreased by Lf. To summarize, these results demonstrate that Lf-NPs of α-asarone have potential as a carrier for nose-to-brain delivery of α-asarone for brain diseases.

[Pharmacokinetics of α-asarone after intranasal and intravenous administration with PLA-α-asarone nanoparticles].

PLA-α-asarone nanoparticles were prepared by using organic solvent evaporation method, and their in vivo distribution and brain targeting after intranasal administration were studied as compared with intravenous administration. The results showed that brain targeting coefficient of PLA-α-asarone nanoparticles after intranasal and intravenous administration was 1.65 and 1.16 respectively. The absolute bioavailability, brain-targeting efficiency and the percentage of nasal-brain delivery of PLA-α-asarone nanoparticles were 74.2%, 142.24 and 29.83%, respectively after intranasal administration. The results of fluorescence labeling showed that the fluorescent intensity of coumarin-6 in the brain tissue was the highest after intranasal administration of PLA-α-asarone fluorescent nanoparticles, achieving the purpose of brain-targeted drug delivery. The fluorescent intensity of coumarin-6 in liver tissue after intravenous administration of PLA-α-asarone nanoparticles was much higher than that after intranasal administration, indicating that intranasal administration of PLA-α-asarone nanoparticles could decrease drug-induced hepatotoxicity. In addition, the fluorescent intensity of coumarin-6 in lung tissue was weaker after intranasal administration, which solved the shortcomings of intranasal administration of α-asarone dry powder prepared by airflow pulverization method. In vivo studies indicated that PLA-α-asarone nanoparticles after intranasal administration had a stronger brain targeting as compared with intravenous administration.

From in vitro to in vivo: Integration of the virtual cell based assay with physiologically based kinetic modelling.

Physiologically based kinetic (PBK) models and the virtual cell based assay can be linked to form so called physiologically based dynamic (PBD) models. This study illustrates the development and application of a PBK model for prediction of estragole-induced DNA adduct formation and hepatotoxicity in humans. To address the hepatotoxicity, HepaRG cells were used as a surrogate for liver cells, with cell viability being used as the in vitro toxicological endpoint. Information on DNA adduct formation was taken from the literature. Since estragole induced cell damage is not directly caused by the parent compound, but by a reactive metabolite, information on the metabolic pathway was incorporated into the model. In addition, a user-friendly tool was developed by implementing the PBK/D model into a KNIME workflow. This workflow can be used to perform in vitro to in vivo extrapolation and forward as backward dosimetry in support of chemical risk assessment.

Pharmacology and toxicology of α- and ß-Asarone: A review of preclinical evidence.

BACKGROUND: Asarone is one of the most researched phytochemicals and is mainly present in the Acorus species and Guatteria gaumeri Greenman. In preclinical studies, both α- and ß-asarone have been reported to have numerous pharmacological activities and at the same time, many studies have also revealed the toxicity of α- and ß-asarone. PURPOSE: The purpose of this comprehensive review is to compile and analyze the information related to the pharmacokinetic, pharmacological, and toxicological studies reported on α- and ß-asarone using preclinical in vitro and in vivo models. Besides, the molecular targets and mechanism(s) involved in the biological activities of α- and ß-asarone were discussed. METHODS: Databases including PubMed, ScienceDirect and Google scholar were searched and the literature from the year 1960 to January 2017 was retrieved using keywords such as α-asarone, ß-asarone, pharmacokinetics, toxicology, pharmacological activities (e.g. depression, anxiety). RESULTS: Based on the data obtained from the literature search, the pharmacokinetic studies of α- and ß-asarone revealed that their oral bioavailability in rodents is poor with a short plasma half-life. Moreover, the metabolism of α- and ß-asarone occurs mainly through cytochrome-P450 pathways. Besides, both α- and/or ß-asarone possess a wide range of pharmacological activities such as antidepressant, antianxiety, anti-Alzheimer's, anti-Parkinson's, antiepileptic, anticancer, antihyperlipidemic, antithrombotic, anticholestatic and radioprotective activities through its interaction with multiple molecular targets. Importantly, the toxicological studies revealed that both α- and ß-asarone can cause hepatomas and might possess mutagenicity, genotoxicity, and teratogenicity. CONCLUSIONS: Taken together, further preclinical studies are required to confirm the pharmacological properties of α-asarone against depression, anxiety, Parkinson's disease, psychosis, drug dependence, pain, inflammation, cholestasis and thrombosis. Besides, the anticancer effect of ß-asarone should be further studied in different types of cancers using in vivo models. Moreover, further dose-dependent in vivo studies are required to confirm the toxicity of α- and ß-asarone. Overall, this extensive review provides a detailed information on the preclinical pharmacological and toxicological activities of α-and ß-asarone and this could be very useful for researchers who wish to conduct further preclinical studies using α- and ß-asarone.

Study on inter-ethnic human differences in bioactivation and detoxification of estragole using physiologically based kinetic modeling.

Considering the rapid developments in food safety in the past decade in China, it is of importance to obtain insight into what extent safety and risk assessments of chemicals performed for the Caucasian population apply to the Chinese population. The aim of the present study was to determine physiologically based kinetic (PBK) modeling-based predictions for differences between Chinese and Caucasians in terms of metabolic bioactivation and detoxification of the food-borne genotoxic carcinogen estragole. The PBK models were defined based on kinetic constants for hepatic metabolism derived from in vitro incubations using liver fractions of the two ethnic groups, and used to evaluate the inter-ethnic differences in metabolic activation and detoxification of estragole. The models predicted that at realistic dietary intake levels, only 0.02% of the dose was converted to the ultimate carcinogenic metabolite 1'-sulfooxyestragole in Chinese subjects, whereas this amounted to 0.09% of the dose in Caucasian subjects. Detoxification of 1'-hydroxyestragole, mainly via conversion to 1'-oxoestragole, was similar within the two ethnic groups. The 4.5-fold variation in formation of the ultimate carcinogenic metabolite of estragole accompanied by similar rates of detoxification may indicate a lower risk of estragole for the Chinese population at similar levels of exposure. The study provides a proof of principle for how PBK modeling can identify differences in ethnic sensitivity and provide a more refined risk assessment for a specific ethnic group for a compound of concern.

ß-Asarone Rescues Pb-Induced Impairments of Spatial Memory and Synaptogenesis in Rats.

Chronic lead (Pb) exposure causes cognitive deficits. This study aimed to explore the neuroprotective effect and mechanism of ß-asarone, an active component from Chinese Herbs Acorus tatarinowii Schott, to alleviate impairments of spatial memory and synaptogenesis in Pb-exposed rats. Both Sprague-Dawley developmental rat pups and adult rats were used in the study. Developmental rat pups were exposed to Pb throughout the lactation period and ß-asarone (10, 40mg kg-1, respectively) was given intraperitoneally from postnatal day 14 to 21. Also, the adult rats were exposed to Pb from embryo stage to 11 weeks old and ß-asarone (2.5, 10, 40mg kg-1, respectively) was given from 9 to 11 weeks old. The level of ß-asarone in brain tissue was measured by High Performance Liquid Chromatography. The Morris water maze test and Golgi-Cox staining method were used to assess spatial memory ability and synaptogenesis. The protein expression of NR2B subunit of NMDA receptor, Activity-regulated cytoskeleton-associated protein (Arc/Arg3.1) and Wnt family member 7A (Wnt7a) in hippocampus, as well as mRNA expression of Arc/Arg3.1 and Wnt7a, was also explored. We found that ß-asarone could pass through the blood brain barrier quickly. And ß-asarone effectively attenuated Pb-induced reduction of spine density in hippocampal CA1 and dentate gyrus areas in a dose-dependent manner both in developmental and adult rats, meanwhile the Pb-induced impairments of learning and memory were partially rescued. In addition, ß-asarone effectively up-regulated the protein expression of NR2B, Arc and Wnt7a, as well as the mRNA levels of Arc/Arg3.1 and Wnt7a, which had been suppressed by Pb exposure. The results suggest the neuroprotective properties of ß-asarone against Pb-induced memory impairments, and the effect is possibly through the regulation of synaptogenesis, which is mediated via Arc/Arg3.1 and Wnt pathway.

Anethole and Its Role in Chronic Diseases.

Anethole is the main fragrance and bioactive compound of anise, fennel, and star anise spices and more than other 20 plant species. It is widely used as flavor agent in food industry and other industries, in cosmetics, perfumery, and pharmaceuticals. In the last few years, various studies have revealed multiple beneficial effects of anethole for human health, such as anti-inflammatory, anticarcinogenic and chemopreventive, antidiabetic, immunomodulatory, neuroprotective, or antithrombotic, that are mediated by the modulation of several cell signaling pathways, mainly NF-kB and TNF-α signaling, and various ion channels. This chapter aims to review the scientific data and attempts to provide an insight into pharmacological activity of anethole and its therapeutic potential in human chronic diseases.

Preparation of drug-in-cyclodextrin-in-liposomes at a large scale using a membrane contactor: Application to trans-anethole.

The present study aimed to prepare liposomes loaded with cyclodextrin/drug inclusion complexes at a pilot scale based on the ethanol injection technique. Anethole (ANE), a major component of anise and fennel essential oils, was used as a model of a volatile and highly hydrophobic drug. Membrane contactor (600mL) and a pilot plant (3L) were used for liposome production. The liposome preparations obtained were characterized for size, polydispersity index, zeta potential, morphology, stability and ANE release rate. All experimental set-ups were shown to be appropriate for the preparation of small, multilamellar vesicles with narrow size distribution and good stability at 4°C. The drug release study showed that only a small amount of ANE was released from liposome formulations after 21days of storage at 4°C. The loading rate of ANE was higher when ethanol was evaporated directly on the pilot plant compared to a rotary evaporation.