Transferrin-Bearing, Zein-Based Hybrid Lipid Nanoparticles for Drug and Gene Delivery to Prostate Cancer Cells.

Gene therapy holds great promise for treating prostate cancer unresponsive to conventional therapies. However, the lack of delivery systems that can transport therapeutic DNA and drugs while targeting tumors without harming healthy tissues presents a significant challenge. This study aimed to explore the potential of novel hybrid lipid nanoparticles, composed of biocompatible zein and conjugated to the cancer-targeting ligand transferrin. These nanoparticles were designed to entrap the anti-cancer drug docetaxel and carry plasmid DNA, with the objective of improving the delivery of therapeutic payloads to prostate cancer cells, thereby enhancing their anti-proliferative efficacy and gene expression levels. These transferrin-bearing, zein-based hybrid lipid nanoparticles efficiently entrapped docetaxel, leading to increased uptake by PC-3 and LNCaP cancer cells and significantly enhancing anti-proliferative efficacy at docetaxel concentrations exceeding 1 µg/mL. Furthermore, they demonstrated proficient DNA condensation, exceeding 80% at polymer-DNA weight ratios of 1500:1 and 2000:1. This resulted in increased gene expression across all tested cell lines, with the highest transfection levels up to 11-fold higher than those observed with controls, in LNCaP cells. These novel transferrin-bearing, zein-based hybrid lipid nanoparticles therefore exhibit promising potential as drug and gene delivery systems for prostate cancer therapy.

Alpha-Mangostin-Loaded Transferrin-Conjugated Lipid-Polymer Hybrid Nanoparticles: Development and Characterization for Tumor-Targeted Delivery.

Alpha-mangostin, a natural xanthone mainly extracted from the pericarp of Garcinia mangostana, has been shown to have promising anticancer properties in many types of cancer. However, the therapeutic potential of α-mangostin has been limited so far due to its poor aqueous solubility and low oral bioavailability, which limited its biopharmaceutical applications. Furthermore, α-mangostin failed to specifically reach tumors at a therapeutic concentration due and rapid elimination in vivo. We hypothesized that this drawback could be overcome by loading the drug within a delivery system conjugated to transferrin (Tf), whose receptors are overexpressed on many cancer cells and would enhance the specific delivery of α-mangostin to cancer cells, thereby enhancing its therapeutic efficacy. The objectives of this study were therefore to prepare and characterize transferrin-conjugated lipid-polymer hybrid nanoparticles (LPHN) entrapping α-mangostin, as well as to evaluate their therapeutic efficacy in vitro. We successfully prepared α-mangostin loaded LPHN using a one-step nanoprecipitation method with high drug entrapment efficiency. The conjugation of Tf to the LPHN was achieved by using the thiol-maleimide "click" reaction, leading to an increase in the particle hydrodynamic size of Tf-LPHN compared to that of unconjugated (control) LPHN (Ctrl-LPHN). Both Tf-LPHN and Ctrl-LPHN were bearing negative surface charges. Tf-LPHN and Ctrl-LPHN exhibited a sustained release of α-mangostin at pH 7.4, following an initial burst release, unlike rapid release of drug solution. The entrapment of α-mangostin in the LPHN led to an increase in α-mangostin uptake by cancer cells, and thus improved its antiproliferative activity compared to that observed with the drug solution. In conclusion, α-mangostin entrapped in the Tf-LPHN is therefore a highly promising therapeutic system that should be further optimized as therapeutic tools for cancer treatment.

The effects of Benjakul extract and its isolated compounds on cell cycle arrest and apoptosis in human non-small cell lung cancer cell line NCI-H226.

BACKGROUND AND PURPOSE: Benjakul, a traditional Thai formulation for cancer treatment, is composed of five plants. This study aimed to assess the cytotoxicity of Benjakul, its five plants, and its isolated compounds against non-small cell lung cancer (NSCLC) by the sulforhodamine B (SRB) assay. EXPERIMENTAL APPROACH: Analyses of cell cycle and membrane asymmetry changes were performed with different fluorescent dyes and analyzed by flow cytometry in NCI-H226 cells. Activation of caspase-3 was measured using a caspase-3 colorimetric assay kit. The pan-caspase inhibitor Z-VAD-FMK was used in analyses of cell cycle and caspase-3 activity. FINDINGS/RESULTS: Benjakul exhibited cytotoxicity against NSCLC with IC50 between 5.56-5.64 µg/mL. Among its five ingredients, Benjakul displayed the highest selectivity with selectivity index values ranging from 2.93 to 6.88, with the exception of Plumbago indica, indicating its protective effects. Plumbagin and 6- shogaol displayed the highest cytotoxicity and underwent molecular studies in NCI-H226 cells. Flow cytometry analysis revealed that Benjakul and 6-shogaol dose-dependently induced G2/M phase arrest, and plumbagin dose-dependently induced S-G2/M phase arrest with the highest percentage in early incubation time (12-24 h). At the highest doses, Benjakul extract, 6-shogaol, and plumbagin time-dependently increased the population of sub-G1 apoptotic cells with the highest percentage in longer incubation time (60-72 h). Similarly, membrane asymmetry changes showed time-dependent increases in the percentage of early and late apoptotic cells. Moreover, the apoptosis-inducing effect of Benjakul, 6-shogaol, and plumbagin at the highest dose, via the caspase cascade was confirmed by time-dependent induction of caspase-3 activity, followed by its complete reduction and abolished sub-G1 peaks upon addition of Z-VAD-FMK. CONCLUSION AND IMPLICATION: Our findings demonstrated for the first time the effects of Benjakul and its compounds on S-G2/M or G2/M phase arrest and caspase-dependent apoptosis in lung cancer cells.

Regression of Melanoma Following Intravenous Injection of Plumbagin Entrapped in Transferrin-Conjugated, Lipid-Polymer Hybrid Nanoparticles.

BACKGROUND: Plumbagin, a naphthoquinone extracted from the officinal leadwort presenting promising anti-cancer properties, has its therapeutic potential limited by its inability to reach tumors in a specific way at a therapeutic concentration following systemic injection. The purpose of this study is to assess whether a novel tumor-targeted, lipid-polymer hybrid nanoparticle formulation of plumbagin would suppress the growth of B16-F10 melanoma in vitro and in vivo. METHODS: Novel lipid-polymer hybrid nanoparticles entrapping plumbagin and conjugated with transferrin, whose receptors are present in abundance on many cancer cells, have been developed. Their cellular uptake, anti-proliferative and apoptosis efficacy were assessed on various cancer cell lines in vitro. Their therapeutic efficacy was evaluated in vivo after tail vein injection to mice bearing B16-F10 melanoma tumors. RESULTS: The transferrin-bearing lipid-polymer hybrid nanoparticles loaded with plumbagin resulted in the disappearance of 40% of B16-F10 tumors and regression of 10% of the tumors following intravenous administration. They were well tolerated by the mice. CONCLUSION: These therapeutic effects, therefore, make transferrin-bearing lipid-polymer hybrid nanoparticles entrapping plumbagin a highly promising anti-cancer nanomedicine.

Bactericidal Effect and Anti-Inflammatory Activity of Cassia garettiana Heartwood Extract.

Natural products are used as alternative drugs in traditional medicine to treat infection and inflammation and relieve pain. Heartwood of Cassia garettiana Craib has been investigated as an ingredient in Thai traditional medicine for anti-HIV protease, but there is no report on its antibacterial and anti-inflammatory activities. The objectives of this study were to investigate the anti-inflammatory and antibacterial activities, time-kill profile, and main active constituents of an ethanolic extract of C. garettiana heartwood. The study followed the generally accepted experimental design. All tests were investigated in triplicate. The heartwood of C. garettiana was extracted by maceration with 95% EtOH. The antibacterial activity of the extract and its chemical constituents were determined by their MIC values using resazurin as an indicator. Time-kill profile was determined at 0, 2, 4, 6, 8, 10, 12, and 24 hrs and expressed as log CFU/mL. The anti-inflammatory activity of the extract and its chemical components was investigated by their inhibiting effect on IL-6 and TNF-α production by ELISA. The ethanolic extract was analyzed for its chemical constituents by HPLC technique. The ethanolic extract showed both dose- and time-dependent bactericidal effects against Staphylococcus aureus, methicillin-resistance Staphylococcus aureus, Staphylococcus epidermidis, Escherichia coli, Pseudomonas aeruginosa, Salmonella Typhi, Salmonella Typhimurium, Klebsiella pneumoniae, and Shigella dysenteriae with MIC values of 312.5, 312.5, 312.5, 1,250, 2,500, 625, 625, 2,500, and 625 µg/mL, respectively. It showed an inhibiting effect on IL-6 production at concentrations of 12.5 to 100 µg/mL. The main active chemical constituent of C. garettiana was piceatannol that showed antibacterial activity against all test bacteria except P. aeruginosa. C. garettiana showed a broad spectrum of antibacterial activity against both Gram-negative and Gram-positive bacteria. Piceatannol and resveratrol from the plant strongly inhibited IL-6 production. Based on these results, we concluded that the ethanolic extract of C. garettiana showed both an antibacterial activity and inhibition of IL-6. Piceatannol is the active constituent of the extract and showed anti-inflammatory and antibacterial activities against Gram-negative and Gram-positive bacteria.

Anti-Tumor Activity of Intravenously Administered Plumbagin Entrapped in Targeted Nanoparticles.

Plumbagin, a natural naphthoquinone from the officinal leadwort, has recently been shown to exert promising anti-cancer effects. However, its therapeutic use is hampered by its failure to specifically reach tumors after intravenous administration, without secondary effects on normal tissues. Its poor solubility in water and rapid elimination following in vivo administration further limit its potential use. We hypothesize that the entrapment of plumbagin within PEGylated PLGA nanoparticles conjugated with transferrin, whose receptors are overexpressed on many types of cancer cells, could lead to a selective delivery of the drug to tumors following intravenous administration and enhance its chemotherapeutic effects. The objectives of this study were therefore to prepare and characterize transferrin-conjugated, PEGylated PLGA nanoparticles entrapping plumbagin, and to assess their anti-cancer efficacy in vitro as well as in tumor-bearing mice. The intravenous administration of transferrin-conjugated PEGylated PLGA nanoparticles resulted in the complete suppression of 10% of B16-F10 tumors and regression of 30% of the tumors, with improvement of the animal survival compared to controls. The treatment was well tolerated by the animals. Transferrin-bearing PEGylated PLGA nanoparticles entrapping plumbagin are therefore highly promising therapeutic systems, able to lead to tumor regression and even suppression after intravenous administration without visible toxicity.

Development of transferrin-bearing vesicles encapsulating aspirin for cancer therapy.

Originally developed for the treatment of inflammatory disorders, the non-steroidal anti-inflammatory drug aspirin was shown to have a preventive effect against cancer in the past decades. Most importantly, recent studies suggested that it might also provide a therapeutic benefit in the treatment of cancer in vitro. However, this drug failed to specifically reach tumors at a therapeutic concentration following intravenous administration, thus resulting in lack of efficacy on tumors. In this work, we demonstrated that aspirin could be formulated in transferrin-bearing vesicles and that this tumor-targeted formulation could lead to an increase in the anti-proliferative efficacy of the drug in three cancer cell lines in vitro. The in vitro therapeutic efficacy of aspirin was significantly improved when formulated in transferrin-bearing vesicles, by about 2-fold compared to that of drug solution. These results are promising and support the optimization of this delivery system to further improve its potential as a therapeutic tool in combination with other anti-cancer therapies.

Transferrin-bearing liposomes entrapping plumbagin for targeted cancer therapy.

The therapeutic potential of plumbagin, a naphthoquinone extracted from the officinal leadwort with anticancer properties, is hampered by its failure to specifically reach tumours at a therapeutic concentration after intravenous administration, without secondary effects on normal tissues. Its use in clinic is further limited by its poor aqueous solubility, its spontaneous sublimation, and its rapid elimination in vivo. We hypothesize that the entrapment of plumbagin within liposomes grafted with transferrin, whose receptors are overexpressed on many cancer cells, could result in a selective delivery to tumours after intravenous administration. The objectives of this study were therefore to prepare and characterize transferrin-targeted liposomes entrapping plumbagin and to evaluate their therapeutic efficacy in vitro and in vivo. The entrapment of plumbagin in transferrin-bearing liposomes led to an increase in plumbagin uptake by cancer cells and improved antiproliferative efficacy and apoptosis activity in B16-F10, A431, and T98G cell lines compared with that observed with the drug solution. In vivo, the intravenous injection of transferrin-bearing liposomes entrapping plumbagin led to tumour suppression for 10% of B16-F10 tumours and tumour regression for a further 10% of the tumours. By contrast, all the tumours treated with plumbagin solution or left untreated were progressive. The animals did not show any signs of toxicity. Transferrin-bearing liposomes entrapping plumbagin are therefore highly promising therapeutic systems that should be further optimized as a therapeutic tool for cancer treatment.

Synergistic Genotoxic Effects and Modulation of Cell Cycle by Ginger Ethanolic Extracts in Adjunct to Doxorubicin in Human Lymphocytes In Vitro.

BACKGROUND: Several natural phytochemicals are increasingly used, as an adjunct to chemotherapy, to reduce drug adverse effects. Zingiber officinale rhizome (ginger) product has been reported to be effective against nausea and vomiting in patients receiving emetogenic chemotherapy such as cisplatin/doxorubicin (DXR). In addition, its ethanolic extract of Zingiber officinale rhizome (EEZOR) has been reported to possess anticarcinogenic properties. However, the mechanism for anticancer activity of ginger especially when used in combination with chemotherapy has not well elucidated, one of its possible mechanisms might involve its genotoxicity. OBJECTIVE: To investigate genotoxic and cytotoxic potentials of EEZOR alone and EEZOR pretreatments followed by 0.1 mcg/ ml DXR, a genotoxic chemotherapeutic agent in human lymphocytes by sister chromatid exchange (SCE) assay in vitro. The effect on cell cycle kinetics was also explored. MATERIAL AND METHOD: Human lymphocytes were treated with EEZOR alone at 25-500 mcg/ml and EEZOR pretreated at 12.5-200 mcg/ml followed by 0.1 mcg/ml DXR. SCE levels and cell cycle kinetics were evaluated. RESULTS: EEZOR significantly induced biphasic SCE at 50 and 400 mcg/ml (p < 0.05). However, cytotoxicity manifested at 500 mcg/ml. All EEZOR pretreatments at 12.5, 25, 50, and 100 mcg/ml, except at 200 mcg/ml, prior to DXR, moderately enhanced DXR-induced genotoxicity by 1.3 times (p < 0.05). Both EEZOR alone and EEZOR prior to DXR at certain concentrations delayed cell cycle. CONCLUSION: At specific doses, EEZOR could induce genotoxicity and in pretreatments could moderately enhance DXR-induced genotoxicity and delay cell cycle. This finding suggests that dosage use of EEZOR needs to be adjusted for long-term safety. In addition, EEZOR in adjunct to DXM might have potential benefits not only as an emetic agent but also in chemotherapy. Further in vivo animal and human studies to support this evidence is essentially needed.

In vitro enhancement of doxorubicin genotoxic activities and interference with cell cycle delay by Plumbago indica root ethanolic extract in human lymphocytes.

BACKGROUND: Combinations of modern medicines with herbal medicines are being developedfor more effectiveness. Data on the safety and drug-herb interactions are needed to be clarified. Ethanolic extract of Plumbago indica root (EEPIR) is medicinally usedfor cancer treatment in Asian traditional medicine. However its mechanism of action is still inconclusive. Our previous study demonstrated that EEPIR was genotoxic and induced cell cycle delay in human lymphocytes in vitro. OBJECTIVE: To investigate genotoxic potency and interference with cell cycle of EEPIR in combination with doxorubicin (DXR), a standard chemotherapeutic agent, in human lymphocytes by in vitro sister chromatid exchange (SCE) assay. MATERIAL AND METHOD: Human lymphocytes were pretreated with EEPIR at 6.25-100 mcg/mlfollowed by DXR (0.1 mcg/ml). SCE levels and cell cycle kinetics were evaluated. RESULTS: EEPIR pretreatments (6.5-50 mcg/ml) significantly enhanced genetic damage induced by DXR (p<0. 05). Delaying of the cell cycle was detected and related to EEPIR concentration. EEPIR at 100 mcg/ml, on the contrary, did not enhance DXR-induced genotoxicity but tended to lower genotoxicity compared to DXR treatment alone. It significantly delayed cell cycle the most (p<0.05). CONCLUSION: EEPIR pretreatments at proper doses enhanced genotoxic damage induced by DXR in human lymphocytes. Delaying cell cycle by EEPIR could lower that potency. Usage of EEPIR, therefore, should be adjusted for safety. Combination of EEPIR with DXR might be usefulfor more efficient cancer treatment with less DXR toxicity. Further in vivo study is needed to support this in vitro evidence.

Cytotoxic activity against small cell lung cancer cell line and chromatographic fingerprinting of six isolated compounds from the ethanolic extract of Benjakul.

BACKGROUND: Benjakul, a Thai traditional herbal preparation, comnprises five plants: Piper chaba, Piper sarmentosum, Piper interruptum, Plumbago indica, and Zingiber officinale. It has widely been used to treat cancer patients in folk medicine in Thailand. Benjakul extract, and its isolated compounds should be investigated for cytotoxic activity and analysis isolated compounds from chemical fingerprinting. OBJECTIVE: To study cytotoxicity ofBenjakul extract and its isolatedpure compounds against human small cell lung cancer cell line (NCI-HI 688) and in normal human lungfibroblast cell line (MRC-5) and analysis the content ofisolated compounds for quality control of Benjakul extract. MATERIAL AND METHOD: Bioassay-guided fractionation was used for isolated active compounds from ethanolic extract of Benjakul. Cytotoxic activity was carried using the SRB assay. HPLC method was applied to analyze six isolated compound contentfrom Benjakul extract. RESULTS: The ethanolic extract ofBenjakul showed cytotoxicity against NCI-H1688 with IC50 value = 36.15±4.35 µg/ml. Hexane fraction as semi-separation by VLC showed the best cytotoxic activity (21.1 7±7.42 µg/ml). Six isolated compounds were identified as myristicin, plumbagin, methyl piperate, 6-shogaol, 6-gingerol and piperine. Plumbagin exhibited the highest cytotoxic activity and 6-shogaol was the second most effective cytotoxic constituent (IC50 values = 1.41±0.01 and 6.45±0.19 µg/ml, respectively). Piperine showed the highest content in both ofHPLC analysis and column chromatography separation. CONCLUSION: Benjakul extract exhibited cytotoxicity against NCI-HI 688. Plumbagin and 6-shogaol are bioactive markers for cytotoxicity against this small cell lung cancer cell line. Chromatographic fingerprinting can be used to analyze six cytotoxic compounds isolatedfrom the ethanolic extract ofBenjakul.

Development and validation of RP-HPLC method to determine anti-allergic compound in Thai traditional remedy called Benjalokawichien.

Benjalokawichien (BLW) or Ya-Ha-Rak (HR) is a traditional remedy in the Nationaldrug list of herbal medicinal products AD 2012 of Thailand. For traditional use, BLW is used as antipyretic agent. It also has anti-allergic effect, particularly treating allergic rash. The ethanolic extract of BLW exhibited anti-allergic activity via inhibitory effect against a release ofbeta-hexosaminidase in RBL-2H3 cell line. Pectolinarigenin has been identified as the active compound ofBLW extract. In this study, a reversed-phase high performance liquid chromatography (RP-HPLC) method was developed in order to control quality ofpreparation in three aspects such as chemical fingerprint, quantification and stability of the ethanolic extract. The RP-HPLC was performed with a gradient mobile phase composed of 0.1% ortho phosphoric acid and acetronitrile, and peaks were detected at 331 nm. Based on validation results, this analytical method is precise, accurate and stable for quantitative determination ofpectolinarigenin. The amount ofpectolinarigenin in Benjalokawichien extract determined by this method was 18.50 mg/g ofextract. Therefore, this method could be consideredfor quality control ofBLWextract.

Biological activities and chemical content of Sung Yod rice bran oil extracted by expression and soxhlet extraction methods.

BACKGROUND: Sung Yod rice is a red-violet pigmented rice and grown in the southern part of Thailand. Its rice bran oil has attracted the attention ofscientists who have described anti-oxidant properties ofsome ingredients in Sung Yod rice bran oil. Normally, extraction methods ofcommercial product from rice bran oil are by expression or soxhlet extraction with hexane. Thus, biological activities of Sung Yod rice bran oil related to health and chemical content ofrice bran oilfrom the two methods should be studied. OBJECTIVE: The objectives of this research were to investigate for biological activities and chemical content ofSung Yod rice bran oil obtainedfrom expression or soxhlet extraction method. MATERIAL AND METHOD: Biological activities such as cytotoxic, anti-inflammatory and antioxidant activities were investigated. Sulphorhodamine (SRB) assay was used to test cytotoxic activity against four human cancer cell lines: lung (COR-L23), cervical (HeLa), prostate (PC-3) and breast (MCF-7) and normal human lung cells (MRC-5). The inhibitory effect on lipopolysaccharide (LPS) induced nitric oxide (NO) production in RA W264. 7 cell lines was usedfor the determination of anti-inflammatory effect. DPPH, TEAC and FRAP assay were carried outfor antioxidant activity. Total phenolic compound was determined by Folin-Ciocalteu reagent. y-oryzanol and vitamin E content were determined by HPLC. Sung Yod rice bran oil was produced by expression method (EX) or by soxhlet extraction method using hexane (SXH-I). RESULTS: The percentage ofyield ofSung Yod rice bran oil by EX and SXH were 2.16 and 15.23 %w/w, respectively. Only EX showed the selective cytotoxicity against prostate cancer cells (PC-3), (IC50 = 52.06±1.60 µg/ml). It also exhibited high inhibitory effects on NO production (IC50 = 30.09 µg/ml). In contrast, SXH had no anti-inflammatory effect and cytotoxic activity against any of the cancer cells. EXshowed higher antioxidant activity determined using DPPH compared to SXH. It also showed higher amount of yoryzanol and vitamin E than that ofSXH (3.09±1.04 and 1.35±1.56 mg % w/w ofextracts, respectively). Yet, SXH exhibited higher antioxidant power determined by FRAP assay and higher total phenolic content compared with EX CONCLUSION: Sung Yod rice bran oil, produced by expression method, had better benefit for health regarding cytotoxicity against prostate cancer cells (PC-3), anti-inflammatory effect and antioxidant (using DPPH) than that produced by soxhlet method extracted with hexane.

Genotoxicity and interference with cell cycle activities by an ethanolic extract from Thai Plumbago indica roots in human lymphocytes in vitro.

In Thai traditional medicine, Plumbago indica or Jetamul-Pleung-Dang in Thai is known to have health benefit especially for anti-inflammatory, antibacterial, and antitumor activities. However, the mechanisms of its action are still uncertain. One of which might be genotoxic effects. In the present study, we investigated the genotoxicity of an ethanolic extract of Plumbago indica root (EEPIR) by sister chromatid exchange (SCE) assay in human lymphocytes. Results have shown that all treatments with EEPIR (12.5-100 µg/ml) could induce cell cycle delay as shown by significant increase in the number of metaphase cells in the first cell cycle but neither in the second nor the third cell cycle. Only at concentrations of 25, 50, and 100 µg/ml were SCE levels significantly increased above that of the control (p<0.05) . EEPIR at a concentration of 500 µg/ml induced cell death as few mitotic cells were shown. Accordingly, EEPIR (25-100 µg/ml) is genotoxic in human lymphocytes and cytotoxic at concentrations of ≥ 500 µg/ml in vitro. Therefore, these activities of the EEPIR could serve its potential therapeutic effects, especially as an anticancer agent. Further study of EEPIR in vivo is now needed to support this in vitro evidence.

In vitro cytotoxic activity of Benjakul herbal preparation and its active compounds against human lung, cervical and liver cancer cells.

BACKGROUND: Benjakul [BEN], a Thai Traditional medicine preparation, is composed of five plants: Piper chaba fruit [PC], Piper sarmentosum root [PS], Piper interruptum stem [PI], Plumbago indica root [PL] and Zingiber officinale rhizome [ZO]. From selective interviews of folk doctors in Southern Thailand, it was found that Benjakul has been used for cancer patients. OBJECTIVE: To investigate cytotoxicity activity of Benjakul preparation [BEN] and its ingredients against three human cancer cell lines, large lung carcinoma cell line (COR-L23), cervical cancer cell line (Hela) liver cancer cell line (HepG2) as compared with normal lungfibroblast cell (MRC-5) by using SRB assay. MATERIAL AND METHOD: The extraction as imitated the method used by folk doctors was done by maceration in ethanol and boiling in water Bioassay guided isolation was used isolated cytotoxic compound. RESULTS: The ethanolic extracts of PL, ZO, PC, PS, BEN and PS showed specific activity against lung cancer cell (IC50 = 3.4, 7.9, 15.8, 18.4, 19.8 and 32.91 microg/ml) but all the water extracts had no cytotoxic activity. Three active ingredients [6-gingerol, plumbagin and piperine as 0.54, 4.18 and 7.48% w/w yield of crude extract respectively] were isolated from the ethanolic extract of BEN and they also showed cytotoxic activity with plumbagin showing the highest cytotoxic activity against COR-L23, HepG2, Hela and MRC-5 (IC50 = 2.55, 2.61, 4.16 and 11.54 microM respectively). CONCLUSION: These data results may support the Thai traditional doctors who are using Benjakul to treat cancer patients and three of its constituents (6-gingerol, plumbagin and piperine) are suggested to be used as biomarkers for standardization of this preparation.

Using 6-gingerol content and gene mapping for identification of two types of ginger used in Thai traditional medicine.

BACKGROUND: Two species of ginger were used in Thai traditional medicine as Zingiber officinale Roscoe and Zingiber ligulatum Roxb. OBJECTIVE: To investigate for identification two types of ginger by morphological and microscopic characters, DNA profiles, and determination of 6-gingerol content by HPLC. MATERIAL AND METHOD: Fresh rhizomes of two gingers, their ages more than one year were collected from 12 sources in 4 parts of Thailand. The fresh leaves were also collected for studying DNA profile by amplified fragment length polymorphism (AFLP) method. RESULTS: The morphological characters of two types of gingers were almost corresponded to AFLP patterns and they were identified as Z officinale Rocs. and Z. ligulatum Roxb. Microscopic examinations of dried rhizomes from the both species showed the same pattern. By means of HPLC and TLC methods, 6-gingerol content was found only in Z. officanale in range of 2.58-17.04% but disappeared in Z. ligulatum. CONCLUSION: Determination of 6-gingerol content by HPLC or TLC pattern can be used to identified two types of ginger used in Thai Traditional Medicine.

Determination of cytotoxic compounds of Thai traditional medicine called Benjakul using HPLC.

Benjakul is a Thai traditional medicine preparation, used for balanced health. From selective interviews of folk doctors in southern Thailand, it was used as the adaptogen drug for cancer patients. In our previous study, the ethanolic extract of Benjakul preparation exhibited high cytotoxic activity against lung cancer cell lines (COR-L23). Piperine has been identified as the main compound in the extract. In addition, plumbagin was found as the most cytotoxic compound. In this study, a reversed-phase high performance liquid chromatography (HPLC) method for quality control such as chemical fingerprint, quantification and stability of the ethanolic extract of Benjakul preparation was developed. The reversed-phase HPLC was performed with a gradient mobile phase composed of water and acetronitrile, and peaks were detected at 256 nm. Based on validation results, this analytical method is precise, accurate and stable for quantitative determination of piperine and plumbagin which are cytotoxic compounds isolated from the ethanolic extract of Benjakul preparation. This method could be suitable for analysis of Benjakul extract.