Micellar propolis nanoformulation of high antioxidant and hepatoprotective activity

Tzankova, Virginia; Aluani, Denitsa; Yordanov, Yordan; Kondeva-Burdina, Magdalena; Petrov, Petar; Bankova, Vassya; Simeonova, Rumiana; Vitcheva, Vessela; Odjakov, Feodor; Apostolov, Alexander; Tzankov, Borislav; Yoncheva, Krassimira

doi:10.1016/j.bjp.2018.12.006

ABSTRACT

The present study reports a promising antioxidant protection by a recently developed micellar propolis formulation, against oxidative stress in in vitro and in vivo models of toxicity. The formulation, based on poplar propolis encapsulated in poly(ethylene oxide)–β-poly(propylene oxide)–β-poly(ethylene oxide) triblock copolymer (PEO₂₆–PPO₄₀–PEO₂₆) micelles is characterized by small size (D _h = 20 nm), enhances aqueous solubility and good colloidal stability. In vitro, propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ micelles (20–100 µg/ml) significantly increased the cell viability of human hepatoma HepG2 cells, subjected to H₂O₂-induced cell injury (0.1 mM, 1 h). Antioxidant activity and protection of the micellar propolis were evaluated in a model of carbon tetrachloride-induced hepatotoxicity in rats (10% CCl₄ solution, 1.25 ml/kg, p.o.) by measurement of non-enzyme (malondialdehyde and glutathione) and enzyme (catalase and superoxide dismutase) biomarkers of oxidative stress. Clinic observations, hematological, biochemical parameters and histological analysis were also performed. In vivo, micellar propolis (20 mg/kg b.w., p.o., 14 days) ameliorated CCl₄-induced acute liver injury in rats. The oral administration of micellar propolis significantly prevented serum transaminase increases, as well as brought the levels of malondialdehyde, glutathione, and antioxidant enzymes catalase and superoxide dismutase toward the controls levels. Therefore, PEO₂₆–PPO₄₀–PEO₂₆ micelles could be considered as a promising oral delivery system of propolis against oxidative stress injury in liver cells.

Keywords:
Liver; Nanocarrier; Oxidative stress; Polymer micelles; Propolis

Introduction

Oxidative stress plays a crucial role in the pathology of different hepatic disorders such as inflammatory injury, liver cirrhosis, ischemia reperfusion impairment (Sumida et al., 2013Sumida, Y., Niki, E., Naito, Y., Yoshikawa, T., 2013. Involvement of free radicals and oxidative stress in NAFLD/NASH. Free Radic. Res. 47, 869-880.; Nita and Grzybowski, 2016Nita, M., Grzybowski, A., 2016. The role of the reactive oxygen species and oxidative stress in the pathomechanism of the age-related ocular diseases and other pathologies of the anterior and posterior Eye Segments in Adults. Oxid. Med. Cell. Longev., http://dx.doi.org/10.1155/2016/3164734.
http://dx.doi.org/10.1155/2016/3164734... ; Torok, 2016Torok, N.J., 2016. Dysregulation of redox pathways in liver fibrosis. Am. J. Physiol. Gastrointest. Liver Physiol. 311, G667-G674.). Therefore, the interest in protective effects of natural antioxidants against oxidative stress in liver is considerable. Recent studies showed a promising antioxidant activity of propolis (Pr) by the mechanisms of scavenging, neutralizing and removing the reactive species after oxidative stress induction (ROS), and by preventing lipid peroxidation (Mavri et al., 2012Mavri, A., Abramovič, H., Polak, T., Bertoncelj, J., Jamnik, P., Smole, S.M., Jeršek, B., 2012. Chemical properties and antioxidant and antimicrobial activities of Slovenian propolis. Chem. Biodivers. 9, 1545-1558.; da Silva Frozza et al., 2014da Silva Frozza, C.O., da Silva Ribeiro, T., Gambato, G., Menti, C., Moura, S., Pinto, P.M., Staats, C.C., Padilha, F.F., Begnini, K.R., Leon, P.M.M. de, Borsuk, S., Savegnago, L., Dellagostin, O., Collares, T., Seixas, F.K., Henriques, J.A.P., Roesch-Ely, M., 2014. Proteomic analysis identifies differentially expressed proteins after red propolis treatment in Hep-2 cells. Food Chem. Toxicol. 63, 195-204.; Hofer et al., 2014Hofer, T., Jørgensen, T.Ø., Olsen, R.L., 2014. Comparison of food antioxidants and iron chelators in two cellular free radical assays: strong protection by luteolin. J. Agric. Food Chem. 62, 8402-8410.; Jug et al., 2014Jug, M., Končić, M.Z., Kosalec, I., 2014. Modulation of antioxidant, chelating and antimicrobial activity of poplar chemo-type propolis by extraction procures. LWT – Food Sci. Technol. 57, 530-537.; El-Guendouz et al., 2018El-Guendouz, S., Aazza, S., Lyoussi, B., Majdoub, N., Bankova, V., Popova, M., Raposo, S., Antunes, M.D., Miguel, M.G., 2018. Effect of poplar-type propolis on oxidative stability and rheological properties of O/W emulsions. Saudi Pharm. J. 26, 1073-1082.).

Nevertheless, the poor solubility of the active lipophilic secondary plant metabolites in biological media reduces their bioavailability, which is an obstacle for effective in vivo application of propolis. Therefore, an increasing interest in the development of new delivery systems for weakly soluble active substances from natural origin exists, aiming to increase the solubility in biological fluids and to improve their bioavailability. Polymeric micelles are widely studied as potential drug delivery carriers (Bastakoti and Liu, 2017Bastakoti, B.P., Liu, Z., 2017. Chapter 10 – Multifunctional polymeric micelles as therapeutic nanostructures: targeting, imaging, and triggered release. In: Ficai, A., Grumezescu, A.M. (Eds.), Nanostructures for Cancer Therapy, Micro and Nano Technologies. Elsevier, pp. 261–283.). Among them, polymeric micelles from amphiphilic block copolymers are explored as a platform for delivery of low soluble drugs in anticancer therapy and imaging (Bastakoti et al., 2013Bastakoti, B.P., Wu, K.C.-W., Inoue, M., Yusa, S., Nakashima, K., Yamauchi, Y., 2013. Multifunctional core-shell-corona-type polymeric micelles for anticancer drug-delivery and imaging. Chemistry 19, 4812-4817.). Their unique properties allow the sustained release of the encapsulated hydrophobic drug and stabilization of the particle in aqueous solution. Recently, different drug-delivery nanoformulations obtained by self-assembly (quantosomes, cubosomes, spongosomes, vesicles, etc.) have been proposed for delivery of weakly soluble compounds, including antioxidants (Ferrer-Tasies et al., 2013Ferrer-Tasies, L., Moreno-Calvo, E., Cano-Sarabia, M., Aguilella-Arzo, M., Angelova, A., Lesieur, S., Ricart, S., Faraudo, J., Ventosa, N., Veciana, J., 2013. Quatsomes: vesicles formed by self-assembly of sterols and quaternary ammonium surfactants. Langmuir ACS J. Surf. Colloids 29, 6519-6528.; Angelova et al., 2011Angelova, A., Angelov, B., Mutafchieva, R., Lesieur, S., Couvreur, P., 2011. Self-assembled multicompartment liquid crystalline lipid carriers for protein, peptide, and nucleic acid drug delivery. Acc. Chem. Res. 44, 147-156., 2018Angelova, A., Drechsler, M., Garamus, V.M., Angelov, B., 2018. Liquid crystalline nanostructures as PEGylated reservoirs of omega-3 polyunsaturated fatty acids: structural insights toward delivery formulations against neurodegenerative disorders. ACS Omega 3, 3235-3247.; Guerzoni et al., 2017Guerzoni, L.P.B., Nicolas, V., Angelova, A., 2017. In vitro modulation of TrkB receptor signaling upon sequential delivery of curcumin-DHA loaded carriers towards promoting neuronal survival. Pharm. Res. 34, 492-505.; Zou et al., 2017Zou, A., Li, Y., Chen, Y., Angelova, A., Garamus, V.M., Li, N., Drechsler, M., Angelov, B., Gong, Y., 2017. Self-assembled stable sponge-type nanocarries for Brucea javanica oil delivery. Colloids Surf. B: Biointerfaces 153, 310-319.). In addition to the improved delivery characteristics, the carrier of the system should allow optimal loading and preservation of antioxidant activity of the active molecule. In previous studies, we found that the encapsulation of flavonoid quercetin in chitosan-alginate nanoparticles led to achievement of higher antioxidant activity at low concentrations (Tzankova et al., 2017Tzankova, V., Aluani, D., Kondeva-Burdina, M., Yordanov, Y., Odzhakov, F., Apostolov, A., Yoncheva, K., 2017. Hepatoprotective and antioxidant activity of quercetin loaded chitosan/alginate particles in vitro and in vivo in a model of paracetamol-induced toxicity. Biomed. Pharmacother. 92, 569-579.), and the ability of curcumin loaded in cationic polymeric micelles to scavenge ABTS radical and hypochlorite ions was higher than that of the free curcumin (Yoncheva et al., 2015Yoncheva, K., Kamenova, K., Perperieva, T., Hadjimitova, V., Donchev, P., Kaloyanov, K., Konstantinov, S., Kondeva-Burdina, M., Tzankova, V., Petrov, P., 2015. Cationic triblock copolymer micelles enhance antioxidant activity, intracellular uptake and cytotoxicity of curcumin. Int. J. Pharm. 490, 298-307.). Overall, micellar formulations based on poly (ethylene oxide)–β-poly(propylene oxide)–β-poly(ethylene oxide) (PEO–PPO–PEO) triblock copolymers are among the most extensively studied for biomedical application (Kabanov et al., 2002Kabanov, A.V., Lemieux, P., Vinogradov, S., Alakhov, V., 2002. Pluronic block copolymers: novel functional molecules for gene therapy. Adv. Drug Deliv. Rev. 54, 223-233.). Various natural antioxidants, such as curcumin, silybin, etc. have been effectively loaded into PEO–PPO–PEO micelles (Li et al., 2009Li, X., Huang, Y., Chen, X., Zhou, Y., Zhang, Y., Li, P., Liu, Y., Sun, Y., Zhao, J., Wang, F., 2009. Self-assembly and characterization of Pluronic P105 micelles for liver-targeted delivery of silybin. J. Drug Target. 17, 739-750.; Sahu et al., 2011Sahu, A., Kasoju, N., Goswami, P., Bora, U., 2011. Encapsulation of curcumin in Pluronic block copolymer micelles for drug delivery applications. J. Biomater. Appl. 25, 619-639.; Gorinova et al., 2016Gorinova, C., Aluani, D., Yordanov, Y., Kondeva-Burdina, M., Tzankova, V., Popova, C., Yoncheva, K., 2016. In vitro evaluation of antioxidant and neuroprotective effects of curcumin loaded in Pluronic micelles. Biotechnol. Biotechnol. Equip. 30, 991-997.). A significant improvement of pharmacokinetic parameters of the bioactive compounds loaded in PEO–PPO–PEO-based micellar formulations and increased time of systemic circulation have been demonstrated by in vivo experiments.

Recently, a novel micellar form of poplar propolis based on PEO₂₆PPO₄₀PEO₂₆ (Pluronic P85) triblock copolymer was prepared and reported by our team (Petrov et al., 2016Petrov, P.D., Tsvetanov, C.B., Mokreva, P., Yoncheva, K., Konstantinov, S., Trusheva, B., Popova, M., Bankova, V., 2016. Novel micellar form of poplar propolis with high cytotoxic activity. RSC Adv. 6, 30728-30731.). All biologically active lipophilic constituents of poplar (Populus nigra L., Salicaceae) propolis were solubilized with the aid of polymeric micelles in aqueous media. Furthermore, the small size of the micelles containing propolis (D _h = 20 nm) and the extremely good colloidal stability of the system offered an opportunity for further in vitro and in vivo characterization of its beneficial effects. This approach could also protect the unstable biologically active metabolites from premature oxidation and would give the opportunity to use the lower effective doses of antioxidant. However, attention should be given to preservation of favorable antioxidant properties of micellar propolis. The aim of the present study was to assess the antioxidant efficiency and hepatoprotective activity of the recently developed micellar form of poplar propolis in a model of oxidative stress injury in vitro (human hepatoma HepG2 cells) and after acute CCl₄-induced hepatotoxicity in vivo.

Material and methods

Chemicals

PEO₂₆PPO₄₀PEO₂₆ (Pluronic P85) was kindly donated by BASF. Poplar propolis was collected in the Balkan Mountains, near the town of Elena, Bulgaria. DMEM cell medium (4500 mg/l glucose, without l-glutamine) with 10% fetal bovine serum, 2 mM l-glutamine, MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide), hydrogen peroxide solution 30% (w/w) were supplied from Sigma-Aldrich (Germany). All other reagents were of analytical grade.

Propolis extraction

Poplar propolis, grated after cooling, was extracted for 24 h with ethanol/water (70/30, v/v) mixture at room temperature (1:10, w/v), filtered and dried using a rotatory evaporator. The dried extracts content was analyzed by GC–MS using the procedure, previously described by Petrov et al. (2016)Petrov, P.D., Tsvetanov, C.B., Mokreva, P., Yoncheva, K., Konstantinov, S., Trusheva, B., Popova, M., Bankova, V., 2016. Novel micellar form of poplar propolis with high cytotoxic activity. RSC Adv. 6, 30728-30731..

Preparation of propolis loaded polymeric micelles

The dried extract was dissolved in ethanol/water (70/30, v/v) mixture and used for further experiment. 4 g of poplar propolis, dissolved in 72.6 ml ethanol/water (70/30, v/v) mixture, were added to 178.2 ml distilled water containing 12 g PEO₂₆PPO₄₀PEO₂₆ triblock copolymer. Then, ethanol was removed from the system by rotary evaporator (50 °C, 70 mbar) giving a transparent yellowish colloidal aqueous solution.

Characterization of propolis loaded polymeric micelles

Dynamic light scattering (DLS) measurements were conducted with a Zetasizer NanoBrook 90Plus PALS, equipped with a 35 mW red diode laser (λ = 640 nm) at a scattering angle of 90°. Transmission electron microscopy (TEM) analysis was conducted with a JEOL 2100 electron microscope at an accelerating voltage of 200 kV, equipped with a digital camera. A drop of sample solution was deposited on a TEM copper grid coated with a Carbon film, and the solvent was allowed to evaporate. Propolis release from PEO₂₆PPO₄₀PEO₂₆ micelles was investigated in phosphate buffer (pH 7.4) by UV–vis spectroscopy using the dialysis method.

Cell lines and culturing

Human hepatocellular carcinoma cells HepG2 were purchased from European collection of cell cultures (ECACC). HepG2 were kept in culture and expanded at 37 °C in a humidified atmosphere of 5% CO₂ in culture medium DMEM cell medium (4500 mg/l glucose, without l-glutamine), with 10% fetal bovine serum (FBS, Gibco BRL) and 2 mM l-glutamine.

Model of oxidative stress in vitro

HepG2 cells were seeded at a density 4 × 10⁴ cells/well. After 24 h the cells were pre-treated (1 h) with propolis-loaded polymer micelles (Pr-PM) (20, 50, 100, 250 µg/ml), propolis (Pr) (20, 50, 100, 250 µg/ml) and blank polymeric micelles (PM) (60, 150, 300, 750 µg/ml). HepG2 cells were exposed to H₂O₂ (0.1 mM, 1 h) to obtain submaximal cytotoxicity (approximately 60% vs untreated controls). Viability was assayed after 24 h by MTT-dye reduction assay (Mosmann, 1983Mosmann, T., 1983. Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. J. Immunol. Methods 65, 55-63.).

Animal selection and care

The in vivo study was conducted on 42 male Wistar rats (body weight 250–280 g). Animals were purchased from the National Breeding Center, Sofia, Bulgaria. The rats were housed under standard laboratory conditions (20 °C ± 2 °C and humidity 72% ± 4%) with free access to water and standard pelleted rat food (ISO 9001:2008). All performed procedures were approved by the Institutional Animal Care Committee (KENIMUS) and the principles stated in the European Convention for the Protection of Vertebrate Animals used for Experimental and other Scientific Purposes (Council of Europe, 1991Council of Europe, 1991. European Convention for the Protection of Vertebrate Animals Used for Experimental and Other Scientific Purposes (ETS123).; EU, 2010, 2010. Directive 2010/63. J. Eur. Union 276, 33-79.) were strictly followed throughout the experiment.

In vivo model of CCl₄-induced liver toxicity

The animals were divided into seven groups of six animals each (n = 6). The compounds were administered orally via gavage (0.5 ml/100 g b.w.) for 14 days, as described:

Group 1 (CNTR): saline (0.5 ml/100 g b.w., p.o., 14 days).
Group 2 (PM): blank polymeric micelles (60 mg/kg b.w., 14 days).
Group 3 (Pr): non-loaded propolis (20 mg/kg b.w., 14 days).
Group 4 (Pr-PM): propolis-loaded polymer (propolis concentration corresponding to 20 mg/kg b.w., 14 days).
Group 5 (CCl₄): saline (0.5 ml/100 g b.w., p.o., 7 days); at day 7 the animals were challenged with CCl₄ (10% solution, 1.25 ml/kg); from day 8–14 the animals were post-treated with saline (0.5 ml/100 g b.w., p.o.).
Group 6 (Pr/CCl₄): animals pre-treated with Pr (20 mg/kg, b.w. 7 days). At day 7, animals were challenged with CCl₄ (10% solution, 1.25 ml/kg); from day 8–14 animals were post-treated with Pr (20 mg/kg, b.w., p.o.).
Group 7 (Pr-PM/CCl₄): animals pre-treated with Pr-PM (20 mg/kg b.w.). At the day 7, they were challenged with CCl₄ (10% solution, 1.25 ml/kg); from day 8–14 the animals were post-treated with Pr-PM (20 mg/kg b.w., p.o.).

On the day 15th, blood samples were collected from the tail vein, the animals were sacrificed by decapitation and the livers were taken for evaluation.

Biomarkers of oxidative stress damage in liver

MDA determination and glutathione (GSH) depletion

MDA quantity was measured spectrophotometrically (λ 535 nm) by molar extinction coefficient 155 mM⁻¹ cm⁻¹ and was expressed as nmol/g liver as previously described (Bai et al., 2007Bai, X., Qiu, A., Guan, J., Shi, Z., 2007. Antioxidant and protective effect of an oleanolic acid-enriched extract of A. deliciosa root on carbon tetrachloride induced rat liver injury. Asia Pac. J. Clin. Nutr. 16, 169-173.). GSH was determined by spectrophotometric measurement at λ = 412 nm and expressed as nmol/g liver (Bai et al., 2007Bai, X., Qiu, A., Guan, J., Shi, Z., 2007. Antioxidant and protective effect of an oleanolic acid-enriched extract of A. deliciosa root on carbon tetrachloride induced rat liver injury. Asia Pac. J. Clin. Nutr. 16, 169-173.).

Analysis of antioxidant enzyme activity

Catalase (CAT) activity (nmol/g liver) was determined by measuring the decrease in absorbance at 240 nm (Aebi, 1974Aebi, H., 1974. Catalase. In: Methods of Enzymatic Analysis. Elsevier, pp. 673–684.). Superoxide dismutase (SOD) activity (nmol/g liver) was measured s as previously described (Misra and Fridovich, 1972Misra, H.P., Fridovich, I., 1972. The role of superoxide anion in the autoxidation of epinephrine and a simple assay for superoxide dismutase. J. Biol. Chem. 247, 3170-3175.). The protein content was measured by the method of Lowry et al. (1951)Lowry, O.H., Rosebrough, N.J., Farr, A.L., Randall, R.J., 1951. Protein measurement with the Folin Phenol reagent. J. Biol. Chem. 193, 265-275..

Biochemistry and hematology parameters

Blood samples (0.5 ml) were collected from the tail vein for evaluation of clinical hematology and biochemical assay, which were performed using BC-2800-Vet (Mindray) haematology analyser.

Histological analysis

Liver samples (0.5 cm³) were fixed in buffered formaldehyde (4% final concentration) and then sectioned at 5 µm. Staining methods have been used according to the standard Hematoxylin–Eosin (HE) and Masson's trichrome (M) protocols. All preparations were analyzed under Leica DM 1000 LED microscope and documented by Leica ICC 50 HD camera on 20× magnification.

Statistical analysis

Results are expressed as mean values and standard deviation (SD) from at least three independent experiments. The cell survival data were normalized as percentage of untreated control set as 100% viability. One-way analysis of variance (ANOVA) with post hoc multiple comparisons procedure (Dunnett's test) was used to assess statistical differences in case of normal distribution. Values of p < 0.05, p < 0.01 and p < 0.001 were considered statistically significant. All statistical analyses were performed using GraphPad Prizm Software.

Results

Chemical composition of the propolis extract

The propolis extract used in this study was characterized by GC–MS analysis after silylation. The chemical composition of the extract is given in Table 1. The constituents of the extract were typical for the poplar type propolis: flavonoid aglycones pinocembrin, galangin, chrysis, esters of caffeic acids (phenethyl, benzyl, and pentenyl), and phenolic acids.

Thumbnail

Table 1
Chemical composition of ethanol extract of propolis sample (% of total ion current).^a a The ion current generated depends on the characteristics of the compound concerned and is not a true quantification.

Preparation and physicochemical characterization of propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ micelles

Micelles

Micellar formulation of poplar propolis developed recently by our team (Petrov et al., 2016Petrov, P.D., Tsvetanov, C.B., Mokreva, P., Yoncheva, K., Konstantinov, S., Trusheva, B., Popova, M., Bankova, V., 2016. Novel micellar form of poplar propolis with high cytotoxic activity. RSC Adv. 6, 30728-30731.) is characterized by enhanced aqueous solubility and superior colloid stability. The improved solubility of propolis in biological media is favorable for in vivo application and, in particular, an increase of antioxidant activity and hepatoprotective effect of micellar propolis as compared to free propolis, was considered.

Briefly, poplar propolis dissolved in ethanol/water (70/30, v/v) mixture was added to an aqueous solution of PEO₂₆–PPO₄₀–PEO₂₆ and, then, the organic solvent was evaporated. The concentration of propolis and PEO₂₆–PPO₄₀–PEO₂₆ copolymer in the final transparent yellowish colloidal solution were 20 g/l and 60 g/l, respectively. Dynamic light scattering and transmission electron microscopy analysis confirmed the formation of rather spherical nanoparticles with an apparent hydrodynamic diameter D _h = 21 nm and dispersity index = 0.18 (Fig. 1). The micellar formulation retained its main characteristics (transparency, stability, D _h) upon storage at temperature of 20–25 °C for several weeks. In contrast, the sample prepared without any copolymer formed a turbid unstable suspension, which tended to precipitate after 2 days of storage. Thus, the role of copolymer seems critical for fabricating a colloid solution of propolis in aqueous media. In water, the hydrophobic interactions between water-insoluble constituents of propolis and the hydrophobic PPO chains were strongly favored, and triggered the encapsulation of natural product within the cores of nano-sized PEO–PPO–PEO micelles. The hydrated PEO shell provided an excellent colloid stability of the formulation. A proof for the successful loading of micelles with propolis was provided by TEM analysis. The spherical particles possessed a high contrast unlie the blank PEO–PPO–PEO micelles. Obviously, the aromatic molecules located within the micellar core contributed, similarly to the standard staining agents, to enhance the quality of visualization of polymeric micelles. Further on, the performed in vitro release studies showed a slight initial weak burst effect followed by a sustained release within 56 h (Fig. 2). This fact also suggests a pronounced hydrophobic interaction between the core-forming PPO segments and the lipophilic molecules of propolis extract.

Fig. 1
Particle size distribution curve (left) and TEM micrograph (right) of poplar propolis loaded PEO₂₆PPO₄₀PEO₂₆ micelles. The concentrations of propolis and copolymer are 20 g/l and 60 g/l, respectively.

Fig. 2
Release profile of propolis from PEO₂₆PPO₄₀PEO₂₆ micelles in phosphate buffer (pH 7.4).

In vitro protective effects in a model of H₂O₂-induced oxidative stress

The safety evaluation of a new propolis-based formulation is an important step in its further characterization. Our preliminary study showed a good safety profile of blank PEO₂₆–PPO₄₀–PEO₂₆ micelles (60–750 µg/ml) against HepG2 cells, since no direct cytotoxicity was observed (data not shown). Based on a good safety profile of the micellar PEO₂₆–PPO₄₀–PEO₂₆ formulation on HepG2 cells, we further evaluated the effectiveness of the propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ micellar formulation in H₂O₂-induced oxidative stress model in vitro.

The cell viability decreased by 60% (p < 0.001) vs untreated controls after H₂O₂-treatment (0.1 mmol/l, 1 h), indicating significant cell damage (Fig. 3). The pretreatment with Pr (20, 50, 100 µg/ml) and Pr-PM (propolis concentration corresponding to 20, 50 and 100 µg/ml) substantially decreased the H₂O₂-induced cell impairment (Fig. 3B, C). The protection seen by Pr-PM was similar to those of free Pr, showing the preservation of antioxidant activity by propolis micellar formulation. In contrast, the blank micelles (60–750 µg/ml) did not show any protection against oxidative stress damage (Fig. 3A). It should be noted that the protection was observed in the propolis concentrations up to 100 µg/ml, while at the higher concentration (250 µg/ml), both Pr and Pr-PM did not show an increase in cell viability, compared to H₂O₂-treatment.

Fig. 3
Effect of blank PEO₂₆PPO₄₀PEO₂₆ micelles (PM), non-loaded propolis (Pr) and propolis-loaded PEO₂₆PPO₄₀PEO₂₆ micelles (Pr-PM) on cell the viability of HepG2 cells in a model of H₂O₂-induced toxicity. Mean ± SD (n = 8). Values of ***p < 0.001 vs control group; ⁺⁺⁺ p < 0.001 vs H₂O₂ group were considered statistically significant.

In vivo hepatoprotection in a model of carbon tetrachloride-induced toxicity

Clinic observations

The repeated oral administration of PM (60 mg/kg b.w.), Pr (20 mg/kg b.w.) and Pr-PM (propolis, equivalent to 20 mg/kg b.w.) did not show any changes in the clinical appearance, reflections, respiration, behavior or mortality of the animals of all treated groups vs untreated controls. The average daily feed intake, body and liver weight in the treatment groups did not show statistically significant changes vs control group (Table 2).

Thumbnail

Table 2
Effects of blank PEO₂₆PPO₄₀PEO₂₆ micelles (60 mg/kg b.w.), non-loaded propolis (20 mg/kg b.w.) and propolis-loaded micelles (Pr-PM, propolis corresponding to 20 mg/kg b.w.) on daily feed intake, total body weight and liver weight after 14 days treatment (p.o.) in male Wistar rats.

Hematology and serum biochemistry analysis

Several hematological parameters were monitored in order to evaluate the eventual hematology impairment (Table 3). As shown, no significant changes in hematology parameters were found in all treatment groups, before and after CCl₄-treatment, compared to the control animal. The effects of blank micelles, non-loaded propolis and propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ micelles on serum biochemical parameters are presented in Table 4. As expected, significant increase in aspartate aminotransferase (AST), alanine aminotransferase (ALT) and alkaline phosphatase (ALP) were detected in the CCl₄ group (**p < 0.01 and *p < 0.05), thus confirming the hepatotoxic injury. Animals orally received 20 mg/kg free or micellar propolis for 7 days prior CCl₄-treatment, followed by a post-treatment period of 7 days, showed significant improvement of the most biochemical markers toward the normal values.

Thumbnail

Table 3
Effects of blank PEO₂₆PPO₄₀PEO₂₆ micelles (60 mg/kg b.w.), non-loaded propolis (20 mg/kg b.w.) and propolis-loaded micelles (Pr-PM, propolis corresponding to 20 mg/kg b.w.) on hematology parameters in a model of CCl₄-induced liver injury.

Thumbnail

Table 4
Effects of blank PEO₂₆PPO₄₀PEO₂₆ micelles (60 mg/kg b.w.), non-loaded propolis (Pr, 20 mg/kg b.w.) and propolis-loaded PEO₂₆PPO₄₀PEO₂₆ micelles (Pr-PM, propolis corresponding to 20 mg/kg b.w.) on serum biochemical parameters in a model of CCl₄-induced liver injury.

Oxidative stress markers assay in liver

The mechanisms of CCl₄-induced toxicity include generation of unstable trichloromethyl (CCl₃ ) and trichloromethyl peroxyl (CCl₃O₂ ) radicals by CYP450 in liver endoplasmic reticulum, which triggers tissue and cell damage (Weber et al., 2003Weber, L.W.D., Boll, M., Stampfl, A., 2003. Hepatotoxicity and mechanism of action of haloalkanes: carbon tetrachloride as a toxicological model. Crit. Rev. Toxicol. 33, 105-136.). Particularly, our attention was focused to the possible protective effects of micellar propolis on the levels of MDA and GSH as markers of non-enzymatic antioxidant defense system.

The repeated oral administration (14 day, p.o.) of PM and Pr-PM did not reveal any signs of toxicity, since no statistically significant changes in the level of GSH and MDA were observed (Fig. 4A, B). In contrast, CCl₄ treatment evidently caused hepatotoxicity. Compared to the control untreated group, CCl₄ administration induced significant pro-oxidant effects, discerned by a marked increase in MDA production by 65% (p < 0.001, vs untreated control) and a decrease in GSH levels by 46% (p < 0.001, vs untreated control). However, the toxic effects were attenuated in the groups pre-treated with propolis, either non-loaded or loaded in polymer micelles (Pr/CCl₄; Pr-PM/CCl₄), and then challenged with CCl₄. The measured parameters were close to/or restored to the control level, thus showing a significant protection (Fig. 4A). MDA levels were significantly decreased by micellar propolis (26% decrease vs CCl₄ group) followed by non-loaded propolis (19.7% decrease vs CCl₄ group).

Fig. 4
Protective effects of blank PEO₂₆PPO₄₀PEO₂₆ micelles (PM), non-loaded propolis (Pr) (20 mg/kg b.w.) and propolis-loaded in polymeric micelles (Pr-PM) (propolis, corresponding to 20 mg/kg b.w.) on the contents of MDA (A) and GSH (B) in a model of CCl₄-induced (10%, 1.25 ml/kg b.w.) liver injury in male Wistar rats. Data are presented as the mean ± SD for 6 animals in each group (n = 6). ***p < 0.001 vs control value (non-treated rats); ⁺⁺⁺ p < 0.001 vs carbon tetrachloride (CCl₄) treated group.

The evaluation of GSH levels in liver homogenate showed significant protection against CCl₄-induced depletion in both experimental groups pre-treated with Pr (46% GSH increase vs CCl₄ group, p < 0.001) and Pr-PM (49% GSH increase vs CCl₄-group, p < 0.001) (Fig. 4B). The protective effect of propolis-loaded micelles was superior to that of non-loaded propolis.

Liver antioxidant enzyme assay

In attempt to elucidate in depth the protective mechanisms of propolis-loaded micelles on toxic hepatic injury and lipid peroxidation, we also evaluated the effects on antioxidant enzymes activity of CAT and SOD (Fig. 5). The treatment with blank micelles, propolis or the propolis-loaded micellar formulation (14 day, p.o.) did not result in any changes of the antioxidant enzymes. In contrast, CCl₄ administration induced a significant decrease in antioxidant activity of both CAT (by 30%, p < 0.001) and SOD (by 26%, p < 0.001), compared to the control untreated group. However, in the groups pre-treated with propolis, either non-loaded or loaded in polymeric micellar formulation and then challenged with CCl₄, the antioxidant enzyme activities were close to controls. Furthermore, the treatment with propolis-loaded micelles led to a significant increase in both antioxidant enzyme activities, CAT by 37% and in SOD by 50% (p < 0.001), vs CCl₄-treatment group.

Fig. 5
Catalese (CAT) and superoxide dismutase (SOD) activities in rat liver microsomes after CCl₄-induced (10%, 1.25 ml/kg b.w.) liver damage in rats. Blank PEO₂₆PPO₄₀PEO₂₆ micelles (PM), non-loaded propolis (Pr) (20 mg/kg b.w.) and propolis-loaded in polymeric micelles (Pr-PM) (propolis, corresponding to 20 mg/kg b.w.) were administered orally, as described in Materials and methods. Data are presented as the mean ± SD for 6 animals in each group (n = 6). ***p < 0.001 vs control values; ⁺⁺⁺ p < 0.001 vs CCl₄-treatment.

Liver histopathological examination

The liver segments were evaluated according the acinar structure related to the central venous and terminal portal circulation, parenchymal cells and reticular system changes and biliary canalicular network (Fig. 6). Pr and Pr-PM samples showed no signs of necrosis, regeneration changes and cell replacement (Fig. 6B, C). In contrary, the CCl₄-treated group showed severe pericentral fatty degeneration, necrosis of hepatocytes and onset of fibrous sinusoidal regeneration (Fig. 6D). The livers of the animals pre-treated with Pr and Pr-PM and after that challenged to CCl₄, showed normal periportal acinar structures with several focuses of pericentral sinusoid congestion (Fig. 6E, F). Lack of necrosis, regeneration changes and cell replacement, as well as intact biliary canalicular network were established. Thus, the histopathological analysis shows high hepatoprotection in both propolis and micellar propolis treatment groups. These findings confirmed the beneficial effects already observed on oxidative stress biomarkers GSH and MDA, and on enzymes SOD and CAT.

Fig. 6
Rat liver sections after H&E staining and Masson's trichrome (M) staining (scale bars = 50 µm). The treatments were as described: (A) untreated controls; (B) non-loaded propolis (Pr; 20 mg/kg b.w.); (C) propolis-loaded PEO–PPO–PEO micelles; (D) CCl₄-treated group (10%, 1.25 ml/kg b.w.); (E) non-loaded propolis (20 mg/kg b.w.) + CCl₄; (F) propolis-loaded PEO₂₆PPO₄₀PEO₂₆ micelles (propolis, corresponding to 20 mg/kg b.w.) + CCl₄. The liver segments are evaluated according the acinar structure related to the central venous and terminal portal circulation, parenchymal cells and reticular system changes and biliary canalicular network.

Discussion

Poplar propolis and the major constituents, and especially caffeic acid and its phenethyl ester (CAPE), galangin, pinocembrin are well-known antioxidants (Boisard et al., 2014Boisard, S., Le Ray, A.-M., Gatto, J., Aumond, M.-C., Blanchard, P., Derbré, S., Flurin, C., Richomme, P., 2014. Chemical composition, antioxidant and anti-AGEs activities of a French poplar type propolis. J. Agric. Food Chem. 62, 1344-1351.; Bacanlı et al., 2016Bacanlı, M., Başaran, A.A., Başaran, N., 2016. The antioxidant, cytotoxic, and antigenotoxic effects of galangin, puerarin, and ursolic acid in mammalian cells. Drug Chem. Toxicol. 40, 256-262.; Coban et al., 2017Coban, F.K., Akil, M., Liman, R., Cigerci, I.H., 2017. Antioxidant and genotoxic effects of caffeic acid phenethyl ester (cape) in exercise-induced oxidative stress. Fresenius Environ. Bull. 26, 2683-2687.; Yang et al., 2018Yang, X., Wang, X., Chen, X.-Y., Ji, H.-Y., Zhang, Y., Liu, A.-J., 2018. Pinocembrin-lecithin complex: characterization, solubilization, and antioxidant activities. Biomolecules 8, http://dx.doi.org/10.3390/biom8020041.
http://dx.doi.org/10.3390/biom8020041... ). Poplar propolis has also demonstrated hepatoprotective properties (Banskota et al., 2000Banskota, A.H., Tezuka, Y., Adnyana, I.K., Midorikawa, K., Matsushige, K., Message, D., Huertas, A.A.G., Kadota, S., 2000. Cytotoxic, hepatoprotective and free radical scavenging effects of propolis from Brazil, Peru, the Netherlands and China. J. Ethnopharmacol. 72, 239-246.). However, propolis active constituents are lipophilic and poorly soluble in water and aqueous/physiological media and this is a serious obstacle for application of propolis in therapy. The therapeutic effects of natural antioxidants, such as propolis, might be hindered by inadequate delivery and low bioavailability. The strategy for improvement of antioxidant delivery includes a choice of an appropriate carrier with gradual, sustained release rate, thus avoiding burst effects. Additionally, a possible pro-oxidant toxicity risk might be prevented by application of the antioxidants at low effective concentrations. The carrier would allow efficient intracellular delivery and protection of the loaded antioxidant from inactivation. Recently, new propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ copolymer micelles were developed and reported by our team (Petrov et al., 2016Petrov, P.D., Tsvetanov, C.B., Mokreva, P., Yoncheva, K., Konstantinov, S., Trusheva, B., Popova, M., Bankova, V., 2016. Novel micellar form of poplar propolis with high cytotoxic activity. RSC Adv. 6, 30728-30731.). The main advantages of the propolis-loaded micelles vs well known alcoholic extracts include the solubilization in aqueous media of biologically active lipophilic constituents of propolis, as well as achievement of sustained release which would give an opportunity for its use in broad spectrum of pathologies, including liver impairments. The present study demonstrates high hepatoprotective and antioxidant activities and a good safety profile of the novel micellar form of propolis in vitro and in a model of CCl₄-induced liver injury in vivo.

H₂O₂ is generated from different sources and could easily enter the body tissues and cells, allowing free radicals formation (i.e. hydroxyl radical formed by Fenton's reaction), which further interact directly with cellular and subcellular structures causing damage to proteins, lipids, DNA, etc. In vitro, we showed a significant antioxidant protection of propolis-loaded micelles at concentrations <100 µg/ml. Nevertheless, we found that at higher concentrations (250 µg/ml) propolis-loaded micelles did not increase HepG2 cell viability. These results were not surprising having in mind the numerous reports regarding propolis mediated suppression of cell proliferation. Many studies have shown an anti-proliferative activity of both propolis and its bioactive compounds (Watanabe et al., 2011Watanabe, M.A.E., Amarante, M.K., Conti, B.J., Sforcin, J.M., 2011. Cytotoxic constituents of propolis inducing anticancer effects: a review. J. Pharm. Pharmacol. 63, 1378-1386.; Sawicka et al., 2012Sawicka, D., Car, H., Borawska, M.H., Nikliński, J., 2012. The anticancer activity of propolis. Folia Histochem. Cytobiol. 50, 25-37.; Tyszka-Czochara et al., 2014Tyszka-Czochara, M., Paśko, P., Reczyński, W., Szlósarczyk, M., Bystrowska, B., Opoka, W., 2014. Zinc and propolis reduces cytotoxicity and proliferation in skin fibroblast cell culture: total polyphenol content and antioxidant capacity of propolis. Biol. Trace Elem. Res. 160, 123-131.; Turan et al., 2015Turan, I., Demir, S., Misir, S., Kilinc, K., Mentese, A., Aliyazicioglu, Y., Deger, O., 2015. Cytotoxic effect of Turkish propolis on liver, colon, breast, cervix and prostate cancer cell lines. Trop. J. Pharm. Res. 14, 777-782.). Recently, it was reported that Chinese poplar propolis (100 and 300 µg/ml; ethanolic extract) or brown Cuban propolis (La Habana) significantly inhibited proliferation of HepG2 cells (Andreu et al., 2015Andreu, G.L.P., Reis, F.H.Z., Dalalio, F.M., Nuñez Figueredo, Y., Cuesta Rubio, O., Uyemura, S.A., Curti, C., Alberici, L.C., 2015. The cytotoxic effects of brown Cuban propolis depend on the nemorosone content and may be mediated by mitochondrial uncoupling. Chem. Biol. Interact. 228, 28-34.; Zhao et al., 2014Zhao, Y., Tian, W., Peng, W., 2014. Anti-proliferation and insulin resistance alleviation of hepatocellular carcinoma cells HepG2 in vitro by Chinese propolis. J. Food Nutr. Res. 2, 228-235.).

Further, we performed in vivo evaluation of the hepatoprotective potential of propolis-loaded polymer micelles (Pr-PM) in a model of CCl₄-induced toxicity in male Wistar rats. The elevated levels of liver serum transaminases ALT, AST and also ALP were considered to be evidence of CCl₄-induced liver injury. In vivo pre-treatment with Pr-PM restored the levels of serum transaminases. The protective mechanisms might include regeneration of parenchymal cells in response to the beneficial effects of different biologically active constituents of poplar propolis (i.e. flavonoids, phenolic acids and their esters). Thus, preventing the cell membrane destruction, the natural antioxidants subsequently might decrease the leakage of liver transaminase in blood circulation. The performed histopathological observation sustained biochemical data and confirmed the protective effects of Pr-PM against CCl₄-induced liver damage. Significant morphological changes coherent with the onset of an acute hepatocellular injury with hepatic necrosis in the CCl₄-treatment group were highly prevented by pre-treatment with Pr-PM.

Considerable lowering of the GSH level and increase in MDA in the liver clearly reflects a fall in the antioxidant status. This reaction is a response to CCl₄ administration and might be due to its increased utilization by hepatocytes in attempt to scavenge CCl₃. and other toxic radicals. In a model of CCl₄-induced hepatotoxicity, we observed protective antioxidant effects of propolis-loaded micelles, as measured by the elevated levels of endogenous GSH and by decreased MDA production in liver. The effect of micellar propolis was superior of those of non-loaded propolis. The observed propolis protection correlates with other in vivo studies. Lin et al. (1998)Lin, C.C., Yen, M.H., Lo, T.S., Lin, J.M., 1998. Evaluation of the hepatoprotective and antioxidant activity of Boehmeria nivea var. nivea and B. nivea var. tenacissima. J. Ethnopharmacol. 60, 9-17. found that propolis improves the antioxidant defense system by increasing the total GSH pool. Antioxidant enzymes, such as SOD, CAT, glutathione peroxidase and peroxireductase act as liver defense system against free radical induced damage. In conditions of liver injury (i.e. CCl₄-intoxication), the ability of the endogenous antioxidant system is impaired and the membrane disintegration of hepatocytes is discerned by a decrease in antioxidant enzyme activities. However, we found that the pre-treatment with Pr-PM prevented the CCl₄-induced oxidative damage by preserving antioxidant enzyme activities of SOD and CAT; the effects resemble those of propolis. Our observations about protective effects of propolis against carbon tetrachloride (CCl₄)-induced injury are consistent with other reports (Mahran et al., 1996Mahran, L.G., el-Khatib, A.S., Agha, A.M., Khayyal, M.T., 1996. The protective effect of aqueous propolis extract on isolated rat hepatocytes against carbon tetrachloride toxicity. Drugs Exp. Clin. Res. 22, 309-316.; Bhadauria et al., 2008Bhadauria, M., Nirala, S.K., Shukla, S., 2008. Multiple treatment of propolis extract ameliorates carbon tetrachloride induced liver injury in rats. Food Chem. Toxicol. 46, 2703-2712.; El-Khatib et al., 2014El-Khatib, A.S., Agha, A.M., Mahran, L.G., Khayyal, M.T., 2014. Prophylactic effect of aqueous propolis extract against acute experimental hepatotoxicity in vivo. Z. Naturforschung C 57, 379-385.). For example, Bhadauria et al. (2008)Bhadauria, M., Nirala, S.K., Shukla, S., 2008. Multiple treatment of propolis extract ameliorates carbon tetrachloride induced liver injury in rats. Food Chem. Toxicol. 46, 2703-2712. evaluated the hepatoprotective effect of propolis (50–400 mg/kg b.w.) in a model of CCl₄-induced liver toxicity. They found an effective protection only after administration of higher doses of propolis (200 and 400 mg/kg, b.w.). It should be mentioned, that we observed considerable hepatoprotective effects of micellar propolis using much lower propolis doses (20 mg/kg, b.w.). Most probably, the high stability and sustained release micellar propolis, contribute to its favorable effects (Petrov et al., 2016Petrov, P.D., Tsvetanov, C.B., Mokreva, P., Yoncheva, K., Konstantinov, S., Trusheva, B., Popova, M., Bankova, V., 2016. Novel micellar form of poplar propolis with high cytotoxic activity. RSC Adv. 6, 30728-30731.). The therapeutic use of low dose propolis could be considered advantageous taking into account that high antioxidant concentrations would exert pro-oxidant effects.

Conclusion

The present study demonstrates antioxidant and hepatoprotective effects of micellar formulation of poplar propolis, based on the biocompatible triblock copolymer PEO₂₆–PPO₄₀–PEO₂₆ in oxidative stress toxicity models in vitro and in vivo. The antioxidant activity and hepatoprotection was proven by restoration of the glutathione levels, by normalizing the serum transaminase activities, and by significant protection of liver antioxidant enzymes SOD and CAT. A significant improvement in the liver histoarchitecture by micellar propolis was observed, suggesting liver protection. Our findings suggest that the newly developed propolis micellar nanoformulation might be considered as a promising and safe delivery system against oxidative stress-induced injury in liver.

Funding

This research did not receive any special grant from funding agencies in the public, commercial or not-for-profit sectors.
Ethical disclosures

Protection of human and animal subjects

The authors declare that the procedures followed were in accordance with the regulations of the relevant clinical research ethics committee and with those of the Code of Ethics of the World Medical Association (Declaration of Helsinki).

Confidentiality of data

The authors declare that no patient data appear in this article.

Right to privacy and informed consent

The authors declare that no patient data appear in this article.

References

Aebi, H., 1974. Catalase. In: Methods of Enzymatic Analysis. Elsevier, pp. 673–684.
Andreu, G.L.P., Reis, F.H.Z., Dalalio, F.M., Nuñez Figueredo, Y., Cuesta Rubio, O., Uyemura, S.A., Curti, C., Alberici, L.C., 2015. The cytotoxic effects of brown Cuban propolis depend on the nemorosone content and may be mediated by mitochondrial uncoupling. Chem. Biol. Interact. 228, 28-34.
Angelova, A., Angelov, B., Mutafchieva, R., Lesieur, S., Couvreur, P., 2011. Self-assembled multicompartment liquid crystalline lipid carriers for protein, peptide, and nucleic acid drug delivery. Acc. Chem. Res. 44, 147-156.
Angelova, A., Drechsler, M., Garamus, V.M., Angelov, B., 2018. Liquid crystalline nanostructures as PEGylated reservoirs of omega-3 polyunsaturated fatty acids: structural insights toward delivery formulations against neurodegenerative disorders. ACS Omega 3, 3235-3247.
Bacanlı, M., Başaran, A.A., Başaran, N., 2016. The antioxidant, cytotoxic, and antigenotoxic effects of galangin, puerarin, and ursolic acid in mammalian cells. Drug Chem. Toxicol. 40, 256-262.
Bai, X., Qiu, A., Guan, J., Shi, Z., 2007. Antioxidant and protective effect of an oleanolic acid-enriched extract of A. deliciosa root on carbon tetrachloride induced rat liver injury. Asia Pac. J. Clin. Nutr. 16, 169-173.
Banskota, A.H., Tezuka, Y., Adnyana, I.K., Midorikawa, K., Matsushige, K., Message, D., Huertas, A.A.G., Kadota, S., 2000. Cytotoxic, hepatoprotective and free radical scavenging effects of propolis from Brazil, Peru, the Netherlands and China. J. Ethnopharmacol. 72, 239-246.
Bastakoti, B.P., Liu, Z., 2017. Chapter 10 – Multifunctional polymeric micelles as therapeutic nanostructures: targeting, imaging, and triggered release. In: Ficai, A., Grumezescu, A.M. (Eds.), Nanostructures for Cancer Therapy, Micro and Nano Technologies. Elsevier, pp. 261–283.
Bastakoti, B.P., Wu, K.C.-W., Inoue, M., Yusa, S., Nakashima, K., Yamauchi, Y., 2013. Multifunctional core-shell-corona-type polymeric micelles for anticancer drug-delivery and imaging. Chemistry 19, 4812-4817.
Bhadauria, M., Nirala, S.K., Shukla, S., 2008. Multiple treatment of propolis extract ameliorates carbon tetrachloride induced liver injury in rats. Food Chem. Toxicol. 46, 2703-2712.
Boisard, S., Le Ray, A.-M., Gatto, J., Aumond, M.-C., Blanchard, P., Derbré, S., Flurin, C., Richomme, P., 2014. Chemical composition, antioxidant and anti-AGEs activities of a French poplar type propolis. J. Agric. Food Chem. 62, 1344-1351.
Coban, F.K., Akil, M., Liman, R., Cigerci, I.H., 2017. Antioxidant and genotoxic effects of caffeic acid phenethyl ester (cape) in exercise-induced oxidative stress. Fresenius Environ. Bull. 26, 2683-2687.
Council of Europe, 1991. European Convention for the Protection of Vertebrate Animals Used for Experimental and Other Scientific Purposes (ETS123).
da Silva Frozza, C.O., da Silva Ribeiro, T., Gambato, G., Menti, C., Moura, S., Pinto, P.M., Staats, C.C., Padilha, F.F., Begnini, K.R., Leon, P.M.M. de, Borsuk, S., Savegnago, L., Dellagostin, O., Collares, T., Seixas, F.K., Henriques, J.A.P., Roesch-Ely, M., 2014. Proteomic analysis identifies differentially expressed proteins after red propolis treatment in Hep-2 cells. Food Chem. Toxicol. 63, 195-204.
El-Guendouz, S., Aazza, S., Lyoussi, B., Majdoub, N., Bankova, V., Popova, M., Raposo, S., Antunes, M.D., Miguel, M.G., 2018. Effect of poplar-type propolis on oxidative stability and rheological properties of O/W emulsions. Saudi Pharm. J. 26, 1073-1082.
El-Khatib, A.S., Agha, A.M., Mahran, L.G., Khayyal, M.T., 2014. Prophylactic effect of aqueous propolis extract against acute experimental hepatotoxicity in vivo Z. Naturforschung C 57, 379-385.
, 2010. Directive 2010/63. J. Eur. Union 276, 33-79.
Ferrer-Tasies, L., Moreno-Calvo, E., Cano-Sarabia, M., Aguilella-Arzo, M., Angelova, A., Lesieur, S., Ricart, S., Faraudo, J., Ventosa, N., Veciana, J., 2013. Quatsomes: vesicles formed by self-assembly of sterols and quaternary ammonium surfactants. Langmuir ACS J. Surf. Colloids 29, 6519-6528.
Gorinova, C., Aluani, D., Yordanov, Y., Kondeva-Burdina, M., Tzankova, V., Popova, C., Yoncheva, K., 2016. In vitro evaluation of antioxidant and neuroprotective effects of curcumin loaded in Pluronic micelles. Biotechnol. Biotechnol. Equip. 30, 991-997.
Guerzoni, L.P.B., Nicolas, V., Angelova, A., 2017. In vitro modulation of TrkB receptor signaling upon sequential delivery of curcumin-DHA loaded carriers towards promoting neuronal survival. Pharm. Res. 34, 492-505.
Hofer, T., Jørgensen, T.Ø., Olsen, R.L., 2014. Comparison of food antioxidants and iron chelators in two cellular free radical assays: strong protection by luteolin. J. Agric. Food Chem. 62, 8402-8410.
Jug, M., Končić, M.Z., Kosalec, I., 2014. Modulation of antioxidant, chelating and antimicrobial activity of poplar chemo-type propolis by extraction procures. LWT – Food Sci. Technol. 57, 530-537.
Kabanov, A.V., Lemieux, P., Vinogradov, S., Alakhov, V., 2002. Pluronic block copolymers: novel functional molecules for gene therapy. Adv. Drug Deliv. Rev. 54, 223-233.
Li, X., Huang, Y., Chen, X., Zhou, Y., Zhang, Y., Li, P., Liu, Y., Sun, Y., Zhao, J., Wang, F., 2009. Self-assembly and characterization of Pluronic P105 micelles for liver-targeted delivery of silybin. J. Drug Target. 17, 739-750.
Lin, C.C., Yen, M.H., Lo, T.S., Lin, J.M., 1998. Evaluation of the hepatoprotective and antioxidant activity of Boehmeria nivea var. nivea and B. nivea var. tenacissima J. Ethnopharmacol. 60, 9-17.
Lowry, O.H., Rosebrough, N.J., Farr, A.L., Randall, R.J., 1951. Protein measurement with the Folin Phenol reagent. J. Biol. Chem. 193, 265-275.
Mahran, L.G., el-Khatib, A.S., Agha, A.M., Khayyal, M.T., 1996. The protective effect of aqueous propolis extract on isolated rat hepatocytes against carbon tetrachloride toxicity. Drugs Exp. Clin. Res. 22, 309-316.
Mavri, A., Abramovič, H., Polak, T., Bertoncelj, J., Jamnik, P., Smole, S.M., Jeršek, B., 2012. Chemical properties and antioxidant and antimicrobial activities of Slovenian propolis. Chem. Biodivers. 9, 1545-1558.
Misra, H.P., Fridovich, I., 1972. The role of superoxide anion in the autoxidation of epinephrine and a simple assay for superoxide dismutase. J. Biol. Chem. 247, 3170-3175.
Mosmann, T., 1983. Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. J. Immunol. Methods 65, 55-63.
Nita, M., Grzybowski, A., 2016. The role of the reactive oxygen species and oxidative stress in the pathomechanism of the age-related ocular diseases and other pathologies of the anterior and posterior Eye Segments in Adults. Oxid. Med. Cell. Longev., http://dx.doi.org/10.1155/2016/3164734
» http://dx.doi.org/10.1155/2016/3164734
Petrov, P.D., Tsvetanov, C.B., Mokreva, P., Yoncheva, K., Konstantinov, S., Trusheva, B., Popova, M., Bankova, V., 2016. Novel micellar form of poplar propolis with high cytotoxic activity. RSC Adv. 6, 30728-30731.
Sahu, A., Kasoju, N., Goswami, P., Bora, U., 2011. Encapsulation of curcumin in Pluronic block copolymer micelles for drug delivery applications. J. Biomater. Appl. 25, 619-639.
Sawicka, D., Car, H., Borawska, M.H., Nikliński, J., 2012. The anticancer activity of propolis. Folia Histochem. Cytobiol. 50, 25-37.
Sumida, Y., Niki, E., Naito, Y., Yoshikawa, T., 2013. Involvement of free radicals and oxidative stress in NAFLD/NASH. Free Radic. Res. 47, 869-880.
Torok, N.J., 2016. Dysregulation of redox pathways in liver fibrosis. Am. J. Physiol. Gastrointest. Liver Physiol. 311, G667-G674.
Turan, I., Demir, S., Misir, S., Kilinc, K., Mentese, A., Aliyazicioglu, Y., Deger, O., 2015. Cytotoxic effect of Turkish propolis on liver, colon, breast, cervix and prostate cancer cell lines. Trop. J. Pharm. Res. 14, 777-782.
Tyszka-Czochara, M., Paśko, P., Reczyński, W., Szlósarczyk, M., Bystrowska, B., Opoka, W., 2014. Zinc and propolis reduces cytotoxicity and proliferation in skin fibroblast cell culture: total polyphenol content and antioxidant capacity of propolis. Biol. Trace Elem. Res. 160, 123-131.
Tzankova, V., Aluani, D., Kondeva-Burdina, M., Yordanov, Y., Odzhakov, F., Apostolov, A., Yoncheva, K., 2017. Hepatoprotective and antioxidant activity of quercetin loaded chitosan/alginate particles in vitro and in vivo in a model of paracetamol-induced toxicity. Biomed. Pharmacother. 92, 569-579.
Watanabe, M.A.E., Amarante, M.K., Conti, B.J., Sforcin, J.M., 2011. Cytotoxic constituents of propolis inducing anticancer effects: a review. J. Pharm. Pharmacol. 63, 1378-1386.
Weber, L.W.D., Boll, M., Stampfl, A., 2003. Hepatotoxicity and mechanism of action of haloalkanes: carbon tetrachloride as a toxicological model. Crit. Rev. Toxicol. 33, 105-136.
Yang, X., Wang, X., Chen, X.-Y., Ji, H.-Y., Zhang, Y., Liu, A.-J., 2018. Pinocembrin-lecithin complex: characterization, solubilization, and antioxidant activities. Biomolecules 8, http://dx.doi.org/10.3390/biom8020041
» http://dx.doi.org/10.3390/biom8020041
Yoncheva, K., Kamenova, K., Perperieva, T., Hadjimitova, V., Donchev, P., Kaloyanov, K., Konstantinov, S., Kondeva-Burdina, M., Tzankova, V., Petrov, P., 2015. Cationic triblock copolymer micelles enhance antioxidant activity, intracellular uptake and cytotoxicity of curcumin. Int. J. Pharm. 490, 298-307.
Zhao, Y., Tian, W., Peng, W., 2014. Anti-proliferation and insulin resistance alleviation of hepatocellular carcinoma cells HepG2 in vitro by Chinese propolis. J. Food Nutr. Res. 2, 228-235.
Zou, A., Li, Y., Chen, Y., Angelova, A., Garamus, V.M., Li, N., Drechsler, M., Angelov, B., Gong, Y., 2017. Self-assembled stable sponge-type nanocarries for Brucea javanica oil delivery. Colloids Surf. B: Biointerfaces 153, 310-319.

Publication Dates

Publication in this collection
26 Aug 2019
Date of issue
Mar-Apr 2019

History

Received
29 Sept 2018
Accepted
14 Dec 2018
Published
19 Jan 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] Funding

This research did not receive any special grant from funding agencies in the public, commercial or not-for-profit sectors.

[2] Ethical disclosures

Protection of human and animal subjects

The authors declare that the procedures followed were in accordance with the regulations of the relevant clinical research ethics committee and with those of the Code of Ethics of the World Medical Association (Declaration of Helsinki).

Confidentiality of data

The authors declare that no patient data appear in this article.

Right to privacy and informed consent

The authors declare that no patient data appear in this article.

Compound	% of TIC	Compound	% of TIC
Aromatic acid	6.6	Chalcones	1.6
Benzoic acid	0.6	Pinocembrin chalcone	1.0
Cinnamic acid	0.1	Trihydroxymonomethoxy chalconem/z = 502	0.2
p-Hydroxybenzoic acid	0.1	Pinobanksinacetate chalcone	0.4
p-Coumaric acid	0.6	Flavanones and dihydroflavonols	37.3
Dimethoxycinnamic acid	1.1	Pinobanksin	5.2
Ferulic acid (Z)	0.8	Pinocembrin	10.4
Ferulic acid (E)	0.8	Sakuranetin	0.2
Caffeic acid	0.2	Dihydroxymethoxyflavanone	2.1
Caffeic acid	2.1	3-Acetylpinobanksin	14.4
		Pinobanksin butanoate	0.7
Phenolic acid esters	13.0	Pinobanksin propanoate	1.6
Pentenyl coumarate	0.1	Pinobanksin pentanoate	1.8
Pentenyl coumarate (isomer)	0.2	Alpinone	0.2
3-Methyl-3-butenyl ferulate	0.1	Pinobanksin pentenoate	0.7
2-Methyl-2-butenyl ferulate	0.1	Flavones and flavonols	22.6
3-Methyl-2-butenyl ferulate	0.9	Galangin	8.2
2-Methyl-2-butenyl caffeate	0.6	Chrysin	7.6
3-Methyl-2-butenyl caffeate	1.9	Dihydroxymonomethoxy flavone	0.8
Phenylethyl p-coumarate	0.1	Kaempferol	0.9
Benzyl caffeate	2.3	Quercetin	1.1
Benzyl ferulate	0.2	Kaempferol methyl ether	1.3
Cinnamyl caffeate	1.3	Quercetin-methyl ether	1.2
Phenylethyl caffeate	3.7	Quercetin-methyl ether (isomere)	0.7
Others	0.2	Quercetin-methyl ether (isomere)	0.6
Phenylethyl alcohol	0.1	Dihydroxymonomethoxy flavone	0.2
Hexadecanoic acid	0.1	Sugars	3.8

Treatment	Body weight (g)	Liver weight (g)	Food intake (g)
Control	272.1 ± 3.2	6.2 ± 1.2	28.9 ± 3.1
PM	271.9 ± 5.1	5.8 ± 1.1	29.1 ± 2.9
Pr	268.3 ± 4.2	5.9 ± 2.2	30.1 ± 2.8
Pr-PM	270.9 ± 3.8	6.1 ± 2.3	28.9 ± 2.3
CCl₄	271.1 ± 4.1	5.7 ± 3.1	29.7 ± 2.9
Pr/CCl₄	269.2 ± 2.9	5.6 ± 2.8	30.0 ± 2.1
Pr-PM/CCl₄	272.2 ± 4.3	6.2 ± 1.8	29.3 ± 1.8

Parameter	Control	PM	Pr	Pr-PM	CCl₄	CCl₄ + Pr	CCl₄ + Pr-M
White blood cell (10⁹/l)	11.43 ± 2.69	7.45 ± 3.70	9.15 ± 3.14	6.05 ± 3.47	9.51 ± 2.62	7.85 ± 2.07	9.11 ± 4.64
Lymphocyte (10⁹/l)	5.31 ± 2.28	4.45 ± 2.31	5. 01 ± 2.19	3.55 ± 2.48	5.42 ± 1.02	5.43 ± 1.11	5.28 ± 2.37
Granulocyte (10⁹/l)	3.68 ± 0.43	2.78 ± 1.41	3.83 ± 0.91	2.38 ± 0.97^a a p<0.05 vs untreated controls.	3.81 ± 2.43	3.18 ± 1.08	3.53 ± 2.18
Red blood cell (10¹²/l)	8.51 ± 0.54	9.06 ± 0.91	8.71 ± 0.67	7.49 ± 0.45	8.29 ± 0.31	7.68 ± 0.43	7.73 ± 1.61
Hemoglobin (g/l)	149.01 ± 10.52	164.10 ± 18.07	153.25 ± 9.91	139.75 ± 8.85	144.51 ± 4.79	131.75 ± 7.63	136.75 ± 27.84
Hematocrit (%)	47.53 ± 2.85	51.5 ± 5.71	48.125 ± 2.67	41.95 ± 2.65	45.63 ± 1.25	41.98 ± 2.58	47.25 ± 8.47
Red cell distribution width (%)	14.325 ± 1.01	13.43 ± 1.02	13.93 ± 0.96	13.31 ± 0.63	14.35 ± 0.44	14.28 ± 0.71	14.20 ± 0.61

Parameter	Control	PM	Pr	Pr-PM	CCl₄	CCl₄ + Pr	CCl₄ + PrPM
Aspartate aminotransferase (U/l)	199.83 ± 67.22	203.35 ± 8.05	166.51 ± 20.60	149.125 ± 15.88	328.35 ± 28.23^a a p < 0.05 vs untreated controls.	193.51 ± 23.24^c c p < 0.05 vs CCl4-treatment group.	170.05 ± 23.11^c c p < 0.05 vs CCl4-treatment group.
Alanine aminotransferase (U/l)	79.75 ± 14.60	77.60 ± 10.95	79.46 ± 20.31	68.41 ± 5.06	368.18 ± 65.01^b b p < 0.01 vs untreated controls.	75.42 ± 12.21^d d p < 0.01 vs CCl4-treatment group.	69.18 ± 13.78^d d p < 0.01 vs CCl4-treatment group.
Total protein (g/l)	63.73 ± 3.78	63.88 ± 2.29	65.23 ± 1.12	64.93 ± 2.99	64.91 ± 1.2	64.93 ± 3.39	63.08 ± 2.64
Alkaline phosphatase (U/l)	551.01 ± 13.29	530.75 ± 58.36	557.51 ± 58.48	575.25 ± 72.51	732.25 ± 29.07^a a p < 0.05 vs untreated controls.	535.25 ± 57.73^c c p < 0.05 vs CCl4-treatment group.	533.25 ± 60.38^c c p < 0.05 vs CCl4-treatment group.

Brasil

Brasil

Micellar propolis nanoformulation of high antioxidant and hepatoprotective activity

ABSTRACT

Introduction

Material and methods

Chemicals

Propolis extraction

Preparation of propolis loaded polymeric micelles

Characterization of propolis loaded polymeric micelles

Cell lines and culturing

Model of oxidative stress in vitro

Animal selection and care

In vivo model of CCl₄-induced liver toxicity

Biomarkers of oxidative stress damage in liver

MDA determination and glutathione (GSH) depletion

Analysis of antioxidant enzyme activity

Biochemistry and hematology parameters

Histological analysis

Statistical analysis

Results

Chemical composition of the propolis extract

Preparation and physicochemical characterization of propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ micelles

Micelles

In vitro protective effects in a model of H₂O₂-induced oxidative stress

In vivo hepatoprotection in a model of carbon tetrachloride-induced toxicity

Clinic observations

Hematology and serum biochemistry analysis

Oxidative stress markers assay in liver

Liver antioxidant enzyme assay

Liver histopathological examination

Discussion

Conclusion

References

Publication Dates

History

Brasil

Brasil

Micellar propolis nanoformulation of high antioxidant and hepatoprotective activity

ABSTRACT

Introduction

Material and methods

Chemicals

Propolis extraction

Preparation of propolis loaded polymeric micelles

Characterization of propolis loaded polymeric micelles

Cell lines and culturing

Model of oxidative stress in vitro

Animal selection and care

In vivo model of CCl4-induced liver toxicity

Biomarkers of oxidative stress damage in liver

MDA determination and glutathione (GSH) depletion

Analysis of antioxidant enzyme activity

Biochemistry and hematology parameters

Histological analysis

Statistical analysis

Results

Chemical composition of the propolis extract

Preparation and physicochemical characterization of propolis-loaded PEO26–PPO40–PEO26 micelles

Micelles

In vitro protective effects in a model of H2O2-induced oxidative stress

In vivo hepatoprotection in a model of carbon tetrachloride-induced toxicity

Clinic observations

Hematology and serum biochemistry analysis

Oxidative stress markers assay in liver

Liver antioxidant enzyme assay

Liver histopathological examination

Discussion

Conclusion

References

Publication Dates

History

In vivo model of CCl₄-induced liver toxicity

Preparation and physicochemical characterization of propolis-loaded PEO₂₆–PPO₄₀–PEO₂₆ micelles

In vitro protective effects in a model of H₂O₂-induced oxidative stress