Abstract
Biodegradable galactosylated methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid) (Gal-PEG-b-PLMA) block copolymer micelles were successfully prepared by a solvent diffusion method, and could efficiently encapsulate doxorubicin. The Gal-PEG-b-PLMA micelles before and after doxorubicin loading were characterized by size, morphology, in vitro drug release, and in vitro cytotoxicity in HepG2 cells. Transmission electron microscopy and dynamic light scattering results showed that the empty and doxorubicin-loaded micelles were approximately spherical in shape and had mean sizes of about 72 nm and 85 nm, respectively. In vitro release behavior of doxorubicin from the micelles was pH-dependent, with obviously faster release rates at mildly acidic pH 4.5 and 5.5 compared with physiologic pH 7.4. Methylthiazoletetrazolium assay and flow cytometric analysis indicated that the doxorubicin-loaded galactosylated micelles exhibited a greater growth-inhibitory effect on HepG2 cells than the nongalactosylated doxorubicin-loaded micelles, and induced S phase cell cycle arrest. Confocal laser scanning microscope observations revealed that the galactosylated micelles could be efficiently internalized by HepG2 cells through receptor-mediated endocytosis. The results suggest that Gal-PEG-b-PLMA copolymer micelles are a promising carrier system for targeted drug delivery in cancer therapy.
Keywords: polymer micelles, targeted drug delivery, doxorubicin, chemotherapy, hepatocellular carcinoma
Introduction
Hepatocellular carcinoma (HCC) is the third leading cause of cancer-related death throughout the world,1 and is strongly associated with highly prevalent hepatitis B virus infections and exposure to food contaminated with aflatoxin B1. In China alone, the estimated annual incidence of new HCC cases is more than 350,000 (approximately 55% of global HCC cases),2 and HCC is the second most common cause of cancer-related death. Surgical resection is considered the optimal treatment approach, but is very limited in HCC patients because of high rates of recurrence and metastasis after surgery. Moreover, conventional chemotherapy is associated with toxicity to normal tissues. In addition, HCC is well known to be highly resistant to chemotherapy drugs.3 Therefore, it is of great importance to search for more effective systemic chemotherapeutic options to improve the survival rate of HCC patients.4 Amongst these, the rapid development of targeted drug delivery systems holds great promise for the treatment of HCC.
Doxorubicin, a well known anticancer drug, has shown strong antitumor activity against various solid tumors, including those of the breast, bladder, lung, ovary, and liver.5 However, its clinical therapeutic potential is restricted by both low bioavailability and serious systemic toxic side effects to normal tissues. To address these problems, a great deal of effort has been focused on developing novel drug delivery systems, including liposomes, micelles, dendrimers, hyperbranched polymers, microspheres, and hydrogels.6–8 During this time, nanosized polymeric delivery systems have attracted considerable attention, because they not only control drug-release kinetics but also preferentially accumulate in solid tumors via passive targeting based on an enhanced permeability and retention effect. Amongst the biodegradable and nontoxic polymers used to prepare nanocarriers, amphiphilic block copolymers have been extensively explored and are rapidly advancing. They can self-assemble into spherical micelles exhibiting a core-shell architecture composed of hydrophobic segments as their inner core and hydrophilic segments as their outer shell in aqueous media.9 The core serves as a nanodepot for hydrophobic anticancer drugs,10 and is protected by the hydrophilic shell.
However, more and more observations show that no substantial therapeutic improvement can be sufficiently guaranteed by passive targeting.11 As we know, the sites of action of many chemotherapeutic agents are located in cells, and the efficient intracellular uptake of drugs by cancer cells is regarded as the determining step for antitumor activity. Therefore, many researchers have aimed to develop more effective site-specific delivery strategies by incorporating targeting ligands or antibodies into the surfaces of drug carriers, permitting them to be taken up by active receptor-mediated endocytosis.12–14 This can significantly improve the therapeutic effect of anticancer drugs and minimize toxic side effects to normal tissues.15 In active targeted therapy for HCC, galactose is considered to be a promising ligand because it can specifically recognize and bind asialoglycoprotein receptor, which is overexpressed exclusively on the surfaces of hepatic parenchymal cells.16,17 Galactose has been conjugated to drug carriers to achieve targeted chemotherapeutic or diagnostic agent delivery to HepG2 cells overexpressing the asialoglycoprotein receptor, although the precise mechanism of asialoglycoprotein receptor-mediated uptake of galactose-modified carriers into HepG2 cells remains unresolved.
The most prominent synthetic polyesters, such as polylactide, poly(lactic-co-glycolic acid), poly(ɛ-caprolactone), and their derivatives, have been extensively used in biomedical fields of controlled drug delivery, suture lines, and tissue engineering18 because they are nontoxic, biocompatible, and bioabsorbable in vivo. However, when used as drug carriers, the high crystallinity of polylactide would lead to a slow degradation rate, resulting in retarded drug release. Therefore, polylactide is usually copolymerized with functional monomers or grafted onto natural polymers to obtain ideal copolymers. Recently, some biodegradable polymers with pendant functional groups, such as hydroxyl, carboxyl, amine, and carboxylate, are attracting more interest because they may be used to conjugate drug molecules via functional covalent bonds and electrostatic actions, endowing the carriers with stimuli-responsive properties. In the past few years, poly(lactic acid-co-malic acid) (PLMA), a biocompatible and biodegradable copolyester with pendent carboxyl groups, has attracted some attention in biomedical applications.19–21 In this study, PLMA was evaluated as a potential antitumor drug carrier. We prepared targeting polymeric micelles from amphiphilic PEG-b-PLMA copolymer and investigated the feasibility of galactosylated PEG-b-PLMA (Gal-PEG-b-PLMA) micelles as an active targeting carrier for the targeted delivery of doxorubicin to HepG2 cells. The doxorubicin-loaded polymer micelles were characterized in terms of size and morphology, drug loading, in vitro drug-release behavior, and in vitro cell cytotoxicity.
Materials and methods
Materials
The HepG2 cell line used in this study was obtained from the Cell Institute of Academia Sinica (Shanghai, China). Doxorubicin was supplied by Beijing Huafeng United Technology Co. Ltd. (Beijing, China). Fetal bovine serum and bovine calf serum were purchased from Hangzhou Sijiqing Biological Engineering Materials Co., Ltd. (Hangzhou, China). 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT), 1-ethyl-3,3-dimethylaminopropyl carbodiimide hydrochloride (EDC), triethylamine, poly(ethylene glycol) bis(amine) (NH2-PEG-NH2, molecular weight 2000), and methoxy poly(ethylene glycol) (molecular weight 2000) were obtained from Sigma Co. (Shanghai, China). N-hydroxysuccinimide (NHS) was obtained from Sinopharm Chemical Reagent Co. (Shanghai, China). Dulbecco’s Modified Eagle’s Medium, RPMI-1640 medium, trypsin-EDTA (0.5% trypsin, 5.3 mM EDTA), and the antibiotic agents penicillin-streptomycin (100 U/mL) were purchased from Gibco BRL (Gaithersburg, MD). The dialysis membrane (molecular weight cutoff 3500 Da) was purchased from Beijing Solar-bio Science and Technology Co., Ltd. (Beijing, China). The block copolymers were synthesized in our laboratory. All other chemicals were commercial products of analytic reagent grade, and were used as received unless otherwise stated.
Synthesis of PEG-b-PLMA and Gal-PEGb-PLMA copolymers
Poly(l-lactide-co-β-benzyloxycarbonyl-β-propiolactone) (PLBCP), with a nominal molar ratio of about 85:15, and its block copolymer with methoxy-poly(ethylene glycol), ie, PEG-b-PLBCP, were synthesized as previously reported in the literature22,23 with some changes. Briefly, predetermined amounts of l-lactide (LA) and β-benzyloxycarbonyl-β-propiolactone (BCP) or their mixture with MPEG were placed in a polymerization tube (8 mL), and 0.5 mL of dried toluene solution containing the catalyst Sn(Oct)2 (0.1% w/w) was added into the tube. The tube was evacuated by a vacuum pump at 30°C for 3 hours and then sealed. The ring-opening copolymerization was performed at 140°C for 24 hours. After polymerization, the reaction system was cooled to ambient temperature, and the product was dissolved in CH2Cl2, precipitated twice with cold diethyl ether, and dried at 35°C for 36 hours in a vacuum oven. Galactosylated PEG-b-PLBCP (Gal-PEG-b-PLBCP) was further synthesized by conjugating PLBCP with Gal-PEG-NH2 at room temperature for 48 hours via the carbodiimide method. Gal-PEG-NH2 was obtained from galactose and NH2-PEG-NH2 through the condensation reaction between NH2-PEG-NH2 and galactonic acid in the presence of NHS/EDC. Before entrapping drug or preparing micelles, PEG-b-PLBCP and Gal-PEG-b-PLBCP were transformed, respectively, into PEG-b-PLMA and Gal-PEG-b-PLMA by removing the protecting benzyl groups of BCP units by introducing H2 in the presence of a Pd/C catalyst.
Preparation of polymer micelles and drug loading
Empty and doxorubicin-loaded polymer micelles were prepared by a solvent diffusion method. Briefly, 50 mg of PEG-b-PLMA or its mixture with Gal-PEG-b-PLMA (molar ratio of 25:1) dissolved in 2 mL of CH2Cl2, with or without addition of 1–15 mg of doxorubicin dissolved in 0.25 mL of dimethyl sulfoxide, was added dropwise into 10 mL of aqueous solution in a round-bottom flask under magnetic stirring at room temperature. The mixture was sonicated for 30 minutes to form a homogeneous micelle solution. Gentle stirring was continued under reduced pressure until the organic solvent had evaporated completely. The micelles were recovered by centrifugation at 12,000 × g and washed 3 times with deionized water. Dry nanomicelles were also collected by freeze drying.
To determine drug loading content and encapsulation efficiency, doxorubicin-loaded micelles were separated by centrifugation at 12,000 × g, and the exact doxorubicin concentration in the solutions was determined by ultraviolet-visible spectrometry (Ultraviolet-visible Spectrophotometer, Puxi Scientific Instruments, Beijing, China) by monitoring the characteristic absorbance of doxorubicin at 480 nm using a calibration curve. The calibration curve of the ultraviolet-visible absorbency was generated with a known doxorubicin concentration range of 0.01–45 μg/mL. Drug loading content was expressed as the percentage of drug amount loaded into micelles with respect to the total amount of drug-loaded micelles. Encapsulation efficiency was defined as the percentage of the drug amount incorporated into micelles with respect to the initially added drug amount to the formulation. All samples were analyzed in triplicate.
Micelle characterization
The morphology of the prepared copolymeric micelles was characterized by transmission electron microscopy (TEM, JEM-200CX, Jeol Co., Japan). A drop of diluted micellar solution (0.1 mg/mL) was placed on a copper TEM grid, and observed at an accelerating voltage of 80 kV. The micelle size and size distribution were measured by dynamic light scattering using a Zetasizer Nano-ZS size analyzer (Malvern Instruments Ltd., Malvern, UK). Measurements were carried out in double-distilled H2O at 25°C and at a fixed wavelength of 633 nm.
The critical micelle concentration of the block polymers was determined by the pyrene method.24 The concentration of polymer solutions was varied from 0.02 μg/mL to 0.2 mg/mL, and the final concentration of fluorescence probe pyrene was fixed at 0.2 μg/mL. The fluorescence spectra were recorded using an LS55 spectrometer (Perkin-Elmer, Waltham, MA) with an excitation wavelength of 350 nm. Emission fluorescence at 372 and 383 nm was monitored. Dynamic light scattering and critical micelle concentration measurements were done in triplicate for each sample, and the results were taken as the average of three measurements.
In vitro release of doxorubicin from polymer micelles
In vitro release behavior of doxorubicin from PEG-b-PLMA micelles (about 8% drug-loaded samples) was observed for 72 hours in phosphate-buffered saline at different pH (4.5, 5.5, and 7.4) using a dialysis-diffusion method. Briefly, doxorubicin-loaded micelles were diluted with corresponding phosphate-buffered saline to give the desired concentration (2 mg/mL, 0.5 mL) and sealed in a dialysis bag, and the dialysis bag was immersed in 10 mL of the release buffer in a 15 mL capped centrifuge tube. The centrifuge tubes were placed in an incubator shaker with gentle shaking at 37°C. At predetermined time intervals, 1 mL of release buffer was withdrawn from the tube and replaced with the same amount of fresh buffer. The amount of doxorubicin released in the collected buffer samples was determined by ultraviolet-visible spectrophotometric analysis. The release experiments were conducted in triplicate, and the results presented are average data.
In vitro cell cytotoxicity
For all the cell culture studies, HepG2 cells were used as a model tumor cell line and maintained in RPMI1640 medium with 10% fetal bovine serum, 0.1% nonessential amino acids, and 100 U/mL penicillin-streptomycin at 37°C in a humidified atmosphere containing 5% CO2. The in vitro anticancer effect (cytotoxicity) of the drug-loaded micelles was evaluated using the MTT assay. Briefly, HepG2 cells at logarithmic growth phase were separately seeded in 96-well plates at a seeding density of 1 × 104 cells/well and incubated for 24 hours to allow the cells to attach, followed by washing with ice-cold phosphate-buffered saline three times and replacing with fresh medium. Thereafter, the cells were treated with free doxorubicin, doxorubicin-loaded PEG-b-PLMA micelles, and Gal-PEG-b-PLMA micelles. The equivalent concentration of doxorubicin in the three formulations was set at 0.05–40 μg/mL. After the predetermined incubation time, 20 μL MTT solution (5 mg/mL in phosphate-buffered saline) was added to each well, and four hours later each well was replaced with dimethyl sulfoxide to ensure solubilization of formazan crystals. Cell viability was quantified by measuring absorbance at 570 nm on a microplate reader (EL310, Bio-Tek Instruments Inc., Winooski, VT), calculated and expressed as a percentage of the absorbance in control cells compared with that in the treated cells.
Intracellular uptake of doxorubicin
To observe the intracellular doxorubicin distribution in micelles, the HepG2 cells were seeded in Lab-Tek® eight-well chambers (Nalgene, Nunc Inc., Denmark) at a density of 5.0 × 104 cells/well and cultured overnight, followed by coincubation with the three doxorubicin formulations (equivalent doxorubicin concentration 5 μg/mL) for 12 hours. The treated cells were washed three times with ice-cold phosphate-buffered saline (pH 7.4), fixed with 4% paraformaldehyde in 95% ethanol at −20°C overnight, and examined by a confocal laser scanning microscope at excitation and emission wavelengths of 490 and 560 nm, respectively. The HepG2 cells were washed once again with phosphate-buffered saline before flow cytometry analysis (FACScan flow cytometry, BD Biosciences, Franklin Lakes, NJ). The experiments were performed in triplicate and the data were analyzed using the FAC station software program.
Statistical analysis
Results were expressed as mean ± standard deviation based on three independent measurements. Statistical analyses were performed by one-way analysis of variance to determine differences among the measured properties of each group using a statistical program (SPSS 10; SPSS Inc, Chicago, IL). Statistical significance was defined as a probability level of P < 0.05 in all cases.
Results and discussion
Synthesis of Gal-PEG-b-PLMA copolymer
The schematic synthesis procedure for Gal-PEG-b-PLMA copolymers is shown in Figure 1. The ring-opening copolymerization of two cyclic aliphatic lactone monomers, LA and BCP, could proceed smoothly in the absence or presence of MPEG-OH at 140°C using Sn(Oct)2 as a catalyst, and the removal of protecting benzyl groups in BCP units yielded the corresponding PLMA or PEG-b-PLMA copolymer. Their physical properties are summarized in Table 1. The molecular weight of PLMA was Mn 11.5 kDa, with a polydispersity of 1.32. Gal-PEG-b-PLMA was further synthesized from Gal-PEG-NH2 and PLMA in anhydrous dimethyl sulfoxide via the condensation reaction between the amino groups of Gal-PEG-NH2 and the carboxylic groups of PLMA in the presence of NHS/EDC. When the copolymerization of LA and BCP was performed in the presence of PEG, the feed molar ratio of PEG to the two monomers was set at 1.39:85:15. The final copolymer had a PEG/LA/BCP molar ratio of 1.4:86:14, which was close to the ratio in feed, whereas, in the absence of PEG, the LA/BCP molar ratio of PLMA copolymer was 87:13, and also approximated the feed molar ratio of 85:15. These findings indicate that these two cyclic ester monomers are capable of copolymerizing in the absence or presence of PEG to produce PLMA and PEG-b-PLMA copolymers.
Figure 1.
Synthesis scheme of PEG-b-PLMA and Gal-PEG-b-PLMA copolymers.
Abbreviations: PEG-b-PLMA, methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid) block copolymer; Gal-PEG-b-PLMA, galactosylated methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid) block copolymer.
Table 1.
Physical properties of PLMA and PEG-b-PLMA copolymers
| Molar ratio in feed (PEG/LA/BCP) | Molar ratio in copolymer (PEG/LA/MA) | Yield (%) | Mn (1H NMR) | Polydispersity | |
|---|---|---|---|---|---|
| PLMA | 0:85:15 | 0:87:13 | 92 | 11500 | 1.32 |
| PEG-b-PLMA | 1.39:85:15 | 1.4:86:14 | 95 | 13000 | 1.16 |
Abbreviations: PLMA, poly(l-lactide-co-β-malic acid); PEG-b-PLMA, methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid) block copolymer.
Preparation and characterization of polymer micelles
In general, the micellization of amphiphilic block copolymers in a selective solvent of one of the blocks is a typical feature of their colloidal properties. In the present study, when amphiphilic PEG-b-PLMA copolymer was dissolved in an aqueous solution that was a thermodynamically good solvent for PEG block and a precipitant for PLMA block, the copolymer chains could associate reversibly to form micellar aggregates, in which the hydrophobic PLMA cores were surrounded by hydrophilic PEG shells. Therefore, the hydrophobic doxorubicin could be incorporated into micelles through the partitioning of doxorubicin within the cores of PEG-b-PLMA micelles formed by self-assembly of the copolymer.
The size and morphology of empty and doxorubicin-loaded PEG-b-PLMA micelles were investigated by dynamic light scattering and TEM. Figure 2 shows the typical size distribution profiles and mean sizes of empty and doxorubicin-loaded PEG-b-PLMA micelles. As shown in Figure 2, empty and doxorubicin-loaded micelles exhibit narrow unimodal size distributions, and the corresponding mean sizes are about 71.9 ± 8.4 nm and 84.5 ± 11.4 nm, respectively. The dynamic light scattering result indicates that the entrapped doxorubicin molecules in the hydrophobic PLMA inner cores increased the mean size of the micelles. The TEM images of empty and drug-loaded PEG-b-PLMA micelles (as shown in Figure 3) indicate that the micelles had approximately spherical morphology and a smooth surface without any aggregation, and the average sizes of the micelles before and after doxorubicin loading were about 61 nm and 70 nm, respectively, which were smaller than those determined by dynamic light scattering. The most probable reason for this is the shrinkage of the PEG shell caused by the evaporation of water during drying before TEM observations. As we know, the particle size and surface characteristics of micelles have a significant impact on the in vivo fate of a micelle drug delivery system. Generally, micelles of < 100 nm diameter with hydrophilic surfaces have a longer circulation time in blood and can selectively accumulate at tumor sites as a result of an enhanced permeability and retention effect25 or be preferentially taken up by tumor cells via receptor-mediated endocytosis,26 because they readily escape from monocytes and the reticuloendothelial system.
Figure 2.
Size distributions of (A) empty, (B) doxorubicin-loaded Gal-PEG-b-PLMA micelles, and (C) their mean sizes measured by dynamic light scattering method.
Abbreviation: Gal-PEG-b-PLMA, galactosylated methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid) block copolymer.
Figure 3.
Transmission electron microscopic images of (A) empty and (B) doxorubicin loaded Gal-PEG-b-PLMA micelles.
Abbreviation: Gal-PEG-b-PLMA, galactosylated methoxy poly (ethylene glycol)/poly (l-lactide-co-β-malic acid) block copolymer.
Doxorubicin has demonstrated significant activity in clinical applications against a wide variety of tumors. However, its serious side effects in normal tissues restrict its wide application. Therefore, the incorporation of doxorubicin into the cores of PEG-b-PLMA micelles would not only increase solubility of the drug but also reduce side effects. During the experiments, the amount of doxorubicin incorporated into the polymer micelles increased as the initial feed weight ratio of doxorubicin to copolymer increased. The drug loading content and encapsulation efficiency of doxorubicin in PEG-PLMA micelles could vary from 2.58% ± 0.44% and 28.1% to 16.4% ± 0.58% and 92.5%, respectively, by adjusting the feed drug-to-polymer weight ratio. The reason for the high drug-loading capacity is that doxorubicin could be encapsulated into the PEG-b-PLMA micelles through the cooperative hydrophobic and electrostatic (hydrogen bond) interactions between the PLMA block with pendant carboxylic groups and doxorubicin with an amine group. However, when the feed weight ratio of doxorubicin to polymer was higher than 0.16:1, little aggregation was found, and drug-loading efficiency gradually decreased due to the hydrophobic nature of doxorubicin. Thus, the initial feed weight ratio of doxorubicin to polymer was fixed at 0.11:1 for all samples, and the actual drug loading content and encapsulation efficiency were 7.93% ± 0.56% and 83.2% ± 3.7%, respectively. In addition, the critical micelle concentration values of PEG-b-PLMA and Gal-PEG-b-PLMA were as low as 0.9 and 1.1 μg/mL, respectively. The results suggested that the micelles had high stability and would have the ability to maintain their integrity even with strong dilution in the body.
In vitro release profile of doxorubicin from micelles
Characterization of the in vitro release of doxorubicin from PEG-b-PLMA micelles is important to assess the stability of doxorubicin incorporated into the micelle. The in vitro release behavior of doxorubicin from PEG-b-PLMA micelles was investigated by the dialysis method at 37°C and at pH 4.5, 5.5, and 7.4, as shown in Figure 4. The results demonstrate that the micelles exhibited pH-dependent release behavior, whereby much faster release of doxorubicin took place at an acidic pH 4.5 and 5.5 than at physiologic pH 7.4. For instance, at least 30, 20, and 10% of the initial doxorubicin amount was released within 5 hours at pH 4.5, 5.5, and 7.4, respectively, while within 48 hours, about 78%, 67%, and 31% of doxorubicin was released at pH 4.5, 5.5, and 7.4, respectively. It should be noted that over 65% of the doxorubicin was released at a lower pH of 4.5 after 24 hours. These results suggest that rapid drug release at endosomal pH renders the pH-responsive micelles promising as smart nanovehicles for triggered release of lipophilic anticancer drugs. The in vitro release profile depicted in Figure 4 indicates two-phase release behavior, ie, a burst release during the initial several hours, followed by a slow sustained-release phase, which can be described by the zero-order equation and Higuchi’s equation, respectively. A burst release of 15%–45% doxorubicin occurred in the first 10 hours, and is attributed to those drug molecules existing near the micellar surface and on the interface of the micelle hydrophobic core and hydrophilic shell, which easily diffuse within the first few hours of incubation via both passive diffusion and hydration, whereas the drug incorporated into the inner core compartment inside the micelles would be responsible for sustained release after the first 10 hours. The results indicated that release of drug from the micelles was diffusion-controlled.
Figure 4.
In vitro release behavior of doxorubicin from PEG-b-PLMA micelles at pH 4.5, 5.5, and 7.4. Each point and error bar represents mean ± standard deviation (n ± 3).
Abbreviation: PEG-b-PLMA, methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid).
The mechanism of pH-responsive doxorubicin release might involve protonation of the amine group of doxorubicin and the ionization degree of the carboxylic groups in the PLMA block (pKa value of PLMA copolymer 3.81). Under physiologic conditions, the hydrophobic and electrostatic interactions between PLMA and doxorubicin were relatively strong, and could prevent rapid drug release. However, under mildly acidic conditions, the protonation degree of doxorubicin increases, and the ionization degree of the carboxyl groups in PLMA decreases, which leads to weaker interaction between doxorubicin and PLMA. At the same time, repulsion between protonated doxorubicin molecules might facilitate doxorubicin to diffuse out of the micelles. In addition, the carboxylic acid groups could catalyze the hydrolysis degradation of PLMA at low pH values, namely, PLMA erosion. The above three mechanisms could lead to rapid in vitro release.
In vitro cytotoxicity in HepG2 cells
The cytotoxic mechanism of doxorubicin involves induction of DNA damage, inhibition of cell proliferation, cell cycle status, and cell death.27 To determine the biologic effects of doxorubicin in HepG2 cells, the cytotoxicity of serial equivalent concentrations of doxorubicin in the three different formulations (free doxorubicin, doxorubicin-loaded PEG-b-PLMA micelles, and doxorubicin-loaded Gal-PEG-b-PLMA micelles) to HepG2 cells was investigated by MTT assay after 24 hours of incubation, as shown in Figure 5. Empty PEG-b-PLMA micelles were used as a negative control. HepG2 cells were reported to overexpress asialoglycoprotein receptors on their surface and to be sensitive to doxorubicin.28,29 Figure 5 shows clearly that the viability of HepG2 cells gradually decreased with increasing doxorubicin concentration. Significant differences in cell cytotoxicity were observed among the three formulations at high doxorubicin doses (>0.5 μg/mL).
Figure 5.
In vitro cytotoxicity of free doxorubicin, doxorubicin-loaded PEG-b-PLMA micelles and doxorubicin-loaded Gal-PEG-b-PLMA micelles in HepG2 cells. Data are shown as mean ± standard deviation (n = 3).
Abbreviations: PEG-b-PLMA, methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid); Gal-PEG-b-PLMA, galactosylated methoxy poly(ethylene glycol)/poly (l-lactide-co-β-malic acid).
In the case of PEG-b-PLMA micelles without galactose groups, the viability of HepG2 cells was as high as 73.2% when the concentration of doxorubicin was 1 μg/mL. In contrast, galactosylated micelles exhibited significantly superior cytotoxicity against HepG2 cells, and the cell survival rate was 65.4%. The cells treated with the doxorubicin-loaded Gal-PEGb-PLMA micelles exhibited lower survival rates than those treated with doxorubicin-loaded PEG-b-PLMA micelles. This result implies that galactosylated micelles could be effectively transferred into HepG2 cells via galactose receptor-mediated endocytosis, producing more efficient killing of cancer cells.
Apoptosis of HepG2 cells induced by the three formulations was also observed by flow cytometry. The respective doxorubicin concentration was adjusted to 5 μg/mL, and the cells were treated with the test solutions for 12 hours. Figure 6 shows the cell cycle profiles of HepG2 cells before and after the doxorubicin treatments. As shown in Figure 6, significant S phase cell cycle arrest is observed in all three doxorubicin treatment groups. The percentages of cells in the S phase are 39.3% ± 1.84% for the free doxorubicin group, 53.2% ± 3.1% for the doxorubicin-loaded PEG-b-PLMA micelle group, and 47.6% ± 2.1% for the doxorubicin-loaded Gal-PEG-b-PLMA micelle group, respectively, and are much higher than the 27.2% ± 0.86% recorded for the control group. This result is accompanied by lower percentages of G0/G1 phase cells and higher percentages of G2/M phase cells in the three doxorubicin-treated groups. It is also noted that the percentages of S phase cells in the two doxorubicin-loaded micelle groups are higher than those in the free doxorubicin group. However, no obvious cell cycle changes were found among the three doxorubicin formulations. Therefore, doxorubicin released from micelles can restore the cell cycle in HepG2 cells, ie, blocking cells at the S phase and retarding G2/M phase progression.
Figure 6.
The cell cycle profiles of HepG2 cells before and after doxorubicin treatment for 12 hours: A) control group, B) free doxorubicin group, C) doxorubicin-loaded PEG-b-PLMA micelle group, and D) doxorubicin-loaded Gal-PEG-b-PLMA micelle group. The data represent mean ± standard deviation where n = 3.
Abbreviations: PEG-b-PLMA, methoxy poly(ethylene glycol)/poly(l-lactide-co-β-malic acid); Gal-PEG-b-PLMA, galactosylated methoxy poly(ethylene glycol)/poly (l-lactide-co-β-malic acid).
Targeting activity of Gal-PEG-b-PLMA micelles in HepG2 cells
The intracellular delivery of doxorubicin into tumor cells is essential to its antitumor activity, because its site of action is at the double-stranded helix DNA in cell nuclei.11 Therefore, to endow a drug carrier with active targeting ability, a bioactive ligand must be available on the carrier surface for efficient chemical ligation of the ligand and its receptor. The cellular uptake of the three doxorubicin formulations in HepG2 cells was evaluated by confocal laser scanning microscopy, and the representative images of HepG2 cells are shown in Figure 7. All three doxorubicin formulations had an equivalent doxorubicin concentration of 5 μg/mL. It can be seen from Figure 7 that fluorescent doxorubicin was visualized in HepG2 cells treated with the three doxorubicin formulations. However, the detected fluorescence in cells treated with doxorubicin-loaded PEG-b-PLMA micelles was much weaker than that in the cells treated with doxorubicin-loaded targeted micelles, indicating that doxorubicin-loaded Gal-PEG-b-PLMA micelles were more efficiently internalized by HepG2 cells. The result confirmed that galactose-modified micelles could be selectively uptaken by HepG2 cells via asialoglycoprotein receptor-mediated endocytosis.
Figure 7.
Confocal laser scanning microscopic images of HepG2 cells (5 × 104 cells/mL) after 12 hours of in vitro exposure to (A) free doxorubicin, (B) doxorubicin-loaded PEG-b-PLMA micelles, and (C) doxorubicin-loaded Gal-PEG-b-PLMA micelles.
Abbreviations: PEG-b-PLMA, methoxy poly(ethylene glycol)/poly (l-lactide-co-β-malic acid); Gal-PEG-b-PLMA, galactosylated methoxy poly(ethylene glycol)/poly(llactide-co-β-malic acid).
Conclusion
New amphiphilic PEG-PLMA block copolymer micelles were successfully developed for targeted delivery of poorly soluble doxorubicin to HepG2 cells. The polymer micelles, composed of a PEG block as the hydrophilic shell and a PLMA block with pendant carboxylic groups as the hydrophobic core, could effectively incorporate doxorubicin through the combination of hydrophobic and electrostatic interactions between doxorubicin and PLMA. The critical micelle concentration value, drug loading content, and encapsulation efficiency of doxorubicin in the PEG-PLMA micelles were about 1 μg/mL, 8wt%, and 83%, respectively. The doxorubicin-loaded or -nonloaded micelles exhibited a smooth surface and spherical shape, and had an average size of less than 100 nm. The micelles showed pH-responsive release behavior, ie, doxorubicin release at mildly acidic pH 4.5 and pH 5.5 was much faster than that at physiologic pH 7.4. The pH-responsive release behavior is closely related to the presence of carboxyl groups in the PLMA block. Gal-PEG-b-PLMA micelles could be selectively taken up by HepG2 cells through asialoglycoprotein receptor-mediated endocytosis, and exhibited much higher cytotoxicity than ungalactosylated micelles. The doxorubicin-loaded micelles could produce S cell cycle arrest in HepG2 cells. Therefore, the pH-responsive PEG-b-PLMA micelles are promising nanovehicles for targeted delivery of poorly soluble anticancer drugs.
Acknowledgment
This research was supported by grants from the National Natural Science Foundation of China (No. 50773062 and No. 30830099), the Natural Science Basic Research Plan in Shaanxi Province of China (No. SJ08-ZT12), and the Fundamental Research Funds for the Central Universities (No. XJJ20100115).
Footnotes
Disclosure
The authors report no conflicts of interest in this work.
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