青蒿琥酯纳米颗粒的制备及其体外抑制肿瘤细胞增殖的作用研究

目的：用壳聚糖（Chitosan,CS）和三聚磷酸钠（tripolyphosphate,TPP）交联制备包载青蒿琥酯纳米粒,并探讨其在体外对肿瘤细胞增殖的抑制作用。方法：以壳聚糖-三磷酸钠（CS／TPP）为基质并优化其比例,采用离子凝胶法制备包载青蒿琥酯（ART）纳米粒,对其进行表征包括粒径大小、Zeta电位、包封率、载药量和体外释放试验,以及红外光谱分析。用MTT法检测包栽青蒿琥酯的壳聚糖·三磷酸钠纳米粒对Hela、Caski、U251、MCF-7和HepG2细胞增殖的抑制作用。结果：成功构建青蒿琥酯一壳聚糖．三磷酸钠纳米颗粒（ARTnanoparticals,ART-NPs）,平均粒径为166．8±0．2nnl,电位为10．2±0．79mV,红外光谱分析表明CS厂rPP成功连接并包裹ART,平均载药量和包封率分别为18％和74．82％;体外释放呈典型的双相分布,前24h呈暴发性释放（44．2％）,其后缓慢释放,第9天累积释放度达67．4％。对不同肿瘤细胞的杀伤作用呈浓度和时间依赖趋势,且ART-NPs作用优于单-ART;相同浓度的ART-NPs在96h时对细胞增殖的抑制率明显高于ART组（P〈O．05）。结论：用壳聚糖和三磷酸钠交联可成功包载青蒿琥酯制成具有缓释性的纳米制剂,对肿瘤细胞的生长具有明显的抑制作用,有潜在的肿瘤治疗价值。     

Comparative Studies on Chitosan and Polylactic-co-glycolic Acid Incorporated Nanoparticles of Low Molecular Weight Heparin

This study was performed to test the feasibility of chitosan and polylactic-co-glycolic acid (PLGA) incorporated nanoparticles as sustained-release carriers for the delivery of negatively charged low molecular weight heparin (LMWH). Fourier transform infrared (FTIR) spectrometry was used to evaluate the interactions between chitosan and LMWH. The shifts, intensity, and broadening of the characteristic peaks for the functional groups in the FTIR spectra indicated that strong interactions occur between the positively charged chitosans and the negatively charged LMWHs. Three types of LMWH nanoparticles (NP-1, NP-2, and NP-3) were prepared using chitosan with or without PLGA: NP-1 nanoparticles were formed by polyelectrolyte complexation after single mixing, NP-2 nanoparticles were prepared by polyelectrolyte complexation after single emulsion–diffusion–evaporation, and NP-3 nanoparticles were optimized by double emulsion–diffusion–evaporation. NP-3 nanoparticles of LMWH prepared by the emulsion–diffusion–evaporation method showed significant differences in particle morphology, size, zeta potential, and drug release profile compared to NP-1 nanoparticles formed by polyelectrolyte complexation. Another ionic complex of LMWH with chitosan-incorporated PLGA nanoparticles (NP-2) showed lower drug entrapment efficiency than that of NP-1 and NP-3. The drug release rate of NP-3 was slower than the release rates of NP-1 and NP-2, although particle morphology of NP-3 was similar to that of NP-2. Cell viability was not adversely affected when cells were treated with all three types of nanoparticles. The data presented in this study demonstrate that nanoparticles formulated with chitosan–PLGA could be a safe sustained-release carrier for the delivery of LMWH.Key words: chitosan, low molecular weight heparin, nanoparticles, PLGA     

Preparation and evaluation of chitosan/carrageenan beads for controlled release of sodium diclofenac

The polyelectrolyte complex (PEC) hydrogel beads based on chitosan (CS) and carrageenan (CR) have been studied as a controlled release device to deliver sodium diclofenac (DFNa) in the simulated gastrointestinal condition. Various factors potentially influencing the drug release (ie, CS/CR proportion, DFNa content, types and amount of cross-linking agents) were also investigated. The optimal formulation was obtained with CS/CR proportion of 2/1 and 5% (wt/vol) DFNa. The controlled release of the drug from this formulation was superior to other formulations and was able to maintain the release for approximately 8 hours. Upon cross-linking with glutaric acid and glutaraldehyde, the resulting beads were found to be more efficient for prolonged drug release than their non-cross-linking counterparts. The bead cross-linked with glutaraldehyde was able to control the release of the drug over 24 hours. The difference in the drug release behavior can be attributed to the differences in ionic interaction between the oppositely charged ions and to the concentrations of the drug within the beads, which depends on the compositions of the formulation and the pH of the dissolution medium. The release of drug was controlled by the mechanism of the dissolution of DFNa in the dissolution medium and the diffusion of DFNa through the hydrogel beads.     

Monodisperse chitosan nanoparticles for mucosal drug delivery

Chitosan nanoparticles (CS NPs) of a controlled size (below 100 nm) and narrow size distribution were obtained through the process of ionic gelation between CS and sodium tripolyphosphate (TPP). A high degree of CS deacetylation and narrow polymer molecular weight distribution were demonstrated to be critical for the controlling particle size distribution. Properties of the CS NPs were examined at different temperatures, values of pH, and ratios of CS to TPP. The model protein, bovine serum albumin, was encapsulated into the NPs, and the in vitro release profiles were examined in physiologically relevant media at 37 degrees C.     

Sulfonates-PMMA nanoparticles conjugates: A versatile system for multimodal application

We report herein the viability of a novel nanoparticles (NPs) conjugated system, namely the attachment, based on ionic and hydrophobic interactions, of different sulfonated organic salts to positively charged poly(methylmethacrylate) (PMMA)-based core-shell nanoparticles (EA0) having an high density of ammonium groups on their shells. In this context three different applications of the sulfonates@EA0 systems have been described. In detail, their ability as cytotoxic drugs and pro-drugs carriers was evaluated in vitro on NCI-H460 cell line and in vivo against human ovarian carcinoma IGROV-1 cells. Besides, 8-hydroxypyrene-1,3,6-trisulfonic acid, trisodium salt (HPTS) was chosen for NPs loading, and its internalization as bioimaging probe was evaluated on Hep G2 cells. Overall, the available data support the interest for these PMMA NPs@sulfonates systems as a promising formulation for theranostic applications. In vivo biological data strongly support the potential value of these core-shell NPs as delivery system for negatively charged drugs or biologically active molecules. Additionally, we have demonstrated the ability of these PMMA core-shell nanoparticles to act as efficient carriers of fluorophores. In principle, thanks to the high PMMA NPs external charge density, sequential and very easy post-loading of different sulfonates is achievable, thus allowing the preparation of nanocarriers either with bi-modal drug delivery behaviour or as theranostic systems.     

Preparation of superparamagnetic iron oxide/doxorubicin loaded chitosan nanoparticles as a promising glioblastoma theranostic tool

Theranostic nanoparticles (NPs) are promising for opening new windows toward personalized disease management. Using a single particle capable of both diagnosis and drug delivery, is the major benefit of such particles. In the present study, chitosan NPs were used as a dual action carrier for doxorubicin (DOX; chemotherapeutic agent) and superparamagnetic iron oxide nanoparticles (SPIONs; imaging agent). SPIONs and DOX were loaded at different concentrations within poly-l -arginine-chitosan-triphosphate matrix (ACSD) using the ionic gelation method. NPs’ size were in the range of 184.33 ± 4.4 nm. Drug release analysis of DOX loaded NPs (NP-DOX) showed burst release at pH 5.5 (as in tumor environment) and slow release at pH 7.4 (physiological condition), demonstrating pH-sensitive drug release profile. NP-DOX internalization was confirmed by flowcytometry and fluorescent microscopy. Uptake process results were corroborated by accumulation of drug in the intracellular space. Iron content was evaluated by inductively coupled plasma and prussian blue staining. In vitro magnetic resonance imaging (MRI) showed a decline in T ₂ relaxation times by increasing iron concentration. MRI analysis also confirmed uptake of NPs at the optimum concentration in C6 glioma cells. In conclusion, ACSD NPs could be utilized as a promising theranostic formulation for both diagnosis and treatment of glioblastoma.     

Polyelectrolyte nanoparticles based on water-soluble chitosan-poly(l-aspartic acid)-polyethylene glycol for controlled protein release

Water-soluble chitosan (WSC)-poly(l-aspartic acid) (PASP)-polyethylene glycol (PEG) nanoparticles (CPP nanoparticles) were prepared spontaneously under quite mild conditions by polyelectrolyte complexation. These nanoparticles were well dispersed and stable in aqueous solution, and their physicochemical properties were characterized by turbidity, FTIR spectroscopy, dynamic light scattering (DLS), transmission electron microscope (TEM), and zeta potential. PEG was chosen to modify WSC-PASP nanoparticles to make a protein-protective agent. Investigation on the encapsulation efficiency and loading capacity of the bovine serum albumin (BSA)-loaded CPP nanoparticles was also conducted. Encapsulation efficiency was obviously decreased with the increase of initial BSA concentration. Furthermore, its in vitro release characteristics were evaluated at pH 1.2, 2.5, and 7.4. In vitro release showed that these nanoparticles provided an initial burst release, followed by a slowly sustained release for more than 24 h. The BSA released from CPP nanoparticles showed no significant conformational change compared with native BSA, which is superior to the BSA released from nanoparticles without PEG. A cell viability study suggested that the nanoparticles had good biocompatibility. This nanoparticle system was considered promising as an advanced drug delivery system for the peptide and protein drug delivery.     

Characterization and in vitro cytotoxicity of doxorubicin-loaded γ-polyglutamic acid-chitosan composite nanoparticles

In this study, γ-polyglutamic acid (γ-PGA) and chitosan (CS) nanoparticles were characterized as a carrier for the anti-cancer drug doxorubicin (DOX). Using ionic complexation between the positively charged DOX and the negatively charged polyelectrolyte γ-PGA, DOX:γ-PGA complexes were produced with an efficiency of approximately 99%. SEM micrographs demonstrated that the complexation of γ-PGA and DOX alone does not lead to the formation of nanoparticles and that the addition of a third component, chitosan, is required. Drug-loaded DOX:γ-PGA:CS nanoparticles were produced with particle sizes ranging from ~150 to ~630 nm. The stability of the DOX:γ-PGA:CS nanoparticles was examined by suspending the nanoparticles in different kinds of aqueous media. For the first time, in vitro studies with DOX-loaded nanoparticles demonstrated the cytotoxicity of the nanoparticles against a human oral squamous cell carcinoma cell line (HN-5a). Non-drug-loaded γ-PGA:CS nanoparticles did not display cytotoxic effects. It was shown that the encapsulated or surface-bound DOX did not lose its bioactivity and the prepared drug-loaded particles exhibited a considerable anti-proliferative activity against the human cancer cell line.     

Synthesis and in vitro evaluation of carboxymethyl starch-chitosan nanoparticles as drug delivery system to the colon

The purpose of this study was to examine chitosan (CS)-carboxymethyl starch (CMS) nanoparticles as drug delivery system to the colon. The 5-aminosalicylic acid (5-ASA) was chosen as model drug molecule. CS-CMS nanoparticles were formulated by a complex coacervation process under mild conditions. The influence of process variables, including the two ionic polymers, on particle size, and nanoparticles entrapment of 5-ASA was studied. In vitro release of 5-ASA was also evaluated, and the integrity of 5-ASA in the release fraction was assessed using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The release of 5-ASA from nanoparticle was based on the ion-exchange mechanism. The CS-CMS nanoparticles developed based on the modulation of ratio show promise as a system for controlled delivery of drug to the colon.     

Oral delivery of peptide drugs using nanoparticles self-assembled by poly(gamma-glutamic acid) and a chitosan derivative functionalized by trimethylation

In the study, chitosan (CS) was conjugated with trimethyl groups for the synthesis of N-trimethyl chitosan (TMC) polymers with different degrees of quaternization. Nanoparticles (NPs) self-assembled by the synthesized TMC and poly(gamma-glutamic acid) (gamma-PGA, TMC/gamma-PGA NPs) were prepared for oral delivery of insulin. The loading efficiency and loading content of insulin in TMC/gamma-PGA NPs were 73.8 +/- 2.9% and 23.5 +/- 2.1%, respectively. TMC/gamma-PGA NPs had superior stability in a broader pH range to CS/gamma-PGA NPs; the in vitro release profiles of insulin from both test NPs were significantly affected by their stability at distinct pH environments. At pH 7.0, CS/gamma-PGA NPs became disintegrated, resulting in a rapid release of insulin, which failed to provide an adequate retention of loaded insulin, while the cumulative amount of insulin released from TMC/gamma-PGA NPs was significantly reduced. At pH 7.4, TMC/gamma-PGA NPs were significantly swelled and a sustained release profile of insulin was observed. Confocal microscopy confirmed that TMC40/gamma-PGA NPs opened the tight junctions of Caco-2 cells to allow the transport of insulin along the paracellular pathway. Transepithelial-electrical-resistance measurements and transport studies implied that CS/gamma-PGA NPs can be effective as an insulin carrier only in a limited area of the intestinal lumen where the pH values are close to the p K a of CS. In contrast, TMC40/gamma-PGA NPs may be a suitable carrier for transmucosal delivery of insulin within the entire intestinal tract.     

Delivery of dermatan sulfate from polyelectrolyte complex-containing alginate composite microspheres for tissue regeneration

Dermatan sulfate (DS) is a glycosaminoglycan (GAG) with a great potential as a new therapeutic agent in tissue engineering. The aim of the present study was to investigate the formation of polyelectrolyte complexes (PECs) between chitosan and dermatan sulfate (CS/DS) and delivery of DS from PEC-containing alginate/chitosan/dermatan sulfate (Alg/CS/DS) microspheres for application in tissue regeneration. The CS/DS complexes were initially formed at different conditions including varying CS/DS ratio (positive/negative charge ratio), buffer, and pH. The obtained CS/DS complexes exhibited stronger electrostatic interaction, smaller complex size, and more stable colloidal structure when chitosan was in large excess (CS/DS 3:1) and prepared at pH 3.5 as compared to pH 5 using acetate buffer. The CS/DS complexes were subsequently incorporated into an alginate matrix by spray drying to form Alg/CS/DS composite microspheres with a DS encapsulation efficiency of 90-95%. The excessive CS induced a higher level of sustained DS release into Tris buffer (pH 7.4) from the microspheres formulated at pH 3.5; however, the amount of CS did not have a significant effect on the release from the microspheres formulated at pH 5. Significant cell proliferation was stimulated by the DS released from the microspheres in vitro. The present results provide a promising drug delivery strategy using PECs for sustained release of DS from microspheres intended for site-specific drug delivery and ultimately for use in tissue engineering.     

Ionic cross‐linking of water‐soluble polyurethane improves protein encapsulation and release

Polymer nanoparticles (NPs) are promising systems for the delivery of protein drugs, as they enhance circulation half‐life, reduce degradation, and increase selectivity of the encapsulated agent. Among the different methods for the preparation of protein‐loaded NPs, ionotropic gelation—which exploits cross‐linking between charged groups in the polymer and counterions in the protein solution—has been extensively investigated for chitosan NPs. The present study aims at exploring the possibility to apply the method to prepare BSA‐loaded polyurethane NPs. A poly(ε‐caprolactone)/poly(ethyleneglicol)‐based polyurethane bearing tert‐butyloxycarbonyl‐protected amino groups was synthesized by a two‐step synthesis procedure. Amino functionalities were exposed under acidic conditions, as confirmed by ninhydrin assay, and then exploited to obtain ionic cross‐linking with sodium tripolyphosphate counterions. The effect of polymer and sodium tripolyphosphate concentration on particles size and BSA encapsulation has been investigated, showing that the PUR concentration plays a major role. Small particles, at 300 nm, with high BSA loading (90%) have been obtained. Sustained BSA release and low burst effect (20%) have been observed, indicating good interaction between the protein and the polymer matrix. The study highlights the possibility of introducing alternative polymers to improve loading and release of proteins from NPs obtained through the ionotropic gelation method.     

Controlled release of ionic drugs from complex micelles with charged channels

Oral administration of ionic drugs generally encounters with significant fluctuation in plasma concentration due to the large variation of pH value in the gastrointestinal tract and the pH-dependent solubility of ionic drugs. Polymeric complex micelles with charged channels on the surface provided us with an effective way to reduce the difference in the drug release rate upon change in pH value. The complex micelles were prepared by self-assembly of PCL-b-PAsp and PCL-b-PNIPAM in water at room temperature with PCL as the core and PAsp/PNIPAM as the mixed shell. With an increase in temperature, PNIPAM collapsed and enclosed the PCL core, while PAsp penetrated through the PNIPAM shell, leading to the formation of negatively charged PAsp channels on the micelle surface. Release behavior of ionic drugs from the complex micelles was remarkably different from that of usual core-shell micelles where diffusion and solubility of drugs played a key role. Specifically, it was mainly dependent on the conformation of the PAsp chains and the electrostatic interaction between PAsp and drugs, which could partially counteract the influence of pH-dependent diffusion and solubility of drugs. As a result, the variation of drug release rate with pH value was suppressed, which was favorable for acquiring relatively steady plasma drug concentration.     

In vitro characterization of coevaporates containing chitosan for colonic drug delivery

A relative simple drug delivery system in the form of coevaporates were prepared and analyzed. They were based on chitosan (CS), a polysaccharide that undergoes specific degradation by colonic enzymes. Enteric polymers, namely cellulose acetate phtalate (CAP) and hydroxypropylmethylcellulose phtalate (HPMCP), were incorporated, due to their insolubility in environments presenting low pH values. The systems were physically characterized, demonstrating that CS affects the swelling properties of the samples. The ability of these systems to reach the colonic region was assessed in vitro in simulated gastric, enteric and colonic fluids. Korsmeyer–Peppas and Weibull models were applied to analyze the drug release kinetics and the results suggested that the drug release from the coevaporates follows a complex release mechanism, in which several processes, including diffusion, swelling, and erosion, are involved and may occur simultaneously. The results demonstrated that it is possible to prepare relative simple drug carrier systems able to reach the colonic environment, since their swelling capacity can be controlled by varying the composition.     

Amphiphilic cholic-acid-modified dextran sulfate and its application for the controlled delivery of superoxide dismutase

A novel amphiphilic and biodegradable polyelectrolyte DS-CA is prepared by the esterification of DS with CA. DS-CA can self-assemble into stable nanoparticles in water. SOD can effectively associate with DS-CA at pH = 5.0 by virtue of electrostatic and hydrophobic interactions. SOD release from the complex nanoparticles is slow at pH = 1.2. The release at pH = 7.4 PBS shows an extended behavior and is tunable by changing the weight ratio of SOD to DS-CA as well as the CA substitution degree. Increasing the CA substitution degree of DS-CA can significantly enhance the cellular uptake of the loaded SOD. This study demonstrates that the amphiphilic DS-CA provides a promising strategy for oral delivery of protein/peptide drugs.     

Characterization of physical interaction between Casiopeina III-ia and chitosan. Toward a Cas III-ia drug delivery system

Casiopeínas® are a new generation of anticancer drugs that have shown great in vitro and in vivo antineoplastic activities. Information about interaction drug-excipient, for developing a based-nanoparticle drug delivery system, has not been investigated yet. In order to elucidate if chitosan (CS) modifies the copper complex due to its interaction with Cu²⁺ ion, different studies in aqueous media between CS and Casiopeina III-ia (Cas III-ia) were carried out. CS–Cas III-ia mixtures were characterized by viscosity curves, UV–vis, EPR, and in vivo activity against HeLa cell line. Rheological behavior showed a decrease of viscosity when the drug was present due to diminished electrostatic interactions of charged amine group. UV–vis results illustrate that Cas III-ia is not stable at low pH as a result of interaction with acetic acid. However, when chitosan is present at the acidic solution Cas III-ia is stable. These results are supported by EPR studies. Finally, activity of the drug against HeLa cell line was not modified. Therefore, the present work presents evidence that there is no breaking of copper complex due to interaction between CS and Cas III-ia in acidic media. In addition, Cas III-ia maintains both its stability and effectiveness against cancer cell line.     

Targeted Anticancer Drug Delivery Using Chitosan,Carbon Quantum Dots,and Aptamers to Deliver Ganoderic Acid and 5-Fluorouracil

Breast cancer is a malignancy that affects mostly females and is among the most lethal types of cancer. The ligand-functionalized nanoparticles used in the nano-drug delivery system offer enormous potential for cancer treatments. This work devised a promising approach to increase drug loading efficacy and produce sustained release of 5-fluorouracil (5-FU) and Ganoderic acid (GA) as model drugs for breast cancer. Chitosan, aptamer, and carbon quantum dot (CS/Apt/COQ) hydrogels were initially synthesized as a pH-sensitive and biocompatible delivery system. Then, CS/Apt/COQ NPs loaded with 5-FU-GA were made using the W/O/W emulsification method. FT-IR, XRD, DLS, zeta potentiometer, and SEM were used to analyze NP's chemical structure, particle size, and shape. Cell viability was measured using MTT assays in vitro using the MCF-7 cell lines. Real-time PCR measured cell apoptotic gene expression. XRD and FT-IR investigations validated nanocarrier production and revealed their crystalline structure and molecular interactions. DLS showed that nanocarriers include NPs with an average size of 250.6 nm and PDI of 0.057. SEM showed their spherical form, and zeta potential studies showed an average surface charge of +37.8 mV. pH 5.4 had a highly effective and prolonged drug release profile, releasing virtually all 5-FU and GA in 48 h. Entrapment efficiency percentages for 5-FU and GA were 84.7±5.2 and 80.2 %±2.3, respectively. The 5-FU-GA-CS-CQD-Apt group induced the highest cell death, with just 57.9 % of the MCF-7 cells surviving following treatment. 5-FU and GA in CS-CQD-Apt enhanced apoptotic induction by flow cytometry. 5-FU-GA-CS-CQD-Apt also elevated Caspase 9 and downregulated Bcl2. Accordingly, the produced NPs may serve as pH-sensitive nano vehicles for the controlled release of 5-FU and GA in treating breast cancer.     

Synthesis and characterization of folate conjugated chitosan and cellular uptake of its nanoparticles in HT-29 cells

Folate–chitosan (FA–CS) conjugates synthesized by coupling FA with CS render new and improved functions because the original properties of CS are maintained and the targeting ligand of FA is incorporated. In this work, FA–CS conjugates were synthesized based on chemical linking of carboxylic group of FA with amino group of CS as confirmed by Fourier transform spectroscopy (FTIR) and nuclear magnetic resonance (¹H NMR). FA–CS conjugates displayed less crystal nature when compared to CS. The FA–CS nanoparticles (NPs) were prepared by crosslinking FA–CS conjugates with sodium tripolyphosphate (STPP). Positively charged FA–CS nanoparticles were spherical in shape with a particle size of about 100 nm. Cellular uptake of CS or FA–CS nanoparticles was assayed by fluorescent microscopy using calcein as fluorescent marker in colon cancer cells (HT-29). The FA–CS nanoparticles exhibited improved uptake of HT-29 and could become a potential targeted drug delivery system for colorectal cancer.     

Interpolyelectrolyte Complexes of Eudragit? EPO with Hypromellose Acetate Succinate and Eudragit? EPO with Hypromellose Phthalate as Potential Carriers for Oral Controlled Drug Delivery

The objective of this study was to compare a novel controlled release tablet formulation based on interpolyelectrolyte complex (PEC). Interpolymer interactions between the countercharged polymers like Eudragit® EPO (polycation) and hypromellose acetate succinate (polyanion) and Eudragit® EPO and hypromellose phthalate (polyanion) were investigated with a view to their use in per oral controlled release drug delivery systems. The formation of inter-macromolecular ionic bonds between cationic polymer and anionic polymer was investigated using Fourier transform infrared (FT-IR) spectroscopy and differential scanning calorimetry. The FT-IR spectra of the tested polymeric matrices are characterized by visible changes in the observed IR region indicating the interaction between chains of two oppositely charged copolymers. The performance of the in situ formed PEC as a matrix for controlled release of drugs was evaluated, using acetaminophen as a model drug. The dissolution data of these matrices were fitted to different dissolution models. It was found that drug release followed zero-order kinetics and was controlled by the superposition of the diffusion and erosion. These profiles could be controlled by conveniently modifying the proportion of the polymer ratio, polymer type, and polymer concentration the in the tablets.KEY WORDS: Eudragit E, hypromellose acetate succinate, hypromellose phthalate polyelectrolyte complexation     

The Investigation on Polyion Complex Micelles Composed of Diammonium Glycyrrhizinate/Poly(Ethylene Glycol)–Glycidyltrimethylammonium Chloride-Grafted Polyasparthydrazide

To prepare stable polyion complex (PIC) micelles, polyasparthydrazide (PAHy) modified with glycidyltrimethylammonium groups and methoxy poly(ethylene glycol) (mPEG) (mPEG-g-PAHy-GTA) was synthesized. The cytotoxicity of the polymer was evaluated by the methyl tetrazolium assay. The polymer entrapped the diammonium glycyrrhizinate (DG) and formed polyion complexes. The effect of pH value, grafting degree of mPEG, copolymer and drug concentration on the micelle formation was investigated by means of measuring entrapment efficiency and micelle size. In vitro DG release from the PIC micelles was detected by dialysis in various media of different ionic strengths. To examine the pharmacokinetic behavior of micelles in vivo, the time course of the drug in plasma was evaluated. The cytotoxicity of the polymer was very low. The results showed that entrapment efficiency can reach about 93%, and the mean particle size was almost 50 nm. The drug release rate decreased with a decrease in ionic strength of the release medium or an increase in the PEG grafting degree. Compared with DG solution, the AUC of DG micelles had a twofold increase. The smaller clearance and longer mean residence time of the DG micelles group compared with DG solution group showed that the DG loaded in PIC micelles can reduce drug elimination and prolong the drug residence time in the blood circulation. The results indicated that PIC micelles composed of mPEG-g-PAHy-GTA would be prospective as a drug carrier to the drugs which can be ionized in solution.KEY WORDS: diammonium glycyrrhizinate, drug delivery systems, poly(ethylene glycol)–glycidyltrimethylammonium chloride-grafted polyasparthydrazide, polyion complex micelles