Self-assembled star-shaped chlorin-core poly(epsilon-caprolactone)-poly(ethylene glycol) diblock copolymer micelles for dual chemo-photodynamic therapies

Amphiphilic 4-armed star-shaped chlorin-core diblock copolymers based on methoxy poly(ethylene glycol) (mPEG) and poly(varepsilon-caprolactone) (PCL) were synthesized and characterized in this study. The synthesized photosensitizer-centered amphiphilic star block copolymer that forms assembled micelle-like structures can be used in a photodynamic therapy (PDT)-functionalized drug delivery system. Moreover, the hydrophobic chemotherapeutic agent, paclitaxel, can be trapped in the hydrophobic inner core of micelles. In our results, the star-polymer-formed micelle exhibited efficient singlet oxygen generation, whereas the hydrophobic photosensitizer failed due to aggregation in aqueous solution. The chlorin-core micelle without paclitaxel loading exhibited obvious phototoxicity in MCF-7 breast cancer cells with 7J/cm2 or 14J/cm2 light irradiation at a chlorin concentration of 125microg/ml. After paclitaxel loading, the size of micelle increased from 71.4nm to 103.2nm. Surprisingly, these micelles were found to improve the cytotoxicity of paclitaxel significantly in MCF-7 cells after irradiation through a synergistic effect evaluated by median effect analysis. This functionalized micellar delivery system is a potential dual carrier for the synergistic combination of photodynamic therapy and chemotherapy for the treatment of cancer.     

Self-assembled thermosensitive micelles based on poly(L-lactide-star block-N-isopropylacrylamide) for drug delivery

A novel seven-arm star block copolymer poly(L-lactide-star block-N-isopropylacrylamide) (PLLA-sb-PNIPAAm), comprised of a hydrophobic poly(L-lactide) (PLLA) arm and an average of six hydrophilic poly(N-isopropylacrylamide) (PNIPAAm) arms, was designed and synthesized. The amphiphilic PLLA-sb-PNIPAAm copolymer was capable of self-assembling into nano-sized micelle in water, which was confirmed by FT-IR, 1H NMR and fluorescence spectroscopy. Transmission electron microscopy images showed that these nano-sized micelles were regularly spherical in shape. Micelle size determined by size analysis was around 100 nm in diameter. The micelles showed reversible dispersion/aggregation in response to temperature changes through an outer polymer shell of PNIPAAm at around 31 degrees C, observed by optical absorbance measurements. The anticancer drug methotrexate (MTX) as model drug was loaded in the polymeric nano-sized micelles. In vitro release behavior of MTX was investigated, which showed a drastic thermoresponsive fast/slow switching behavior according to the temperature-responsive structural changes of a micellar shell structure. The reversible and sensitive thermoresponse of this micelle might provide opportunities to construct a novel drug delivery system in conjunction with localized hyperthermia.     

Mixed micelle systems formed from critical micelle concentration and temperature-sensitive diblock copolymers for doxorubicin delivery

Mixed micelles formed by critical micelle concentration (Cmc) character's diblock copolymer, and temperature-sensitive character's diblock copolymer were studied for their capabilities in improving stability with and without drug. Experimental results showed that this type of mixed micellar systems possessed complementary effects in adjusting external temperature shift (storage vs. body temperature) and concentration change (dilution after intravenous injection). Therefore, they provided excellent stability as drug carriers. Further results obtained from physicochemical property and drug release kinetics studies demonstrated such systems could also be applied to physiological conditions, in compliance with varied pH environments. We concluded that the newly developed mixed micelles can serve as a potential injectable drug delivery system for anticancer drugs, such as doxorubicin and many others.     

Micelles with a Loose Core Self‐Assembled from Coil‐g‐Rod Graft Copolymers Displaying High Drug Loading Capacity

High drug loading capacity is one of the critical demands of micellar drug‐delivery vehicles; however, it is a challenging work. Herein, it is demonstrated that micelles self‐assembled from poly(ethylene glycol)‐graft‐poly(γ‐benzyl‐l ‐glutamate) (PEG‐g‐PBLG) coil‐g‐rod graft copolymers display high drug‐loading capacity for doxorubicin (DOX) model drugs. As revealed by a combination study of experiments and dissipative particle dynamics simulations, the high drug‐loading capacity of the micelles is related to the loose core structure of the micelles. In these micelles, the hydrophobic PBLG grafts randomly disperse in the micelle core due to their rigid nature and the coil‐g‐rod topology of the graft copolymers, which results in a loose core of the micelles. The structure of the graft copolymer, including the length of rod grafts, the length of coil backbone, and the grafting ratio of the rod grafts affecting the arrangement of the rod grafts in the micelle core has influence on the drug‐loading capacity of the micelles. Besides, the strong π–π stacking interaction between graft copolymers and DOX also plays an important part in achieving high drug‐loading capacity. In vitro studies reveal that these drug‐loaded micelles show good biocompatibility, and the DOX can be gradually released from the micelles.     

Effect of polymer architecture on surface properties, plasma protein adsorption, and cellular interactions of pegylated nanoparticles

The aim of the present study was to evaluate the cellular interaction of nanoparticles (NPs) prepared from different pegylated polymers and elucidate the effect of polymer architecture, for instance, grafted versus block copolymer on their cellular uptake. Fluorescein-labeled NPs of four different polymers, viz., poly(D,L-lactide) (PLA), poly(ethylene glycol)(1%)-graft-poly(D,L-lactide) (PEG(1%)-g-PLA), poly(ethylene glycol)(5%)-graft-poly(D,L-lactide) (PEG(5%)-g-PLA), and (poly(D,L-lactide)-block-poly(ethylene glycol)-block-poly(D,L-lactide))(n) multiblock copolymer (PLA-PEG-PLA)(n) were prepared. These NPs were characterized for their size, zeta-potential, and surface morphology. XPS studies revealed possibility of chemical interaction between PLA-COOH groups and PVA-OH groups, thus making it difficult to be washed off the NP surface completely. Grafted polymer NPs showed more surface PEG coverage than (PLA-PEG-PLA)(n) despite of their comparatively lower PEG content. The results of surface properties were translated into protein binding showing least amount of proteins bound to grafted copolymer NPs as against multiblock copolymer NPs. NPs showed no toxicity to RAW 264.7 cells. Cellular uptake of NPs was temperature and concentration-dependent as well as involved clathrin-mediated processes. Thus, this study confirms the importance of polymer architecture in determining the surface properties and hence, protein binding and cellular interactions of NPs. Also, it was shown that grafted copolymer NPs reduced macrophage uptake as compared to multiblock copolymer although mechanisms different than phagocytosis were involved.     

Supramolecular self-assembly of monoend-functionalized methoxy poly(ethylene glycol) and α-cyclodextrin: from micelles to hydrogel

An effective strategy was developed to fabricate a supramolecular hydrogel with the complexation of α-cyclodextrins (α-CDs) and monoend-functionalized low molecular weight methoxy poly(ethylene glycol) (mPEG, Mn=2000) micelles. Hydrophobic cinnamic acid was immobilized on methoxy poly(ethylene glycol) via L-lysine as linker to prepare amphiphilic mPEG. The monoend-functionalized mPEG self-assembled micelles in aqueous solution. The size and size distribution of the micelles were tested by dynamic laser scattering (DLS). The morphology of the micelles was observed by SEM, TEM and AFM. The critical micelle concentration (CMC) was tested and it was 42.5 mg/L. The monodisperse micelles had core-shell structure and the mean diameter was around 40 nanometers. α-cyclodextrins were added in the suspension of micelles to form supramolecular hydrogel with the polypseudorotaxanes complexation. Hydrophilic drug doxorubicin hydrochloride was used as model drug to study the release profile. The results showed that the hydrogel was a promising carrier for drug delivery.     

Drug releasing behavior of hybrid micelles containing polypeptide triblock copolymer

We report a new type of hybrid polymeric micelles for drug delivery applications. These micelles consist of PLGA (PLGA: poly(l-glutamic acid)) and PEG (PEG: polyethylene glycol) mixed corona chains. In acidic condition, PLGA undergoes a transformation from water-soluble random coils to water-insoluble alpha-helix, leading to microphase separation in micelle coronas and formation of PEG channels. These channels connect the inner core and the outer milieu, accelerating the diffusion of drugs from micelles. The micelles were prepared through a co-micellization of PLGA-b-PPO-b-PLGA (PPO: poly(propylene oxide)) and PEG-b-PPO in water. During the self-assembly, the PPO blocks of both block copolymers aggregated into cores that were surrounded by mixed corona chains of PLGA and PEG blocks. We confirmed this structure by using a number of characterization techniques including nuclear magnetic resonance spectroscopy, zeta potential, circular dichroism, and dynamic light scattering. We also performed molecular dynamics (MD) simulations to verify the models of the hybrid micelle structure. One advantage of the hybrid micelles as drug carriers is their tunable release rate without sacrificing colloidal stability. The rate can be tuned by either micelle structures such as the composition of the mixture or external parameters such as pH.     

Folate-conjugated amphiphilic star-shaped block copolymers as targeted nanocarriers

Folate (FA)-conjugated star-shaped copolymer was prepared as a targeted carrier for anticancer drug delivery by ring-opening polymerization of L-lactide using pentaerythritol (PTL) as an initiator, followed by conjugation with methoxy poly(ethylene glycol) (MPEG) and FA-poly(ethylene glycol) (FA-PEG). The resulting amphiphilic star-shaped copolymer was shaped into drug-loaded micelles, and the achieved micelles had an average size of around 146 nm in diameter. It was found that the sustained release time of model drug (indomethacin, IMC) from some selected micelles could reach around 40 h. In comparison with linear poly(L-lactic acid)-block-methoxy poly(ethylene glycol) copolymer (PLA-MPEG), the stability of the star-shaped pentaerythritol-co-poly(L-lactic acid)-block-[methoxy poly(ethylene glycol) and FA-poly(ethylene glycol)] (PTL-PLA-MPEG/PEG-FA) micelle was significantly improved because of the lower critical micelle concentration (CMC). The specificity of PTL-PLA-MPEG/PEG-FA targeting cancer cells was demonstrated by intracellular uptake of PTL-PLA-MPEG/PEG-FA and PTL-PLA-MPEG using HeLa human cervical cancer cells. After 2 h in vitro incubation, a significant intracellular uptake for PTL-PLA-MPEG/PEG-FA over PTL-PLA-MPEG was observed by using inverted fluorescence microscope and flow cytometry. These results suggested that PTL-PLA-MPEG/PEG-FA polymeric micelle could be a potentially useful carrier for delivering selected drugs to FA-receptor positive cancer cells.     

The accumulation of dual pH and temperature responsive micelles in tumors

An optimized, biodegradable, dual temperature- and pH-responsive micelle system conjugated with functional group Cy5.5 was prepared in order to enhance tumor accumulation. The Dynamic light scattering (DLS) measurements showed that these diblock copolymers form micelle in PBS buffer with a size of around 50 nm by heating of an aqueous polymer solution from below to above the cloud point (CP). Anticancer drug, doxorubicin was incorporated into the inner core of micelle by hot shock protocol. The size and stability of the micelle were controlled by the copolymer composition and is fine tuned to extracellular pH of tumor. The mechanism then caused pH change and at body temperature which induce doxorubicin release from micelles and have strong effects on the viability of HeLa, ZR-75-1, MCF-7 and H661 cancer cells. Our in vivo results revealed a clear distribution of Doxorubicin-loaded mixed micelle (Dox-micelle) and efficiency targeting tumor site with particles increasing size in the tumor interstitial space, and the particles could not diffuse throughout the tumor matrix. In vivo tumor growth inhibition showed that Dox-micelle exhibited excellent antitumor activity and a high rate of anticancer drug in cancer cells by this strategy.     

Synthesis and cytotoxicity of brefeldin A conjugated monomethoxy-poly(ethylene glycol)-b-poly(L-lactide) polymeric micelles

A diblock copolymer of monomethoxy-poly(ethylene glycol)-b-poly(L-lactide) (MePEG-PLLA)/brefeldin A (BFA) conjugate was synthesized by the reaction of carboxyl-terminated copolymer MePEG-PLLA with BFA in the presence of dicyclohexylcarbodiimide and dimethylaminopyridine. The conjugation efficiency was found to be 95%. Its structure was confirmed by ¹H nuclear magnetic resonance and gel permeation chromatography. The MePEG-PLLA/BFA conjugate could self-assemble into micelles in aqueous solutions with a low critical micelle concentration of 1.8?×?10^?3?g/L. Dynamic light scattering and transmission electron microscopy analyses of the MePEG-PLLA/BFA micelles revealed their spherical structure with an average diameter of 120?nm. The release profiles of BFA in PBS were measured by high performance liquid chromatography (HPLC), demonstrating that the controlled release of BFA can be gained for long time. The in vitro antitumor activity of the conjugate micelles against human liver carcinoma HepG2 cells was evaluated by 3-(4,5-dimethylthiazolyl-2)-2,5-diphenyl tetrazolium bromide method, and the results showed that BFA can be released from the conjugate micelles without losing cytotoxicity.     

Folate‐Conjugated Poly(N‐(2‐hydroxypropyl) methacrylamide)‐block‐Poly(benzyl methacrylate): Synthesis,Self‐Assembly,and Drug Release

Well‐defined amphiphilic diblock copolymers of poly(N‐(2‐hydroxypropyl)methacrylamide)‐block‐poly(benzyl methacrylate) (PHPMA‐b‐PBnMA) are synthesized using reversible addition–fragmentation chain transfer polymerization. The terminal dithiobenzoate groups are converted into carboxylic acids. The copolymers self‐assemble into micelles with a PBnMA core and PHPMA shell. Their mean size is <30 nm, and can be regulated by the length of the hydrophilic chain. The compatibility between the hydrophobic segment and the drug doxorubicin (DOX) affords more interaction of the cores with DOX. Fluorescence spectra are used to determine the critical micelle concentration of the folate‐conjugated amphiphilic block copolymer. Dynamic light scattering measurements reveal the stability of the micelles with or without DOX. Drug release experiments show that the DOX‐loaded micelles are stable under simulated circulation conditions and the DOX can be quickly released under acidic endosome pH.     

Self-assembled, fluorescent polymeric micelles of a graft copolymer containing carbazole for thermo-controlled drug delivery in vitro

A novel thermosensitive amphiphilic graft copolymer PNIPAAm-g-PCbzEA appending carbazole group was successfully designed and synthesized by the free radical copolymerization of N-isopropylacrylamide with hydrophobic precursor polymers of vinyl-functionalized poly(2-(N-carbazolyl)ethyl acrylate) (PCbzEA) in DMF. The PNIPAAm-g-PCbzEA copolymer was characterized by FTIR, (1)H NMR, GPC analysis, UV-vis spectroscopy and fluorescence spectroscopy. The TEM observation shows that the graft copolymer may self-assemble into polymeric micelles exhibiting a nanospheric morphology within a narrow size range of 30-60 nm in aqueous solution. From the (1)H NMR and FTIR analysis, the polymer micelles are composed of hydrophobic PCbzEA segments as the cores and the hydrophilic PNIPAAm segements as outer shells. The resulting micelles exhibited the temperature sensitivity with a lower critical solution temperature (LCST) of 31.5 degrees C and a critical micelle concentration (CMC) of 12.9 mg/L in water. In the study of drug release, an "on-off" drug release profile was found in response to stepwise temperature changes between 20 and 40 degrees C. The cytotoxicity assays for vero cells shows good biocompatibility of the graft copolymer in vitro.     

Nanoporous Gold Film Prepared by the Epoxidation of Poly(styrene‐b‐butadiene) Diblock Copolymer Templated Micelles

A new approach is developed for the preparation of nanoporous gold (Au) films using diblock copolymer micelles as templates. Stable Au nanoparticles (NPs) with a narrow distribution are prepared by modifying NPs functionalized with 4‐(dimethylamino)pyridine ligands (DMAP Au NPs) and a spherical micelle formed through the epoxidation of poly(styrene‐b‐butadiene) diblock copolymer to produce poly(styrene‐b‐vinyl oxirane) (PS‐b‐PBO) in tetrahydrofuran–acetonitrile solution. The exchange reaction of 4‐aminothiophenol of PS‐b‐PBO diblock copolymer micelles with DMAP Au NPs can produce block copolymer–Au NPs composite films. After the pyrolysis of the diblock copolymer templates at a specific temperature to avoid the collapse of the Au NPs, a nanoporous Au film is prepared.     

Encapsulation and stabilization of indocyanine green within poly(styrene-alt-maleic anhydride) block-poly(styrene) micelles for near-infrared imaging

Indocyanine green (ICG) is a Federal Drug Administration-approved near-infrared imaging agent susceptible to chemical degradation, nonspecific binding to blood proteins, and rapid clearance from the body. In this study, we describe the encapsulation of ICG within polymeric micelles formed from poly(styrene-alt-maleic anhydride)-block-poly(styrene) (PSMA-b-PSTY) diblock copolymers to stabilize ICG for applications in near-infrared diagnostic imaging. In aqueous solution, the diblock copolymers self-assemble to form highly stable micelles approximately 55 nm in diameter with a critical micelle concentration (CMC) of approximately 1 mg/L. Hydrophobic ICG salts readily partition into the PSTY core of these micelles with high efficiency, and produce no change in micelle morphology or CMC. Once loaded in the micelle core, ICG is protected from aqueous and thermal degradation, with no significant decrease in fluorescence emission over 14 days at room temperature and retaining 63% of its original emission at 37 degrees C. Free ICG does not release rapidly from the micelle core, with only 11% release over 24 h. The ICG-loaded micelles do not exhibit significant cell toxicity. This system has the potential to greatly improve near-infrared imaging in breast cancer detection by increasing the stability of ICG for formulation/administration, and by providing a means to target ICG to tumor tissue.     

A polymeric micelle system with a hydrolysable segment for drug delivery

A potential anti-cancer drug-delivery polymeric micelle system with an in vitro degradation half-life of about 48 h that releases its drug upon application of ultrasound was synthesized. This vehicle was composed of an amphiphilic co-polymer, poly(ethylene oxide)-b-poly(N-isopropylacrylamide-co-2-hydroxyethyl methacrylate-lactate(n)). The degree of polymerization of the lactate side group, n, was 0, 3 or 5. The molar ratio of NIPAAm to HEMA-lactate(n) to PEO in polymerization was optimized to produce an in vitro polymeric micelle half-life of about 48 h at 40 degrees C. 1,6-Diphenyl-1,3,5-hexatriene (DPH) was used as a fluorescent probe to study the hydrophobicity of the cores of the polymeric micelles. The results showed that the cores of the polymeric micelles were hydrophobic enough to sequester DPH and the anti-cancer drug doxorubicin (Dox). Dox was encapsulated into the polymeric micelles having a molar feed ratio of NIPAAm to HEMA-lactate3 to PEO equal to 20:5:1; this drug was released upon the application of low-frequency ultrasound. The Dox release was about 2% at room temperature and 4% at body temperature, and the drug returned to the polymeric micelles when insonation ceased.     

Multifunctional hollow nanoparticles based on graft-diblock copolymers for doxorubicin delivery

This article reports a flexible hollow nanoparticles, self-assembling from poly(N-vinylimidazole-co-N-vinylpyrrolidone)-g-poly(d,l-lactide) graft copolymers and methoxyl/functionalized-PEG-PLA diblock copolymers, as an anticancer drug doxorubicin (Dox) carrier for cancer targeting, imaging, and cancer therapy. This multifunctional hollow nanoparticle exhibited a specific on-off switch drug release behavior, owning to the pH-sensitive structure of imidazole, to release Dox in acidic surroundings (intracellular endosomes) and to capsulate Dox in neutral surroundings (blood circulation or extracellular matrix). Imaging by SPECT/CT shows that nanoparticle conjugated with folic acids ensures a high intratumoral accumulation due to the folate-binding protein (FBP)-binding effect. In vivo tumor growth inhibition shows that nanoparticles exhibited excellent antitumor activity and a high rate of apoptosis in cancer cells. After 80-day treatment course of nanoparticles, it did not appreciably cause heart, liver and kidney damage by inactive Dox or polymeric materials. The results indicate that the flexible carriers with an on-off switched drug release may be allowed to accurately deliver to targeted tumors for cancer therapy.     

Tetraphenylsilane‐Cored Star‐Shaped Amphiphilic Block Copolymers for pH‐Responsive Anticancer Drug Delivery

Four‐arm star‐shaped poly[2‐(diethylamino)ethyl methacrylate]‐b‐poly[2‐hydroxyethyl methacrylate]s block copolymers using tetraphenylsilane (TPS) as a core with adjustable arm lengths are synthesized through two‐step atom transfer radical polymerizations. For comparison, a linear block copolymer with similar molecular weight is also prepared. The assembled star‐shaped copolymer micelles exhibit sizes of 102–139 nm and critical micelle concentrations of 1.49–3.93 mg L^?1. Moreover, the bulky and rigid TPS core is advantageous for propping up the four star‐shaped arms to generate large intersegmental space. As a result, the drug‐loading capacity in the micelles is up to 33.97 wt%, much surpassing the linear counterpart (8.92 wt%) and the previously reported star‐shaped copolymers prepared using pentaerythritol as the core. Furthermore, the micelles show sensitive pH‐responsive drug release when the pH changes from 7.4 to 5.0. The in vitro cytotoxicity to Hela cells indicates that the doxorubicin (DOX)‐loaded micelles have similar anticancer activity to the pristine DOX. The combination of excellent micelle stability, high drug‐loading, sensitive pH response, and good anticancer activity endows the copolymers with promising application in drug control delivery for anticancer therapy.     

siRNA delivery from triblock copolymer micelles with spatially-ordered compartments of PEG shell,siRNA-loaded intermediate layer,and hydrophobic core

Hydrophobized block copolymers have widely been developed for construction of polymeric micelles for stable delivery of nucleic acids as well as anticancer drugs. Herein, we elaborated an A-B-C type of triblock copolymer featuring shell-forming A-segment, nucleic acid-loading B-segment, and stable core-forming C-segment, directed toward construction of a three-layered polymeric micelle as a small interfering RNA (siRNA) vehicle. The triblock copolymer was prepared with nonionic and hydrophilic poly(ethylene glycol) (PEG), cationic poly(l-lysine) (PLys), and poly{N-[N-(2-aminoethyl)-2-aminoethyl]aspartamide} [PAsp(DET)] bearing a hydrophobic dimethoxy nitrobenzyl ester (DN) moiety in the side chain [PEG-PLys-PAsp(DET-DN)]. The resulting triblock copolymers spontaneously formed sub-100 nm-sized polymeric micelles with a hydrophobic PAsp(DET-DN) core as well as PEG shell in an aqueous solution. This micelle was able to incorporate siRNA into the intermediate PLys layer, associated with slightly reduced size and a narrow size distribution. The triblock copolymer micelles (TCMs) stably encapsulated siRNA in serum-containing medium, whereas randomly hydrophobized triblock copolymer [PEG-PLys(DN)-PAsp(DET-DN)] control micelles (RCMs) gradually released siRNA with time and non-PEGylated diblock copolymer [PLys-PAsp(DET-DN)] control micelles (DCMs) immediately formed large aggregates. The TCMs thus induced appreciably stronger sequence-specific gene silencing in cultured cancer cells, compared to those control micelles. The siRNA delivery with TCMs was further examined in terms of cellular uptake and intracellular trafficking. The flow cytometric analysis revealed that the cellular uptake of TCMs was more efficient than that of RCMs, but less efficient than that of DCMs. The intracellular trafficking study using confocal laser scanning microscopy combined with fluorescence resonance energy transfer (FRET) revealed that the TCMs could readily release the siRNA payload within cells, which was in contrast to the DCMs exhibiting much slower release profile. This result indicates that PEG shell contributed to the smooth release of siRNA from TCMs within the cells, presumably due to avoiding irreversible aggregate formation. The obtained results demonstrated that the design of separately functionalized polymer segments expanded the performance of polymeric micelles for successful siRNA delivery.     

聚乙二醇单甲醚-聚(D,L-乳酸)嵌段共聚物的研究

采用熔融缩聚反应合成一系列聚（D，L-乳酸）（PDLLA）／聚乙二醇单甲醚（mPEG）两亲性二嵌段共聚物（PEDLLA），采用IR、^1H-NMR、DSC、WAXD和TEM等手段分析和研究PEDLLA的结构与性能。实验结果表明，PEDLLA的结构和组成与设计相一致，结晶度和熔点均低于均聚物，且随着PEDLLA中PDLLA含量的增加，mPEG嵌段熔点降低，随着PDLLA嵌段相对分子质量的增大，PEDLLA降解速率增大。载药纳米粒呈核壳结构，载药量达30％。     

Polypeptide-based combination of paclitaxel and cisplatin for enhanced chemotherapy efficacy and reduced side-effects

A novel methoxy poly(ethylene glycol)-b-poly(l-glutamic acid)-b-poly(l-phenylalanine) (mPEG-b-P(Glu)-b-P(Phe)) triblock copolymer was prepared and explored as a micelle carrier for the co-delivery of paclitaxel (PTX) and cisplatin (cis-diamminedichlo-platinum, CDDP). PTX and CDDP were loaded inside the hydrophobic P(Phe) inner core and chelated to the middle P(Glu) shell, respectively, while mPEG provided the outer corona for prolonged circulation. An in vitro release profile of the PTX + CDDP-loaded micelles showed that the CDDP chelation cross-link prevented an initial burst release of PTX. The PTX + CDDP-loaded micelles exhibited a high synergism effect in the inhibition of A549 human lung cancer cell line proliferation over 72 h incubation. For the in vivo treatment of xenograft human lung tumor, the PTX + CDDP-loaded micelles displayed an obvious tumor inhibiting effect with a 83.1% tumor suppression rate (TSR%), which was significantly higher than that of a free drug combination or micelles with a single drug. In addition, more importantly, the enhanced anti-tumor efficacy of the PTX + CDDP-loaded micelles came with reduced side-effects. No obvious body weight loss occurred during the treatment of A549 tumor-bearing mice with the PTX + CDDP-loaded micelles. Thus, the polypeptide-based combination of PTX and CDDP may provide useful guidance for effective and safe cancer chemotherapy.