Chun-Liang Lo

Graft and diblock copolymer multifunctional micelles for cancer chemotherapy and imaging

Multifunctional mixed micelles that constructed from poly(HEMA-co-histidine)-g-PLA and diblock copolymer PEG-PLA with functional moiety was developed in this study. The mixed micelles had well defined core shell structure which was evaluated by TEM. The functional inner core of poly(HEMA-co-histidine)-g-PLA exhibited pH stimulate to enable intracellular drug delivery and outer shell of PEG-b-PLA with functional moiety Cy5.5 for biodistribution diagnosis and folate for cancer specific targeting were synthesized at the end of the polymer chain. The graft and diblock copolymer self assembled to nanospheres against water with an average diameter below 120 nm without doxorubicin, and an average diameter of around 200 nm when loaded with drug. From drug released study, a change in pH destroy the inner core to lead a significant doxorubicin(Dox) release from mixed micelles. Cellular uptake of folate-micelles was found to be higher than that of non-folate-micelles due to the folate-binding effect on the cell membrane, thereby providing a similar cytotoxic effect to drug only against the HeLa cell line. In vivo study revealed that specific targeting of folate-micelles exhibited cancer targeting and efficiency expression on tumor growth, indicating that multifunctional micelles prepared from poly(HEA-co-histidine)-g-PLA and folate-PEG-PLA have great potential in cancer chemotherapy and diagnosis.

pH-Responsive polymer-liposomes for intracellular drug delivery and tumor extracellular matrix switched-on targeted cancer therapy

This study presents a tumor-extracellular matrix pH-induced targeting liposome (ECM-targeting liposomes), crosslinked from methoxy-poly(ethylene glycol)-b-poly(N-2-hydroxypropyl methacrylamide-co-histidine)-cholesterol copolymers and biotin2-polyethylene glycol crosslinkers by hydrogen bonds to overcome the defects of liposomes. In this study, ECM-targeting liposomes were completely investigated their pH-responsibility, drug releasing behaviors, anticancer efficiencies and the time-dependent organ distribution and toxic effects. Experimental results indicate that ECM-targeting liposomes showed rapid drug releasing profiles in acidic conditions. Because the ECM-targeting liposomes accumulated preferentially in tumor, the ECM-targeting liposomes exhibited exceptional anticancer activity inxa0vivo and lower hepatic and renal toxicity. The ECM-targeting liposomes which are switched on the targeting ability in tumor ECM possess potential for future application in anticancer therapy.

Reactive oxygen species and glutathione dual redox-responsive micelles for selective cytotoxicity of cancer.

This study developed reactive oxygen species (ROS) and glutathione (GSH) dual redox-responsive micelles, which encapsulate anticancer drug camptothecin (CPT), protect CPT activity, and trigger CPT release in cancer cell H2O2- or GSH-rich surroundings. Experimental results show that CPT-loaded dual redox-responsive micelles remain stable at low levels of ROS and GSH in blood circulation, have high redox sensitivities needed to CPT release in cancer cells with high ROS or GSH (e.g., lung, gastric, and colon cancer cells), and prevent undersigned CPT toxicity in ROS/GSH balanced normal cells (e.g., fibroblast cells, etc.) or normal organs (e.g., liver, kidney, etc.). The CPT-loaded dual redox-responsive micelles also had high inxa0vivo antitumor efficacy. This study demonstrates that ROS and GSH dual redox-responsive micelles have potential use as anticancer therapeutic nanomedicine in various cancer therapies.

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.

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.

Rapamycin encapsulated in dual-responsive micelles for cancer therapy.

Rapamycin has been developed as a potential anticancer drug for treatment in rapamycin-sensitive cancer models, but its poor water solubility greatly hampers the application to cancer therapy. This study investigated the preparation, release profiles, uptake and in vitro/in vivo study of a dual-responsive micellar formulation of rapamycin. Rapamycin-loaded micelles (rapa-micelles) measured approximately ca. 150 nm with narrow size distribution and high stability in bovine serum albumin solution. It was shown that rapamycin could be loaded efficiently in mixed micelles up to a concentration of 1.8 mg/mL by a hot shock protocol. Rapamycin release kinetic studies demonstrated that this type of micellar system could be applied in physiological conditions under varied pH environments. Confocal and pH-topography imaging revealed a clear distribution of rapa-micelles, and visible intracellular pH changes which induced encapsulated rapamycin to be released and then induced autophagolysosome formation. In vivo tumor growth inhibition showed that rapa-micelles exhibited excellent antitumor activity and a high rate of apoptosis in HCT116 cancer cells. These results indicated that dual-responsive mixed micelles provided a suitable delivery system for the parenteral administration of drugs with poor water solubility, such as rapamycin, in cancer therapy.

Multifunctional nanomicellar systems for delivering anticancer drugs

Most anticancer drugs cause severe side effect due to the lack of selectivity for cancer cells. In recent years, new strategies of micellar systems, which design for specifically target anticancer drugs to tumors, are developed at the forefront of polymeric science. To improve efficiency of delivery and cancer specificity, considerable emphasis has been placed on the development of micellar systems with passive and active targeting. In this review article, we summarized various strategies of designing multifunctional micellar systems in the purpose of improving delivery efficiency. Micellar systems compose of a multifunctional copolymer or a mixture of two or more copolymers with different properties is a plausible approach to tuning the resulting properties and satisfied various requirements for anticancer drug delivery. It appears that multifunctional micellar systems hold great potential in cancer therapy.

The effect of PEG-5K grafting level and particle size on tumor accumulation and cellular uptake

PEG-modified gold nanoparticles (PEG-modified GNs) with diameters of 40 nm and 70 nm were prepared to elucidate the effect of extent of PEG (M.W. 5000) grafting and particle size on tumor accumulation and cellular uptake. Flow cytometry reveals that cellular uptake is strongly related to the size of PEG-modified GNs, rather than the extent of PEG-5K grafting level. Cytotoxicity analysis based on the intracellular release of drugs showed that the 70 nm PEG-modified GNs have the higher cytotoxicity, beccause of their greater cellular uptake. Also, particle size, rather than PEG-5K grafting level affects tumor accumulation. However, PEG-5K grafting level significantly affects the accumulation of particles in the liver and spleen. This finding is important in determining the proper PEG-5K grafting level and particle size for designing nano-medicines.

Specific Cancer Cytosolic Drug Delivery Triggered by Reactive Oxygen Species-Responsive Micelles

Cytosolic drug delivery, a major route in cancer therapy, is limited by the lack of efficient and safe endosomal escape techniques. Herein, we demonstrate a reactive oxygen species (ROS)-responsive micelle composed of methoxy polyethylene glycol-b-poly(diethyl sulfide) (mPEG-PS) copolymers which can induce specific endosome escape in cancer cells by changes in the hydrophobicity of copolymers. Owing to the more ROS levels in cancer cells than normal cells, the copolymers can be converted into more hydrophilic and insert into and destabilize the cancer intracellular endosome membrane after cellular uptake. More importantly, we show that acid-intolerant drugs successfully maintain their bioactivity and cause selective cytotoxicity for cancer cells over normal cells. Our results suggest that the endosomal escape induced by hydrophobic-hydrophilic exchange of copolymers has great potential to locally and efficiently deliver biological agents (e.g., proteins and genes) in the cancer cell cytosol.

Vitamin E containing polymer micelles for reducing normal cell cytotoxicity and enhancing chemotherapy efficacy.

An α-tocopheryl succinate (α-TOS) containing diblock copolymer micellar system was used to deliver doxorubicin (Dox), an anticancer drug, for HCT116 colon cancer therapy. The α-TOS containing diblock copolymers were synthesized by conjugation of α-TOS molecules and a mPEG-b-PHEMA hydrophilic diblock copolymer by ester bonds. The Dox-loaded polymeric micelles were then obtained by solvent exchange process. In acidic surroundings such as endosomes or secondary lysosomes, the structures of the Dox-loaded polymeric micelles deformed and released the drug loads. Additionally, Dox-loaded polymeric micelles enhanced the cytotoxicity of Dox and α-TOS to cancer cells in vitro. Dox-loaded polymeric micelles also showed an exceptional tumor inhibiting effect in vivo. This study indicates that the α-TOS containing polymeric micelle system can be used as a drug carrier for cancer therapy.