A new method for the determination of total and released docetaxel from docetaxel-entrapped core-crosslinked polymeric micelles (CriPec®) by LC-MS/MS and its clinical application in plasma and tissues in patients with various tumours.

A sensitive, high-performance liquid chromatographic method was developed and validated, for determination of docetaxel from docetaxel-entrapped core-crosslinked polymeric micelles (CriPec®) in human potassium EDTA plasma and released docetaxel to support the clinical development of Cripec® docetaxel. CriPec® docetaxel is a novel formulation of docetaxel - covalently conjugated via a linker agent in a nanoparticle. The analytical characterization of CriPec® docetaxel comprises determination of both released and total docetaxel, the first being the already deconjugated docetaxel, whereas total is representative of all docetaxel (deconjugated as well as CriPec® nanoparticle conjugated material). Total docetaxel was determined by incubation of human plasma with 0.5 M ammonium acetate buffer pH 7.4 for 3-days at 37 °C. Hereafter, a liquid-liquid extraction with 1-chlorobutane was performed using paclitaxel as internal standard. Released docetaxel from CriPec® docetaxel nanoparticles was determined in human plasma stabilized with 5 M ammonium acetate, pH 5.0. Hereafter, a liquid-liquid extraction with 1-chlorobutane was performed using docetaxel-d5 in acetonitrile as internal standard. Released docetaxel and its internal standard were eluted. The validated ranges for total docetaxel were 2,000-100,000 ng/mL for the high concentrations and 2-500 ng/mL for the low concentrations and 0.250-100 ng/mL for released docetaxel. In conclusion the newly developed assay met the required standards for validation and was applied successfully to support pharmacokinetic analysis in both serum and tissue in patients treated with Cripec®.

Antitumor efficacy of dexamethasone-loaded core-crosslinked polymeric micelles.

In the current study, core-crosslinked polymeric micelles (DEX-PMs) loaded with three different DEX derivatives designed to display different drug release kinetics, were evaluated for cancer therapy and compared to another effective nanomedicine formulation (long-circulating liposomes encapsulating dexamethasone, LCL-DEX). Pharmacokinetic studies with both radiolabeled dexamethasone and polymer showed that these polymeric systems have long circulating half-lives and may accumulate at the tumor site to a higher extent than liposomes. The in vitro drug release profiles and circulating drug levels in the blood stream show that DEX-PMs with dexamethasone covalently entrapped via a sulfone ester-containing linker (DMSL2) have prolonged circulation time and intermediate drug release kinetics compared to the other polymeric DEX-releasing systems. Furthermore, as the free dexamethasone circulating levels were similar when administered as DMSL2-PM or LCL-DEX, these systems were evaluated simultaneously for antitumor efficacy in B16F10 melanoma bearing mice. The corticosteroid-targeted systems inhibited tumor growth to a similar extent and both increased survival compared to free drug. Recently antitumor efficacy of targeted formulations has been correlated with a systemic effect: a decrease of white blood cell count. In this study all three polymeric systems, liposomes as well as free drug had similar effects on the number of circulating white blood cells, although white blood cell counts recovered faster in the group receiving free drug. In conclusion, corticosteroid-targeting with a polymeric system or a liposomal system translates in similar therapeutic effects. The proven high versatility of the PM with possible optimization and adjustment of the drug release to that required by the therapeutic application, clearly demonstrates the potential of these systems for the treatment of chronic inflammatory diseases including cancer.

Synthesis and characterization of biodegradable and thermosensitive polymeric micelles with covalently bound doxorubicin-glucuronide prodrug via click chemistry.

Doxorubicin is an anthracycline anticancer agent that is commonly used in the treatment of a variety of cancers, but its application is associated with severe side effects. Biodegradable and thermosensitive polymeric micelles based on poly(ethylene glycol)-b-poly[N-(2-hydroxypropyl) methacrylamide-lactate] (mPEG-b-p(HPMAmLac(n))) have been studied as drug delivery systems for therapeutic and imaging agents and have shown promising in vitro and in vivo results. The purpose of this study was to investigate the covalent coupling of a doxorubicin-glucuronide prodrug (DOX-propGA3) to the core of mPEG-b-p(HPMAmLac(2)) micelles. This prodrug is specifically activated by human ß-glucuronidase, an enzyme that is overexpressed in necrotic tumor areas. To this end, an azide modified block copolymer (mPEG(5000)-b-p(HPMAmLac(2)-r-AzEMA)) was synthesized and characterized, and DOX-propGA3 was coupled to the polymer via click chemistry with a high (95%) coupling efficiency. Micelles formed by this DOX containing polymer were small (50 nm) and monodisperse and released 40% of the drug payload after 5 days incubation at 37 °C in the presence of ß-glucuronidase, but less than 5% in the absence of the enzyme. In vitro cytotoxicity experiments demonstrated that DOX micelles incubated with 14C cells showed the same cytotoxicity as free DOX only in the presence of ß-glucuronidase, indicating full conversion of the polymer-bound DOX into the parent drug. Overall, this novel system is very promising for enzymatically responsive anticancer therapy.

Micelles based on HPMA copolymers.

Polymeric micelles have been under extensive investigation during the past years as drug delivery systems, particularly for anticancer drugs. They are formed by the self-assembly of amphiphilic block copolymers in aqueous solutions and have a spherical shape and a size in the nano-range (<200nm). Tumor accumulation of polymeric micelles upon intravenous administration can occur as a result of the leaky vasculature of tumor tissue (called the enhanced permeation and retention (EPR) effect).To benefit from the EPR effect, polymeric micelles need to have prolonged circulation times as well as high and stable drug loadings. Poly[N-(2-hydroxypropyl) methacrylamide] (pHPMA) is a hydrophilic polymer currently under investigation for its use in polymer-drug conjugates. Its biocompatibility, non-immunogenicity and the possibility for functionalization are properties that resulted in broad pharmaceutical and biomedical applications, also in the micelle technology research. Being hydrophilic, it can serve as a micellar stealth corona, while it can also be modified with hydrophobic moieties to serve as a micellar core in which hydrophobic drugs can be solubilized and retained. HPMA-based polymeric micelles have been showing very promising in vitro and in vivo results. This review summarizes the applications of pHPMA in the field of polymeric micelles, either serving as a micellar stealth corona, or, if hydrophobically rendered by derivatization, as a micellar core.

The influence of bile acids on the oral bioavailability of vitamin K encapsulated in polymeric micelles.

The purpose of this study was to assess the ability of polymeric micelles to enable gastrointestinal absorption of the extremely hydrophobic compound vitamin K, by comparison of its absorption in bile duct ligated and sham operated rats. Hereto, vitamin K was encapsulated in micelles composed of mPEG(5000)-b-p(HPMAm-lac(2)), a thermosensitive block copolymer. Vitamin K plasma levels rose significantly upon gastric administration of 1 mg vitamin K encapsulated in polymeric micelles in sham operated rats, but not after bile duct ligation (AUC 4543 and 1.64 ng/mL/h respectively, p<0.01). Duodenal administration of polymeric micelles together with bile acids in bile duct ligated rats fully restored absorption. Dynamic light scattering time series showed a significant and dose dependent rise in micellar size in the presence of bile acids in vitro, indicating the gradual formation of mixed micelles during the first 3 h of incubation. The highest bile acid amounts (11 mM deoxycholic acid and 41 mM taurocholic acid) eventually caused aggregation of the loaded micelles after the formation of mixed micelles. These data suggest that the gastrointestinal absorption of encapsulated vitamin K from polymeric micelles is mediated by free bile and that uptake of intact micelles through pinocytosis is insignificant.

Triggered destabilisation of polymeric micelles and vesicles by changing polymers polarity: an attractive tool for drug delivery.

Polymeric micelles and vesicles have emerged as versatile drug carriers during the past decades. Furthermore, stimuli-responsive systems are developed whose properties change after applying certain external triggers. Therefore, a triggered release of drugs from stimuli-sensitive micelles and vesicles has become an interesting challenge in the pharmaceutical field. Polymeric micelles or vesicles are mainly composed of amphiphilic block copolymers that are held together in water due to strong hydrophobic interactions between the insoluble hydrophobic blocks, thus forming a core-shell or bilayer morphology. Consequently, destabilisation of these assemblies is induced by increasing the polarity of the hydrophobic blocks. Preferably, this process should be the consequence of an external trigger, or take place in a certain time frame or at a specific location. A variety of mechanisms has recently been described to accomplish this transition, which will be reviewed in this paper. These mechanisms include the destabilisation of polymeric micelles and vesicles by temperature, pH, chemical or enzymatic hydrolysis of side chains, oxidation/reduction processes, and light.