Jingxin Gou

Dual-responsive mPEG-PLGA-PGlu hybrid-core nanoparticles with a high drug loading to reverse the multidrug resistance of breast cancer: An in vitro and in vivo evaluation

In this study, monomethoxy (polyethylene glycol)-b-P (d,l-lactic-co-glycolic acid)-b-P (l-glutamic acid) (mPEG-PLGA-PGlu) nanoparticles with the ability to rapidly respond to the endolysosomal pH and hydrolase were prepared and the pH-sensitivity was tuned by adjusting the length of the PGlu segment. The mPEG5k-PLGA20k-PGlu (60) nanoparticles were specifically responsive to an endosomal pH of 5.0-6.0 due to the configuration transition of the PGlu segment and rapidly initiated chemical degradation after incubation with proteinase k for 10 min. Doxorubicin hydrochloride (DOX), used as a model drug, was easily encapsulated into nanoparticles and the DOX-loaded nanoparticles (DOX-NPs) exhibited a pH-dependent and enzyme-sensitive release profile in vitro. The dual sensitivity enabled the rapid escape of DOX-loaded nanoparticles from the endolysosomal system to target cellular nuclei, which resulted in increased cell toxicity against MCF/ADR resistant breast cancer cells and a higher cellular uptake than free DOX. In Vivo Imaging studies indicated that the nanoparticles could continuously accumulate in the tumor tissues through EPR effects and Ex vivo Imaging biodistribution studies indicated that DOX-NPs increased drug penetration into tumors compared with normal tissues. The in vivo antitumor activity demonstrated that DOX-loaded NPs had less body loss and a significant regression of tumor growth, indicating the increased anti-tumor efficacy and lower systemic toxicity. Therefore, this dual sensitive nanoparticle system may be a potential nanocarrier to overcome the multidrug resistance exhibited by breast cancer.

Decreased Core Crystallinity Facilitated Drug Loading in Polymeric Micelles without Affecting Their Biological Performances

Cargo-loading capacity of polymeric micelles could be improved by reducing the core crystallinity and the improvement in the amount of loaded cargo was cargo-polymer affinity dependent. The effect of medium chain triglyceride (MCT) in inhibiting PCL crystallization was confirmed by DSC and polarized microscope. When incorporating MCT into polymeric micelles, the maximum drug loading of disulfiram (DSF), cabazitaxel (CTX), and TM-2 (a taxane derivative) increased from 2.61 ± 0.100%, 13.5 ± 0.316%, and 20.9 ± 1.57% to 8.34 ± 0.197%, 21.7 ± 0.951%, and 28.0 ± 1.47%, respectively. Moreover, the prepared oil-containing micelles (OCMs) showed well-controlled particle size, good stability, and decreased drug release rate. MCT incorporation showed little influence on the performances of micelles in cell studies or pharmacokinetics. These results indicated that MCT incorporation could be a core construction module applied in the delivery of hydrophobic drugs.

Cysteine-Functionalized Nanostructured Lipid Carriers for Oral Delivery of Docetaxel: A Permeability and Pharmacokinetic Study

Here we report the development and evaluation of cysteine-modified nanostructured lipid carriers (NLCs) for oral delivery of docetaxel (DTX). The NLCs ensure high encapsulation efficiency of docetaxel, while the cysteine bound the NLCs with PEG2000-monostearate (PEG2000-MSA) as a linker, and allowed a specific interaction with mucin of the intestinal mucus layer and facilitated the intestinal transport of docetaxel. The cysteine-modified NLCs (cNLCs) had a small particle size (<100 nm) and a negative zeta potential (-13.72 ± 0.07 mV), which was lower than that of the unmodified NLCs (uNLCs) (-6.39 ± 0.07 mV). This correlates well with the location of the cysteine group on the surface of the NLCs obtained by X-ray photoelectron spectroscopy (XPS). The cNLCs significantly improved the mucoadhesion properties compared with uNLCs. The intestinal absorption of cNLCs in total intestinal segments was greatly improved in comparison with uNLCs and docetaxel solution (DTX-Sol), and the in vivo imaging system captured pictures also showed not only increased intestinal absorption but also improved accumulation in blood. The cNLCs could be absorbed into the enterocytes via both endocytosis and passive transport. The results of the in vivo pharmacokinetic study indicated that the AUC0-t of cNLCs (1533.00 ng/mL·h) was markedly increased 12.3-fold, and 1.64-fold compared with docetaxel solution and uNLCs, respectively. Overall, the cysteine modification makes nanostructured lipid carriers more suitable as nanocarriers for oral delivery of docetaxel.

Novel hydrophobin-coated docetaxel nanoparticles for intravenous delivery: in vitro characteristics and in vivo performance.

Novel hydrophobin (H star Protein® B, HPB)-coated docetaxel (DTX) nanoparticles were designed for intravenous delivery. DTX-HPB nanoparticles (DTX-HPB-NPs) were prepared using a nanoprecipitation-ultrasonication technique. The physicochemical properties in terms of particle size, size distribution, zeta potential, morphology, crystalline state of the drug, in vitro release and plasma stability were evaluated. To investigate the drug-hydrophobin interaction, FTIR analysis was carried out. The pharmacokinetics of DTX-HPB-NPs and Taxotere were compared after i.v. administration to rats. The optimized formulations have a high drug loading (>25%) and nanoparticle yield (>93%), small particle size with a narrow distribution, and exhibit delayed release. X-ray diffraction (XRD) demonstrated that the drug is present in a crystalline state. FTIR analysis suggested that the interaction of DTX and HPB involved hydrogen bonding. In vitro hemolysis study confirmed the safety of these nanoparticles. In plasma, DTX-HPB nanoparticles exhibited a significantly enhanced Cmax (1300.618±405.045 ng/mL vs 453.174±164.437 ng/mL, p<0.05), and AUC0-t (409.602±70.267 vs 314.924±57.426 μg/Lh, p<0.05), and a significantly reduced volume of distribution (36.635±15.189 vs 95.199±40.972 L/kg, p<0.05) compared with the Taxotere. These results demonstrated that hydrophobin has the potential to be used as a novel biocompatible biomaterial for drug delivery.

PSMA Ligand Conjugated PCL-PEG Polymeric Micelles Targeted to Prostate Cancer Cells

In this content, a small molecular ligand of prostate specific membrane antigen (SMLP) conjugated poly (caprolactone) (PCL)-b-poly (ethylene glycol) (PEG) copolymers with different block lengths were synthesized to construct a satisfactory drug delivery system. Four different docetaxel-loaded polymeric micelles (DTX-PMs) were prepared by dialysis with particle sizes less than 60 nm as characterized by dynamic light scattering (DLS) and transmission electron microscope (TEM). Optimization of the prepared micelles was conducted based on short-term stability and drug-loading content. The results showed that optimized systems were able to remain stable over 7 days. Compared with Taxotere, DTX-PMs with the same ratio of hydrophilic/hydrophobic chain length displayed similar sustained release behaviors. The cytotoxicity of the optimized targeted DTX-PCL12K-PEG5K-SMLP micelles (DTX-PMs2) and non-targeted DTX-PCL12K-mPEG5K micelles (DTX-PMs1) were evaluated by MTT assays using prostate specific membrane antigen (PSMA) positive prostate adenocarcinoma cells (LNCaP). The results showed that the targeted micelles had a much lower IC50 than their non-targeted counterparts (48 h: 0.87±0.27 vs 13.48±1.03 µg/ml; 72 h: 0.02±0.008 vs 1.35±0.54 µg/ml). In vitro cellular uptake of PMs2 showed 5-fold higher fluorescence intensity than that of PMs1 after 4 h incubation. According to these results, the novel nano-sized drug delivery system based on DTX-PCL-PEG-SMLP offers great promise for the treatment of prostatic cancer.

Strategies for improving the payload of small molecular drugs in polymeric micelles

Abstract In the past few years, substantial efforts have been made in the design and preparation of polymeric micelles as novel drug delivery vehicles. Typically, polymeric micelles possess a spherical core–shell structure, with a hydrophobic core and a hydrophilic shell. Consequently, poorly water‐soluble drugs can be effectively solubilized within the hydrophobic core, which can significantly boost their drug loading in aqueous media. This leads to new opportunities for some bioactive compounds that have previously been abandoned due to their low aqueous solubility. Even so, the payload of small molecular drugs is still not often satisfactory due to low drug loading and premature release, which makes it difficult to meet the requirements of in vivo studies. This problem has been a major focus in recent years. Following an analysis of the published literature in this field, several strategies towards achieving polymeric micelles with high drug loading and stability are presented in this review, in order to ensure adequate drug levels reach target sites. Graphical abstract The strategies for improve the payload of micelles. Figure. No Caption available.

Modified PLGA–PEG–PLGA thermosensitive hydrogels with suitable thermosensitivity and properties for use in a drug delivery system

PLGA-PEG-PLGA (PPP) triblock copolymer is the most widely studied thermosensitive hydrogel owing to its non-toxic, biocompatible, biodegradable, and thermosensitive properties. PPP thermosensitive hydrogels are being investigated as in situ gels because, at a low temperature, PPP solutions with drugs can be injected at the target site, and converted into a gel without surgical procedures. To meet the requirements of different therapeutic applications, PPP hydrogels with different properties need to be synthesized. The adjustable properties include the sol-gel transition temperature, gel window width, retention time and drug release time. Furthermore, thermo- and pH-, thermo- and electro-, and thermo- and photo-dual sensitive hydrogels are needed for some special therapies. Thus, this review examines the methods of modification of PPP thermosensitive hydrogels used to obtain desired drug delivery systems with appropriate physicochemical and pharmaceutical properties.

Self-Assembled Micelles Composed of Doxorubicin Conjugated Y-Shaped PEG-Poly(glutamic acid)2 Copolymers via Hydrazone Linkers

In this work, micelles composed of doxorubicin-conjugated Y-shaped copolymers (YMs) linked via an acid-labile linker were constructed. Y-shaped copolymers of mPEG-b-poly(glutamate-hydrazone-doxorubicin)2 and linear copolymers of mPEG-b-poly(glutamate-hydrazone-doxorubicin) were synthesized and characterized. Particle size, size distribution, morphology, drug loading content (DLC) and drug release of the micelles were determined. Alterations in size and DLC of the micelles could be achieved by varying the hydrophobic block lengths. Moreover, at fixed DLCs, YMs showed a smaller diameter than micelles composed of linear copolymers (LMs). Also, all prepared micelles showed sustained release behaviors under physiological conditions over 72 h. DOX loaded in YMs was released more completely, with 30% more drug released in acid. The anti-tumor efficacy of the micelles against HeLa cells was evaluated by MTT assays, and YMs exhibited stronger cytotoxic effects than LMs in a dose- and time-dependent manner. Cellular uptake studied by CLSM indicated that YMs and LMs were readily taken up by HeLa cells. According to the results of this study, doxorubicin-conjugated Y-shaped PEG-(polypeptide)2 copolymers showed advantages over linear copolymers, like assembling into smaller nanoparticles, faster drug release in acid, which may correspond to higher cellular uptake and enhanced extracellular/intracellular drug release, indicating their potential in constructing nano-sized drug delivery systems.

A comparison of the effect of temperature and moisture on the solid dispersions: Aging and crystallization

The purpose of this work was to compare the effect of temperature and relative humidity (RH) on the physical stability and dissolution of solid dispersions. Cinnarizine-Soluplus(®) solid dispersions (SDs) at three different drug loadings (10, 20 and 35 wt%) were prepared by hot melt extrusion and exposed to stress conditions: high temperatures (40 and 60 °C), high relative humidities (75% and 94% RH) and accelerated conditions (40 °C/75% RH) for 30 days, or stored at 25 °C for up to 5 months. Changes in solid state and dissolution of SDs were investigated by differential scanning calorimetry (DSC), powder X-ray diffraction (PXRD) and dissolution testing. For samples under stress conditions, the results showed a reduced dissolution and a recrystallization of the drug with an increased crystallinity in the order of 40 °C/75% RH, >60 °C/0% RH, >25 °C/94% RH, >40 °C/0% RH, >25 °C/75% RH. For samples stored at 25 °C, nonlinear physical aging was observed and the dissolution also decreased although the SDs were still amorphous. The results indicated that temperature and humidity seemed to have comparable effects on the crystallization of cinnarizine-Soluplus(®) SDs. It is not reasonable to regard recrystallization as a sign of reduced dissolution, and glass transition temperature (Tg) may be a good indicator of the changes in dissolution.

Preparation and characterization of azithromycin--Aerosil 200 solid dispersions with enhanced physical stability.

The main purpose of this study was to investigate the feasibility of azithromycin (AZI)--Aerosil 200 solid dispersions specifically with high stability under accelerated condition (40 °C/75% RH). Ball milling (BM) and hot-melt extrusion (HME) were used to prepare AZI solid dispersions. The physical properties of solid dispersions were evaluated by differential scanning calorimetry (DSC), scanning electron microscopy (SEM), powder X-ray diffraction (PXRD), Fourier transform infrared spectroscopy (FT-IR) and thermogravimetric analysis (TGA). For solid dispersions prepared with both methods, no crystalline of AZI was detected (except for AZI: Aerosil 200=75:25) by DSC or PXRD, indicating the amorphous state of AZI in solid dispersions. The FT-IR results demonstrated the loss of crystallization water and the formation of hydrogen bonds between Aerosil 200 and AZI during the preparation of solid dispersions. After 4 weeks storage under accelerated condition, the degree of crystallinity of AZI increased in solid dispersions prepared by BM, whereas for solid dispersions containing AZI, Aerosil 200 and glyceryl behenate (GB) prepared by HME, no crystalline of AZI was identified. This high stability can be attributed to the hydrophobic properties of GB and the presence of hydrogen bonds. Based on the above results, it is inferred the protection of hydrogen bonds between AZI and Aerosil 200 formed during preparation process effectively inhibited the recrystallization of AZI and improved the physical stability of amorphous AZI in the presence of Aerosil 200.