Tianyang Ren

Polypeptide-based vesicles: formation, properties and application for drug delivery

It is well known that amphiphilic block copolymers can self-assemble in selective solvents to adopt various morphologies, such as micelles, vesicles, and cylinders. Polypeptide-containing amphiphilic block copolymers have received a great deal of attention due to their unique physicochemical and biological features. They can form vesicular structures, spontaneously mimicking the self-assemblies of virus capsids. This article focuses on recent advances involving polypeptide-based vesicles, including their formation and properties, which are significantly different from those of conventional coil–coil copolymers. The preparation of vesicles with a tunable size is also described. Unlike other polymers, polypeptides can adopt different conformations and undergo conformation transitions under specific conditions. The stimuli–responses of the vesicles based on conformation transitions will be highlighted. Polypeptides are ideal materials for gene and drug delivery because they are highly biocompatible, biodegradable, and exhibiting precise secondary conformations and inherent functionality. Polypeptide-based vesicles have shown much promise with regard to anti-cancer drug delivery.

Lipid emulsions in parenteral nutrition: current applications and future developments

Introduction: A parenteral lipid emulsion (LE), used as a key source of energy, essential fatty acids (FAs), and fat-soluble vitamins, is an integral part of a parenteral nutrition (PN) regimen. The conventional LEs, such as soybean oil (SO)-based emulsions, have caused concerns about the potential adverse effects involving oxidative stress, inflammation, and immune response probably because of undesirable FA composition. Areas covered: Recently, alternative LEs, optimizing the FA composition with partial substitution of SO with medium-chain triglyceride (MCT), olive oil (OO), and fish oil (FO), have been developed and applied in clinical practice. This review summarizes the characteristics and beneficial clinical effects of alternative parenteral LEs in critically ill, pediatric, and long-term PN patients. Expert opinion: More clinical data from sufficiently high-powered studies are required to characterize the integral biological properties of alternative LEs for further selection to fit individual needs and disease characteristics. Simultaneously, potential lipid sources with desirable FA compositions and biological properties should be selected to develop new therapeutic LEs. As supplements to current parenteral lipids, the new LEs with different therapeutic effects are expected to fit specified subpopulations of patients with different diseases. Great efforts should be devoted to the development of parenteral LEs.

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.

A highly stable norcantharidin loaded lipid microspheres: Preparation, biodistribution and targeting evaluation

The purpose of this study was to prepare norcantharidin (NCTD)-loaded lipid microspheres (LMs) with a high encapsulation efficiency (EE) and stability during sterilization. The NCTD-phospholipid complex (NPC) was produced and characterized to increase the lipophilic properties of NCTD and a novel concentrated homogenization method was applied for the preparation of LMs. The results of the UV, DSC and IR investigations confirmed the formation of NPC. The oil-water partition coefficient (log P) of NPC was significantly increased with a value of -1.34 ± 0.06 at pH 7.4, nearly 224 times higher than that of NCTD. A concentrated emulsion was prepared based on a homogenization method and then diluted with water. After optimization of the NPC formation and emulsion preparation process, the EE was dramatically increased from 21.6% to 84.6%, and a highly sterilization stability was achieved with only a minor change in particle size from 168.2 ± 39.4 nm to 173.4 ± 43.5 nm. The tissue distribution of NPCLM was measured after intravenous administration to rats of a dose of 3.9 mg/kg with NCTD injection (NI) as the reference. Considerably increased concentrations of NCTD in the liver, spleen and lung were detected with NPCLM and the values were 1.67, 1.49 and 1.06 times higher than in the NI group, respectively while, in the kidney, the concentration was slightly reduced 0.96-fold. Overall, based on these techniques, this NPCLM with an improved EE and stability offers great promise in clinical applications and industrial-scale production along with a potentially increased targeting effect on the liver and reduced toxicity in the kidney.

A bufadienolide-loaded submicron emulsion for oral administration: Stability, antitumor efficacy and toxicity

The purpose of this study was to develop an alternative submicron emulsion containing three bufadienolides for oral administration and evaluate its preclinical stability, efficacy, and toxicity. The bufadienolide-loaded oral submicron emulsion (BU-OE) was prepared by high-pressure homogenization. The storage stability, in vitro cytotoxicity, in vivo antitumor efficacy, acute toxicity, and long-term toxicity of BU-OE were investigated in detail to evaluate the formulation. The stability study suggested that BU-OE was stable at room temperature and could be stored for at least 18 months at 6±2 °C. The cytotoxicity test revealed that BU-OE had marked cytotoxic activities against cancer cells, but no evident inhibitory effects on normal cells. Likewise, BU-OE exhibited significant antitumor efficacy against Hep G2, HCT-8, and EC9706 cell lines and a slight inhibitory effect on BGC 803 cell line in nude mice, while comparable antitumor activity with fluorouracil injection. The LD50 of BU-OE in mice was 29.4 mg/kg (male) and 22.8 mg/kg (female), respectively. As for the long-term toxicity, BU-OE showed no apparent toxic effects except minor cardiotoxic effects which were reversible. In conclusion, submicron emulsion is a suitable delivery system for oral administration of bufadienolides, with satisfactory stability, superior antitumor efficacy and low toxicity.

Effects of Pluronic F127-PEG multi-gel-core on the release profile and pharmacodynamics of Exenatide loaded in PLGA microspheres.

Pluronic F127 and PEG as a multi-gel-core were used to prepare Exenatide-loaded microspheres and store the drug within the microspheres. Also, the sol-gel transition and novel functions of the Pluronic F127-PEG gel core were investigated.Microspheres with a multi-gel-core (GCMs) and without a multi-gel-core (Ms) were compared in terms of the rate of PLGA degradation, therelease kinetics in vitro and the efficacy in KKAy mice. The drug release of GCMs was at a constant rate, and slower than Ms. In addition, after the KKAy mice were given Exenatide for 55days, the blood glucose concentration and HbA1c concentration in the GCMs group were lower than that in the Ms group. The obtained results demonstrated that a single injection of GCMs allowed the mice to maintain a stable blood glucose concentration for two weeks and their body weight was reduced more effectively than that in the Ms group. In addition, GCMs had a longer interval between dosing (two weeks) and a lower dosage(2.4μg/kg) than Bydureon(®) (one week, 33μg/kg). The bioactivity and release of macromolecular Exenatide was improved by the multi-gel-core structure:(1)The hydrophilic Exenatide tended to partition into the PEG chains of F127 and PEG homopolymer, and so it was protected from the organic solvent and vigorous stirring; (2)The macromolecular Exenatide was released both by diffusing through the hydrophilic F127-PEG chains and hydrophobic PLGA.

Increased absorption of mangiferin in the gastrointestinal tract and its mechanism of action by absorption enhancers in rats

The therapeutic efficiency of mangiferin is restricted by its low intestinal permeability. In order to improve the oral absorption of mangiferin, potential of enhancers, including TPGS, sodium deoxycholate and Carbopol 974P, were investigated in a series of in vivo experiments. After administration of mangiferin at a dose of 30 mg/kg combining with sodium deoxycholate, the bioavailability of mangiferin increased four-fold, and this may be due to sodium deoxycholate weakening the compactness between lecithin molecules and increased the paracellular permeability. When Carbopol 974P (100 mg/kg) was combined with mangiferin, the oral bioavailability of it increased seven-fold compared with the control group, and this may be related to the mucoadhesive properties of Carbopol 974P and paracellular drug permeation. However, following coadministration of TPGS (50 mg/kg), the oral absorption of mangiferin increased slightly compared with that of the control group (p > 0.05). The increased oral absorption by the three coexcipients was in the order of Carbopol 974P > sodium deoxycholate > TPGS. The absolute bioavailability of mangiferin in the three different doses following oral administration were evaluated based on the AUC(0–t) of the intravenous dose and there was no increase from low doses to high doses (25 mg/kg to 100 mg/kg). The above results show that the low absorption of mangiferin was due to presence of a narrow absorption window, which may also exist in these compounds, which have structures similar to mangiferin including three fused aromatic rings with polyphenolic hydroxyl groups. Bioadhesion polymers are effective enhancers of the absorption of mangiferin in the gastrointestinal tract.

Evaluating the safety of phytosterols removed perilla seed oil-based lipid emulsion

ABSTRACT Objectives: The aim of this study was to ascertain the potential toxicity of perilla seed oil-based lipid emulsion (POLE) caused by phytosterols and confirm the efficacy of the technique for removing phytosterols from perilla seed oil, and evaluate the safety of a low phytosterol POLE in a long-term tolerance study in dogs. Methods: A comparison between a soybean oil lipid emulsion (Intralipid group A) and POLE with high (group B) versus low (group C) levels of phytosterols was made with regard to their effects on the general condition, hematological and biochemical parameters, urinalysis and histopathological changes in nine dogs receiving daily infusions for four weeks at dosage levels of 6, 6, 9 g fat /kg. Results: Dogs in group A and group C remained in good condition and gained weight during the infusion period and no diarrhea or gastrointestinal bleeding occurred. Only a moderate degree of anemia was observed, the biochemical parameters changed only slightly and returned to normal after treatment had ceased. However, the dogs in group B exhibited significant symptoms of ‘fat overload syndrome’. Vomiting, diarrhoea and blood in the faeces were observed. Moreover, triglyceridemia, cholesteremia, and dark urine as well as microscopic signs of liver and gastrointestinal tract damage and generalized jaundice were clearly seen. Conclusions: Phytosterols promote ‘fat overload syndrome’ in long-term tolerance studies of POLE in dogs by producing cholestatic liver injury and interfering with fat metabolism. And the toxicity of POLE was reduced by removing phytosterols.

Poly(vinyl methyl ether/maleic anhydride)-Doped PEG–PLA Nanoparticles for Oral Paclitaxel Delivery To Improve Bioadhesive Efficiency

Bioadhesive nanoparticles based on poly(vinyl methyl ether/maleic anhydride) (PVMMA) and poly(ethylene glycol) methyl ether-b-poly(d,l-lactic acid) (mPEG-b-PLA) were produced by the emulsification solvent evaporation method. Paclitaxel was utilized as the model drug, with an encapsulation efficiency of up to 90.2 ± 4.0%. The nanoparticles were uniform and spherical in shape and exhibited a sustained drug release compared with Taxol. m-NPs also exhibited favorable bioadhesive efficiency at the same time. Coumarin 6 or DiR-loaded nanoparticles with/without PVMMA (C6-m-NPs/DiR-m-NPs or C6-p-NPs/DiR-p-NPs) were used for cellular uptake and intestinal adhesion experiments, respectively. C6-m-NPs were shown to enhance cellular uptake, and caveolae/lipid raft mediated endocytosis was the primary route for the uptake of the nanoparticles. Favorable bioadhesive efficiency led to prolonged retention in the intestine reflected by the fluorescence in isolated intestines ex vivo. In a ligated intestinal loops model, C6-m-NPs showed a clear advantage for transporting NPs across the mucus layer over C6-p-NPs and free C6. The apparent permeability coefficient (Papp) of PTX-m-NPs through Caco-2/HT29 monolayers was 1.3- and 1.6-fold higher than PTX-p-NPs and Taxol, respectively, which was consistent with the AUC0-t of different PTX formulations after oral administration in rats. PTX-m-NPs also exhibited a more effective anticancer efficacy, with an IC50 of 0.2 ± 1.4 μg/mL for A549 cell lines, further demonstrating the advantage of bioadhesive nanoparticles. The bioadhesive nanoparticles m-NPs demonstrated both mucus permeation and epithelial absorption, and thus, this bioadhesive drug delivery system has the potential to improve the bioavailability of drugs that are insoluble in the gastrointestinal environment.