Retraction of ‘A multifunctional self-dissociative polyethyleneimine derivative coating polymer for enhancing the gene transfection efficiency of DNA/polyethyleneimine polyplexes in vitro and in vivo’ by Cheng Wang, et al., Polym. Chem., 2015, 6, 780–796.
Herein, we describe the preparation of a targeted cellular delivery system for morin hydrate (MH), based on a low-molecular-weight hyaluronic acid-poly(butyl cyanoacrylate) (HA-PBCA) block copolymer. In order to enhance the therapeutic effect of MH, D-alpha-tocopheryl polyethylene glycol 1000 succinate (TPGS) was mixed with HA-PBCA during the preparation process. The MH-loaded HA-PBCA “plain” nanoparticle (MH-PNs) and HA-PBCA/TPGS “mixed” nanoparticles (MH-MNs) were concomitantly characterized in terms of loading efficiency, particle size, zeta potential, critical aggregation concentration, and morphology. The obtained MH-PNs and MH-MNs exhibited a spherical morphology with a negative zeta potential and a particle size less than 200 nm, favorable for drug targeting. Remarkably, the addition of TPGS resulted in about 1.6-fold increase in drug-loading. The in vitro cell viability experiment revealed that MH-MNs enhanced the cytotoxicity of MH in A549 cells compared with MH solution and MH-PNs. Furthermore, blank MNs containing TPGS exhibited selective cytotoxic effects against cancer cells without diminishing the viability of normal cells. In addition, the cellular uptake study indicated that MNs resulted in 2.28-fold higher cellular uptake than that of PNs, in A549 cells. The CD44 receptor competitive inhibition and the internalization pathway studies suggested that the internalization mechanism of the nanoparticles was mediated mainly by the CD44 receptors through a clathrin-dependent endocytic pathway. More importantly, MH-MNs exhibited a higher in vivo antitumor potency and induced more tumor cell apoptosis than did MH-PNs, following intravenous administration to S180 tumor-bearing mice. Overall, the results imply that the developed nanoparticles are promising vehicles for the targeted delivery of lipophilic anticancer drugs.
N-octyl-N-Arginine chitosan (OACS) was synthesized in an attempt to combine the permeation enhancing effects of arginine-rich peptides and the drug loading capacity of the amphipathic polymers for insulin oral delivery. OACS self-assembled micelles of insulin were prepared by the conventional stirring technique, which were characterized by Dynamic light scattering, transmission electron microscopy and differential scanning calorimetry. Molecular docking by Discovery studio software confirmed that the interactions between OACS and insulin were mostly electrostatic in nature. In vitro, the result of the degradation experiment by enzyme showed that the OACS has a relative protective effect for insulin from proteolyses. Compared to the insulin solution, OACS micelles increased the Caco-2 cell's internalization by up to 22.3 folds. In vivo, the pharmacological activity PA% of series OACS-insulin micelles ranged from 7.7%-16.8%. Meanwhile by increasing arginine degree of the substitution both the uptake in Caco-2 cells and the hypoglycemic effect in diabetic rats were enhanced. Therefore, it is concluded that using arginine polymeric micelles for the enhancement of oral insulin delivery is a promising approach for the oral peptide delivery.
Mixed micelles were designed to increase oral bioavailability of Apigenin (Ap). The phospholipid (Ph) complex technology was exploited alongside TPGS' stabilizing effect by PEG chain sterical hindrance of the phase II enzymes. This prevented extensive metabolism of Ap while inhibiting P-glycoprotein's exocytosis. TPGS modified micelles of Ap-Ph complex (TPGS-Ap-Ph) were prepared by thin film hydration method. Ap-Ph complex was confirmed by FTIR and NMR spectroscopy while Ap, Ph and TPGS interactions were studied by surface tensiometry. TPGS-Ap-Ph micelles achieved 87.35% drug encapsulation and 12.6% drug loading showing spherical morphology 137.1 +/- 3.4 nm particle size and -12.94 mV surface charge. The negative zeta potential confirmed computer simulation predictions that PEG moieties of TPGS were at micelles surface, while hydrophobic part inserted to the phospholipid hydrophobic core by electrostatic interactions. TPGS-Ap-Ph micelles were found to be stable for more than 90 days after lyophilization. Comparing to free drug, the micelles increased intestinal absorption of Ap 2.4 fold, illustrating apparent permeation (P(app)) and absorption constant (K(a)) of 7.9 x 10(-4) and 2.05 x 10(-4) (p < 0.001) respectively. Moreover, cell culture studies showed high cellular uptake with sufficient intracellular trafficking in A549 cells. MTT assays revealed a significant cytotoxic effect by TPGS-Ap-Ph micelles. In vivo, an effective inhibition of 72.9% was achieved upon oral administration to S180 carcinoma mice compared to 19.5% by Ap-Ph complex. Altogether reflect that orally administered mixed micelles of TPGS-Ap-Ph could effectively inhibit cancer. The results present the designed micelles as a new way to improve oral bioavailability of sparingly soluble and poorly absorbed drugs.
Cell-penetrating peptides (CPPs) have been previously shown to be powerful transport vector tools for the delivery of a large variety of cargoes through the cell membrane, as well as other physiological membranes. And since they're relatively cell-, receptor- and energy-independent, CPPs have unique advantages in facilitating drugs entry into cells. This paper briefly reviews the discovery, mechanism and classification of CPPs, and especially focuses on the specific limitations of CPPs and their potential applications for tumor-targeted delivery of biologically active molecules, imaging agents and carriers.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.