Improved oral absorption and anti-lung cancer activity of paclitaxel-loaded mixed micelles

The aim of this study was to establish a paclitaxel (PTX)-loaded mixed micelle delivery system (PTX-TP-M) with vitamin E-TPGS (TPGS) and Plasdone®S-630 Copovidone (PVPS630) as carriers to improve the solubility, oral absorption, and anti-tumor activity of PTX against lung cancer. In this study, PTX-TP-M was prepared using the ethanol thin-film dispersion method followed by characterization of the binary mixed micelles system. The average size of the PTX-TP-M was 83.5?±?1.8?nm with a polydispersity index of 0.265?±?0.007 and the drug loading (DL%) and entrapment efficiency (EE%) were 3.09?±?0.09% and 95.67?±?2.84%, respectively, which contributed to a high solubility of PTX about 24947-fold increase in water (4.78?±?0.14?mg/mL). In addition, TEM analysis showed that the PTX-TP-M appeared spherical in structure and was well dispersed without aggregation and adhesion. In vitro release studies showed that the PTX-TP-M displayed a sustained release compared to free PTX in the dialysis bag. The efflux ratio of PTX reduced from 44.83 to 3.52 when formulated as PTX-TP-M; a 92.15% reduction, studied using the Caco-2 monolayer model. The oral bioavailability of PTX also improved by 4.35-fold, suggesting that PTX-TP-M can markedly promote the absorption in the gastrointestinal tract. Using in vitro MTT assays, it was observed that cytotoxicity was markedly increased, and IC₅₀ values of PTX-TP-M (3.14?±?0.85 and 8.28?±?1.02?μg/mL) were lower than those of PTX solution (5.21?±?0.93 and 14.53?±?1.96?μg/mL) in A549 and Lewis cell, respectively. In vivo anti-tumor studies showed that PTX-TP-M achieved higher anti-tumor efficacy compared with PTX in Lewis bared C57BL/6 mice. Furthermore, a gastrointestinal safety assay also proved the safety of PTX-TP-M. All results demonstrated that the PTX-TP-M exhibited great potential for delivering PTX with increased solubility, oral bioavailability, and anti-cancer activity and this binary mixed micelles drug delivery system has potential to be used clinically.     

Epidermal growth factor receptor-targeted peptide conjugated phospholipid micelles for doxorubicin delivery

Specific targeting of tumor cells to achieve higher drug levels in tumor tissue and to overcome side effects is the major goal in cancer chemotherapy. In this study, we used a tumor targeting peptide, GE11, to conjugate onto the surface of doxorubicin encapsulated phospholipid micelles. The GE11 peptide triggered specific binding to epidermal growth factor receptor (EGFR), leading to enhanced cellular uptake and cytotoxicity in vitro and highly accumulation in the tumors in vivo. The results indicated that GE11 conjugated phospholipid micelles should have potential applications in cancer therapy.     

Preparation of sodium cholate-based micelles through non-covalent ıbonding interaction and application as oral delivery systems for paclitaxel

In present study, two types of micelles based on sodium cholate (NaC) were prepared through non-covalent bonding interaction and the potential of micelles as oral drug delivery systems for paclitaxel (PTX) was evaluated. Pluronic–chitosan (F127–CS) and Pluronic–poly (acrylic acid) (F127–PAA) copolymers were synthesized. Electrostatic interaction and hydrogen bond were used to prepare F127–CS/NaC micelles and F127–PAA/NaC micelles, respectively. The physicochemical characteristics of micelles were determined. An average diameter of 67.5?nm and unimodal pattern of size distribution were observed for F127–CS/NaC micelles. While for F127–PAA/NaC micelles, an average diameter of 85.89?nm and non-unimodal pattern of size distribution were observed. The results revealed that F127–CS/NaC micelles were more integrated than F127–PAA/NaC micelles. Further experiments showed that the F127–CS/NaC micelles had a higher drug-loading content of 12.8% and a lower critical micelle concentration (CMC) of 2.5?×?10^?3?mol/L compared with F127–PAA/NaC micelles. In vitro cytotoxicity analysis demonstrated that the PTX-loaded F127–CS/NaC micelles were of great efficiency in inhibiting the growth of drug-resistant breast cancer MCF-7 cells (MCF-7/Adr). The intragastric administration of the PTX-loaded F127–CS/NaC micelles in rats provided a 4.33-fold higher absolute bioavailability compared to commercial Taxol®, indicating an efficient oral absorption of PTX delivered by micelles. These findings signify that F127–CS/NaC micelle may be a promising carrier for the delivery of PTX.     

Pluronic F127 polymeric micelles for co-delivery of paclitaxel and lapatinib against metastatic breast cancer: preparation,optimization and in vitro evaluation

Abstract

The aim of this study was to develop and characterize the paclitaxel (PTX)-lapatinib (LPT) loaded micelles for simultaneous delivery against metastatic breast cancer. Efflux pump-mediated drug resistance influences the efficacy of chemotherapeutic regimens. However, in the newly developed delivery system, LPT was selected to act as chemosensetizer. LPT increases the intracellular level of PTX by inhibition of efflux pumps. Pluronic F127 was selected for the preparation of the micelles, and its critical micelle concentration was determined to be 0.012?mg/ml. D-optimal design was used to analyze the impact of different experimental parameters on PTX and LPT encapsulation ratio. PTX encapsulation ratio was optimized at 68.3%, while LPT encapsulation ratio found to be 70.1%. Transmission electron microscope analyses demonstrate that micelles possess a good core–shell structure without any sharp edge. Laser scattering method results indicated that size of the optimized micelles is 64.81?nm with acceptable polydispersity index (0.309). In vitro release studies showed a sustain release pattern. PTX–LPT-loaded micelles suppressed the proliferation of resistant T-47D cell line (IC₅₀?=?0.6?±?0.1?µg/ml) compared to binary mixture of PTX and LPT (IC₅₀?=?6.7?±?1.2?µg/ml). Therefore, it is concluded that the developed formulation might increase the therapeutic efficacy in drug resistant metastatic breast cancer.     

Cholesterol-conjugated poly(D,L-lactide)-based micelles as a nanocarrier system for effective delivery of curcumin in cancer therapy

Polymeric micelles have been widely explored preclinically as suitable delivery systems for poorly soluble chemotherapeutic drugs in cancer therapy. The present study reported the development of cholesterol (Ch)-conjugated poly(D,L-Lactide) (PLA)-based polymeric micelles (mPEG–PLA-Ch) for effective encapsulation and delivery of curcumin (CUR) at the tumor site. Cholesterol conjugation dramatically affected the particle size and improved drug loading (DL) and encapsulation efficiency (EE). mPEG–PLA-Ch-CUR showed bigger hydrodynamic diameter (104.6?±?2.1?nm, and 169.3?±?1.52?nm for mPEG–PLA and mPEG–PLA-Ch, respectively) due to increased size of the hydrophobic core. The newly developed polymer exhibited low critical micelles concentration (CMC) (25?μg/mL) which is close to lipid-based polymer, PEG-phosphatidyl ethanolamine (12.5?μg/mL) compared to mPEG–PLA (50?μg/mL). mPEG–PLA-Ch micelles exhibited relatively higher EE (93.74?±?1.6%) and DL (11.86?±?0.8%) compared to mPEG–PLA micelles (EE 91.89?±?1.2% and DL 11.06?±?0.8%). mPEG–PLA-Ch micelles were internalized by the cancer cells effectively and exhibited higher cytotoxicity compared to free CUR in both, murine melanoma (B16F10) and human breast cancer (MDA-MB-231) cells. mPEG–PLA-Ch exhibited satisfactory hemocompatibility indicating their potential for systemic application. Further, mPEG–PLA-Ch-CUR demonstrated higher rate of reduction of tumor volume in B16F10-xenografted tumor-bearing mice compared to free CUR. At the end of 22 days, the tumor reduced to 1.87-fold (627.72?±?0.9?mm³ versus 1174.68?±?1.64?mm³) compared to the treatment with free CUR. In conclusion, the experimental data in vitro and in vivo indicated that the newly developed CUR-mPEG–PLA-Ch micelles may have promising applications in solid tumors.     

Systemic delivery of alpha-asarone with Kolliphor HS 15 improves its safety and therapeutic effect on asthma

Abstract

The commercially available alpha-asarone injections (CA-ARE) were frequently found to cause severe anaphylactic reactions by the solubilizer contained in the formulation such as polysorbate 80 and propylene glycol. This study aimed to develop a new ARE injection using Kolliphor HS 15 as solubilizing agent (HS 15-ARE) by the dissolution method to resolve its poor solubility problem and reduce the anaphylaxis of CA-AREs caused by Polysorbate 80. The HS 15-ARE micelle showed a homogeneous round shape with the mean particle size of around 13.73?±?0.02?nm, polydisperse index (PDI) of 0.19?±?0.01 and solubilizing efficiency of 95.7%?±?2.4%. In vitro and in vivo studies showed that HS 15-ARE is a stable injection presenting the same pharmacokinetic profile with CA-ARE. Moreover, improved therapeutic effect was observed for HS 15-ARE in treating asthma compared to CA-ARE (p?<?0.05) with no anaphylactic reactions observed. These results demonstrate that the new formulation of ARE (HS 15-ARE) has a great potential for replacing CA-AREs injections.     

The characterisation,pharmacokinetic and tissue distribution studies of TPGS modified myricetrin mixed micelles in rats

This study was designed to investigate the bioavailability and targeting of myricetrin-loaded ternary micelles modified with and without TPGS. The particle diameters of myricetrin-loaded micelles and myricetrin-loaded-TPGS micelle were 30.93?±?1.34?nm and 26.42?±?0.89?nm, respectively, while their respective encapsulation efficiencies (m/m, %) were 83.3?±?1.08 and 93.8?±?1.18. The release rate of myricetrin in the micellar system clearly exceeded the free myricetrin in the three media (pH 6.8 phosphate buffer, pH 1.2 HCl solution and double distilled water). In vivo studies displayed that the bioavailability of myricetrin mixed micelles was remarkably improved than the free drug after oral administration. Moreover, the results of tissue distribution showed that myricetrin-loaded-TPGS micelles accumulated well in the liver tissue. Based on these results, it was speculated that myricetrin-loaded-TPGS micelles might act as a promising carrier for liver targeting with improved hepatic concentration of myricetrin compared with the myricetrin-loaded micelles.     

Cytotoxic enhancement of hexapeptide-conjugated micelles in EGFR high-expressed cancer cells

Objectives: The aim of this study was to develop the hexapeptide-conjugated active targeting micelles for delivery of doxorubicin (DOX) and paclitaxel (PTX) to EGFR high-expressed cancer cells.

Methods: A hexapeptide, which mimicked the EGFR, was applied as a targeting ligand. The active targeting micelles were prepared using the synthesized poly(D,L-lactide-co-glycolide)–PEG copolymer conjugated with the hexapeptide. The micelles were used for encapsulating DOX and/or PTX, and the cellular uptake, in vitro drug release and cellular viability of drug-loaded peptide-conjugated and peptide-free micelles were investigated.

Results: The particle size of drug-loaded peptide-conjugated and peptide-free micelles was < 150 nm with narrow size distribution. The uptake of peptide-conjugated micelles was more efficient in EGFR high-expressed MDA-MB-468 and SKOV3 cells than in EGFR low-expressed HepG2 cells. The in vitro release of DOX and PTX was faster in pH 4.0 (500 U lipase) than in pH 7.4 release medium. The cytotoxicity in terms of IC₅₀ of DOX/PTX-loaded peptide-conjugated micelles was 4.8-folds lower than that of peptide-free micelles and 18.2-folds lower than DOX/PTX drug solution in SOKV3 cells.

Conclusion: The peptide-conjugated micelles acted as a nanocarrier to increase intracellular accumulation of anticancer drugs in EGFR high-expressed SKOV3 cancer cells to enhance cell cytotoxicity.     

Collagen loaded nano-sized surfactant based dispersion for topical application: formulation development,characterization and safety study

Abstract

Collagen, a high molecular weight, hydrophilic and highly abundant protein is known to have anti-ageing, anti-wrinkle, anti-acne, anti-scar and wound healing properties. High molecular weight and hydrophilic nature hinder its effective topical delivery. So, the objective of present study was to develop effective topical nano-surfactant dispersion (NSD) for collagen delivery. NSD was prepared from sorbitan monostearate (Span60) and cholesterol using ethanol injection method followed by probe sonication. NSD was characterized for entrapment efficiency (%EE), size and size distribution (Z-avg and polydispersity index (PDI)), shape, zeta-potential (ζ), in vitro drug release, skin hydration and skin irritation test and histopathological examination. Optimized NSD (NSD3) had %EE, z-avg, PDI and ζ-potential of 77.56%?±?1.09%, 158.1?±?2.31?nm, 0.211 and ?17.2?±?0.64?mV, respectively. In in vivo skin hydration test, NSD treatment showed nearly 2.5-fold and 3-fold increase in the thickness of stratum corneum (SC) as compared to the collagen gel treated and untreated skin, respectively. The mean scores of skin irritation test in two animal species, rats and rabbits, were found to be 1.42?±?1.01 and 1.71?±?0.29, respectively, indicating the non-irritant nature of collagen loaded NSD. Histopathology of the skin after application of developed NSD showed non-significant changes in skin anatomy indicating its safe nature.     

Fabrication of long-acting insulin formulation based on poly (3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) nanoparticles: preparation,optimization, characterization,and in vitro evaluation

The purpose of this research was the fabrication, statistical optimization, and in vitro characterization of insulin-loaded poly(hydroxybutyrate-co-hydroxyvalerate) (PHBV) nanoparticles (INS-PHBV-NPs). Nanopar-ticles were successfully developed by double emulsification solvent evaporation method. The NPs were characterized for particle size, entrapment efficiency (EE%), and polydispersity index (PDI). The NPs also were characterized by scanning electron microscopy (SEM), Fourier transformed infrared spectroscopy (FTIR), X-ray diffraction (XRD), differential scanning calorimetry (DSC), and circular dichroism (CD). The optimum conditions were found to be 1.6% polyvinyl alcohol (PVA), 0.9% of PHBV, and 15?mg/ml of insulin with the aid of the Box–Behnken experimental design results. The optimized NPs showed spherical shape with particle size of 250.21?±?11.37?nm, PDI of 0.12?±?0.01, and with EE% of 90.12?±?2.10%. In vitro drug release pattern followed Korsmeyer–Peppas model and exhibited an initial burst release of 19% with extended drug release of 63.2% from optimized NPs within 27?d. In conclusion, these results suggest that INS-PHBV-NPs could be a promising candidate for designing an injectable sustained release formulation for insulin.     

Genkwanin nanosuspensions: a novel and potential antitumor drug in breast carcinoma therapy

Recently, genkwanin (GKA) has been shown to display in vitro antitumor activity against some cancer cells, but its poor solubility restricted the in vivo study and further investigation of its antitumor therapeutic efficacy. In this paper, genkwanin nanosuspensions (GKA-NSps) were successfully prepared using D-alpha tocopherol acid polyethylene glycol succinate (TPGS) as a stabilizer using the precipitation-homogenization method. The obtained GKA-NSps had an average particle size of 183.1?±?4.4?nm, a PDI value of 0.16?±?0.07, a zeta potential of ?16.2?±?0.1?mV, and a drug loading content of 49.36?±?0.14%. GKA-NSps showed spherical morphology and very good stability in normal saline, phosphate buffer saline (PBS, pH 7.4), 5% glucose, artificial gastric juice, artificial intestinal juice and plasma; thus, it is suitable for both oral and intravenous administration. The resultant GKA-NSps displayed sustained drug release behavior and stronger in vitro cytotoxicity against 4T1, MCF-7, MDA-MB-453, HeLa, HepG2, BT474, and A549 cells than free GKA. The in vivo study in MCF-7 tumor-bearing nude mice indicated that GKA-NSps (60?mg/kg, i.v.) achieved similar therapeutic efficacy as PTX injection (8?mg/kg, i.v.) (62.09% vs. 61.27%), while the minimal lethal dose was more than 320?mg/kg, indicating good safety. By using nanotechnology, our study suggested that some antitumor flavonoids of low potency, such as GKA, are promising as safe but effective anticancer drugs.     

Transferrin-Modified Vitamin-E/Lipid Based Polymeric Micelles for Improved Tumor Targeting and Anticancer Effect of Curcumin

Purpose

Transferrin receptor (TfR) is up-regulated in various malignant tumors not only to meet the iron requirement, but also to increase the cell survival via participation in various cellular signaling pathways. Here we explored transferrin as ligand for Poly(ethylene Glycol) (PEG)-ylated vitamin-E/lipid (PE) core micelles (VPM).

Methods

Transferrin modified polymer was synthesized and drug loaded micelles were evaluated in 2D Hela and HepG2 cancer cells for cellular uptake and cytotoxicity and in 3D Hela spheroids for growth inhibition, uptake and penetration studies.

Results

Targeted (Tf-VPM) and non-targeted (VPM) micelles showed mean hydrodynamic diameter of 114.2?±?0.64 nm and 117.4?±?0.72 nm and zeta potential was ?22.8?±?0.62 and ?14.8?±?1.74 mV, respectively. Cellular uptake study indicated that the Tf-CVPM were taken up by cancer cells (Hela and HepG2) with higher efficiency. Enhanced cytotoxicity was demonstrated for Tf-VPM compared to CVPM. Marked spheroid growth inhibition following treatment with Tf-CVPM was observed compared to the treatment with non-targeted CVPM.

Conclusions

The developed transferrin-modified micelles have improved ability to solubilize the loaded drugs and could actively target solid tumors by its interaction with over-expressed transferrin receptors. Therefore, the nano-micelles could be further explored for its potential utilization in cancer therapy.

     

Improving the therapeutic efficiency of ginger extract for treatment of colon cancer using a suitably designed multiparticulate system

Abstract

Ginger extract (GE), a potential natural anticancer agent, has compromised therapeutic utilization due to poor bioavailability and physicochemical properties. Present study aimed at assigning GE with a pharmaceutical couture so as to improve its biopharmaceutical performance by monitoring its localized (though prolonged) delivery in the distal parts of gastrointestinal tract for the treatment of colon cancer. Alginate beads entrapping 85.9?±?1.78% GE were subjected to Eudragit S100 coating. Latter is insoluble at acidic and near neutral (6.8) pH of stomach and upper part of small intestine and it led to 50% retardation (upto 12?h) in release of GE. However, it was solubilised at pH?>?7.0 resulting in colon targeted system. Developed beads were free flowing, showed a particle size of 0.9?±?0.006?mm and super class-II release controlled by swelling and polymer relaxation. Preclinical evaluation using 1,2-dimethylhydrazine-induced colon cancer, in male Wistar rats, in terms of histopathology, oxidative stress, mitochondrial complex activity, β-glucuronidase and ammonia concentration determinations indicated GE loaded beads (50?mg/kg) to be significantly better (p?<?0.05) than free GE. Highlight of the study was that GE loaded coated alginate beads were administered after the induction of colon cancer and significant recession of the cancers was observed after 4 weeks of treatment.     

Comparison of hyaluronic acid-based micelles and polyethylene glycol-based micelles on reversal of multidrug resistance and enhanced anticancer efficacy in vitro and in vivo

Polyethylene glycol (PEG)-based block copolymer micelles and hyaluronic acid (HA)-based grafted copolymer micelles have been widely investigated in chemotherapy. In this study, to evaluate the differences among HA-based grafted polymer micelles, PEG-based block polymer micelles and the mixed of these two micelles in enhancing antitumor effects and overcoming MDR, two amphiphilic vitamin E succinate (VES) derivatives, HA VES (HA-g-VES) and PEG 2000 VES (TPGS2k), were applied as nanocarriers to prepare HA-VES micelles (HA-PMs), TPGS2k micelles (TPGS2k-PMs) and the mixed micelles (HA/TPGS2k-PMs) for the co-delivery of doxorubicin (DOX) and curcumin (Cur). With the addition of TPGS2k, the particle size of HA/TPGS2k-PMs (153.37?±?1.00?nm) was smaller than that of HA-PMs (223.83?±?1.84) but significantly larger than that of TPGS2k-PMs (about 20?nm). The loading efficiency of HA/TPGS2k-PMs was 7.10%, which was lower than HA-PMs (8.31?±?0.15%) but higher than TPGS2k-PMs (4.38?±?0.24%). In vitro, HA/TPGS2k-PMs and TPGS2k-PMs exhibited higher cytotoxicity and reversal MDR effects than HA-PMs in MCF-7/Adr cells. However, HA/TPGS2k-PMs, HA-PMs and TPGS2k-PMs all significantly improved the tumor biodistribution, the antitumor effects and reduced the side effects of DOX in 4T1-tumor-bearing mice, but these three micelles displayed no differences in vivo. Therefore, EPR passive targeting effects caused by PEGylated micelles and CD44 active targeting effects caused by HA-based micelles have no significant variance in the delivery of antitumor drugs by i.v.     

Encapsulation of Sesbania grandiflora extract in polymeric micelles to enhance its solubility,stability, and antibacterial activity

Clinical applications of Sesbania grandiflora bark extract (SGE) are limited because of its poor water solubility and stability. SGE was loaded in micelles of Pluronics. In vitro and in vivo antibacterial and toxicity tests were investigated using broth dilution and silkworm model. Aqueous solubility of SGE was improved by these micelles. Activity and toxicity of SGE loaded micelles were dependent on type and concentration of Pluronics. The micelles composed of 1:3 SGE to Pluronic F68 (SGE-PF68-13) showed small size (24.95?±?0.34?nm), narrow PdI (<0.2), high entrapment efficiency (99.63?±?0.19%) and negative zeta potential (?41.53?±?0.15?mV). Stability of SGE in SGE-PF68-13 was 10 times higher than the unentrapped SGE. SGE-PF68-13 showed a dose dependent activity and significantly higher therapeutic effect than the unentrapped SGE. It is concluded that encapsulation of SGE in Pluronic micelles can enhance SGE solubility, stability, and antibacterial activity. SGE-PF68-13 is suitable for further study in mammalian animals.     

Role of GABAB receptors and p38MAPK/NF-κB pathway in paclitaxel-induced apoptosis of hippocampal neurons

Context: The effects of the anticancer drug paclitaxel on learning and memory are rarely studied.

Objective: This study investigated changes in GABA_B receptor expression during paclitaxel-induced apoptosis of hippocampal neurons and the role of the p38MAPK/NF-κB pathway in this process.

Materials and methods: Hippocampal neurons isolated from neonatal Sprague–Dawley rats were divided into six groups: Control (C), SB (10?µL of 10-µmol/L SB203580), SN (53?µg/mL SN50), N (1?µmol/L paclitaxel), SB?+?N (10?µmol/L SB203580?+?1?µmol/L paclitaxel) and SN?+?N (53?µg/mL SN50?+?1?µmol/L paclitaxel). Cells in different groups were treated with corresponding agents for 24?h at 37?°C. The apoptosis rate and protein levels of GABA_B1 receptors and NF-κB p65 were evaluated. Rat models of neuropathic pain was induced by paclitaxel and were divided into four groups such as N, B?+?N, SN?+?N and SN?+?B?+?N groups. Rats in the N group received intrathecal injections of normal saline solution. Rats in the B?+?N group received intrathecal injections of 10?μL baclofen (0.05?μg/μL). Rats in the SN?+?N and SN?+?B?+?N groups received intrathecal injections of SN50 and SN50 plus baclofen, respectively. Spatial learning and memory were evaluated in rat models based on the escape latency and the number of crossings over the platform and protein levels of GABA_B1 receptors, NF-κB, IL-1β and TNFα were measured by immunohistochemistry assay and western blot.

Results: The neuronal apoptosis rate was significantly increased in N (49.16?±?3.12)%, SB?+?N (31.18?±?3.02)% and SN?+?N (28.47?±?3.75)% groups, accompanied by increased levels of GABA_B1 receptors and NF-κB p65 (p?p?B1:9.0?±?1.6, NF-κB p65:29.6?±?2.4, IL-1β: 30.4?±?3.4, TNFα: 31.0?±?3.4), B?+?N, SN?+?N and SN?+?B?+?N groups evidently increased levels of GABA_B1 receptor (B?+?N:SN?+?N:SN?+?B?+?N?=?19.4?±?2.1:20.8?±?1.9:28.0?±?1.9) but significantly decreased levels of NF-κB p65 (B?+?N:SN?+?N:SN?+?B?+?N?=?21.2?±?1.5:18.6?±?2.1:12.6?±?1.5), IL-1β (B?+?N:SN?+?N:SN?+?B?+?N?=?22.0?±?1.0:19.6?±?1.8:14.6?±?1.5) and TNF α (B?+?N:SN?+?N:SN?+?B?+?N?=?23.0?±?1.6:22.2?±?0.8:16.6?±?1.7). Similar findings were found in western blot analysis.

Discussions and conclusions: Paclitaxel may reduce cognitive function in rats through the p38MAPK/NF-κB pathway and GABA_B1 receptors.     

Preparation and pharmacokinetics evaluation of oral self-emulsifying system for poorly water-soluble drug Lornoxicam

Abstract

The present work was performed aiming to develop a new solid self-emulsifying system (SMEDDS) for poorly water-soluble drug Lornoxicam and evaluate the bioavailability in Wister rats by oral gavage. Liquid SMEDDS of Lornoxicam was formulated with Labrafil M 1944 CS as oil phase, Kolliphor HS 15 as a surfactant and Transcutol HP as a cosurfactant after screening various vehicles. The microemulsion system selected from the phase diagram and optimized by central composite design (CCD) response surface method was transformed into solid-SMEDDS (S-SMEDDS) by lyophilization using sucrose as cryoprotectant. The formulations were further characterized by the particle size, poly dispersity index (PDI), self-emulsifying time, zeta potential, transmission electron microscope (TEM), differential scanning calorimeter (DSC), in vitro drug release and in vivo pharmacokinetics. Results of DSC studies confirmed that the drug was incorporated in the S-SMEDDS. The in vitro drug release from Lornoxicam SMEDDS was found to be greatly higher in comparison with that from the commercial tablets. It was indicated that SMEDDS might be effective in reducing the effect of pH variability of Lornoxicam and improving the release performance of Lornoxicam. HPLC system was applied to study the concentration of Lornoxicam in the plasma of the Wister rats after oral administration of Lornoxicam SMEDDS and Lornoxicam commercial tablets. The pharmacokinetics parameters of the rats were C_max 1065.91?±?224.90 and 1855.22?±?748.25?ngmL^?1, T_max were 2.5?±?0.4?h and 1.8?±?0.5?h, and AUC_0～t were 5316.35?±?323.62 and 7758.07?±?241.57?ngmL^?1?h, respectively. Calculated by AUC_0～∞, the relative bioavailability of Lornoxicam S-SMEDDS was 151.69?±?15.32%. It suggested that this S-SMEDDS could be used as a successful oral solid dosage form to improve the solubility and bioavailability of poorly water-soluble drug Lornoxicam as well.     

Polymeric micelle nanocarriers for targeted epidermal delivery of the hedgehog pathway inhibitor vismodegib: formulation development and cutaneous biodistribution in human skin

Background: The aim was to investigate cutaneous delivery and biodistribution of the hedgehog pathway inhibitor, vismodegib (VSD), indicated for basal cell carcinoma (BCC), from polymeric micelle formulations under infinite/finite dose conditions.

Methods: VSD-loaded micelles were characterized for drug content, particle size, and shape; a micelle gel was characterized for its rheological behavior. Cutaneous deposition and biodistribution of VSD were determined using porcine and human skin in vitro with quantification by UHPLC-MS/MS.

Results: The optimal micelle solution (Z_av 20–30 nm) increased the aqueous solubility of VSD by >8000-fold; drug content was stable after 4 weeks at 4°C. Application of micelle solution and micelle gel (0.086% w/v) to human skin for 12 h under infinite dose conditions resulted in statistically equivalent VSD deposition (0.62 ± 0.11 and 0.67 ± 0.14 μg/cm², respectively). Cutaneous biodistribution in human skin under infinite (micelle solution and gel) and finite (micelle gel) dose conditions showed that the VSD concentrations obtained in the basal epidermis, at depths of 120–200 μm, were ?3800- and ?2300-fold greater than the IC₅₀ reported for hedgehog signaling pathway inhibition in vitro.

Conclusion: Cutaneous delivery of VSD from micelle-based formulations might enable targeted, topical treatment of superficial BCC with minimal risk of systemic exposure.     

Lipid Based nanoformulation of lycopene improves oral delivery: formulation optimization,ex vivo assessment and its efficacy against breast cancer

This study aims at developing an optimised nanostructured lipid carrier (NLC) of lycopene for efficient absorption following oral administration. The optimised formulation showed an average particle size of 121.9?±?3.66?nm, polydispersity index (PDI) 0.370?±?0.97 and zeta potential ?29.0?±?0.83?mV. Encapsulation Efficiency (% EE) and drug loading (% DL) was found to be 84.50%?±?4.38 and 9.54%?±?2.65, respectively. In vitro release studies demonstrated the burst release within 4–9?h followed by sustained release over 48?h. The IC₅₀ value of lycopene extract and optimised NLC for ABTS^+? were found to be 172.37?μg Trolox equivalent and 184.17?μg Trolox equivalent whereas, for DPPH^?, 117.76?μg Trolox equivalent and 143.08?μg Trolox equivalent respectively. Ex vivo studies and MTT assay revealed that the NLC had better permeation and cause sufficiently more cytotoxicity as compared to drug extract due to higher bioavailability and greater penetration.     

Fatty Acid–RGD Peptide Amphiphile Micelles as Potential Paclitaxel Delivery Carriers to αvβ3Integrin Overexpressing Tumors

Purpose

To design and synthesize fatty acid-RGD peptide amphiphiles with ADA linker for their potential delivery of hydrophobic drugs like paclitaxel targeted to α_vβ₃ integrin overexpressing tumors.

Methods

Four amphiphiles - C16 or C18 fatty acid–RGD peptide and ADA linker were designed and synthesized. CMC, size and zeta potential of the amphiphiles were determined. FITC loaded micelles uptake into A2058 melanoma cells was investigated at 4°C and 37°C using confocal microscopy. Paclitaxel was loaded into micelles, their encapsulation efficiency and cytotoxicity of micelles was evaluated. The stability of the micelles was determined using FRET method.

Results

Mass, ¹H NMR and HPLC analysis confirmed the formation of amphiphiles and their purity. Among the amphiphiles, C18-(ADA)₂-RGD amphiphile exhibited lowest CMC (9.00?±?1.73?μM) and its micelles had suitable size (194.63?±?44.86?nm) and zeta potential (0.27?±?1.96?mV) for targeting. The cellular uptake of the micelles was temperature dependent and the micelles were stable. The IC50 of paclitaxel loaded in micelles decreased 50% in α_vβ₃ integrin overexpressing cells and showed a 4 fold increase in normal cells when compared to free paclitaxel.

Conclusion

Amphiphiles of fatty acids–ADA-RGD were synthesized. These amphiphiles formed stable micelles and were effective as targeted delivery carriers to α_vβ₃ integrin overexpressing tumors.