Monoterpenes-containing PEGylated transfersomes for enhancing joint cavity drug delivery evidenced by CLSM and double-sited microdialysis.

The synovial tissues are natural sites of drug delivery for the treatment of rheumatoid arthritis. Our previous study showed that mixed monoterpenes edge-activated PEGylated transfersomes (MMPTs) could significantly enhance the percutaneous absorption of sinomenine (SIN), an anti-inflammation drug. The aim of this study was to investigate the potential of MMPTs for delivery of SIN to the synovial tissues in joint cavities. To this end, conventional liposomes (LPSs) were used as a reference. Transmission electron microscope, constant pressure extrusion method, and differential scanning calorimetry (DSC) were used for physicochemical characterization of the formulations. Confocal laser scanning microscopy (CLSM) and double-sited microdialysis coupled with LC-MS/MS were exploited to study the distribution of MMPTs in different skin layers and pharmacokinetics of SIN in the blood and the joint cavities. The results showed that mixed monoterpenes could significantly enhance the elasticity of MMPTs, evidenced by a decrease in the main transition temperature (Tm) and transition enthalpy (△H). CLSM analyses demonstrated that MMPTs were distributed in deep layers of the skin, indicating that MMPTs might transport SIN through the skin. In contrast, LPSs were confined in the stratum corneum, which deterred SIN from penetrating through the skin. The results from double-sited microdialysis pharmacokinetics showed that in the joint cavities the steady state concentration (Css) and AUC0→t of SIN from MMPTs were 2.1-fold and 2.5-fold of those from LPSs, respectively. In contrast, in the blood the Css and AUC0→t of SIN from MMPTs were about 1/3 of those from LPSs. This study suggested that MMPTs could enhance the delivery of SIN to the joint cavities. A combination of CLSM and double-sited microdialysis could give an insight into the mechanism of transdermal and local drug delivery.

Flexible two-layer dissolving and safing microneedle transdermal of neurotoxin: A biocomfortable attempt to treat Rheumatoid Arthritis.

This study is directed towards the gentle transdermal delivery of Neurotoxin (NT) and study of the treatment of Rheumatoid Arthritis (RA) in rats by NT loaded dissolving Microneedles (DMNs-NT). The DMNs-NT fabrication involved a two-step centrifugation method. The quadrangular pyramid shape needles had great mechanical strength. The upper part of the needle contained 15.4 ±â€¯0.5 µg of drug per patch. Blank DMNs showed favorable biocompatibility and low toxicity on the chondrocyte cells. Both NT and DMNs-NT displayed anti-inflammatory capabilities ex-vitro. The results of ex-vitro evaluation of DMNs the skin penetration depth of DMNs-NT rats was higher than 70 µm and the cumulative penetration of NT in DMNs could reach 95.8% in 4 h, whereas, the NT solution could barely penetrate the skin, thereby proving the favorable facilitation of NT transdermal delivery. The needle structure dissolved completely after 10 min in vivo and the channel on the Stratum Corneum (SC) was closed after 6 h. There was no significant adverse reaction on the skin after 15 days of administration. The pharmacodynamic study showed that DMNs-NT significantly reduced the toe swelling of RA rats and reduced the levels of TNF-α and IL-1ß in serum to alleviate the injury of the ankle joints. DMNs-NT held favorable stability in 3 months. All these results established that DMNs-NT could penetrate the skin of rats in a biocompatible manner, and have a strong therapeutic effect on rat RA by transdermal delivery.

A single-label fluorescent derivatization method for quantitative determination of neurotoxin in vivo by capillary electrophoresis coupled with laser-induced fluorescence detection.

Neurotoxin (NT), a short-chain α-neurotoxin, is the main neurotoxic protein identified from the venom of Naja naja atra. As an effective drug for the analgesis of advanced cancer patients, NT lasts longer than morphine and does not cause addiction. However, achieving a sensitive and high-resolution measurement of NT is difficult because of the extra-low content of NT in vivo. Therefore, developing a novel method to quantify NT is essential to study its pharmacokinetics in vivo. Although NT contains four primary amine groups that could react with the thiourea in fluorescein isothiocyanate (FITC), we developed a simple and reproducible single-label fluorescent derivatization method for NT which is related to the reaction of N-terminal α-amino of NT alone under optimized derivatization conditions. Furthermore, neurotoxin labelled with fluorescein isothiocyanate (NT-FITC) was prepared by high-performance liquid chromatography (HPLC) with a purity value higher than 99.29% and identified by MALDI-TOF/TOF-MS. Finally, NT-FITC could be detected at 0.8 nmol L(-1) in rat plasma using capillary electrophoresis coupled with laser induced fluorescence detection (CE-LIF). In this paper, the established method robustly and reliably quantified NT labelled with FITC via intravenous and intramuscular administrations in vivo. In addition, this work fully demonstrated the pharmacokinetic characteristics of NT in vivo, which could reduce the risk of drug accumulation, optimize therapies, and provide sufficient evidence for the rational use of NT in clinical and research laboratories.

A novel doxorubicin loaded folic acid conjugated PAMAM modified with borneol, a nature dual-functional product of reducing PAMAM toxicity and boosting BBB penetration.

Effective targeting drug delivery system for glioma treatment is still greatly challenged by the existence of the blood-brain barrier (BBB) and the intracranial overspreading of anti-tumor drug. Herein, we presented a dual-functional glioma targeting delivery of doxorubicin based on the PAMAM G5 dendrimer, modified with folic acid (FA) to target tumor cell, also borneol (BO), a well known safe material derived from traditional Chinese medicine, to facilitate the BBB permeability and reduce the toxicity of naked PAMAM. The intracranial transportation and glioma targeting ability were evaluated on the BBB model and C6 glioma cells in vitro. Also, pharmacokinetics and biodistribution were studied on C6 glioma-bearing rats in vivo. It indeed reduced the cytotoxicity of PAMAM against both HBMEC and C6 cells by coupling BO on the surface, while efficiently boosted BBB permeability with the improvement of transportation ratio by 2 folds to the BO-unmodified conjugates. Furthermore, conjugated FA increased total uptake amount by C6 cells leading to strong inhibition with the 3-fold lower IC50 value than FA-unmodified DOX conjugate. In comparison with DOX solution, FA-BO-PAMAM/DOX exhibited significantly prolonged half-life time and increased area under the curve and improved DOX accumulation in brain tumor. The tumor growth inhibition, in vivo, was significantly increased up to 57.4%. The median survival time of xenograft rats after administering FA-BO-PAMAM/DOX (28days) was significantly prolonged compared to free DOX (18days, P<0.05) or other controls. In conclusion, this strategy of novel targeting nanocarrier provides a promising method to increase the drug accumulation in the tumor site for therapy of glioma.