Enhanced Oral Delivery of Curcumin via Vitamin E TPGS Modified Nanodiamonds: a Comparative Study on the Efficacy of Non-covalent and Covalent Conjugated Strategies.

Despite that either non-covalent or covalent attachment of hydrophilic polymers or surfactants onto nanodiamonds (NDs) could overcome the shortcomings of being a drug delivery system, it is hard to draw a definite conclusion which strategy is more effective. Hence, with the purpose of comparing the influence of different coating approach of NDs on the oral delivery efficiency of water-insoluble model drug curcumin (CUR), NDs were firstly modified with D-α-tocopheryl polyethylene glycol 1000 succinate (TPGS) via non-covalent or covalent conjugation method, and then loaded with CUR (CUR@NDs-COOH/TPGS or CUR@NDs-TPGS). In comparison with the core-shell-structured CUR@NDs-COOH/TPGS, CUR@NDs-TPGS were irregular in shape with dense TPGS film, and exhibited smaller size, more negatively potential, and higher drug loading efficiency. The covalent connection group also showed higher anti-cancer activity, cellular uptake, and permeability through the Caco-2 cell monolayers, as well as favorable distribution, penetration, and retention in rat intestines. The oral bioavailability study in rats demonstrated that CUR@NDs-TPGS showed significantly greater Cmax and AUC0-t in contrast with CUR suspension and the TPGS-coated ones, respectively. The findings illustrated that covalent grafting TPGS onto the surface of NDs possesses better efficacy and biocompatibility on oral delivery of poorly soluble drug CUR than pristine and non-covalent coated nanoparticles.

Investigations on the interactions between curcumin loaded vitamin E TPGS coated nanodiamond and Caco-2 cell monolayer.

This study aimed at investigating the potential mechanism of improved transportation of the curcumin loaded D-α-tocopherol polyethylene glycol 1000 succinate coated nanodiamonds system (NDs/CUR/TPGS complexes) using an in vitro Caco-2 cell monolayer model. The core-shell structured NDs/CUR/TPGS nanocomplexes were 196.32 ±â€¯5.76 nm in size, with a high loading efficiency of 81.59 ±â€¯3.42%. Cytotoxicity results suggested that the blank NDs did not induce any serious toxicity on Caco-2 cells even after incubated for 72 h. The cell viability for all the series of CUR loaded preparations was found to follow the sequence of CUR suspension > NDs/CUR > NDs/CUR/TPGS. Confocal laser fluorescence microscopy (CLSM) and flow cytometry system (FACS) studies confirmed that the cellular uptake of NDs could be efficiently enhanced by TPGS decoration. The transport mechanism of NDs/CUR and TPGS coated ones was mainly through an energy dependent, clathrin-mediated and caveolin-mediated endocytosis, and the endocytosis of NDs/CUR was also via macropinocytosis. Furthermore, the Papp value (AP-BL) of NDs/CUR and NDs/CUR/TPGS was 2.09- and 3.86-fold higher than that of the CUR suspension. All the results demonstrated that the pharmacological activates and intestinal permeability of CUR across Caco-2 cell monolayer was greatly enhanced by NDs/CUR/TPGS nanocomplexes. Thus NDs could be a promising oral drug delivery platform for improving the intestinal permeability and oral bioavailability of poorly soluble drugs.

Functionalization of nanodiamond with vitamin E TPGS to facilitate oral absorption of curcumin.

The purpose of this work was to develop a d-α-tocopherol polyethylene glycol 1000 succinate (TPGS) decorated nanodiamond (ND) system loading water-insoluble curcumin (ND/CUR/TPGS) to improve the colloidal dispersity and oral bioavailability of the preparation. CUR was physically loaded into ND clusters, then TPGS was coated to the ND/CUR complex forming amorphous nanostructure on the interparticle nanocage of the ND substrate. The formulation of the nanocomplexes was optimized using response surface methodology, and the optimal ND/CUR/TPGS showed small particle size (196.32 nm), high drug loading efficiency (81.59%) and core-shell structure. In vitro release study demonstrated that the nanocomplexes provided a sustained release behavior. The absorptive concentration of ND/CUR/TPGS was dramatically improved in total intestinal tract compared with CUR suspension, and the absorption was controlled by multiple transcytosis mechanisms. Furthermore, the pharmacokinetic studies demonstrated that ND/CUR/TPGS had significantly higher Cmax (4.50-fold), larger AUC0-t (10.67-fold), and longer MRT0-t (3.07-fold) in contrast with that of CUR suspension. Therefore, ND/CUR/TPGS presented great potential for oral delivery of insoluble and poorly permeable drugs.

Two kinds of ketoprofen enteric gel beads (CA and CS-SA) using biopolymer alginate.

To obtain expected rapid-release and sustained-release of ketoprofen gel beads, this paper adopted biopolymer alginate to prepare alginate beads and chitosan-alginate gel beads. Formulation factors were investigated and optimized by the single factor test. The release of ketoprofen from calcium alginate gel beads in pH 1.0 hydrochloric acid solution was less than 10% during 2 h, then in pH6.8 was about 95% during 45 min, which met the requirements of rapid-release preparations. However, the drug release of chitosan-alginate gel beads in pH1.0 was less than 5% during 2 h, then in pH6.8 was about 50% during 6 h and reached more than 95% during 12 h, which had a good sustained-release behavior. In addition, the release kinetics of keteprofen from the calcium alginate gel beads fitted well with the Korsmeyer-Peppas model and followed a case-II transport mechanism. However, the release of keteprofen from the chitosan-alginate gel beads exhibited a non-Fickian mechanism and based on the mixed mechanisms of diffusion and polymer relaxation from chitosan-alginate beads. In a word, alginate gel beads of ketoprofen were instant analgesic, while chitosan-alginate gel beads could control the release of ketoprofen during gastro-intestinal tract and prolong the drug's action time.

Transport mechanism of chitosan-N-acetylcysteine, chitosan oligosaccharides or carboxymethyl chitosan decorated coumarin-6 loaded nanostructured lipid carriers across the rabbit ocular.

To facilitate the hydrophobic drugs modeled by coumarin-6 (Cou-6) acrossing the cornea to the anterior chamber of the rabbit eye, chitosan (CS) derivatives including chitosan-N-acetyl-l-cysteine (CS-NAC), chitosan oligosaccharides (COS) and carboxymethyl chitosan (CMCS) modified nanostructured lipid carriers (NLCs) were designed and characterized. We found that, with similar size distribution and positivecharges, different CS derivatives based on NLCs led to distinctive delivery performance. In vivo precorneal retention study on rabbits revealed that these CS derivatives coating exhibited a stronger resistant effect than Cou-6 eye drops and Cou-6-NLC (P<0.05), moreover, the AUC(0-∞), Cmax and MRT(0-∞) of them followed the sequence of CMCS-Cou-6-NLC

Ex Vivo and in Vivo Evaluation of the Effect of Coating a Coumarin-6-Labeled Nanostructured Lipid Carrier with Chitosan-N-acetylcysteine on Rabbit Ocular Distribution.

This study is focused on further understanding the characteristics of chitosan-N-acetylcysteine surface-modified nanostructured lipid carriers (CS-NAC-NLCs) in their interaction with ocular mucosa. Coumarin-6 (C6)-labeled NLCs, including uncoated NLCs, chitosan hydrochloride (CH)-, and CS-NAC-coated NLCs, were developed using a melt-emulsification technique and subsequently decorated with different types or portions of chitosan derivatives. Mucoadhesion was evaluated ex vivo using a flow-through process with fluorescence detection. The results demonstrated that the presence of CS-NAC on the C6-NLC surface provided the most obvious enhancement in adhesion due to the formation of both noncovalent (ionic) and covalent (disulfide bridges) interactions with mucus chains. Meanwhile, the concentration of CS-NAC in the formulation positively influenced the viscosity of the nanoparticles and hence prolonged their retention in the ocular tissue. Transcorneal penetration studies revealed that CS-NAC-NLC particles were able to penetrate through the entire corneal epithelium primarily via a transcellular route. The transport depth and velocity strongly relied on the modification material and the particle size. Ex vivo fluorescence imaging and in vivo ocular distribution investigations showed that C6 was broadly distributed in rabbit eye tissues and absorbed by aqueous humor after CS-NAC-NLC instillation. In relation to C6 eye drops, CS-NAC-NLCs achieved considerably higher Cmax (4.01-fold), MRT0-∞ (1.87-fold), and AUC0-∞ (16.29-fold) in the aqueous humor. Moreover, the increase in drug absorption was greater in the cornea than in the conjunctiva. Thereby, it is possible to draw a conclusion that CS-NAC-NLCs presented great potential for drug application to the front portion of the eye.

A pH-independent instantaneous release of flurbiprofen: a study of the preparation of complexes, their characterization and in vitro/in vivo evaluation.

In this study, furbiprofen/hydroxypropyl-ß-cyclodextrin (HPßCD) inclusion complexes were prepared to improve the drug dissolution and facilitate its application in hydrophilic gels. Inclusion complexes were prepared using a supercritical fluid processing and a conventional optimized co-lypholization method was employed as a reference. The entrapment efficacy and drug loading of both methods were investigated. Evaluation of drug dissolution enhancement was conducted in deionized water as well as buffer solutions of different pH. Carbopol 940 gels of both flurbiprofen and flurbiprofen/HPßCD inclusion complexes, with or without penetration enhancers, were prepared and percutaneous permeation studies were performed using rat abdominal skin samples. Formation of flurbiprofen/HPßCD inclusion complexes was confirmed by Fourier transform-infrared spectroscopy, differential scanning calorimetry, X-ray diffraction and scanning electron microscopy. The results obtained showed that SCF processing produced a higher EE (81.91 ± 1.54%) and DL (6.96 ± 0.17%) compared with OCL with values of 69.11 ± 2.23% and 4.00 ± 1.01%, respectively. A marked instantaneous release of flurbiprofen/HPßCD inclusion complexes prepared by SCF processing (103.04 ± 2.66% cumulative release within 5 min, a 10-fold increase in comparison with flurbiprofen alone) was observed. In addition, this improvement in dissolution was shown to be pH-independent (the percentage cumulative release at pH 1.2, 4.5, 6.8 and 7.4 at 5 min was 95.19 ± 1.71, 101.75 ± 1.44, 105.37 ± 4.58 and 96.84 ± 0.56, respectively). Percutaneous permeability of flurbiprofen-in-HPßCD-in-gels could be significantly accelerated by turpentine oil and was related to the water content in the system. An in vivo pharmacokinetic study showed a 2-fold increase in Cmax and a shortened Tmax as well as a comparable relative bioavailability when compared with the commercial flurbiprofen Cataplasms (Zepolas®). With their superior dissolution, these flurbiprofen/HPßCD inclusion complexes prepared by SCF processing could provide improved applications for flurbiprofen.

Original research paper. A superior preparation method for daidzein-hydroxypropyl-ß-cyclodextrin complexes with improved solubility and dissolution: Supercritical fluid process.

Advantages of the supercritical fluid (SCF) process compared to the conventional solution stirring method (CSSM) in the preparation of daidzein-hydroxypropyl-ß-cyclodextrin (HPßCD) complexes were investigated. Formation of daidzein/ HPßCD inclusion complexes was confirmed by Fourier transformed-infrared spectroscopy (FTIR), differential scanning calorimetry (DSC), X-ray diffraction (XRD) and scanning electron microscopy (SEM). Particle size, inclusion yield, drug solubility and dissolution of daidzein/HPßCD complexes were evaluated. Compared to CSSM, the SCF process resulted in higher inclusion yield and higher solubility. Also, extended dissolution of daidzein from the SCF processed HPßCD inclusion complexes was observed, with only 22.94 % released in 45 min, compared to its rapid release from those prepared by CSSM, with 98.25 % drug release in 15 min. This extended release of daidzein from SCF prepared inclusion complexes was necessary to avoid drug precipitation and improve drug solubilisation in the gastrointestinal tract. The results showed that the SCF process is a superior preparation method for daidzein-hydroxypropyl-ß-cyclodextrin complexes.

A novel application of electrospinning technique in sublingual membrane: characterization, permeation and in vivo study.

Isosorbide dinitrate-polyvinylpyrrolidone (ISDN-PVP) electrospinning fibers were formulated and explored as potentially sublingual membrane. The addition of polyethylene glycol (PEG) to the formulation improved flexibility and reduced fluffiness of the fiber mat. The scanning electron microscopy (SEM) demonstrated that the fibers tended to be cross-linking, and the crosslinking degree increased with the increase of PEG amount. The differential scanning calorimetry (DSC) indicated that ISDN existed in non-crystalline state in the fibers (except at the highest drug content). The infrared spectroscopy suggested that ISDN had better compatibility with the ingredients owing to the hydrogen bonding (or hydrophobic interactions). The fibers were highly favorable for the fabrication of sublingual membrane due to neutral pH, large folding endurance and rapid drug release (complete dissolution within 120 s). The permeation study of ISDN through both dialysis membrane (DM) and porcine sublingual mucosa (SM) were carried out. A significant relationship of drug permeation rate through DM and SM was built up, which indicated that DM could be used to partly simulate SM and assess formulation. The pharmacokinetic study in rats demonstrated that the electrospinning fiber membrane had a higher Cmax and lower Tmax compared to the reference preparation, and the relative bioavailability of the fiber membrane was 151.6%.