Thiolated pectins: In vitro and ex vivo evaluation of three generations of thiomers.

In recent decades, three generations of thiomers have been developed with the main purpose of obtaining enhanced interactions with mucosal tissues. Therefore, many different types of thiolated ligands have been generated and attached to polymeric backbones. The aim of this study was to synthesize all three generations of thiomers and to directly compare their properties regarding mucus penetration and mucoadhesion. Starting from pectin, the unprotected thiomer pectin-cysteine (Pec-Cys), the preactivated S-protected thiomer pectin-cysteine-mercaptonicotinic acid (Pec-Cys-MNA) and the less reactive S-protected thiomer pectin-cysteine-glutathione (Pec-Cys-GSH) were synthesized and characterised by FT-IR, NMR, and colorimetric studies. The polymers were evaluated regarding their cytotoxicity, swelling behaviour, viscosity after mixing with mucus, mucus diffusion, penetration into mucosa, and mucoadhesion. The amount of the three ligands (Cys, Cys-MNA and Cys-GSH) bound to the polymer was determined to be in the range of 193-196 µmol/g. All polymers showed no cytotoxicity. Viscosity of the mixture of Pec-Cys-MNA and Pec-Cys-GSH with mucus increased 21.5- and 26.7-fold, respectively, compared to the unmodified polymer within 3 hours. Swelling, mucoadhesion, interpenetration and mucus diffusion were increased in the following rank order: Pec-Cys < Pec-Cys-MNA < Pec-Cys-GSH. Results of mucoadhesion study indicated a 7.4 and 8.1-fold increase of Pec-Cys-MNA and Pec-Cys-GSH, respectively, compared to the unmodified polymer. As the less reactive S-protected thiomer exhibited higher mucoadhesive properties than the other thiomers, this study provides evidence for the superior mucoadhesion of 3rd generation thiomers. STATEMENT OF SIGNIFICANCE: Three generations of thiolated polymers have been developed bearing different types of thiol ligands with the main purpose of enhancing mucus interactions. In this study, all generations were synthesized on the polymeric backbone of pectin for the first time to directly compare their mucus penetrating and mucoadhesive properties. 1st generation exhibited covalently bound L-cysteine moieties. For 2nd generation, thiols of cysteines were S-protected with 2-mercaptonicotinic acid (MNA), resulting in high reactive disulfide bonds. 3rd generation was synthesized by a thiol/disulfide exchange of glutathione with MNA, producing a less reactive disulfide bond. Mucus penetrating and mucoadhesive properties were found to be increased as follows: 1st generation < 2nd generation < 3rd generation. According to these results, the thiomer of 3rd generation represents a promising excipient with strong mucoadhesion.

Strategies for improved hair binding: Keratin fractions and the impact of cationic substructures.

Keratin extracts and hydrolysates from varying sources, their chemical modifications and compositions thereof have shown potential in the restoration of hair properties. Within this study on reactivity of thiol groups and the shielding effect of anionic charges the binding of keratin-associated proteins (KAP) and α-keratins (Ker) extracted from human hair to natural and permed hair fibers was evaluated. Selectively extracted KAP and Ker were preactivated with 6-mercaptonicotinamide in a quantity of 194 ± 21 µmol/g for KAP and 169 ± 27 µmol/g for Ker resulting in 1.9- and 1.4-fold enhanced binding to natural hair, respectively. The amount of accumulated Ker on hair fibers was furthermore increased by 1.7-fold in presence of 25 mM L-arginine. Perming of hair impaired binding characteristics of Ker with negligible effects for preactivation, whereas unmodified and preactivated KAP showed results comparable to natural hair. Strongly enhanced penetrability after perming was reflected by the mean penetration depth for fluorescein of 25 µm compared to 5 µm for natural fibers.

Composite nanocellulose-based hydrogels with spatially oriented degradation and retarded release of macromolecules.

The oral delivery of macromolecular therapeutics to the intestinal tract requires novel, robust, and controlled formulations. Here, we report on fabrication by molding of composite hydrogel cylinders made of cellulose nanocrystals (CNCs) and chitosan (Cht) and their performance as delivery vehicles. CNCs provide excellent mechanical and chemical stress resistance, whereas Cht allows scaffold degradation by enzyme digestion. The release of a representative medium size protein (bovine serum albumin) dispersed in the hydrogel is slow and shows a sigmoidal profile; meanwhile, the hydrogel scaffold degrades according to a preferred route, that is the cylinder is eroded along the vertical axis. The cup-like, scarcely interconnected porous network, with a gradient of hardness along the cylinder axis, and the compact skin-like layer covering the lateral wall which stayed in contact with the mold during gelification, explain the preferred erosion direction and the long-term protein release. The possible effect of the molding process on hydrogel structure suggests that molding could be a simple and cheap way to favor surface compaction and directional scaffold degradation.

Characterization of an amino acid based biodegradable surfactant facilitating the incorporation of DNA into lipophilic delivery systems.

HYPOTHESIS: Lysine based cationic surfactants are well-tolerated tools for hydrophobic ion pairing (HIP) with DNA and its incorporation into lipophilic delivery systems. EXPERIMENTS: Di-Boc-lysine was esterified with 1-hexadecanol and the Boc-residues were cleaved off resulting in hexadecyl lysinate (HL). Subsequently, its Log POctanol/water and the critical micelle concentration (CMC) were determined. Degradability was evaluated utilizing trypsin and pancreas lipase as well as Caco-2 cells. Afterwards, the viability of Caco-2 cells upon incubation with HL was investigated. Finally, HL was ion-paired with plasmid DNA (pDNA, 6159 bp) and the obtained complex was incorporated into self-emulsifying drug delivery systems (SEDDS) for transfection studies on HEK-293 cells. FINDINGS: HL was synthesized with a yield of 53% and subsequent characterization revealed a Log PWater/Octanol of 0.05 and a CMC of 2.7 mM. Enzymatic degradation studies showed rapid degradation of HL by isolated enzymes and Caco-2 cells and cell viability experiments revealed no toxic effect of HL even in a concentration of 250 µg·ml-1 within 24 h. HIP with pDNA was the most efficient in a molar ratio of 6159:1 (HL:pDNA) equalling a charge ratio of 1:1. Formed complexes could be incorporated into SEDDS facilitating successful transfection of HEK-293 cells.

Grafting of wool fibers through disulfide bonds: An advanced application of S-protected thiolated starch.

The purpose of this study is to develop a potential pathway for grafting polymers onto wool fibers based on thiol-disulfide exchange reactions. S-protected thiolated starch (PTS) was synthesized by coupling 3-(2-pyridyldithio) propanoic acid to starch through esterification, resulting in 417.3 ± 15.1 µmol ligand binding to 1 g of starch. PTS was labelled with fluorescein isothiocyanate (FITC) prior to grafting. Wool fibers were preactivated by raising the amount of thiol groups utilizing mild reducing agents. The highest degree of preactivation on the surface of wool fibers was achieved by a 0.2% (w/v) sodium borohydride and 1.5% (w/v) sodium bisulfite mixture pH 5.0 resulting in 182.6 ± 8.7 µmol thiol groups per gram of fibers. Different incubation times and ratios between FITC-labelled PTS and wool fibers were investigated. A graft yield of 58.5% was achieved at a ratio of 1:1.5 (w/w) between wool fibers and FITC-labelled PTS within 18 h of incubation. Successful coating of PTS on wool fibers was confirmed by confocal imaging, scanning electron microscopy and FT-IR. Mechanical properties of grafted wool fibers were tested regarding elongation and tensile strength. These results provide evidence for the potential of S-protected thiolated starch as a superior coating material for wool fibers.

Mucoadhesive hydrogels for buccal drug delivery: In vitro-in vivo correlation study.

AIM: It was the aim of this study to assess in vitro methods for the characterization of mucoadhesive hydrogels for their potential to predict the residence time on human buccal mucosa. METHODS: Mixtures of hydrogels comprising hydroxyethyl cellulose (HEC), sodium carboxymethyl cellulose (CMC), xanthan gum (XTGM), hyaluronic acid sodium salt (HA), sodium alginate (ALG), carbopol (CP) as well as polycarbophil (PCP) and porcine mucus were analysed for relative rheological synergism. Furthermore, hydrogels were characterized for their texture and mechanical properties. For the assessment of mucoadhesive strength of formulations tensile studies were performed on porcine buccal mucosa. To facilitate a direct comparability of data the residence time of stained hydrogels was determined ex vivo on porcine buccal mucosa and in the oral cavity of volunteers. RESULTS: The extent of relative rheological synergism was in good agreement with data from in vivo residence time studies. Results of tensile studies were further effected by textural properties of hydrogels leading to a restricted correlation with data from the in vivo experiment. The resistance towards removal by artificial saliva flow ex vivo revealed the highest correlation to the in vivo experiment with increasing mucosal residence time in the rank order CP < HEC, HA, ALG, PCP < CMC < XTGM. CONCLUSIONS: This overview of measurement principles to predict the residence time of hydrogels for buccal application in humans may be a potent tool for the development of semisolid intraoral formulations.

In Vitro-in Vivo Correlation of Mucoadhesion Studies on Buccal Mucosa.

BACKGROUND: For the development of novel buccoadhesive formulations, their physicochemical properties, strength of the interfacial joint, and residence time on the buccal mucosa are considered as a measure for their in vivo mucoadhesive properties. Focusing on these parameters, the predictive power of established in vitro systems was assessed for mucoadhesive properties in humans using discs as the model solid dosage form. METHODS: Compressed into discs, hydroxyethyl cellulose, carboxymethyl cellulose, carbopol, polycarbophil, alginate, and xanthan gum were used as model polymers. Mucosal residence time, maximum detachment force (MDF), and total work of adhesion (TWA) were determined ex vivo on the porcine buccal mucosa and in vivo on healthy volunteers. The impact of detachment velocity, humidification, and experimental set-up employed for tensile studies was examined and correlated to in vivo studies. RESULTS: Ex vivo results for mucosal residence time showed a very high correlation ( r = 0.997) with data obtained in vivo. For tensile studies, a set-up optimized for moistening the interface, speed, and alignment of the tensile force provided ex vivo results with very high correlation to in vivo experiments with r = 0.983 obtained for MDF and r = 0.973 for TWA, respectively. CONCLUSIONS: Experimental set-ups for the determination of mucosal residence time and tensile studies could be identified as valid methods for the development of intraoral solid dosage forms.

Entirely S-Protected Thiolated Silicone: A Novel Hydrophobic Mucoadhesive and Skin Adhesive.

The aim of this study was the synthesis and evaluation of an entirely S-protected thiolated silicone as novel hydrophobic mucoadhesive and skin adhesive. 2-[(2-Amino-2-carboxyethyl)disulfanyl]nicotinic acid was covalently attached to a poly(dimethylsiloxane)-graft-polyacrylate via amide bond formation. Adhesive properties were determined via the rotating cylinder method and tensile studies on porcine small intestinal mucosa besides on porcine abdominal skin. Rheological characteristics were evaluated on a cone-plate rheometer. The S-protected thiolated silicone exhibited 128 ± 18 µmol immobilized 2-mercaptonicotinic acid per gram of polymer and showed a 5.9-fold extended time of mucosal adhesion compared with the unmodified silicone on the rotating cylinder. With a 2.3-fold higher maximum detachment force and a 1.7-fold higher total work of adhesion tested on porcine small intestinal mucosa, the S-protected thiolated silicone is superior to the unmodified silicone. Furthermore, using porcine abdominal skin, a 2.4-fold higher maximum detachment force and a 4.4-fold higher total work of adhesion obtained for the S-protected thiolated silicone outlines the preferentially adhesion to skin. Triggered by N-acetyl-L-cysteine liberated thiol groups form interchain and intrachain disulfide bonds within the polymer (6.7% m/v) causing a 23.0-fold increase in dynamic viscosity (ƞ). In parallel, the elastic modulus (G') and the viscous modulus (G") increased 39.2-fold and 8.1-fold, respectively.

In vitro evaluation of a self-emulsifying drug delivery system (SEDDS) for nasal administration of dimenhydrinate.

The objective of the study was the development and in vitro characterization of a self-emulsifying drug delivery system (SEDDS) for the nasal application of dimenhydrinate. Final composition of SEDDS was established based on drug solubility and stability studies. Dimenhydrinate was loaded into the SEDDS pre-concentrates to 7.5% (m/v). The droplet size of the final SEDDS formulations was in a range between 60 and 220 nm. Permeability, as well as tissue toxicity, of the formulations was investigated using bovine nasal mucosa. Enhancement in permeation up to 2.8-fold compared to pure dimenhydrinate was confirmed. Furthermore, toxicity studies did not reveal any serious tissue damages related to the SEDDS. Additionally, irritation potential of SEDDS was evaluated in ciliary beat frequency measurements. Incorporation of dimenhydrinate into SEDDS might therefore be considered as a promising approach within the field of nasal delivery of antiemetics by utilizing permeation enhancement strategy.

N-Hydroxysulfosuccinimide Esters versus Thiomers: A Comparative Study Regarding Mucoadhesiveness.

The objective of the study was to compare poly(acrylic acid)- N-hydroxysulfosuccinimide reactive esters (PAA-Sulfo-NHS) and poly(acrylic acid)-cysteine conjugates (PAA-Cys) regarding their mucoadhesiveness. Polymer conjugates were synthesized in a water free environment and characterized by UV-vis spectroscopy and FTIR. Water uptake studies were performed, and the polymers were further examined for their mucoadhesive properties and cohesiveness using the rotating cylinder method. Tensile force measurements were conducted to define the strength of adhesion to porcine intestinal mucosa. Additionally, polymer-mucus mixtures were assessed for rheological synergism by measuring the increase in dynamic viscosity. Both modifications led to a prolonged adhesion time compared to unmodified PAA. Fast dissolution of PAA-Sulfo-NHS derivatives was monitored, whereas PAA-Cys tended to extensively swell while exhibiting high cohesive properties. Measurements of tensile force revealed up to 2.7-fold (PAA-Sulfo-NHS) and 2.3-fold (PAA-Cys) enhancement of the maximum detachment force and 7.6-fold (PAA-Sulfo-NHS) and 3.6-fold (PAA-Cys) increase in the total work of adhesion. Formation of a gel network between polymer and mucus was confirmed by a 10.8-fold (PAA-Sulfo-NHS) and 20.8-fold (PAA-Cys) increase in viscosity. Both types of polymers show high mucoadhesive properties due to the formation of covalent bonds with the mucus. As thiolated polymers are capable of forming stabilizing disulfide bonds within their polymeric network, they are advantageous over PAA-Sulfo-NHS.

Reactive keratin derivatives: A promising strategy for covalent binding to hair.

HYPOTHESIS: Restoration of damaged hair structure by replacing lost keratin is still of paramount interest. On account of the fact that native keratin is a highly cross-linked protein with numerous disulfide bonds but just a few nucleophilic thiol groups, binding affinity to hair is comparatively low. Hence, the design of reactive keratin derivatives bearing free sulfhydryl groups that are optionally S-protected and preactivated should enhance permanent binding to hair fibers. EXPERIMENTS: Keratin was extracted from human Caucasian hair and reduced with NaBH4 to obtain free sulfhydryl groups (keratin-SH). These thiol groups were S-protected via disulfide linkage to 2-mercaptonicotinic acid (keratin-MNA). Hair fibers were either utilized in their natural form or chemically damaged by bleaching. Amount of keratin derivatives being bound to hair fibers was quantified by fluorescence detection of fluorescein isothiocyanate labeled keratins. FINDINGS: Both modifications induced higher affinity of keratin to hair fibers, resulting in up to 1.7-fold (keratin-MNA) improved binding to natural hair and up to 3.6-fold (keratin-MNA) improved binding to bleached hair. Confocal laser microscopy confirmed the accumulation of keratin derivatives in distinct regions of the cuticle layer. Thiol functionalization seems therefore to be a promising strategy for efficient durable binding of keratin to hair.

Anhydrous thiomers: Strategy for enhanced mucoadhesion.

AIM: The aim of this study was to evaluate the impact of the absence of water during the synthesis of thiolated poly(acrylic acid) (PAA) on its mucoadhesive properties. Previously, thiolation of hydrophilic polymers was performed in aqueous media, where (poly)acrylates undergo a conformational transition to form an entangled network of polymer chains stabilized by neutralization. The impact of chain entanglement, porosity and degree of functionalization of anhydrous precipitated polymers on their mucoadhesive characteristics were therefore evaluated in comparison to the equivalent products synthesized in water and dried by lyophilization. METHODS: Anhydrous synthesis and purification procedures were designed for the thiolation and entire preactivation of PAA by means of immobilization of l-cysteine (PAA-Cys) and 2-mercaptonicotinic acid (PAA-Cys-MNA), respectively. The obtained conjugates were characterized chemically and for their particle size. Differences in mucoadhesive properties were determined by means of the residence time as well as tensile strength of polymer test disks on porcine small intestinal mucosa. RESULTS: Anhydrous products revealed a 4.2-fold higher amount of immobilized free thiol moieties for PAA-Cys and a 3.1-fold higher quantity of 2-mercaptonicotinic acid for PAA-Cys-MNA. The impact of particle size of anhydrous products on their mucoadhesive properties was negligible. In comparison to the corresponding aqueous products a 2.5-fold increase in residence time for PAA-Cys and 21.2-fold increase for PAA-Cys-MNA was achieved and in agreement with these results, the improvement in the total work of adhesion was 2.9-fold for PAA-Cys and 5.1-fold for PAA-Cys-MNA. CONCLUSION: According to these findings, anhydrous synthesis conditions seem to be a promising tool for improved modification rates and moreover enhanced mucoadhesive properties of hydrophilic polymers.