Chitosan-Based Materials Featuring Multiscale Anisotropy for Wider Tissue Engineering Applications.

We designed graphene oxide composites with increased morphological and structural variability using fatty acid-coupled polysaccharide co-polymer as the continuous phase. The matrix was synthesized by N, O-acylation of chitosan with palmitic and lauric acid. The obtained co-polymer was crosslinked with genipin and composited with graphene oxide. FTIR spectra highlighted the modification and multi-components interaction. DLS, SEM, and contact angle tests demonstrated that the conjugation of hydrophobic molecules to chitosan increased surface roughness and hydrophilicity, since it triggered a core-shell macromolecular structuration. Nanoindentation revealed a notable durotaxis gradient due to chitosan/fatty acid self-organization and graphene sheet embedment. The composited building blocks with graphene oxide were more stable during in vitro enzymatic degradation tests and swelled less. In vitro viability, cytotoxicity, and inflammatory response tests yielded promising results, and the protein adsorption test demonstrated potential antifouling efficacy. The robust and stable substrates with heterogeneous architecture we developed show promise in biomedical applications.

Nickel (II) and Cobalt (II) Alginate Biopolymers as a "Carry and Release" Platform for Polyhistidine-Tagged Proteins.

Protein immobilization using biopolymer scaffolds generally involves undesired protein loss of function due to denaturation, steric hindrance or improper orientation. Moreover, most methods for protein immobilization require expensive reagents and laborious procedures. This work presents the synthesis and proof of concept application of two alginate hydrogels that are able to bind proteins with polyhistidine tags by means of interaction with the crosslinking cations. Nickel (II) and cobalt (II) alginate hydrogels were prepared using a simple ionic gelation method. Hydrogels were characterized by optical microscopy and AFM, and evaluated for potential cytotoxicity. In addition, binding capacity was tested towards proteins with or without HisTAG. Hydrogels had moderate cytotoxicity and were able to exclusively bind polyhistidine-tagged proteins with a binding capacity of approximately 300 µg EGFP (enhanced green fluorescent protein) per 1 mL of hydrogel. A lyophilized hydrogel-protein complex dissolved upon the addition of PBS and allowed the protein release and regain of biological activity. In conclusion, the nickel (II) and cobalt (II) alginate biopolymers provided an excellent platform for the "carry and release" of polyhistidine-tagged proteins.

Generation of a 3D melanoma model and visualization of doxorubicin uptake by fluorescence imaging.

Melanoma is the most dangerous type of skin cancer and is responsible for 75% of deaths from skin cancers. For an accurate evaluation of potential treatment efficacy, it is important to use study models as close as possible to the in vivo conditions. A 3D model consisting of B16F10 spheroids was developed using liquid overlay technique on plates coated with 1% agarose, in the presence of 1% methylcellulose and L929-conditioned medium. The model is suitable and can be further used for more complex in vitro drug testing than the classical 2D approach. For exemplification, the behavior of a well-known cytostatic, doxorubicin (DOX), was evaluated in spheroids as compared to classical 2D culture conditions. Fluorescence imaging was used to visualize DOX uptake by B16F10 spheroids at different periods of time. The results showed that a much higher DOX concentration is necessary to produce similar effects compared with the monolayer. The fluorescence images revealed that at least 4 h of stimulation is needed for a sufficient DOX uptake. The 3D model developed in this study was suitable to investigate drug penetration in time. Our findings may explain the decrease of the doxorubicin therapeutical effect, suggesting the need of maintaining the drug concentration at the tumoral place for at least 2 h upon administration. Similar or more advanced studies can lead to a better understanding of drug delivery kinetics and distribution upon administration, conducing toward a better performance in designing suitable delivery systems for obtaining the optimum dose-response effect.