Sustainable production of porous chitosan microparticles by energy-efficient membrane emulsification.

In drug delivery, it is common to use porous particles as carrier media, instead of dense particles, due to their high specific surface area and available entrapment volume, which allows a higher amount of drug to be encapsulated and then released. Chitosan microparticles are extensively used in drug delivery, but porous chitosan microparticles are scarcely reported. In this work, the preparation of porous chitosan microparticles using membrane emulsification is addressed, a technology that involves mild operating conditions and less energy consumption than traditional methods (such as ultrasound), and with higher control of the particle size.

GelMA/bioactive silica nanocomposite bioinks for stem cell osteogenic differentiation.

Leveraging 3D bioprinting for processing stem cell-laden biomaterials has unlocked a tremendous potential for fabricating living 3D constructs for bone tissue engineering. Even though several bioinks developed to date display suitable physicochemical properties for stem cell seeding and proliferation, they generally lack the nanosized minerals present in native bone bioarchitecture. To enable the bottom-up fabrication of biomimetic 3D constructs for bioinstructing stem cells pro-osteogenic differentiation, herein we developed multi-bioactive nanocomposite bioinks that combine the organic and inorganic building blocks of bone.

Efficient Single-Dose Induction of Osteogenic Differentiation of Stem Cells Using Multi-Bioactive Hybrid Nanocarriers.

Bone regeneration requires the presence of specific factors to induce the differentiation of stem cells into osteoblasts. These factors induce osteogenesis by stimulating the expression of bone-related proteins, bone cell proliferation and differentiation. Herein, bioactive mesoporous silica nanoparticles are doped with calcium and phosphate ions while the porous network is loaded with dexamethasone (MSN-CaPDex).

Bioactive silica nanoparticles with calcium and phosphate for single dose osteogenic differentiation.

The differentiation of adult stem cells is usually performed in vitro, by exposing them to specific factors. Alternatively, one can use nanocarriers containing such factors, to be internalized by the cells. In this work we have reduce the size of those carriers to the nanoscale, developing bioactive silica nanoparticles with diameters under 100 nm, containing calcium and phosphate ions (SiNPs-CaP).