Biopebble Containers: DNA-Directed Surface Assembly of Mesoporous Silica Nanoparticles for Cell Studies.

The development of methods for colloidal self-assembly on solid surfaces is important for many applications in biomedical sciences. Toward this goal, described is a versatile class of mesoporous silica nanoparticles (MSN) that contain on their surface various types of DNA molecules to enable their self-assembly into micropatterned surface architectures useful for cell studies. Monodisperse dye-doped MSN are synthesized by biphase stratification and functionalized with an aptamer oligonucleotide that serves as gatekeeper for the triggered release of encapsulated molecular cargo, such as fluorescent dye rhodamine B or the anticancer drug doxorubicin. One or two additional types of oligonucleotides are installed on the MSN surface to enable DNA-directed immobilization on solid substrates bearing patterns of complementary capture oligonucleotides. It is demonstrated that this strategy can be used for efficient self-assembly of microstructured surface architectures, which not only promote the adhesion and guidance of cells but also are capable of affecting the fate of adhered cells through triggered release of their cargo. It is believed that this approach is useful for diverse applications in tissue engineering and nanobio sciences.

Biocompatibility of Amine-Functionalized Silica Nanoparticles: The Role of Surface Coverage.

Here, amorphous silica nanoparticles (NPs), one of the most abundant nanomaterials, are used as an example to illustrate the utmost importance of surface coverage by functional groups which critically determines biocompatibility. Silica NPs are functionalized with increasing amounts of amino groups, and the number of surface exposed groups is quantified and characterized by detailed NMR and fluorescamine binding studies. Subsequent biocompatibility studies in the absence of serum demonstrate that, irrespective of surface modification, both plain and amine-modified silica NPs trigger cell death in RAW 264.7 macrophages. The in vitro results can be confirmed in vivo and are predictive for the inflammatory potential in murine lungs. In the presence of serum proteins, on the other hand, a replacement of only 10% of surface-active silanol groups by amines is sufficient to suppress cytotoxicity, emphasizing the relevance of exposure conditions. Mechanistic investigations identify a key role of lysosomal injury for cytotoxicity only in the presence, but not in the absence, of serum proteins. In conclusion, this work shows the critical need to rigorously characterize the surface coverage of NPs by their constituent functional groups, as well as the impact of serum, to reliably establish quantitative nanostructure activity relationships and develop safe nanomaterials.

Oriented immobilization of a delicate glucose-sensing protein on silica nanoparticles.

Silica nanoparticles are widely used platform materials for the immobilization of proteins to realize applications in biomedicine and biotechnology. We here report on the use of a highly delicate protein for the systematic evaluation of routes for the surface modification of multifunctional silica nanoparticles. To investigate how surface immobilization methods affect the functionality of surface-bound proteins, we constructed a novel fusion protein, dubbed FlipHOB, that combines the glucose sensor protein FLIP with a variant of the commercially-available self-ligating Halo-tag. As indicated by the spectroscopic properties and sensing capabilities of FlipHOB, the oriented immobilization of this protein through its HOB tag domain or DNA-directed immobilization were superior over the non-directional statistical immobilization via glutardialdehyde-mediated cross-coupling. Immobilization through double-stranded DNA bridges also allows for the triggered disassembly of FlipHOB nanosensors and the controlled recovery of the sensor protein. We demonstrate that the nanosensors are functional in in vitro settings and can be used for imaging in vivo. We believe that our results show generic strategies and provide essential guidelines for the development of protein-based nanoparticle sensors for applications in the life sciences.