Superparamagnetic iron oxide nanoparticles (NPs) are used in a rapidly expanding number of applications in e.g. the biomedical field, for which brushes of biocompatible polymers such as poly(ethylene glycol) (PEG) have to be densely grafted to the core. Grafting of such shells to monodisperse iron oxide NPs has remained a challenge mainly due to the conflicting requirements to replace the ligand shell of as-synthesized NPs with irreversibly bound PEG dispersants. We introduce a general two-step method to graft PEG dispersants from a melt to iron oxide NPs first functionalized with nitrodopamine (NDA). This method yields uniquely dense spherical PEG-brushes (∼3 chains per nm(2) of PEG(5 kDa)) compared to existing methods, and remarkably colloidally stable NPs also under challenging conditions.
The promising applications of core–shell
nanoparticles in the biological and medical field have been well investigated
in recent years. One remaining challenge is the characterization of
the structure of the hydrated polymer shell. Here we use small-angle
X-ray scattering (SAXS) to investigate iron oxide core–poly(ethylene
glycol) brush shell nanoparticles with extremely high polymer grafting
density. It is shown that the shell density profile can be described
by a scaling model that takes into account the locally very high grafting
density near the core. A good fit to a constant density region followed
by a star-polymer-like, monotonously decaying density profile is shown,
which could help explain the unique colloidal properties of such densely
grafted core–shell nanoparticles. SAXS experiments probing
the thermally induced dehydration of the shell and the response to
dilution confirmed that the observed features are associated with
the brush and not attributed to structure factors from particle aggregates.
We thereby demonstrate that the structure of monodisperse core–shell
nanoparticles with dense solvated shells can be well studied with
SAXS and that different density models can be distinguished from each
other.
Previous results have shown that glial cells provide a soft environment for the neurons of the mammalian central nervous system (CNS). This raises the question whether neurons are confined to the CNS and cannot wander off into more rigid tissues, such as brain capillary walls. We investigated the mechanical properties and force generation of extending mouse retinal ganglion cells and NG108-15 growth cones (GCs) using different atomic force microscope (AFM)-based methods. For the first time, to our knowledge, we were able to measure the forward pushing forces at the leading edge of outgrowing neuronal GCs with our drift-stabilized AFM. Our results demonstrate that these GCs have neither the required stability nor the ability to produce forces necessary to penetrate tissues that are at least an order of magnitude stiffer.
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