Although various drugs, environmental pollutants and nanoparticles (NP) can cross the human placental barrier and may harm the developing fetus, knowledge on predictive placental transfer rates and the underlying transport pathways is mostly lacking. Current available in vitro placental transfer models are often inappropriate for translocation studies of macromolecules or NPs and do not consider barrier function of placental endothelial cells (EC). Therefore, we developed a human placental in vitro co-culture transfer model with tight layers of trophoblasts (BeWo b30) and placental microvascular ECs (HPEC-A2) on a low-absorbing, 3 µm porous membrane. Translocation studies with four model substances and two polystyrene (PS) NPs across the individual and co-culture layers revealed that for most of these compounds, the trophoblast and the EC layer both demonstrate similar, but not additive, retention capacity. Only the paracellular marker Na-F was substantially more retained by the BeWo layer. Furthermore, simple shaking, which is often applied to mimic placental perfusion, did not alter translocation kinetics compared to static exposure. In conclusion, we developed a novel placental co-culture model, which provides predictive values for translocation of a broad variety of molecules and NPs and enables valuable mechanistic investigations on cell type-specific placental barrier function.
High-Z metal oxide nanoparticles hold promise as imaging probes and radio-enhancers. Hafnium dioxide nanoparticles have recently entered clinical evaluation. Despite promising early clinical findings, the potential of HfO 2 as a matrix for multimodal theranostics is yet to be developed. Here, we investigate the physicochemical properties and the potential of HfO 2 -based nanoparticles for multimodal theranostic imaging. Undoped and lanthanide (Eu 3+ , Tb 3+ , and Gd 3+ )-doped HfO 2 nanoparticles were synthesized and functionalized with various moieties including poly-(vinylpyrrolidone) (PVP), (3-aminopropyl)triethoxysilane (APTES), and folic acid (FA). We show that different synthesis routes, including direct precipitation, microwave-assisted synthesis, and sol−gel chemistry, allow preparation of hafnium dioxide particles with distinct physicochemical properties. Sol−gel based synthesis allows preparation of uniform nanoparticles with dopant incorporation efficiencies superior to the other two methods. Both luminescence and contrast properties can be tweaked by lanthanide doping. We show that MRI contrast can be unified with radio-enhancement by incorporating lanthanide dopants in the HfO 2 matrix. Importantly, ion leaching from the HfO 2 host matrix in lysosomal-like conditions was minimal. For Gd:HfO 2 nanoparticles, leaching was reduced >10× compared to Gd 2 O 3 , and no relevant cytotoxic effects have been observed in monocyte-derived macrophages for nanoparticle concentrations up to 250 μg/mL. Chemical surface modification allows further tailoring of the cyto-and hemocompatibility and enables functionalization with molecular targeting entities, which lead to enhanced cellular uptake. Taken together, the present study illustrates the manifold properties of HfO 2 -based nanomaterials with prospective clinical utility beyond radio-enhancement.
The mechanistic understanding
of structure–function relationships
in biological systems heavily relies on imaging. While fluorescence
microscopy allows the study of specific proteins following their labeling
with fluorophores, electron microscopy enables holistic ultrastructural
analysis based on differences in electron density. To identify specific
proteins in electron microscopy, immunogold labeling has become the
method of choice. However, the distinction of immunogold-based protein
labels from naturally occurring electron dense granules and the identification
of several different proteins in the same sample remain challenging.
Correlative cathodoluminescence electron microscopy (CCLEM) bioimaging
has recently been suggested to provide an attractive alternative based
on labels emitting characteristic light. While luminescence excitation
by an electron beam enables subdiffraction imaging, structural damage
to the sample by high-energy electrons has been identified as a potential
obstacle. Here, we investigate the feasibility of various commonly
used luminescent labels for CCLEM bioimaging. We demonstrate that
organic fluorophores and semiconductor quantum dots suffer from a
considerable loss of emission intensity, even when using moderate
beam voltages (2 kV) and currents (0.4 nA). Rare-earth element-doped
nanocrystals, in particular Y2O3:Tb3+ and YVO4:Bi3+,Eu3+ nanoparticles
with green and orange-red emission, respectively, feature remarkably
high brightness and stability in the CCLEM bioimaging setting. We
further illustrate how these nanocrystals can be readily differentiated
from morphologically similar naturally occurring dense granules based
on optical emission, making them attractive nanoparticle core materials
for molecular labeling and (multi)color CCLEM.
Here, we report the use of rare earth element-doped nanocrystals as probes for correlative cathodoluminescence electron microscopy (CCLEM) bioimaging. This first experimental demonstration shows potential for the simultaneous acquisition of luminescence and electron microscopy images with nanometric resolution in focused ion beam cut biological samples.
Osteoderms are hard tissues embedded in the dermis of vertebrates and have been suggested to be formed from several different mineralized regions. However, their nano architecture and micro mechanical properties had not been fully characterized. Here, using electron microscopy, µ-CT, atomic force microscopy and finite element simulation, an in-depth characterization of osteoderms from the lizard Heloderma suspectum, is presented. Results show that osteoderms are made of three different mineralized regions: a dense apex, a fibre-enforced region comprising the majority of the osteoderm, and a bone-like region surrounding the vasculature. The dense apex is stiff, the fibreenforced region is flexible and the mechanical properties of the bone-like region fall somewhere between the other two regions. Our finite element analyses suggest that when combined into the osteoderm structure, the distinct tissue regions are able to shield the body of the animal by dampening the external forces. These findings reveal the structure-function relationship of the Heloderma suspectum osteoderm in unprecedented detail .
ABSTRACT:The magnetic separation of pathogenic compounds from body fluids is an appealing therapeutic concept. Recently, removal of a diverse array of pathogens has been demonstrated using extracorporeal dialysis-type devices. The contact time between the fluid and the magnetic beads in such devices is limited to a few minutes. This poses challenges, particularly if large compounds such as bacteria or cells need to be removed. Here, we report on the feasibility to remove cells from body fluids in a continuous dialysis type of setting. We assessed tumor cell removal efficiencies from physiological fluids with or without white blood cells using a range of different magnetic bead sizes (50−4000 nm), concentrations, and contact times. We show that tumor cells can be quantitatively removed from body fluids within acceptable times (1−2 min) and bead concentrations (0.2 mg per mL). We further present a mathematical model to describe the minimal bead number concentration needed to remove a certain number of cells, in the presence of competing nonspecific uptake. The present study paves the way for investigational studies to assess the therapeutic potential of cell removal by magnetic blood purification in a dialysis-like setting.
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