This work explores time-resolved emission imaging microscopy (TREM) for noninvasive imaging and mapping of live cells on a hitherto uncharted microsecond time scale. Simple robust molecules for this purpose have long been sought. We have developed highly emissive, synthetically versatile, and photostable platinum(II) complexes that make TREM a practicable reality. fluorescence microscopy ͉ time-resolved luminescence spectroscopy ͉ transition metal complexes ͉ cyclometalation
Fibrous
networks assembled from synthetic peptides are promising
candidates for biomimetic cell culture platforms and implantable biomaterials.
The ability of the materials to reproduce physiological cell–matrix
interactions is essential. However, the synthetic complexity of such
systems limits their applications, thus alternative materials are
desirable. Here, we design lysozyme derived amyloid fibril networks
with controllable topographies, and perform a comprehensive study
of the response of cultured fibroblast and epithelial cells. At high
surface coverage a favorable increase in spreading and the generation
of focal adhesions was observed, due to a combination of biomimetic
chemistry and morphology. Their ease of synthesis, makes the nanoscale
fibrils presented here ideal materials for future clinical applications
whereby large volumes of biomimetic biomaterials are required. Furthermore,
the surface chemistry of the fibrils is sufficient for the promotion
of focal adhesions with cultured cells, eliminating the need for complex
protocols for fibril decoration with bioactive moieties.
Biodegradable polymers, such as polycaprolactone (PCL), are promising materials in the field of tissue engineering and regenerative medicine, which aims at creating viable options to replace permanent orthopedic implants. The material, cells, and growth-stimulating factors are often referred to as the key components of engineered tissues. In this article, we studied the hypothesis of specific surface modification of PCL being capable of inducing mesenchymal stem cell differentiation in bone cells in the absence of cell-differentiating factors. The systematic investigation of the linearly varying surface-roughness gradient showed that an average PCL roughness of 0.93 μm alone can serve as a compelling alternative to soluble osteogenic inducers in orthopedic applications featuring the clinically relevant biodegradable polymer polycaprolactone.
T cell precursors undergo asymmetric cell division after T cell receptor genomic recombination, with stromal cell cues controlling the differential inheritance of fate determinants Numb and α-Adaptin by the daughters of a dividing DN3a T cell precursor.
Our aim was to develop a biodegradable fibrous dressing to act as a tissue guide for in situ wound repair while releasing Ibuprofen to reduce inflammation in wounds and reduce pain for patients on dressing changes. Dissolving the acid form of Ibuprofen (from 1% to 10% by weight) in the same solvent as 75% polylactide, 25% polyglycolide (PLGA) polymers gave uniformly loaded electrospun fibers which gave rapid release of drug within the first 8 h and then slower release over several days. Scaffolds with 10% Ibuprofen degraded within 6 days. The Ibuprofen released from these scaffolds significantly reduced the response of fibroblasts to major pro-inflammatory stimulators. Fibroblast attachment and proliferation on scaffolds was unaffected by the addition of 1-5% Ibuprofen. Scaffolds loaded with 10% Ibuprofen initially showed reduced cell attachment but this was restored by soaking scaffolds in media for 24 h. In summary, addition of Ibuprofen to electrospun biodegradable scaffolds can give acute protection of adjacent cells to inflammation while the scaffolds provide an open 3D fibrous network to which cells can attach and migrate. By 6 days, such scaffolds will have completely dissolved into the wound bed obviating any need for dressing removal.
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