Biocompatible carboxyethyl chitosan/poly(vinyl alcohol) (CECS/PVA) nanofibers were successfully prepared by electrospinning of aqueous CECS/PVA solution. The composite nanofibrous membranes were subjected to detailed analysis by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and X-ray diffraction (XRD). SEM images showed that the morphology and diameter of the nanofibers were mainly affected by the weight ratio of CECS/PVA. XRD and DSC demonstrated that there was strong intermolecular hydrogen bonding between the molecules of CECS and PVA. The crystalline microstructure of the electrospun fibers was not well developed. The potential use of the CECS/PVA electrospun fiber mats as scaffolding materials for skin regeneration was evaluated in vitro using mouse fibroblasts (L929) as reference cell lines. Indirect cytotoxicity assessment of the fiber mats indicated that the CECS/PVA electrospun mat was nontoxic to the L929 cell. Cell culture results showed that fibrous mats were good in promoting the cell attachment and proliferation. This novel electrospun matrix would be used as potential wound dressing for skin regeneration.
Commercial or clinical
tissue adhesives are currently limited due
to their weak bonding strength on wet biological tissue surface, low
biological compatibility, and slow adhesion formation. Although catechol-modified
hyaluronic acid (HA) adhesives are developed, they suffer from limitations:
insufficient adhesiveness and overfast degradation, attributed to
low substitution of catechol groups. In this study, we demonstrate
a simple and efficient strategy to prepare mussel-inspired HA hydrogel
adhesives with improved degree of substitution of catechol groups.
Because of the significantly increased grafting ratio of catechol
groups, dopamine-conjugated dialdehyde–HA (DAHA) hydrogels
exhibit excellent tissue adhesion performance (i.e., adhesive strength
of 90.0 ± 6.7 kPa), which are significantly higher than those
found in dopamine-conjugated HA hydrogels (∼10 kPa), photo-cross-linkable
HA hydrogels (∼13 kPa), or commercially available fibrin glues
(2–40 kPa). At the same time, their maximum adhesion energy
is 384.6 ± 26.0 J m–2, which also is 40–400-fold,
2–40-fold, and ∼8-fold higher than those of the mussel-based
adhesive, cyanoacrylate, and fibrin glues, respectively. Moreover,
the hydrogels can gel rapidly within 60 s and have a tunable degradation
suitable for tissue regeneration. Together with their cytocompatibility
and good cell adhesion, they are promising materials as new biological
adhesives.
In this study, dynamic
imine covalent bonds were introduced into
vanillin-based vitrimers networks, endowing thermosets with hot-reprocessing
ability and chemical recyclability under acid hydrolysis. First, dialdehyde
monomer, which was synthesized from lignin-derived vanillin monomer,
was reacted with conventional amine cross-linkers to form dynamic
imine bond networks. Even after three hot-processing cycles, the tensile
strength and elongation at break of polyschiff vitrimers could be
recovered at least up to 71.2 and 72.8%, respectively, through the
imine metathesis reaction. Importantly, the dialdehyde monomers showed
enhanced recyclability under strong acid solution and could be reused
to regenerate polyschiff vitrimers. These characteristics of reprocessablility,
recyclablility, and biobased monomer present a feasible way to satisfy
the demands of sustainability.
In response to UV irradiation, mammalian cells elicit a gene expression programme designed to repair damage and control cell proliferation and apoptosis. Important members of this stress response include the NF-kappaB (nuclear factor-kappaB) family. However, the mechanisms by which UV irradiation activates NF-kappaB are not well understood. In eukaryotes, a variety of environmental stresses are recognized and remediated by a family of protein kinases that phosphorylate the alpha subunit of eIF2 (eukaryotic initiation factor-2). In the present study we show that NF-kappaB in MEF (murine embryo fibroblast) cells is activated by UV-C and UV-B irradiation through a mechanism requiring eIF2alpha phosphorylation. The primary eIF2alpha kinase in response to UV is GCN2 (general control non-derepressible-2), with PEK/PERK (pancreatic eIF2alpha kinase/RNA-dependent-protein-kinase-like endoplasmic-reticulum kinase) carrying out a secondary function. Our studies indicate that lowered protein synthesis accompanying eIF2alpha phosphorylation, combined with eIF2alpha kinase-independent turnover of IkappaBalpha (inhibitor of kappaBalpha), reduces the levels of IkappaBalpha in response to UV irradiation. Release of NF-kappaB from the inhibitory IkappaBalpha would facilitate NF-kappaB entry into the nucleus and targeted transcriptional control. We also find that loss of GCN2 in MEF cells significantly enhances apoptosis in response to UV exposure similar to that measured in cells deleted for the RelA/p65 subunit of NF-kappaB. These results demonstrate that GCN2 is central to recognition of UV stress, and that eIF2alpha phosphorylation provides resistance to apoptosis in response to this environmental insult.
Misselected CD8 cells that express T cell receptors (TCRs) that do not recognize class I major histocompatibility complex (MHC) protein can emerge from thymic selection. A postthymic quality control mechanism that purges these cells from the repertoire is defined here. The failure of mature CD8 cells to simultaneously engage their TCR and CD8 coreceptor triggers an activation process that begins with inhibition of CD8 gene expression through remethylation and concludes with up-regulation of surface Fas and Fas ligand and cellular apoptosis. Thus, inhibition of a death signal through continued TCR-CD8 coengagement of MHC molecules is a key checkpoint for the continued survival of correctly selected T cells. Molecular defects that prevent delivery of the death signal to mistakenly selected T cells underlie the expansion of double-negative T cells, which is the cellular signature of a subset of systemic autoimmune diseases.
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