A silicon(IV) phthalocyanine with two axial p-phenylene-linked boron dipyrromethene and monostyryl boron dipyrromethene moieties has been prepared. The resulting pentad absorbs strongly in most of the UV-visible region and serves as an artificial photosynthetic antenna-reaction centre model.
Neuronal cell apoptosis is a complex pathophysiological change that occurs following spinal cord injury (SCI) and affects self-repair. Therefore, preventing neuronal cell apoptosis can promote the recovery of nerve function. The present study aimed to investigate the effects of butorphanol on neuronal inflammatory response and apoptosis. The effects of butorphanol on cell viability and pathway-related protein expression were first assessed using the CCK8 and western blot assays, respectively. Lipopolysaccharide (LPS) was used to establish models. The influences of additional anisomycin, an agonist of MAPK pathway, on cell viability, pathway-related protein expression and lactate dehydrogenase level were determined using the CCK8 assay, western blotting and assay kits, respectively. In addition, the roles of butorphanol and anisomycin in inflammatory factor levels and cell apoptosis were determined using reverse transcription-quantitative PCR, TUNEL and western blot assays. Butorphanol was found to protect PC12 cells from the action of LPS on viability and effectively upregulated the p38/JNK/activation of transcription factor 2 (ATF2)/p53 protein expression levels. In addition, anisomycin could break the protective role of butorphanol in cell viability and the inhibitory roles in inflammatory response and apoptosis. To sum up, butorphanol reduces neuronal inflammatory response and apoptosis via inhibiting p38/JNK/ATF2/p53 signaling. The present findings may provide a new direction for the treatment for SCI.
Boron dipyrromethenes (BDPs) are excellent building blocks for design of artificial light harvesting and charge separation systems. In the present work, we report the results of photophysical studies of a novel dyad, in which a BDP and a mono-styryl BDP (MSBDP) are covalently linked to each other at the meso-position via a p-phenylene unit. It was found that the photophysical properties of the dyad dissolved in polar as well as nonpolar solvents are strongly affected by two different types of interactions between the BDP and MSBDP parts, namely excitation energy transfer and photoinduced electron transfer. The first process delivers the excitation energy to the first excited singlet state of the MSBDP-part upon excitation of the BDP unit. The direct or indirect (via excitation energy transfer) population of the first excited singlet state of the MSBDP moiety is followed by hole transfer to generate the charge-separated state. In non-polar toluene, the probability of charge separation is low, whereas in polar acetonitrile the charge separation quantum yield is close to unity, resulting in strong quenching of the MSBDP fluorescence.
Microglial activation is a vital process in the neuroinflammatory response induced by I/R injury. It has been reported that myocyte enhancer factor (MEF)2D expression in activated microglia is associated with microgliainduced inflammatory responses and plays an important role in neuronal survival. This research aimed to investigate the role and mechanism of MEF2D in microglial activation and neuroinflammation in cerebral I/R in vitro and in vivo. Methods: A cerebral I/R model was established. In vitro, neuronal, or microglial cells were exposed to oxygen-glucose deprivation and reoxygenation to mimic I/R. MEF2D overexpression was induced, and siRNA was administered in vitro and in vivo. Microglial polarization; MEF2D, nuclear transcription factor (NF)-kb, TLR4, and cytokine levels; neuronal injury; mitochondrial function; brain injury and cognitive function were detected in the different groups in vitro and in vivo. Results: We found that oxygenglucose deprivation increased MEF2D expression in a time-dependent manner in BV2 cells and primary microglia. MEF2D overexpression inhibited microglial activation, the expression of NF-kb and TLR, cytokine levels, and neuronal injury in microglia exposed to oxygen-glucose deprivation and reoxygenation. In the middle cerebral artery occlusion model, microglial activation, the neuroinflammatory response, mitochondrial dysfunction, brain injury, and cognitive function were improved by MEF2D overexpression and aggravated by MEF2D siRNA treatment. Conclusion: These results indicate that MEF2D is a necessary molecule for neuroinflammation regulation and neuronal injury in cerebral ischemia.
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