Metformin alleviates benzo[a]pyrene-induced alveolar injury by inhibiting necroptosis and protecting AT2 cells.

Exposure to benzo[a]pyrene (B[a]P) has been linked to lung injury and carcinogenesis. Airway epithelial cells express the B[a]P receptor AHR, so B[a]P is considered to mainly target airway epithelial cells, whereas its potential impact on alveolar cells remains inadequately explored. Metformin, a first-line drug for diabetes, has been shown to exert anti-inflammatory and tissue repair-promoting effects under various injurious conditions. Here, we explored the effect of chronic B[a]P exposure on alveolar cells and the impact of metformin on B[a]P-induced lung injury by examining the various parameters including lung histopathology, inflammation, fibrosis, and related signal pathway activation. MLKL knockout (Mlkl-/-) and AT2-lineage tracing mice (SftpcCre-ERT2;LSL-tdTomatoflox+/-) were used to delineate the role of necroptosis in B[a]P-induced alveolar epithelial injury and repair. Mice receiving weekly administration of B[a]P for 6 weeks developed a significant alveolar damaging phenotype associated with pulmonary inflammation, fibrosis, and activation of the necroptotic cell death pathway. These effects were significantly relieved in MLKL null mice. Furthermore, metformin treatment, which were found to promote AMPK phosphorylation and inhibit RIPK3, as well as MLKL phosphorylation, also significantly alleviated B[a]P-induced necroptosis and lung injury phenotype. However, the protective efficacy of metformin was rendered much less effective in Mlkl null mice or by blocking the necroptotic pathway with RIPK3 inhibitor. Our findings unravel a potential protective efficacy of metformin in mitigating the detrimental effects of B[a]P exposure on lung health by inhibiting necroptosis and protecting AT2 cells.

FGF1 ameliorates obesity-associated hepatic steatosis by reversing IGFBP2 hypermethylation.

Obesity is a major contributing factor for metabolic-associated fatty liver disease (MAFLD). Fibroblast growth factor (FGF) 1 is the first paracrine FGF family member identified to exhibit promising metabolic regulatory properties capable of conferring glucose-lowering and insulin-sensitizing effect. This study explores the role and molecular underpinnings of FGF1 in obesity-associated hepatic steatosis. In a mouse high-fat diet (HFD)-induced MAFLD model, chronic treatment with recombinant FGF1(rFGF1) was found to effectively reduce the severity of insulin resistance, hyperlipidemia, and inflammation. FGF1 treatment decreased lipid accumulation in the mouse liver and palmitic acid-treated AML12 cells. These effects were associated with decreased mature form SREBF1 expression and its target genes FASN and SCD1. Interestingly, we uncovered that rFGF1 significantly induced IGFBP2 expression at both mRNA and protein levels in HFD-fed mouse livers and cultured hepatocytes treated with palmitic acid. Adeno-associated virus-mediated IGFBP2 suppression significantly diminished the therapeutic benefit of rFGF1 on MAFLD-associated phenotypes, indicating that IGFBP2 plays a crucial role in the FGF1-mediated reduction of hepatic steatosis. Further analysis revealed that rFGF1 treatment reduces the recruitment of DNA methyltransferase 3 alpha to the IGFBP2 genomic locus, leading to decreased IGFBP2 gene methylation and increased mRNA and protein expression. Collectively, our findings reveal FGF1 modulation of lipid metabolism via epigenetic regulation of IGFBP2 expression, and unravel the therapeutic potential of the FGF1-IGFBP2 axis in metabolic diseases associated with obesity.

In vitro-in vivo correlation of inhalable budesonide-loaded large porous particles for sustained treatment regimen of asthma.

Large porous particles (LPPs) are well-known vehicles for drug delivery to the lungs. However, it remains uncertain whether or to which extent the in vitro drug release behavior of LPPs can be predictive of their in vivo performance (e.g., systemic exposure and therapeutic efficacy). With regard to this, three budesonide-loaded LPP formulations with identical composition but distinct in vitro drug release profiles were studied in vivo for their pharmacokinetic and pharmacodynamic behavior after delivery to rat lung, and finally, an in vitro/in vivo correlation (IVIVC) was established. All formulations reduced approximately 75% of the uptake by RAW264.7 macrophages compared with budesonide/lactose physical mixture and showed a drug release-dependent retention behavior in the lungs of rats. Likewise, the highest budesonide plasma concentration was measured for the formulation revealing the fastest in vitro drug release. After deconvolution of the plasma concentration/time profiles, the calculated in vivo drug release data were successfully utilized for a point-to-point IVIVC with the in vitro release profiles and the predictability of the developed IVIVC was acceptable. Finally, effective therapy was observed in an allergic asthma rat model for the sustained drug release formulations. Overall, the obtained in vitro results correlate well with the systemic drug exposure and the therapeutic performance of the investigated lung-delivered formulations, which can provide an experimental basis for IVIVC development in the pulmonary-controlled delivery system. STATEMENT OF SIGNIFICANCE: Large porous particles (LPPs) are well-known vehicles for drug delivery to the lungs. However, it remains uncertain whether or to which extent the in vitro drug release behavior of LPPs can be predicted by their in vivo performance (e.g., systemic exposure and therapeutic efficacy). With regard to this, three budesonide-loaded PLGA-based LPP formulations with identical composition but distinct in vitro drug release profiles were studied in vivo for their pharmacokinetic and pharmacodynamic behavior, and finally, an in vitro/in vivo correlation (IVIVC) was established. It was demonstrated that the influence of the in vitro drug release profile was obvious during lung retention, systemic exposure, and therapeutic efficacy measurements. An IVIVC (Level A) was successfully established for the budesonide-loaded LPPs delivered to the airspace of rats for the first time. Taken together, the present work will clearly support research and development activities in the field of controlled drug delivery to the lungs.

Sustained therapeutic efficacy of budesonide-loaded chitosan swellable microparticles after lung delivery: Influence of in vitro release, treatment interval and dose.

Sustained drug delivery to the respiratory tract is highly desirable for local treatment of chronic lung diseases. In this context, a correlation of in vitro drug release with in vivo efficacy data is essential to accelerate the application of sustained drug delivery system for inhalation into the clinical setting. In this study, budesonide was incorporated into distinct chitosan-based swellable microparticles, which were characterized, and the in vitro drug release behavior determined. The particles were then given to an allergic asthma animal model as single and successive administrations, and the therapeutic response was determined by measuring cell counts, IL-4 and IL-5 levels in bronchoalveolar lavage fluid, IL-4 and IL-5 mRNA in the lung and by histopathologic examination of lung tissues. After a single administration, the time-dependent therapeutic effect of the swellable microparticles was correlated with the in vitro release behavior, which lasted for 12 or 18 h depending on the molecular weight of the chitosan. After seven days of successive treatment, the number of eosinophils decreased further and IL-4 and IL-5 mRNA expression in the lung tissue was more greatly inhibited. Moreover, the chitosan-based swellable microparticles allowed longer administration intervals (every two days), which decreased the required dose for effectiveness by 50%. These results demonstrate that chitosan-based swellable microparticles can sustain the therapeutic effect of budesonide in the respiratory tract which in principal can be applied to other drugs for the treatment of local lung diseases.

Activity of Brucea javanica oil emulsion against gastric ulcers in rodents.

The present study aims to investigate the gastroprotective effect of Brucea javanica oil emulsion (BJOE) in animals. Gastroprotective potential of BJOE was studied on absolute ethanol, aspirin, reserpine and restraint plus water immersion-induced gastric ulcers in mice as well as glacial acetic acid (GAA) and pyloric ligation (PL)-induced gastric ulcers in rats. Except for ulcer scores, total acidity as well as pepsin activity as for the PL-induced gastric ulcer model and ulcer incidence as for the GAA-induced gastric ulcer model were also determined. Histopathological evaluation as for aspirin, reserpine, PL-induced models was conducted. Results showed that BJOE significantly (P < 0.05) reduced ulcer index in the mouse and rat models in a dose-dependent manner. It had significant (P < 0.05) suppressive effect on total activity of gastric juice as well in PL-induced model. Histopathological examination for the stomach samples confirmed the findings in the aspirin, reserpine or PL-induced gastric lesion models, which showed relatively complete mucosa structure and less inflammation. It is concluded that BJOE could be effective on gastric ulcer in rodents and its gastroprotective activity might be related to antioxidant, anti-inflammatory ability and promote gastric mucus secreted. The results may provide beneficial basis for increasing BJOE's clinical indication in future.

Stimulated CB1 Cannabinoid Receptor Inducing Ischemic Tolerance and Protecting Neuron from Cerebral Ischemia.

BACKGROUND: It is reported that endogenous cannabinoids can cause vasodilation and bradycardia. They have anti-inflammatory effect and protect endothelial cells from injury, therefore they have potential application prospect in the prevention of cardio-cerebrovascular diseases. However, the mechanisms of the neuroprotection mediated by cannabinoid 1 receptors (CB1Rs) have not been uncovered in detail. METHODS: Nearly one hundred of new publications relevant to the theme are almost selected from Pubmed. The advanced details associated with the involvement of CB1R in cerebral ischemia as well as cerebral ischemic tolerance are reviewed. RESULTS: Anandamide system is mainly made up of cannabinoid receptors, their endogenous ligands and some related enzymes. The activation of the system mediates various molecular events so that plays a crucial role in the neuroprotection of cerebral ischemia. Increasing evidences suggest that CB1R is one of key molecules that mediate cerebral ischemia and cerebral ischemia tolerance. It is likely to provide an appropriate antioxidant balance by increasing endogenous free radical scavengers and helpful to exert the neuroprotective effects. Moreover, MAPKs, including ERK1/2, c-Jun Nterminal kinase (JNK) and p38MAPK can be recruited and stimulated through a complex signaling networks mediated by CB1R. Considerable evidences have indicated that CB1R was a crucial regulator for ERK1/2 signaling pathway. It is known that PI3K/Akt is a classical signaling pathway and its activation exerts neuroprotective effect via significant promoting cell survival. Glycogen synthase kinase-3ß (GSK-3ß) is an important downstream target of p-Akt. The PI3K/Akt/GSK-3ß signaling pathway mediated by CB1Rs takes an important part in cerebral ischemic injury. PKC and CB1R are found to be abundantly co-expressed in presynaptic nerve endings of brain. There are considerable reports that different PKC isozymes played vital roles respectively in cerebral ischemic injury and preconditioning. The CB1R -mediated activation of PKCε can effectively stimulate ischemic tolerance. CONCLUSION: CB1R played an important part via several signaling pathways in the protection from ischemic stroke and in ischemic tolerance. The involved molecular signaling pathways include ERK1/2, PI3K/Akt/GSK-3ß and the translocation and activation of PKCε. With the intimate association between CB1R and neuron injuries, to target the receptor will exert neuroprotective effects on cerebral ischemia, which provides wide foreground for a novel therapy target.