Objective To explore the efficacy and action mechanism of a novel phenothiazine derivative,DA414,in rats with intracerebral hemorrhage(ICH).Methods Male Sprague-Dawley(SD)rats(aged 8～10 weeks,weighing 250～300 g)were randomly divided into sham operation,model,and low and high dose DA414 groups[5 and 10 mg/(kg·d)],with 20 animals per group.The size and extent of injury in the ICH area were measured by magnetic resonance imaging(MRI)and histopathological slices.Neurological function was evaluated with a behavioral grading system.Western blotting was used to detect the expression of ferroptosis-related factor,glutathione peroxidase 4(GPX4).Multiplex immunohistochemistry was employed to quantitatively evaluate microglial activation in perihematomal tissue.RT-qPCR was applied to measure the mRNA expression levels of NLRP3 inflammasome components(NLRP3,Caspase-1,IL-1β),pro-inflammatory(IL-18,TLR4,IL-6,TNF-α)and anti-inflammatory cytokines(IL-4,IL-10).The integrity of the blood-brain barrier(BBB)was assessed by Evans blue staining,and the biosafety of DA414 for the liver,kidneys and heart was assessed by HE staining and clinical biochemical tests.Results DA414 significantly promoted the absorption of hematoma,reduced neuronal injury,and improved neurological function scores.DA414 significantly up-regulated the ferroptosis regulatory factor GPX4(P<0.01),and also significantly inhibited the activation of microglia after ICH(P<0.001).RT-qPCR indicated that DA414 treatment resulted in down-regulation of mRNA expression in the inflammasome pathway(NLRP3,Caspase-1,IL-1β,all P<0.01)and pro-inflammatory cytokines(TLR4,IL-6,both P<0.05;IL-18,TNF-α,both P<0.01)and up-regulation of anti-inflammatory cytokines(IL-4,IL-10,both P<0.05),suggesting that DA414 exerts its neuroprotective effect probably by regulating ferroptosis and inflammation.Safety assessment revealed that DA414 had no significant effect on BBB integrity or damage to the liver,kidneys,and heart in rats.Conclusion DA414 exerts significant neuroprotective effects in ICH model by targeted inhibition for ferroptosis and modulating inflammatory response.Our study provides an experimental foundation for ICH treatment.

Objective To investigate the neural basis of glucagon-like peptide-1(GLP-1)in regulating glucose homeostasis and elucidate the molecular mechanisms.Methods Male Glp1r-IRES-Cre,Glp1r-KO,and wild-type mice were used in this study.Fiber photometry was employed to record Ca2+signals of neurons in ventromedial hypothalamus(VMH)and patch-clamp was used to analyze electrophysiological properties of GLP-1 receptor-positive(GLP-1RVMH)neurons.Viral stereotaxic injections,chemogenetics,plasma hormone assays,and routine glucose metabolism assessments were combined to determine the regulatory role of GLP-1RVMH neurons in glucose homeostasis.Tissue and cell mitochondrial respiratory function assays,transmission electron microscopy,and conventional molecular biology methods were used to explore the mechanism by which GLP-1R agonists regulate glucose homeostasis.Results When the glucose concentration decreased from 5.0 mmol/L to 0.5 mmol/L,the action potential frequency of GLP-1RVMH neuron decreased significantly[(4.51±0.80)Hz vs.(1.43±0.51)Hz,P<0.01].Activation of GLP-1RVMH neuron significantly enhanced insulin secretion[(7.60±0.56)μU/mL vs.(11.34±0.93)μU/mL,P<0.01],while inhibition of these neuronal activities impaired the hypoglycemic efficiency of GLP-1 agonists[(32.03%±0.91%)vs.(25.77%±1.09%),P<0.001)].Mechanistically,GLP-1 regulated glucose homeostasis through Drp1 phosphorylation-mediated mitochondrial fission and improved mitochondrial energy metabolism.Conclusion GLP-1RVMH neurons are a class of glucose-excited neurons,and which activated directly promotes secretion of insulin.The hypoglycemic effect of GLP-1R agonists depend on the neuronal activity of GLP-1RVMH.

Objective:To preliminarily investigate the safety and efficacy of programmed death-1(PD-1)inhibitor combined with cord blood-derived natural killer cells(NK cells)in the treatment of advanced malignant solid tumors in an exploratory clinical trial.Methods:Three patients with advanced solid tumors treated at the Second Affiliated Hospital of Xi'an Medical University from December 2019 to December 2021 were enrolled.According to tumor type and CSCO guidelines,patients received multiple treatment cycles(21 days per cycle)consisting of standard chemotherapy,targeted therapy,or bevacizumab combined with PD-1 inhibitor.Umbilical cord blood-derived NK cells(8×107 cells per infusion)were infused at appropriate intervals during the treatment course.Target lesion size,tumor markers,levels of 12 peripheral blood cytokines,and lymphocyte subsets were assessed in each treatment cycle.Adverse events were also monitored throughout the treatment.Results:Following the treatment with PD-1 inhibitor combined with cord blood NK cells,2 patients achieved stable disease(SD,per RECIST 1.1 criteria),with durations of 118 days and 92 days,respectively.After NK cell infusion,patient#1 exhibited a marked decrease in the tumor marker CA199 to normal range and sustained for three follow-up periods;patient#2 showed significant reductions in tumor markers CA199,CA242,and CA724.Conclusion:The combination of NK cells with chemotherapy and PD-1 inhibitor demonstrates potential therapeutic efficacy for solid tumors.No severe immune-related adverse reactions were observed in the three patients enrolled in this study.

Objective To investigate the neural basis of glucagon-like peptide-1(GLP-1)in regulating glucose homeostasis and elucidate the molecular mechanisms.Methods Male Glp1r-IRES-Cre,Glp1r-KO,and wild-type mice were used in this study.Fiber photometry was employed to record Ca2+signals of neurons in ventromedial hypothalamus(VMH)and patch-clamp was used to analyze electrophysiological properties of GLP-1 receptor-positive(GLP-1RVMH)neurons.Viral stereotaxic injections,chemogenetics,plasma hormone assays,and routine glucose metabolism assessments were combined to determine the regulatory role of GLP-1RVMH neurons in glucose homeostasis.Tissue and cell mitochondrial respiratory function assays,transmission electron microscopy,and conventional molecular biology methods were used to explore the mechanism by which GLP-1R agonists regulate glucose homeostasis.Results When the glucose concentration decreased from 5.0 mmol/L to 0.5 mmol/L,the action potential frequency of GLP-1RVMH neuron decreased significantly[(4.51±0.80)Hz vs.(1.43±0.51)Hz,P<0.01].Activation of GLP-1RVMH neuron significantly enhanced insulin secretion[(7.60±0.56)μU/mL vs.(11.34±0.93)μU/mL,P<0.01],while inhibition of these neuronal activities impaired the hypoglycemic efficiency of GLP-1 agonists[(32.03%±0.91%)vs.(25.77%±1.09%),P<0.001)].Mechanistically,GLP-1 regulated glucose homeostasis through Drp1 phosphorylation-mediated mitochondrial fission and improved mitochondrial energy metabolism.Conclusion GLP-1RVMH neurons are a class of glucose-excited neurons,and which activated directly promotes secretion of insulin.The hypoglycemic effect of GLP-1R agonists depend on the neuronal activity of GLP-1RVMH.