Objective To analyze differentially expressed proteins(DEPs)in the hippocampal tissue of an amyloid-beta 1-42(Aβ1-42)-induced Alzheimer's disease(AD)rat model using Tandem mass tag(TMT)-based quantitative proteomics,followed by bioinformatic analysis to explore potential AD mechanisms.Methods Twelve male Sprague-Dawley(SD)rats were randomly assigned to a control group(n=6)and a model group(n=6).The AD model was established by bilateral hippocampal injection of Aβ1-42 in the model group,while the control group received an equivalent volume of saline.Cognitive function was assessed using the novel object recognition test,and hippocampal Aβ deposition was detected by immunofluorescence.DEPs were identified using TMT-based proteomics and subsequently analyzed via Gene Ontology(GO)annotation,Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway enrichment,and protein-protein interaction(PPI)network analysis.Key DEPs were validated using parallel reaction monitoring(PRM)technology.Results The model group exhibited a significantly lower novel object recognition index(P<0.01)and significantly increased hippocampal Aβ deposition(P<0.01)compared to the control group.Proteomic analysis identified 183 DEPs(87 upregulated,96 downregulated).GO analysis revealed that DEPs were primarily enriched in processes such as amyloid-beta binding and ion transmembrane transport.KEGG analysis indicated significant enrichment in 42 pathways,including dopaminergic synapse,glutamatergic synapse,cholinergic synapse,and long-term potentiation.Ten core DEPs were identified from the PPI network,and PRM validation confirmed expression trends consistent with the TMT results.Conclusion Aβ1-42-induced AD involves the synergistic action of multiple targets,biological processes,and pathways.The activation of glutamatergic and dopaminergic synaptic signaling pathways,mediated by core DEPs(e.g.,Th、D1、VGLUT2、GluN2A、GluA1、GluA3、Shank1、DARPP-32、PKC-δ、PKC-α、PKA C-β、CaMKⅡα、PTK2B),likely represents a key molecular mechanism in this AD model,providing a basis for identifying potential therapeutic targets.

Stroke imposes a tremendous burden on patients'families and society due to its high rates of mortality,disability,and recurrence.Advances in neuroimaging technologies have provided critical theoretical foundations for investigating the pathophysiological mechanisms of stroke,as well as enabling early clinical intervention and personalized rehabilitation.This article reviewed the application of five commonly used magnetic resonance imaging(MRI)techniques in acupuncture therapy for stroke,including functional MRI(fMRI)for cerebral blood oxygen metabolism,magnetic resonance spectroscopy(MRS),diffusion MRI(dMRI),perfusion MRI(pMRI),and structural MRI(sMRI).By examining functional,metabolic,structural,and hemodynamic aspects,these imaging modalities offer evidence to validate the multi-target effect and efficacy of acupuncture in stroke treatment.

Objective To analyze differentially expressed proteins(DEPs)in the hippocampal tissue of an amyloid-beta 1-42(Aβ1-42)-induced Alzheimer's disease(AD)rat model using Tandem mass tag(TMT)-based quantitative proteomics,followed by bioinformatic analysis to explore potential AD mechanisms.Methods Twelve male Sprague-Dawley(SD)rats were randomly assigned to a control group(n=6)and a model group(n=6).The AD model was established by bilateral hippocampal injection of Aβ1-42 in the model group,while the control group received an equivalent volume of saline.Cognitive function was assessed using the novel object recognition test,and hippocampal Aβ deposition was detected by immunofluorescence.DEPs were identified using TMT-based proteomics and subsequently analyzed via Gene Ontology(GO)annotation,Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway enrichment,and protein-protein interaction(PPI)network analysis.Key DEPs were validated using parallel reaction monitoring(PRM)technology.Results The model group exhibited a significantly lower novel object recognition index(P<0.01)and significantly increased hippocampal Aβ deposition(P<0.01)compared to the control group.Proteomic analysis identified 183 DEPs(87 upregulated,96 downregulated).GO analysis revealed that DEPs were primarily enriched in processes such as amyloid-beta binding and ion transmembrane transport.KEGG analysis indicated significant enrichment in 42 pathways,including dopaminergic synapse,glutamatergic synapse,cholinergic synapse,and long-term potentiation.Ten core DEPs were identified from the PPI network,and PRM validation confirmed expression trends consistent with the TMT results.Conclusion Aβ1-42-induced AD involves the synergistic action of multiple targets,biological processes,and pathways.The activation of glutamatergic and dopaminergic synaptic signaling pathways,mediated by core DEPs(e.g.,Th、D1、VGLUT2、GluN2A、GluA1、GluA3、Shank1、DARPP-32、PKC-δ、PKC-α、PKA C-β、CaMKⅡα、PTK2B),likely represents a key molecular mechanism in this AD model,providing a basis for identifying potential therapeutic targets.

Stroke imposes a tremendous burden on patients'families and society due to its high rates of mortality,disability,and recurrence.Advances in neuroimaging technologies have provided critical theoretical foundations for investigating the pathophysiological mechanisms of stroke,as well as enabling early clinical intervention and personalized rehabilitation.This article reviewed the application of five commonly used magnetic resonance imaging(MRI)techniques in acupuncture therapy for stroke,including functional MRI(fMRI)for cerebral blood oxygen metabolism,magnetic resonance spectroscopy(MRS),diffusion MRI(dMRI),perfusion MRI(pMRI),and structural MRI(sMRI).By examining functional,metabolic,structural,and hemodynamic aspects,these imaging modalities offer evidence to validate the multi-target effect and efficacy of acupuncture in stroke treatment.

Objective To observe the effects of electroacupuncture on the learning and memory abilities of Alzheimer disease(AD)rats;To explore its potential mechanism based on proteomics.Methods Totally 36 SD male rats were randomly divided into sham-operation group,model group and heart meridian acupoints group,with 12 rats in each group.Aβ1-42 were injected into the bilateral hippocampus to establish AD rat model,the sham-operation group was injected with an equal volume of normal saline.The heart meridian acupoints group received electroacupuncture treatment,accompanied by a stimulation time of 20 minutes,rest for 1 day after 6 days of electroacupuncture for 7 consecutive weeks.The Morris water maze experiment was used to evaluate the learning and memory abilities of AD rats,tandem mass tag(TMT)labeling technology and bioinformatics analysis were used to screen core differentially expressed proteins in important typical pathways,and key differentially expressed protein was verified by parallel reaction monitoring(PRM).Results There was no statistically significant difference in swimming speed between each group of rats(P>0.05).Compared with the sham-operation group,the escape latency of Morris water maze experiment in the model group increased significantly(P<0.01);compared with the model group,the escape latency of heart meridian acupoints group was significantly shortened on the 2-4th day(P<0.01).A total of 209 differentially expressed proteins were identified in different groups using TMT labeling quantification,among which 12 proteins showed significant changes among the 3 groups.GO annotation involved biological processes such as metal ion transport,sodium ion transport,and sodium ion transmembrane transport,as well as cellular components such as synapses,presynapse,and synaptic vesicle,involving solute:sodium symporter activity,organic acid:sodium symporter activity,amino acid:cation symporter activity,amino acid:sodium symporter activity,and other molecular functions;KEGG analysis significantly enriched the synaptic vesicle pathway.The PRM validation results indicated that electroacupuncture at the heart meridian acupoints could reduce the expressions of sodium and chloride dependent GABA transporter protein 3(GAT3),which was consistent with the quantitative detection results of TMT labeling quantification.Conclusion Electroacupuncture at the heart meridian acupoints can improve the learning and memory abilities of AD rats,possibly by regulating the expression of synaptic transporter GAT3 on the synaptic vesicle pathway to exert neuroprotective effects.