Yiqi Yangxin Anshen Oral Liquid (YQYX) is a multi-herbs compound derived from the ancient Chinese formulae Suanzaoren Decoction and Guipi Tang. It has been clinically used to treat insomnia and anxiet Show more
Yiqi Yangxin Anshen Oral Liquid (YQYX) is a multi-herbs compound derived from the ancient Chinese formulae Suanzaoren Decoction and Guipi Tang. It has been clinically used to treat insomnia and anxiety for nearly three decades. To evaluate the efficacy of YQYX and to elucidate its therapeutic mechanisms in mitigating pathological changes induced by sleep deprivation (SD). Chemical constituents and serum-absorbed components were characterized using UHPLC-Orbitrap-MS/MS. Network pharmacology was employed to predicted therapeutic targets. PCPA-induced SD rats underwent pentobarbital-induced sleep test, Morris water maze, and open field test. Serum inflammatory cytokines were measured by ELISA, and hypothalamic neurotransmitters were quantified using a validated UHPLC-QQQ-MS/MS method. Hippocampal damage was evaluated by H&E and NeuN immunofluorescence, and cAMP/PKA/CREB/BDNF pathway was studied by Western blot and immunofluorescence. LC-MS identified 102 chemical constituents and 49 serum-absorbed components in YQYX. Network pharmacology analysis based on the serum-absorbed components predicted the cAMP signaling pathway as a key therapeutic target. YQYX significantly ameliorated SD-induced sleeplessness effects, spatial learning-memory impairments, and anxiety-like behaviors. It also reduced serum levels of IL-1β, TNF-α, and IL-6. Notably, YQYX restored hypothalamic neurotransmitters homeostasis (serotonin, dopamine, histamine, and acetylcholine). Histological analysis showed that YQYX prevented SD-induced hippocampal damage. Moreover, YQYX upregulated the cAMP/PKA/CREB/BDNF signaling pathway. YQYX exhibits multi-target therapeutic effects by maintaining neurotransmitter homeostasis, protecting hippocampal neurons, and activating neuroplasticity pathways, thereby validating its ethnopharmacological basis for treating sleep disorders. Show less
Microplastic (MPs) pollution is widespread in the environment and poses growing risks to food safety and human health. In a 60-day oral exposure study, male Swiss mice received MPs (10 mg/kg b.wt), an Show more
Microplastic (MPs) pollution is widespread in the environment and poses growing risks to food safety and human health. In a 60-day oral exposure study, male Swiss mice received MPs (10 mg/kg b.wt), and the neuroprotective potential of taurine (Tau, 200 mg/kg b.wt) was evaluated. MPs exposure induced pronounced anxiety-like behavior, evidenced by increased peripheral zone activity in the open field test (+ 81.1%) and elevated anxiety index in the elevated plus maze (+ 75.9%), along with significant memory and spatial learning impairments in the Y-maze (increased trials + 31.6% and latency + 75.2%). Neurochemically, MPs increased acetylcholinesterase (AChE) activity (+ 89.4%) while reducing dopamine (-29.4%) and γ-aminobutyric acid (GABA) (-17.9%) levels. MPs also triggered marked oxidative stress, as shown by elevated reactive oxygen species (+ 107.6%) and malondialdehyde (+ 249.0%), accompanied by reduced total antioxidant capacity (-26.2%). At the molecular level, MPs downregulated CREB1 (-82.2%) and BDNF (-80.2%) while markedly upregulating AKT1 (~ fivefold) and pro-inflammatory cytokines (TNF-α, IL-6, CXCL-10, and IL-1β; 5.2-7.2-fold). Histopathological analysis revealed severe neurodegenerative alterations across the cerebrum, hippocampus, and cerebellum. Tau co-treatment significantly ameliorated MPs' induced neurotoxicity by reducing anxiety and memory deficits, lowering AChE activity (- 17.3%), restoring dopamine (+ 28.8%) and GABA (+ 14.2%) levels, attenuating oxidative stress (ROS -45.4% and MDA -44.7%), suppressing inflammatory gene expression (-51.0 to -68.1%), and partially normalizing CREB1 and BDNF expression (+239% and +240%, respectively). Collectively, these findings identify Tau as a promising natural neuroprotective agent against MPs' induced neurotoxicity. Show less
For decades, major depressive disorder was attributed to a deficit in monoamine neurotransmitters. Clinical latency of tricyclic and selective serotonin reuptake inhibitors, high nonresponse rates, an Show more
For decades, major depressive disorder was attributed to a deficit in monoamine neurotransmitters. Clinical latency of tricyclic and selective serotonin reuptake inhibitors, high nonresponse rates, and inconsistent genetic findings challenged this view and redirected research toward downstream biology. Preclinical work revealed that chronic stress triggers dendritic and spine loss in the hippocampus and prefrontal cortex, whereas all effective treatments-including slow-acting monoaminergic drugs, rapid-acting ketamine, electroconvulsive therapy, and aerobic exercise-restore synapse number and function through brain-derived neurotrophic factor, TrkB, and mTOR signaling. Human connectomic studies then reframed depression as a disorder of mistimed large-scale networks; targeted neuromodulation of nodes intrinsically anticorrelated with the subgenual cingulate provides proof of concept. Parallel findings in immunology and gut-brain science show that psychosocial stress, peripheral cytokines, and metabolic cues converge on the same plasticity pathways, dissolving the historical boundary between "reactive" and "endogenous" depression. Ketamine crystallizes this multiscale model: within minutes, it induces dendritic-spine formation, normalizes default-mode and limbic connectivity, and relieves symptoms within hours. We synthesize these lines of evidence into a framework of precision synaptic psychiatry, in which pharmacological, neuromodulatory, and lifestyle interventions are selected according to biomarkers that index glutamatergic tone, inflammatory load, or network dynamics. Future therapeutics will be judged less by the neurotransmitters they influence and more by their capacity to restore flexible, resilient brain circuitry. Show less