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Frontiers In Cellular Neuroscience[JOURNAL]

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Altered lipid peroxidation, perineuronal net and oligodendrocyte markers in the frontal cortex of a dual-hit neurodevelopmental model support its relevance to schizophrenia.

Esuaikoh V, Ibegbulam S, Cook A … +6 more , McFarland B, Nunnington N, Perera A, Feng J, Cale JA, King MV

Front Cell Neurosci · 2026 · PMID 41918881 · Full text

INTRODUCTION: The pathogenesis of schizophrenia begins in early neurodevelopment and leads to an array of frontal cortical deficits. They include redox dysregulation, white matter perturbation, loss of perineuronal nets... INTRODUCTION: The pathogenesis of schizophrenia begins in early neurodevelopment and leads to an array of frontal cortical deficits. They include redox dysregulation, white matter perturbation, loss of perineuronal nets (PNNs) and reduced synaptic density. It is therefore highly desirable that preclinical models used to understand disease, select drug targets and evaluate novel therapeutics encompass similar changes. One approach to improved preclinical modeling incorporates dual-hit neurodevelopmental interventions, like neonatal administration of phencyclidine (PCP, to disrupt development of glutamatergic circuitry) then post-weaning isolation (Iso, to mimic adolescent social stress). We recently showed that rats exposed to PCP-Iso develop GABAergic and inflammatory changes in the frontal cortex, and the current study expands on this by comparing changes to additional cellular and extracellular matrix markers relevant to oxidative stress, myelination, PNN integrity and synaptic vesicle density. METHODS: The study used tissue from a previously described cohort of male Lister-hooded rats. They received saline vehicle (Veh, 1 ml/kg s.c.) or PCP (10 mg/kg s.c) on postnatal days (PND) 7, 9 and 11 then were housed in social groups (Gr, 3-4/cage) or post-weaning isolation from PND 21 onwards. Declarative memory was assessed in adulthood (PND 57-80) using a novel object discrimination (NOD) test. Frontal cortical samples were obtained on PND 79-80 and used for immunohistochemical or lectin binding examinations of the lipid peroxidation product 4-hydroxynonenal (4-HNE), oligodendrocyte-associated protein 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNPase), PNNs and synaptic vesicle glycoprotein 2A (SV2A) throughout the orbitofrontal, prelimbic and infralimbic cortices. In each case data from dual-hit PCP-Iso and single-hit Veh-Iso were compared to each other, and to data from Veh-Gr controls. RESULTS: Single-hit isolation-reared and dual-hit PCP-Iso both showed impaired declarative memory. They also both exhibited reduced PNN density in the orbitofrontal cortex and reduced PNN thickness in the prelimbic/infralimbic cortex. However, PCP-Iso showed additional PNN thinning, 4-HNE upregulation and CNPase downregulation in orbitofrontal regions. DISCUSSION: These findings enhance the face validity of PCP-Iso and support wider use of this preclinical model for evaluating novel therapeutics designed to support parvalbumin-positive neurons and PNNs, promote myelination or normalize redox dysregulation. Unaltered SV2A expression in young adult PCP-Iso mirrors recent dorsolateral prefrontal cortical findings in first-episode psychosis, supports expectations that increased microglial activation precedes aberrant synaptic pruning, and justifies further examinations of synaptic markers in PCP-Iso at later developmental stages.

Glial D-serine modulates oligodendrocyte lineage progression under inflammatory conditions.

Espinoza JP, Cisterna I, Triviño JJ … +2 more , Arancibia V, Beltrán-Castillo S

Front Cell Neurosci · 2026 · PMID 41918880 · Full text

Inflammatory environments may shape oligodendrocyte lineage dynamics beyond classical cytokine signaling, in part through the release of glial neuromodulators. Here, we investigated whether inflammation-associated D-seri... Inflammatory environments may shape oligodendrocyte lineage dynamics beyond classical cytokine signaling, in part through the release of glial neuromodulators. Here, we investigated whether inflammation-associated D-serine signaling modulates oligodendrocyte lineage progression. Using highly purified primary oligodendrocyte precursor cell (OPC) cultures, we show that D-serine exposure during late differentiation reduces the proportion of OLIG2 and myelin basic protein-positive (MBP) cells without altering net cell number, while selectively decreasing apoptosis within the mature MBP population. These findings indicate that D-serine attenuates late-stage lineage progression while preserving oligodendrocyte survival . In parallel, inflammatory activation of mixed glial cultures with lipopolysaccharide (LPS) increased tumor necrosis factor- release, upregulated serine racemase expression, and elevated extracellular D-serine levels. Conditioned media from reactive glial cultures recapitulated the effects of D-serine on OPC maturation, which were prevented by enzymatic degradation of D-serine or pharmacological blockade of N-methyl-D-aspartate receptors (NMDARs). Together, these findings support the involvement of glia-derived D-serine as a modulatory signal influencing oligodendrocyte lineage progression consistent with NMDAR-dependent mechanisms under inflammatory conditions that may contribute to impaired remyelination.

Correction: Advances in astrocytic calcium signaling research.

Chen Y, Ye Y, Jia J … +3 more , Long B, Dou T, Yan X

Front Cell Neurosci · 2026 · PMID 41918879 · Full text

[This corrects the article DOI: 10.3389/fncel.2025.1719532.]. [This corrects the article DOI: 10.3389/fncel.2025.1719532.].

Function of the large intestine and its interaction with the brain after ischemic stroke: a comprehensive literature review.

Jia X, Simo L, Rosenfeld S … +4 more , Li F, Zhou Y, Ding Y, Geng X

Front Cell Neurosci · 2026 · PMID 41909488 · Full text

The large intestine, part of the distal gastrointestinal tract, is vital for water and electrolyte absorption and microbial fermentation. It is also a significant immune organ endowed with an extensive and intricate neur... The large intestine, part of the distal gastrointestinal tract, is vital for water and electrolyte absorption and microbial fermentation. It is also a significant immune organ endowed with an extensive and intricate neural network. Intestinal epithelial cells are essential for endocrine regulation and maintaining the integrity of the intestinal barrier. Stroke, a leading cause of adult mortality and disability, occurs when there is a lack of oxygen to the brain and involves complex cerebrovascular dynamics that significantly impact systemic functions. In this framework, the gut-brain axis-the bidirectional circuitry connecting the gut and the central nervous system (CNS)-emerges as a critical interface. This review examines the immunological, neurological, endocrine, and barrier functions of the large intestine and explores its interplay with stroke pathophysiology. By detailing the interrelation between stroke and large intestinal functions, this paper aims to provide a foundational reference for advancing research into their intertwined mechanisms and identifying potential therapeutic targets.

Neurovascular dysfunction in the development and progression of neuroinflammatory diseases.

Gowdy J, Ahn J, Miller RH … +1 more , Islam Y

Front Cell Neurosci · 2026 · PMID 41909487 · Full text

The neurovascular unit (NVU) is critical for brain homeostasis through its roles in maintenance of an effective blood brain barrier (BBB) and regulation of cerebral blood flow. Perturbation of the NVU is a hallmark of th... The neurovascular unit (NVU) is critical for brain homeostasis through its roles in maintenance of an effective blood brain barrier (BBB) and regulation of cerebral blood flow. Perturbation of the NVU is a hallmark of the pathology of multiple neurodegenerative diseases resulting in loss of BBB integrity, neuroinflammation and neuronal dysfunction. The NVU is a complex structure composed of endothelial cells, pericytes, as well as central nervous system (CNS) glial and neuronal components. While the importance of the CNS vasculature in health and disease is well established, the mechanisms underlying vascular pathology and its contributions to neurodegenerative diseases are less well defined. Neuroinflammation and reactive gliosis occurs in the majority of neurodegenerative diseases and recent studies suggest that immune mediated disruption of the BBB contributes to the induction of reactive gliosis and neuronal dysfunction. Potential consequences of NVU disruption include immune-driven vascular inflammation and leukocyte infiltration in Multiple Sclerosis (MS), protease-mediated tight junction degradation in ischemic stroke (IS), -synuclein-associated endothelial dysfunction in Parkinson's Disease (PD), amyloid-- and tau-induced pericyte injury in Alzheimer's Disease (AD), and complement-mediated vascular damage in Amyotrophic Lateral Sclerosis (ALS). Here we review the nature of NVU perturbations in these common neurodegenerative diseases, with an emphasis on the contribution of immune modulation of BBB disruption in neuropathology and disease progression.

Silencing MALAT1 represses pathological progression, inflammation, and vascular smooth muscle cell phenotype switching by regulating the SEMA3C-mediated Smad pathway in intracranial aneurysms.

Kang J, Li W, Gao X … +9 more , Tian X, Feng W, Yao X, Wei F, Chen L, Chen H, Tong J, Chen E, Gu Y

Front Cell Neurosci · 2026 · PMID 41890214 · Full text

BACKGROUND: The crucial role of metastasis-associated lung adenocarcinoma transcript 1 (MALAT1) in regulating aneurysm formation, inflammation, and neural dysfunction has gradually been recognized. This study aimed to ev... BACKGROUND: The crucial role of metastasis-associated lung adenocarcinoma transcript 1 (MALAT1) in regulating aneurysm formation, inflammation, and neural dysfunction has gradually been recognized. This study aimed to evaluate the effects of MALAT1 modification on pathological changes, inflammation, vascular smooth muscle cell (VSMC) phenotype switching, and the underlying mechanism in intracranial aneurysms (IAs). METHODS: MALAT1-overexpressing (oeMALAT1), MALAT1 short hairpin (shMALAT1), and semaphorin 3C (SEMA3C)-overexpressing (oeSEMA3C) lentiviruses were transfected alone or in combination into basilar artery VSMCs originating from IA rats. These lentiviruses were then stereotactically injected into IA rats. RESULTS: , the overexpression of MALAT1 inhibited cell proliferation while promoting cell apoptosis and invasion; the release of TNF-α, IL-1β, and IL-6; and the transformation of IA basilar artery VSMCs from the contractile type to the synthetic type. However, the silencing of MALAT1 had the opposite effect. The silencing of MALAT1 downregulated SEMA3C, and its silencing inactivated the Smad pathway. Furthermore, SEMA3C overexpression attenuated the effects of MALAT1 silencing on IA basilar artery VSMC proliferation, apoptosis, invasiveness, proinflammatory cytokines, phenotype switching, and Smad pathway inactivation. , silencing MALAT1 reduced the release of TNF-α, IL-1β, and IL-6, decreased pathological progression, inhibited VSMC synthetic type switching, and inactivated the Smad pathway in IA rats. However, the overexpression of SEMA3C reversed these effects. CONCLUSION: Silencing MALAT1 represses pathological progression, inflammation, and VSMC phenotype switching by regulating the SEMA3C-mediated Smad pathway in IA.

Preclinical models of stem cell-mediated analgesia and tissue repair: mechanisms, challenges, and future directions.

Zhu M, Zhang H, Liang L … +2 more , Wu S, Chen J

Front Cell Neurosci · 2026 · PMID 41890213 · Full text

As an emerging biological therapeutic approach, stem cell therapy demonstrates broad application prospects in analgesia and tissue regeneration, particularly achieving significant advances in treating conditions such as... As an emerging biological therapeutic approach, stem cell therapy demonstrates broad application prospects in analgesia and tissue regeneration, particularly achieving significant advances in treating conditions such as spinal cord injury and intervertebral disc degeneration. In recent years, preclinical model studies have deepened our understanding of the mechanisms underlying stem cell-mediated pain relief and tissue repair, revealing their potential to regulate inflammatory responses, promote nerve regeneration, and repair damaged tissues through multiple pathways. However, the heterogeneity of preclinical models and the discrepancies between these models and clinical practice, coupled with often insufficient critical appraisal of study quality, remain critical issues requiring urgent resolution in this field. This narrative review systematically summarizes the fundamental theories and key mechanisms underlying stem cell-mediated analgesia and regeneration. It comprehensively evaluates the advantages and limitations of different animal models, critically analyzes major controversies and technical challenges in research, and identifies key directions for future studies. The literature discussed herein was identified through searches in PubMed and Web of Science databases, focusing on recent preclinical studies (primarily within the last decade) involving stem cells, pain models, and tissue regeneration. Selected studies were evaluated for their methodological rigor and contribution to mechanistic understanding. This review aims to synthesize current evidence, critically appraise preclinical models, and provide a forward-looking perspective for research on stem cell-related analgesia and regenerative mechanisms, thereby promoting further development in clinical translation.

Reduced peripheral serotonin levels in women with multiple sclerosis: associations with underweight status, treatment duration, and use of interferon beta 1a.

Pérez-Sánchez G, Aguilar-Gómez LA, Vela-Sancho GB … +9 more , Jacinto-Gutiérrez S, Becerril-Villanueva E, Alvarez-Herrera S, Vallejo-Castillo L, Reyes-Mata MP, Mireles-Ramírez MA, Guerrero-García JJ, Ortuño-Sahagún D, Pavón L

Front Cell Neurosci · 2026 · PMID 41890212 · Full text

Multiple sclerosis (MS) is a chronic autoimmune-mediated demyelinating disease of the CNS, characterized by neuroinflammatory, axonal degeneration, and pronounced sexual dimorphism. Experimental data implicate dysregulat... Multiple sclerosis (MS) is a chronic autoimmune-mediated demyelinating disease of the CNS, characterized by neuroinflammatory, axonal degeneration, and pronounced sexual dimorphism. Experimental data implicate dysregulated 5-HT levels in MS. However, the effects of clinical parameters and disease-modifying-therapies (DMTs) on peripheral 5-HT concentrations remain underexplored. This study aimed to quantify peripheral levels of tryptophan (Trp), 5-HT, and 5-hydroxyindoleacetic acid (5-HIAA) in patients with relapsing-remitting MS (RRMS) and to assess the effects of BMI, DMT duration, and specific DMT regimens. In this cross-sectional analysis, 226 participants were enrolled and stratified into four groups: healthy men (HM;  = 29), healthy women (HW;  = 84), men with RRMS (MMS;  = 29), and women with RRMS (WMS;  = 84). Serum concentrations of Trp, 5-HT, and 5-HIAA were measured using reverse-phase high-performance liquid chromatography (HPLC) with fluorescence detection. Nonparametric statistical tests were applied. Peripheral 5-HT levels were significantly reduced in underweight WMS (BMI < 18 kg/m;  < 0.05), WMS with DMT duration over 4 years ( < 0.01), and WMS receiving interferon beta-1a ( < 0.01) compared to HW. No significant intergroup differences in Trp or 5-HIAA were observed across all stratifications. These findings reveal a novel association between reduced peripheral 5-HT and specific clinical-therapeutic factors in WMS, extending recent MS research on sex-specific vulnerabilities, serotonergic dysregulation in neuroinflammation, and psychiatric comorbidity. By highlighting the influence of low BMI, prolonged DMT exposure, and interferon beta-1a on 5-HT homeostasis, this study underscores the need for multidisciplinary management integrating neurological and psychiatric care in WMS and suggests avenues for precision interventions targeting serotonergic pathways to reduce disease burden.

Microglia-derived metabolites as novel signaling molecules: regulating neural circuit function, behavior, and their role in psychiatric disorders.

Li J, Zhao Y

Front Cell Neurosci · 2026 · PMID 41890211 · Full text

Microglia, central immune and metabolic regulators, release metabolites that act as signaling molecules into the interstitial space within the neuro-immune-metabolic axis (NIMA). This review synthesizes evidence on how m... Microglia, central immune and metabolic regulators, release metabolites that act as signaling molecules into the interstitial space within the neuro-immune-metabolic axis (NIMA). This review synthesizes evidence on how microglia-derived metabolites modulate neural circuit function-affecting synaptic plasticity, network oscillations, and behavior-and how their dysregulation contributes to psychiatric disorders. We highlight the dynamic role of the interstitial space in shaping metabolite signaling and discuss therapeutic strategies targeting this axis. Reconceptualizing microglial metabolites as active circuit modulators offers novel insights into psychiatric pathophysiology and potential metabolic interventions.

Predicting stroke-associated infection in acute ischemic stroke patients treated by thrombolysis.

Yu X, Wang Z, Chen D … +11 more , Li S, Gao H, Zhao W, Ji Z, Han Z, Sun R, Cai S, Jiang Z, Du S, Hermann DM, Liu Y

Front Cell Neurosci · 2026 · PMID 41884174 · Full text

BACKGROUND: Acute ischemic stroke (AIS) remains one of the major contributors to mortality and disability worldwide. Stroke-associated infection (SAI) is one of the most frequent complications following AIS and has a sub... BACKGROUND: Acute ischemic stroke (AIS) remains one of the major contributors to mortality and disability worldwide. Stroke-associated infection (SAI) is one of the most frequent complications following AIS and has a substantial impact on clinical outcomes, being closely linked to unfavorable prognosis. This study aimed to provide a comprehensive description of SAI, identify independent risk factors, and develop a predictive nomogram for its early identification. METHODS: This study included 836 AIS patients of the Dalian Single-center Study on Intravenous Thrombolysis for Ischaemic Stroke (DATIS) cohort who received recombinant tissue-plasminogen activator-induced thrombolysis at Central Hospital of Dalian University of Technology between January 2018 and November 2021. Patients were divided into a training cohort ( 586, 70%) and a validation cohort ( 250, 30%). Composition and economic features of SAI was explored. Independent risk factors were identified using univariate, multivariate, and multimodal logistic regression analyses. A predictive nomogram was then developed based on these independent risk factors. Model performance was assessed with receiver operating characteristic curves, and calibration curves. RESULTS: Among the 836 enrolled patients, 168 (20.1%) developed SAI. Composition of 168 patients with SAI were: 99 pulmonary infections (58.93%), 44 upper respiratory tract infections (26.19%), 15 urinary tract infection (8.93%), 2 gastrointestinal tract infections (1.19%), 1 periodontal infection (0.60%), 1 conjunctival infection (0.60%), and 1 erysipela (0.60%). In addition, 5 patients (2.98%) had multi-site infections (4 pulmonary plus urinary tract infection, 1 pulmonary plus gastrointestinal tract infection). Compared with non-infected patients, the SAI group experienced a significantly longer median hospitalization duration [9 days, IQR (7, 10) vs. 8 days, IQR (7, 9),  0.001] and incurred higher median inpatient medical costs [28114.04 RMB, IQR (23230.12, 33379.85) vs. 22292.84 RMB, IQR (19203.53, 25999.63),  0.001]. Five variables-higher modified Rankin Scale at admission, male sex, prolonged prothrombin time, elevated blood urea nitrogen and lower thyroid-stimulating hormone-were independent risk factors for SAI. The nomogram constructed based on above predictors achieved an area under the curve of 0.80 in the training cohort and 0.72 in the validation cohort. Calibration curves supported the model's performance. CONCLUSION: This prospective cohort study comprehensively described composition and economic features, identified risk factors and developed predictive nomogram for SAI in AIS patients receiving intravenous rt-PA. Early identification of high-risk patients may facilitate targeted interventions, potentially reducing infection-related complications and improving clinical outcomes.

Focal cortical dysplasias: modeling pediatric drug-resistant epilepsy using human brain organoids.

Petralla S, Crocco E, Giustizieri M … +6 more , De Palma L, Cremisi F, Cherubini E, Specchio N, Cattaneo A, Marinelli S

Front Cell Neurosci · 2026 · PMID 41884173 · Full text

Epilepsy is a prevalent neurological disorder characterized by recurrent, unprovoked seizures and altered electroencephalographic patterns. This condition is viewed as a malfunctioning of extensive neural networks due to... Epilepsy is a prevalent neurological disorder characterized by recurrent, unprovoked seizures and altered electroencephalographic patterns. This condition is viewed as a malfunctioning of extensive neural networks due to an imbalance of excitatory and inhibitory signals leading neurons to be excessively excitable and to abnormal synchronized electrical activity. Despite the growing number of new antiepileptic drugs, patients suffering from drug-resistant forms of epilepsy do not respond to pharmacological treatment, and the only effective cure remains the neurosurgical resection of the epileptic focus. Nevertheless, several patients fail to achieve seizure freedom after surgical resection. This emphasizes the urgent need for novel human-relevant models to explore the mechanisms underlying drug-refractory forms of epilepsy. While acute and organotypic slices from resected neurological tissue offer a promising method for studying patient-derived brain tissue mechanisms, this technique is limited by its inherently low throughput and challenges in obtaining appropriate control tissue. Recent advances in organoid technology have allowed for the generation of cerebral dorsal/ventral assembloids, which more accurately model the functional connectivity between excitatory and inhibitory neurons and recapitulate key aspects of cortical circuits. This review summarizes current knowledge on the use of human brain organoids and assembloids to model epilepsy, with a particular focus on organoids harboring focal cortical dysplasia-linked mutations. Human brain organoids and assembloids will allow addressing an important question in the field, namely the relative contribution of neurodevelopmental defects vs. those arising at later stages of CNS development. Limitations of this "neuron-only" model and potential ways to include non-neuronal cells will also be discussed. Finally, we highlight recent advances in employing these new powerful platforms for investigating network dysfunctions underlying FCDs, screening potential antiepileptic drug candidates, and developing personalized therapeutic strategies.

The mesencephalic trigeminal neuron: electrophysiological insights into function and dysfunction.

Seki S, Enomoto A, Tanaka S

Front Cell Neurosci · 2026 · PMID 41884172 · Full text

Mesencephalic trigeminal neurons (MTNs) are the sole primary afferent neurons with cell bodies located within the central nervous system. MTNs convey proprioceptive inputs from masticatory muscles and periodontal ligamen... Mesencephalic trigeminal neurons (MTNs) are the sole primary afferent neurons with cell bodies located within the central nervous system. MTNs convey proprioceptive inputs from masticatory muscles and periodontal ligaments, thereby contributing to the precise regulation of jaw-oral motor functions. Through ionic mechanisms such as currents generated by the voltage-dependent sodium (Nav) channel isoform Nav1.6, hyperpolarization-activated currents, and persistent inward currents, MTNs generate sustained and burst firing that regulate masticatory rhythm and jaw-jerk reflex timing. Their activity is further modulated by neurotransmitters, including serotonin and norepinephrine, which provide flexibility in sensorimotor integration. Pathological conditions such as chronic stress and sodium channel dysfunction induce MTN hyperexcitability or irregular firing, contributing to bruxism, temporomandibular disorders, and feeding impairment in amyotrophic lateral sclerosis models. In addition, aging and tooth loss lead to Piezo2 downregulation and neuronal death, potentially resulting in masticatory dysfunction and cognitive decline. Recent findings suggest that interventions targeting vesicular glutamate transporter 1 projections, melanocortin 4 receptor signaling, and nitric oxide pathways represent novel therapeutic approaches. Taken together, MTNs have emerged as promising targets for treating conditions ranging from masticatory motor disorders to neurodegenerative diseases.

Developmental stage-dependent neurotoxicity of sevoflurane: evidence from brain organoids.

Chen N, Zhang Y, Chen Y … +1 more , Chen G

Front Cell Neurosci · 2026 · PMID 41878540 · Full text

Sevoflurane is widely used in pediatric anesthesia because it allows rapid induction and recovery, yet its use during vulnerable periods of brain development has raised concerns about long-term neurocognitive effects. Ex... Sevoflurane is widely used in pediatric anesthesia because it allows rapid induction and recovery, yet its use during vulnerable periods of brain development has raised concerns about long-term neurocognitive effects. Experimental data indicate that sevoflurane engages multiple interacting pathways, including mitochondrial dysfunction, oxidative and iron-dependent injury, and immune-mediated synaptic and inflammatory responses, whose net impact depends on dose, timing, and exposure duration. Human brain organoids have meanwhile emerged as human-based three-dimensional models that reproduce key aspects of cortical and midbrain development and permit clinically relevant exposure paradigms to be tested . In both cortical-like and midbrain-like organoids, sevoflurane narrows and disorganizes progenitor zones, disrupts interkinetic nuclear migration, reduces apical mitoses, and accelerates neuronal or dopaminergic differentiation, with more pronounced changes after more intense exposure. These architectural alterations are accompanied by molecular and electrophysiological signatures of mitochondrial stress, iron dysregulation, and inflammatory activation, forming multidimensional "injury fingerprints" that parallel clinical observations that single, brief anesthetics rarely cause overt global decline, whereas repeated or prolonged anesthetics are associated with subtler, domain-specific deficits. This review synthesizes current evidence on the developmental stage-dependent effects of sevoflurane and highlights how brain organoids are being used to dissect underlying cellular and molecular mechanisms. It also discusses key limitations of current organoid systems and considers how more mature, vascularized, and microglia-containing models, integrated with perioperative cohorts and targeted interventions, may eventually inform exposure-aware anesthetic planning without delaying necessary surgery. Overall, this review advances a developmental stage-aware, organoid-centered conceptual framework that integrates animal and human-based evidence to better understand and stratify the risk of sevoflurane-induced neurotoxicity.

Molecular and developmental insights into proprioceptive identity in the mesencephalic trigeminal nucleus neurons.

Lee PR, Oh SB

Front Cell Neurosci · 2025 · PMID 41878294 · Full text

The mesencephalic trigeminal nucleus (MTN) contains trigeminal proprioceptive neurons, a unique class of primary sensory neurons with centrally located cell bodies and a developmental origin distinct from that of periphe... The mesencephalic trigeminal nucleus (MTN) contains trigeminal proprioceptive neurons, a unique class of primary sensory neurons with centrally located cell bodies and a developmental origin distinct from that of peripheral ganglion-derived spinal proprioceptors. MTN neurons have long been recognized for their morphological heterogeneity, but their functions were traditionally viewed as confined to the jaw jerk reflex and oromotor control, reflecting their predominant innervation of jaw-closing muscles. Recent single-cell transcriptomic studies have provided new insight into MTN neurons by uncovering molecular determinants of proprioceptive identity, revealing discrete transcriptional programs that underlie their developmental trajectories and functional specialization. While some subsets of MTN neurons share features with Group Ia and II proprioceptors, they are distinguished by characteristic molecular signatures, including the absence of , differential and expression, and broader transcriptional features that are not observed in classical spinal counterparts. Accumulating evidence also supports a functional role for MTN neurons in the behavioral transition from suckling to mastication during the weaning period in mammals. In this review, we integrate anatomical, molecular, and functional perspectives to refine the proprioceptive identity of MTN neurons and highlight their implications for sensorimotor maturation and developmental disorders.

From metabolism to mood regulation: astrocytes as a driver of depression.

Nasu Y, Terunuma M

Front Cell Neurosci · 2026 · PMID 41859358 · Full text

Astrocytes are increasingly recognized as active regulators of mood and cognition, extending far beyond their classical supportive roles. In major depressive disorder, converging evidence from postmortem analyses, magnet... Astrocytes are increasingly recognized as active regulators of mood and cognition, extending far beyond their classical supportive roles. In major depressive disorder, converging evidence from postmortem analyses, magnetic resonance spectroscopy (MRS), and animal stress models points toward the possibility of astrocytic abnormalities, including reduced density, impaired glutamate-glutamine cycling, and altered mitochondrial function. However, the causal contribution of these alterations remains insufficiently defined. This review aims to summarize experimental studies employing both loss- and gain-of-function approaches to directly probe the involvement of astrocytes in depression. We first introduce which inhibited astrocytic functions induce depressive-like behaviors, and then explore how enhancing these astrocytic functions-through overexpression and pharmacological manipulation methods-rescues stress-induced depression phenotypes. We further connect astrocyte alterations with circuit-level dysfunctions and behavioral outcomes, such as impaired prefrontal-amygdala regulation and reduced mesolimbic reward responses. Finally, we discuss therapeutic opportunities including astrocyte-targeting pharmacological strategies and MRS-based biomarkers. By integrating mechanistic evidence with translational perspectives, this review positions astrocyte metabolism as a promising frontier for antidepressant development.

Personalized resilience: how individual variability in brain-immune responses to stress influences the development of anxiety disorders.

Peixoto N, Fonseca R

Front Cell Neurosci · 2026 · PMID 41853172 · Full text

Stress exposure has increased significantly, contributing to higher rates of anxiety, depression, and post-traumatic stress disorder. However, individual responses to stress vary greatly, underscoring the concept of stre... Stress exposure has increased significantly, contributing to higher rates of anxiety, depression, and post-traumatic stress disorder. However, individual responses to stress vary greatly, underscoring the concept of stress resilience. The acute stress response activates the amygdala, hippocampus, and prefrontal cortex, stimulating the HPA axis and triggering cortisol release, which typically restores balance through negative feedback mechanisms. In contrast, chronic stress or exposure to severe stressors leads to sustained HPA axis activation, amygdala hyperreactivity, and immune dysfunction, all of which promote the development of anxiety disorders. This review explores potential central and peripheral biomarkers of resilience, emphasizing the interplay between immune responses, the HPA axis, and the endocannabinoid signaling system. We discuss whether amygdala reactivity could serve as a predictor of stress vulnerability, along with cortisol levels and sleep disturbances, as these are often hallmarks of stress-related disorders. Furthermore, we suggest that pro-inflammatory cytokines such as TNF-α and IL-6-key indicators of stress-induced inflammation-may serve as predictors of anxiety-related vulnerability. Furthermore, we discuss the potential role of the endocannabinoid system as an integrative hub for stress responses. Given its capacity to coordinate central and peripheral mechanisms-from neuroimmune to metabolic processes-we examine how genetic and functional variations in CB1R and FAAH may influence individual resilience, highlighting their potential as biomarkers of stress susceptibility. Clinically is of utmost relevance the identification of reliable and reproducible biomarkers for advancing diagnostic precision and developing personalized therapeutic interventions for stress-related disorders.

Peri-implantitis derived extracellular vesicle as vectors of neuroinflammation.

Tessarin GWL, Dos Santos RM, Toro LF

Front Cell Neurosci · 2026 · PMID 41853171 · Full text

Abstract loading — click title to view on PubMed.

Anxiety is associated with systemic pro-inflammatory profile and plasma lipid changes in Mexican young adults.

Bernal-Vega S, Vázquez-Manjarrez N, Villegas-Romero M … +4 more , Ortiz-López R, de la Barquera JAO, Pérez-Maya AA, Camacho-Morales A

Front Cell Neurosci · 2026 · PMID 41835967 · Full text

INTRODUCTION: Systemic inflammation and altered lipid metabolism have been implicated in anxiety disorders, but the relationship between circulating cytokines, plasma lipid species and symptom severity remains unclear. M... INTRODUCTION: Systemic inflammation and altered lipid metabolism have been implicated in anxiety disorders, but the relationship between circulating cytokines, plasma lipid species and symptom severity remains unclear. METHODS: We studied 34 young adults (17 healthy controls, 17 with clinician-confirmed anxiety; age 21-27 years). Anxiety severity was assessed with standardized clinical instruments. Plasma cytokines were quantified by multiplex immunoassay and targeted lipid profiling was performed by mass spectrometry. Group comparisons used nonparametric tests (Mann-Whitney U), and associations were examined with Spearman correlations and robust regression models appropriate for nonparametric data. RESULTS: Compared with controls, individuals with anxiety showed elevated plasma IL-6, MCP-1 and TNF-α and reduced IL-17A. Targeted lipidomics detected no group differences in total ceramides, dihydroceramides, hexosylceramides or lactosylceramides; nominal reductions were observed for DG 18:2/22:4, DG 18:2/22:6, LPC 24:1 and TG 60:11 (FA 22:5). None of the lipid species correlated with anxiety severity, and combined lipid-cytokine regression models failed to identify independent lipid predictors. MCP-1 and TNF-α showed associations with anxiety severity that were restricted to the clinical group. (All results are presented as unadjusted values; lipid findings did not remain significant after correction for multiple testing.). DISCUSSION: The data indicate a reproducible pro-inflammatory signal in clinical anxiety and point to modest, exploratory alterations in selected glycerolipids and lysophospholipids that require validation. These results should be considered hypothesis-generating; larger, longitudinal studies are needed to determine causality and the clinical relevance of immunometabolic signatures in anxiety.

Increased dendritic inhibition of dentate gyrus granule cells in a mouse model of Down syndrome.

Gutmann N, Häussler U, Mersi A … +3 more , Follo M, Bischofberger J, Schulz JM

Front Cell Neurosci · 2026 · PMID 41835966 · Full text

Down syndrome is the most common genetic neurodevelopmental disorder associated with mild-to-moderate intellectual disability. A disturbed excitation-inhibition balance is thought to be a major cause for the intellectual... Down syndrome is the most common genetic neurodevelopmental disorder associated with mild-to-moderate intellectual disability. A disturbed excitation-inhibition balance is thought to be a major cause for the intellectual deficits in DS. In this study, we used patch-clamp electrophysiology, optogenetic stimulation and immunohistochemistry to investigate synaptic inhibition from specific interneuron subpopulations onto granule cells of the dentate gyrus in Ts65Dn mice. Optogenetically evoked inhibitory postsynaptic currents (IPSCs) from somatostatin (SOM) interneurons onto dendrites of granule cells in the outer molecular layer (ML) did not differ between euploid (Eu) and Ts65Dn mice, indicating normal distal dendritic inhibition in Ts65Dn mice. In addition, optogenetically evoked IPSCs from parvalbumin (PV) interneurons were significantly reduced, indicating reduced functional somatic inhibition in Ts65Dn mice. In contrast, activation of cholecystokinin (CCK) positive interneurons by targeted electrical microstimulation of the inner molecular layer (iML) resulted in IPSCs of increased amplitude (Eu: 372.5 ± 51.97 pA,  = 10; Ts65Dn: 619.9 ± 74.68 pA,  = 9). GABAergic synaptic terminals of CCK interneurons express cannabinoid receptor 1 (CB1). Quantitative analysis of synapses double-labeled for CB1 and the vesicular GABA transporter (VGAT) revealed a significantly increased number of putative CCK interneuron terminals in the iML of Ts65Dn mice (Eu: 0.048 ± 0.014 puncta/μm, Ts65Dn: 0.34 ± 0.12 puncta/μm). In contrast, the density of PV-VGAT double-positive synapses within the granule cell layer did not differ between the two genotypes. Taken together, our results indicate that proximal dendritic inhibition from CCK interneurons is increased in the dentate gyrus of Ts65Dn mice, while PV interneuron-mediated somatic inhibition appears to be unchanged or functionally diminished.

Editorial: Interneurons in pathological conditions.

Lacaille H, Vacher CM

Front Cell Neurosci · 2026 · PMID 41835965 · Full text

Abstract loading — click title to view on PubMed.

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