Neuroinflammatory Disorders Research Articles

Understanding the neurobiological mechanisms of LPS‑induced memory impairment.

In recent years, growing evidence suggests that lipopolysaccharide (LPS), a bacterial endotoxin found in the outer membrane of gram‑negative bacteria, can influence cognitive functions, particularly memory formation and retrieval. However, the underlying mechanisms through which LPS exerts its effects on memory remain incompletely understood. This review used various electronic databases, including PubMed, Scopus, and Web of Science, to identify relevant studies published between 2000 and 2024. Articles were selected based on their focus on LPS‑induced memory impairments, including experimental models, molecular pathways, and neurochemical alterations. LPS administration has been consistently shown to disrupt memory processes in both animals and humans, although the magnitude and duration of memory impairments might vary depending on factors such as dose, timing, and context of LPS exposure. Several potential mechanisms have been proposed to explain LPS‑induced memory deficits, including neuroinflammation, alterations in synaptic plasticity, disruption of neurotransmitter systems, and dysfunction of the blood‑brain barrier. Moreover, LPS has been found to activate immune signaling pathways, such as toll‑like receptors, interleukins, and microglia, which can further contribute to cognitive impairments. Such insights may pave the way for the development of targeted therapeutic interventions aimed at ameliorating memory deficits associated with conditions involving LPS exposure, including bacterial infections, sepsis, and neuroinflammatory disorders.

Characterizing Microglial Signaling Dynamics During Inflammation Using Single-Cell Mass Cytometry.

Microglia play a critical role in maintaining central nervous system (CNS) homeostasis and display remarkable plasticity in their response to inflammatory stimuli. However, the specific signaling profiles that microglia adopt during such challenges remain incompletely understood. Traditional transcriptomic approaches provide valuable insights, but fail to capture dynamic post-translational changes. In this study, we utilized time-resolved single-cell mass cytometry (CyTOF) to measure distinct signaling pathways activated in microglia upon exposure to bacterial and viral mimetics-lipopolysaccharide (LPS) and polyinosinic-polycytidylic acid (Poly(I:C)), respectively. Furthermore, we evaluated the immunomodulatory role of astrocytes on microglial signaling in mixed cultures. Microglia or mixed cultures derived from neonatal mice were treated with LPS or Poly(I:C) for 48 h. Cultures were stained with a panel of 33 metal-conjugated antibodies targeting signaling and identity markers. High-dimensional clustering analysis was used to identify emergent signaling modules. We found that LPS treatment led to more robust early activation of pp38, pERK, pRSK, and pCREB compared to Poly(I:C). Despite these differences, both LPS and Poly(I:C) upregulated the classical reactivity markers CD40 and CD86 at later time points. Strikingly, the presence of astrocytes significantly blunted microglial responses to both stimuli, particularly dampening CD40 upregulation. Our studies demonstrate that single-cell mass cytometry effectively captures the dynamic signaling landscape of microglia under pro-inflammatory conditions. This approach may pave the way for targeted therapeutic investigations of various neuroinflammatory disorders. Moreover, our findings underscore the necessity of considering cellular context, such as astrocyte presence, in interpreting microglial behavior during inflammation.

Differential impact of lymphatic outflow pathways on cerebrospinal fluid homeostasis.

Dysfunctional lymphatic drainage from the central nervous system (CNS) has been linked to neuroinflammatory and neurodegenerative disorders, but our understanding of the lymphatic contribution to CNS fluid autoregulation remains limited. Here, we studied forces that drive the outflow of the cerebrospinal fluid (CSF) into the deep and superficial cervical lymph nodes (dcLN and scLN) and tested how the blockade of lymphatic networks affects CNS fluid homeostasis. Outflow to the dcLN occurred spontaneously in the absence of lymphatic pumping and was coupled to intracranial pressure (ICP), whereas scLN drainage was driven by pumping. Impaired dcLN drainage led to elevated CSF outflow resistance and delayed CSF-to-blood efflux despite the recruitment of the nasal-to-scLN pathway. Fluid regulation was better compensated after scLN obstruction. The dcLN pathway exhibited steady, consistent drainage across conditions, while the nasal-to-scLN pathway was dynamically activated to mitigate perturbances. These findings highlight the complex physiology of CSF homeostasis and lay the groundwork for future studies aimed at assessing and modulating CNS lymphatic function.

The Impact of Immunotherapy Drugs on the Human Nervous System

Immunotherapy is rapidly becoming one of the most promising directions in the modern approach to cancer treatment. CAR-T cell therapy, immune checkpoint inhibitors, monoclonal antibodies, and gene therapies have shown great potential in enhancing the quality of life of patients, through the activation of the body’s immune system against cancerous cells. In addition to cancer, immunotherapy is being tested in neurodegenerative and neuroinflammatory disorders such as multiple sclerosis and Alzheimer disease. However, these therapies entail certain risks especially with regard to the nervous system. There is increasing evidence that immunotherapies are associated with neurotoxic side effects such as neuroinflammation, encephalitis, cognitive decline and peripheral neuropathy which can greatly affect patient’s quality of life. This review focuses on the description of these immunotherapies’ mechanisms and clinical use as well as their impact on the CNS and PNS adverse effects. Measures that can help avoid these risks include precision medicine, better gene delivery vectors, and selective treatment approaches, which are very helpful in maximizing the safety and efficacy of immunotherapy. One of the critical issues of further development of these novel therapeutic interventions is the optimization of desired therapeutic outcomes and possible neurological adverse effects.

Chemokines in neurodegenerative diseases.

Neurodegeneration and neuroinflammation disorders are mainly the result of the deposition of various proteins, such as α-synuclein, amyloid-β and prions, which lead to the initiation and activation of inflammatory responses. Different chemokines are involved in the infiltration and movement of inflammatory leukocytes into the central nervous system (CNS) that express chemokine receptors. Dysregulation of several members of chemokines has been shown in the CNS, cerebrospinal fluid and peripheral blood of patients who have neurodegenerative disorders. Upon infiltration of various cells, they produce many inflammatory mediators such as cytokines. Besides them, some CNS-resident cells, such as neurons and astrocytes, are also involved in the pathogenesis of neurodegeneration by producing chemokines. In this review, we summarize the role of chemokines and their related receptors in the pathogenesis of neurodegeneration and neuroinflammation disorders, including multiple sclerosis, Parkinson's disease and Alzheimer's disease. Therapeutic strategies targeting chemokines or their related receptors are also discussed in this article.

Single-cell analysis of cerebrospinal fluid reveals common features of neuroinflammation.

Neuroinflammation is often characterized by immune cell infiltrates in the cerebrospinal fluid (CSF). Here, we apply single-cell RNA sequencing to explore the functional characteristics of these cells in patients with various inflammatory, infectious, and non-inflammatory neurological disorders. We show that CSF is distinct from the peripheral blood in terms of both cellular composition and gene expression. We report that the cellular and transcriptional landscape of CSF is altered in neuroinflammation but is strikingly similar across different neuroinflammatory disorders. We find clonal expansion of CSF lymphocytes in all disorders but most pronounced in inflammatory diseases, and we functionally characterize the transcriptional features of these cells. Finally, we explore the genetic control of gene expression in CSF lymphocytes. Our results highlight the common features of immune cells in the CSF compartment across diverse neurological diseases and may help to identify new targets for drug development or repurposing in multiple sclerosis (MS).

Cathelicidin antimicrobial peptide expression in neutrophils and neurons antagonistically modulates neuroinflammation.

Multiple sclerosis (MS) is an autoimmune disease that affects the central nervous system (CNS), the pathophysiology of which remains unclear and for which there is no definitive cure. Antimicrobial peptides (AMPs) are immunomodulatory molecules expressed in various tissues, including the CNS. Here, we investigated whether the cathelicidin-related AMP (CRAMP) modulated the development of experimental autoimmune encephalomyelitis (EAE), a mouse model of MS. We showed that, at early stage, CNS-recruited neutrophils produced neutrophil extracellular traps (NETs) rich in CRAMP that was required for EAE initiation. NET-associated CRAMP stimulated IL-6 production by dendritic cells via the cGAS/STING pathway, thereby promoting encephalitogenic Th17 response. However, at a later disease stage, neurons also expressed CRAMP that reduced EAE severity. Camp knockdown in neurons led to disease exacerbation, while local injection of CRAMP1-39 at the peak of EAE promoted disease remission. In vitro, CRAMP1-39 regulated the activation of microglia and astrocytes through the formyl peptide receptor (FPR)2. Finally, administration of butyrate, a gut microbiota-derived metabolite, stimulated the expression of neural CRAMP via the free fatty acids receptors (FFAR)2/3, and prevented EAE. This study shows that CRAMP produced by different cell types have opposing effects on neuroinflammation, offering therapeutic opportunities for MS and other neuroinflammatory disorders.

Pharmacological inhibition of receptor protein tyrosine phosphatase β/ζ decreases Aβ plaques and neuroinflammation in the hippocampus of APP/PS1 mice.

Alzheimer's disease (AD) is a major neurodegenerative disorder that courses with chronic neuroinflammation. Pleiotrophin (PTN) is an endogenous inhibitor of Receptor Protein Tyrosine Phosphatase (RPTP) β/ζ which is upregulated in different neuroinflammatory disorders of diverse origin, including AD. To investigate the role of RPTPβ/ζ in neuroinflammation and neurodegeneration, we used eight-to ten-month-old APP/PS1 AD mouse model. They were administered intragastrically with MY10, an inhibitor of RPTPβ/ζ, at different doses (60 and 90mg/kg) every day for 14days. Treatment with 90mg/kg MY10 significantly reduced the number and size of amyloid beta (Aβ) plaques in the dorsal subiculum of the hippocampus of APP/PS1 mice. In addition, we observed a significant decrease in the number and size of astrocytes in both sexes and in the number of microglial cells in a sex-dependent manner. This suggests that RPTPβ/ζ plays an important role in modulating Aβ plaque formation and influences glial responses, which may contribute to improved Aβ clearance. In addition, MY10 treatment decreased the interaction of glial cells with Aβ plaques in the hippocampus of APP/PS1 mice. Furthermore, the analysis of proinflammatory markers in the hippocampus revealed that MY10 treatment decreased the mRNA levels of Tnfa and Hmgb1. Notably, treatment with MY10 increased Bace1 mRNA expression, which could be involved in enhancing Aβ degradation, and it decreased Mmp9 levels, which might reflect changes in the neuroinflammatory environment and impact Aβ plaque dynamics. These results support the therapeutic potential of inhibition of RPTPβ/ζ in modulating Aβ pathology and neuroinflammation in AD.

Irisin reprograms microglia through activation of STAT6 and prevents cognitive dysfunction after surgery in mice.

Postoperative cognitive dysfunction (POCD) is common in the aged population and associated with poor clinical outcomes. Irisin, an endogenous molecule that mediates the beneficial effects of exercise, has shown neuroprotective potential in several models of neurological diseases. Here we show that preoperative serum level of irisin is reduced in dementia patients over the age of 70. Comprehensive proteomics analysis reveals that deletion of irisin affects the nervous and immune systems, and reduces the expression of complement proteins. Systemically administered irisin penetrates the blood-brain barrier in mice, targets the microglial integrin αVβ5 receptor, activates signal transducer and activator of transcription 6 (STAT6), induces microglia reprogramming to the M2 phenotype, and improves immune microenvironment in LPS-induced neuroinflammatory mice. Finally, prophylactic administration of irisin prevents POCD-like behavior, particularly early cognitive dysfunction. Our findings provide new insights into the direct regulation of the immune microenvironment by irisin, and reveal that recombinant irisin holds great promise as a novel therapy for preventing POCD and other neuroinflammatory disorders. SUMMARY: Our findings reveal molecular and cellular mechanisms of irisin on neuroinflammation, and show that prophylactic administration of irisin prevents POCD-like behavior, particularly early cognitive dysfunction.

Tackling Neuroinflammation in Cognitive Disorders with Single-targeted and Multi-targeted Histamine H3 Receptor Modulators.

Neuroinflammation is a process involved in a variety of central nervous system (CNS) diseases and is being increasingly recognized as a key mediator of cognitive impairments. Neuroinflammatory responses including glial activation, increased production of proinflammatory cytokines, and aberrant neuronal signaling, contribute to cognitive dysfunctions. Histamine is a key peripheral inflammatory mediator, but plays an important role in neuroinflammatory processes as well. The unique localization of histamine H3 receptor (H3R) in the CNS along with the modulation of the release of other neurotransmitters via its action on heteroreceptors on non-histaminergic neurons have led to the development of several H3R ligands for various brain diseases. H3R antagonists/ inverse agonists have revealed potential to treat diverse neuroinflammatory CNS disorders, including neurodegenerative diseases, attention-deficit hyperactivity syndrome and schizophrenia. In this mini review, we provide a brief overview on the crucial involvement of the histaminergic transmission in the neuroinflammatory processes underlying these cognitive disorders, with a special focus on H3R involvement. The anti-neuroinflammatory potential of single-targeted and multi-targeted H3R antagonists/inverse agonists for the treatment of these conditions is discussed here.

Microglial and Macrophage Plasticity and Regional Cerebral Blood Flow in the Prenatal Brain and Gut Under Vagus Nerve Stimulation.

An intricate relationship exists between the vagus nerve and systemic immune cell regulation, specifically during fetal development. Little is known about the connection between the vagus nerve and the brain's regional circulatory control. In this chapter, we present a methodology for studying the impact of vagus nerve signaling on these connections in the developing fetus using the sheep model for human fetal physiology. First, we present the protocol to study the connection between the vagus nerve physiology and the regional cerebral blood flow (rCBF). Next, we detail the protocol for measuring how vagal signaling alters microglial cell plasticity in gut and brain. In previous work, our team showed that vagotomy results in amplified redistribution of rCBF toward subcortical structures in the fetal brain. Conversely, efferent VNS reduces rCBF to cortical structures while afferent VNS diminishes the rise of rCBF to subcortical structures (independent of cortical rCBF) when compared to controls in the fetal brain. Additionally, our team showed that Iba-1 expression, a marker for microglial cellular signaling activation, rises in a dose-dependent relationship with systemic inflammatory activation in the setting of vagotomy. The findings support existing preclinical and clinical evidence in adult human physiology that vagotomy is neuroprotective for neurodegenerative diseases such as Parkinson's likely via a glial cell-mediated mechanism. Vagus nerve stimulation (VNS) has also been shown to alter rCBF patterns in adults with treatment-resistant depression, underscoring the importance of further investigation of the relationship between the vagus nerve and rCBF as early as in utero. Together, the body of evidence emphasizes that the vagal pathway is an important player in the programming of microglial cell phenotypes within the developing brain. Further study is needed to better understand the significance of these relationships for the development and treatment of early susceptibility to neuroinflammatory and neurodegenerative disorders in later life. Therefore, we present a methodology for assessing rCBF and morphometric features of microglial and macrophage cell activation to allow future teams to expand on the existing body of work and further examine these relationships at a cellular and systems' levels.

Unraveling neuroprotection with Kv1.3 potassium channel blockade by a scorpion venom peptide

Voltage-gated potassium channels play a crucial role in cellular repolarization and are potential therapeutic targets in neuroinflammatory disorders and neurodegenerative diseases. This study explores Tityus bahiensis scorpion venom for neuroactive peptides. We identified the αKtx12 peptide as a potent neuroprotective agent. In SH-SY5Y cells, αKtx12 significantly enhances viability, validating its pharmacological potential. And in the animal model, we elucidate central nervous system (CNS) mechanism of αKtx12 through neuroproteomic analyses highlighting αKtx12 as a valuable tool for characterizing neuroplasticity and neurotropism, revealing its ability to elicit more physiological responses. The peptide’s potential to promote cell proliferation and neuroprotection suggests a role in functional recovery from nervous system injury or disease. This research unveils the neuroactive potential of scorpion venom-derived αKtx12’s, offering insights into its pharmacological utility. The peptide’s impact on neuronal processes suggests a promising avenue for therapeutic development, particularly in neurodegenerative conditions.

Assessing the landscape and charting paths: UK neurology trainees’ opinions on neuroinflammation subspecialty

Therapeutics of neuroinflammatory disorders including multiple sclerosis is one of the fastest growing areas in neurology. However, pressures on higher specialty training in neurology together with an expanding curriculum have led to challenges in adequately preparing trainees for a subspecialist career. In this study we set out to understand current perceptions and barriers to training in neuroinflammatory disorders among neurology trainees in the UK. A structured questionnaire was used to assess trainees' perspectives on training opportunities and career aspirations. Findings reveal significant gaps in training, including insufficient training opportunities, lack of mentorship, and concerns about managing complex treatment regimes. We used these findings to develop structured action points with aim of improving training and retention in this subspecialty. These include early exposure to subspecialty experiences, enhanced mentorship, and equal access to training opportunities regardless of geographical location. Our findings underscore the need for further curriculum development in neurology training, potentially combining early support with dedicated fellowships later in training, in order to ensure sustainability of neuroinflammation as a subspecialty and to meet the growing demand for expertise in MS and related conditions.

PU-H71 (NSC 750424): a molecular masterpiece that targets HSP90 in cancer and beyond.

Heat shock protein 90 (HSP90) is a pivotal molecular chaperone with multifaceted roles in cellular health and disease. Herein, we explore how HSP90 orchestrates cellular stress responses, particularly through its partnership with heat shock factor 1 (HSF-1). PU-H71, a selective inhibitor of HSP90, demonstrates significant potential in cancer therapy by targeting a wide array of oncogenic pathways. By inducing the degradation of multiple client proteins, PU-H71 disrupts critical signaling pathways such as MAPK, PI3K/Akt, JAK/STAT, EGFR, and mTOR, which are essential for cancer cell survival, proliferation, and metastasis. We examined its impact on combating triple-negative breast cancer and enhancing the effectiveness of carbon-ion beam therapy, offering new avenues for cancer treatment. Furthermore, the dual inhibition of HSP90A and HSP90B1 by PU-H71 proves highly effective in the context of myeloma, providing fresh hope for patients with this challenging malignancy. We delve into its potential to induce apoptosis in B-cell lymphomas that rely on Bcl6 for survival, highlighting its relevance in the realm of hematologic cancers. Shifting our focus to hepatocellular carcinoma, we explore innovative approaches to chemotherapy. Moreover, the current review elucidates the potential capacity of PU-H71 to suppress glial cell activation paving the way for developing novel therapeutic strategies for neuroinflammatory disorders. Additionally, the present report also suggests the promising role of PU-H71 in JAK2-dependent myeloproliferative neoplasms. Eventually, our report sheds more light on the multiple functions of HSP90 protein as well as the potential therapeutic benefit of its selective inhibitor PU-H71 in the context of an array of diseases, laying the foundations for the development of novel therapeutic approaches that could achieve better treatment outcomes.

Dehydroervatamine as a promising novel TREM2 agonist, attenuates neuroinflammation

Microglia play a dual role in neuroinflammatory disorders that affect millions of people worldwide. These specialized cells are responsible for the critical clearance of debris and toxic proteins through endocytosis. However, activated microglia can secrete pro-inflammatory mediators, potentially exacerbating neuroinflammation and harming adjacent neurons. TREM2, a cell surface receptor expressed by microglia, is implicated in the modulation of neuroinflammatory responses. In this study, we investigated if and how Dehydroervatamine (DHE), a natural alkaloid, reduced the inflammatory phenotype of microglia and suppressed neuroinflammation. Our findings revealed that DHE was directly bound to and activated TREM2. Moreover, DHE effectively suppressed the production of pro-inflammatory cytokines, restored mitochondrial function, and inhibited NLRP3 inflammasome activation via activating the TREM2/DAP12 signaling pathway in LPS-stimulated BV2 microglial cells. Notably, silencing TREM2 abolished the suppression effect of DHE on the neuroinflammatory response, mitochondrial dysfunction, and NF-κB/NLRP3 pathways in vitro. Additionally, DHE pretreatment exhibited remarkable neuroprotective effects, as evidenced by increased neuronal viability and reduced apoptotic cell numbers in SH-SY5Y neuroblastoma cells co-cultured with LPS-stimulated BV2 microglia. Furthermore, in our zebrafish model, DHE pretreatment effectively alleviated behavioral impairments, reduced neutrophil aggregation, and suppressed neuroinflammation in the brain by regulating TREM2/NF-κB/NLRP3 pathways after intraventricular LPS injection. These findings provide novel insights into the potent protective effects of DHE as a promising novel TREM2 agonist against LPS-induced neuroinflammation, revealing its potential therapeutic role in the treatment of central nervous system diseases associated with neuroinflammation.

Border-Associated Macrophages: From Embryogenesis to Immune Regulation.

Border-associated macrophages (BAMs) play a pivotal role in maintaining brain homeostasis and responding to pathological conditions. Understanding their origins, characteristics, and roles in both healthy and diseased brains is crucial for advancing our knowledge of neuroinflammatory and neurodegenerative diseases. This review addresses the ontogeny, replenishment, microenvironmental regulation, and transcriptomic heterogeneity of BAMs, highlighting recent advancements in lineage tracing and fate-mapping studies. Furthermore, we examine the roles of BAMs in maintaining brain homeostasis, immune surveillance, and responses to injury and neurodegenerative diseases. Further research is crucial to clarify the dynamic interplay between BAMs and the brain's microenvironment in health and disease. This effort will not only resolve existing controversies but also reveal new therapeutic targets for neuroinflammatory and neurodegenerative disorders, pushing the boundaries of neuroscience.

An initial investigation of transcutaneous delivery of plasmid DNA encoding interleukin-10 for the treatment of psoriatic skin conditions

Psoriasis is a chronic immune-mediated skin disorder characterized by intense local inflammation, epidermal hyperplasia, and leukocyte infiltration. Current treatment approaches for psoriasis aim to alleviate symptoms and prevent disease progression, including systemically administered drugs with whole body side effects. Despite some advances in psoriasis treatment, success has been quite limited. To begin to address this challenge, we undertook an initial investigation of whether transcutaneous delivery of an endogenous anti-inflammatory cytokine could provide an effective, local treatment of psoriatic-like skin conditions. To do this, we utilized a previously documented rodent model of psoriasis, induced via a single topical application of Imiquimod (IMQ) to the shaved back of rats. The therapeutic approach used for this initial investigation was delivery of plasmid DNA encoding rat interleukin-10 (pDNA-rIL10), a non-viral gene therapy approach previously shown to be effective in suppressing neuroinflammatory disorders after localized delivery either intracerebrally or intrathecally. Translation of this CNS therapeutic for use in psoriatic-like skin disorders required reformulation to enable transcutaneous delivery. Toward that end, pDNA-rIL10 was topically applied in Lipoderm HMW, a base explicitly designed to deliver higher molecular weight compounds into skin. Here we show that a single topical application of pDNA-rIL10 in Lipoderm HMW was effective in decreasing mRNA levels of pro-inflammatory cytokines as well as reducing the recruitment of T-cells to IMQ-treated skin. Furthermore, this transcutaneous IL-10 gene therapy decreased signs of skin inflammation, reflected by reduced erythema. Moreover, the results provide an initial indication that IL10 may stimulate hair regrowth in psoriatic-like skin.

Clinical Applications of Micro/Nanobubble Technology in Neurological Diseases.

Nanomedicine, leveraging the unique properties of nanoparticles, has revolutionized the diagnosis and treatment of neurological diseases. Among various nanotechnological advancements, ultrasound-mediated drug delivery using micro- and nanobubbles offers promising solutions to overcome the blood-brain barrier (BBB), enhancing the precision and efficacy of therapeutic interventions. This review explores the principles, current clinical applications, challenges, and future directions of ultrasound-mediated drug delivery systems in treating stroke, brain tumors, neurodegenerative diseases, and neuroinflammatory disorders. Additionally, ongoing clinical trials and potential advancements in this field are discussed, providing a comprehensive overview of the impact of nanomedicine on neurological diseases.

Is vagus nerve-mediated regulation of immunity an etiological target for therapeutic intervention in endometriosis?

Endometriosis is a complex chronic neuro-inflammatory disorder, affecting roughly 10% of reproductive-age women. It is characterized by the presence of endometrial-like tissue outside the uterus, which induces a chronic inflammatory reaction. This disease can present a wide range of symptoms, including chronic pain and infertility. Despite extensive research, the exact pathogenesis of endometriosis remains incompletely understood. New strategies and paradigms on pathogenesis and treatment are needed. Schematic factors contributing to the development of endometriosis lesions include genetic, hormonal, and immunological factors. Although genetics may contribute to the epidemiologically suggested heritability of endometriosis, epigenetics has gained an increasing consideration in research. Remarkably, microbiota dysbiosis, acting as a catalyst for the main acknowledged epigenetic etiologies (locally produced estradiol, pro-inflammatory cytokines, and hypoxic stress) demands further attention. Indeed, over the past 10 years, it has become clear that the vagus nerve, the fastest component of the microbiota-gut-brain axis, can efficiently control inflammation through the cholinergic anti-inflammatory pathway. Therefore, stimulation of the vagus nerve could be a good candidate for modulating the severity of endometriosis. The detrimental consequences of microbiome dysbiosis and the estrobolome activity on the initiation of the disease as well as counterpart dysfunctions in the central nervous system will be focused on, both supporting a key role of the vagus nerve since the early stage of endometriosis. Consequently, the rationale for using non-invasive vagus nerve stimulation will be discussed, introducing a fruitful shift of paradigm in this still enigmatic disease.

Human Umbilical Cord-Mesenchymal Stem Cells Promote Extracellular Matrix Remodeling in Microglia.

Human mesenchymal stem cells modulate the immune response and are good candidates for cell therapy in neuroinflammatory brain disorders affecting both adult and premature infants. Recent evidence indicates that through their secretome, mesenchymal stem cells direct microglia, brain-resident immune cells, toward pro-regenerative functions, but the mechanisms underlying microglial phenotypic transition are still under investigation. Using an in vitro coculture approach combined with transcriptomic analysis, we identified the extracellular matrix as the most relevant pathway altered by the human mesenchymal stem cell secretome in the response of microglia to inflammatory cytokines. We confirmed extracellular matrix remodeling in microglia exposed to the mesenchymal stem cell secretome via immunofluorescence analysis of the matrix component fibronectin and the extracellular crosslinking enzyme transglutaminase-2. Furthermore, an analysis of hallmark microglial functions revealed that changes in the extracellular matrix enhance ruffle formation by microglia and cell motility. These findings point to extracellular matrix changes, associated plasma membrane remodeling, and enhanced microglial migration as novel mechanisms by which mesenchymal stem cells contribute to the pro-regenerative microglial transition.