Search Results (557)

Neutrophils are an essential protective component of the innate immune system. However, in severe bacterial infections, neutrophils are known to mis-localise from the primary site of infection to other organs, where excessive release of cytokines, chemokines, and neutrophil extracellular traps (NETs) can induce organ damage and death. In this study, we use an animal model of bacterial infection originating in the peritoneum to show that hydrogen peroxide (H₂O₂, a potent neutrophil chemoattractant) is initially released in high concentrations both in the peritoneum and in multiple ‘off-target’ organs (lungs, liver and kidneys). The initial high H₂O₂ release inhibits neutrophil chemotaxis, but after 24 h concentrations of H₂O₂ reduce and can promote neutrophil migration to organs, where they release pro-inflammatory cytokines and chemokines along with NETs. The antimalarial compound artesunate potently inhibits neutrophil migration to off-target organs. It also abolishes cytokine, chemokine, and NET production, suggesting that artesunate may be a valuable novel therapy for preventing off-target organ inflammation associated with severe bacterial infections. Finally, the potency of H₂O₂ as a chemoattractant is shown by in vitro experiments in which, faced with competing gradients of H₂O₂ and other chemoattractants, neutrophils preferentially migrate towards H₂O₂. Full article

Sepsis is a life-threatening condition driven by a dysregulated host response to infection, with high mortality and few treatment options. Decades of failed drug development underscore the urgent need for therapies with novel mechanisms of action. Vimentin, an intermediate filament protein, acts as a network hub that senses and integrates cellular signals. Its involvement in key sepsis pathologies, including infection, hyperinflammation, immunosuppression, coagulopathy and metabolic dysregulation, positions it as a potential therapeutic target. This study evaluated the efficacy of ALD-R491, a novel small-molecule vimentin modulator, in a murine model of polymicrobial sepsis induced by cecal ligation and puncture (CLP). Mice received ALD-R491 prophylactically or therapeutically, alone or with ceftriaxone. The treatment significantly reduced serum levels of key biomarkers of sepsis, including C-reactive protein (CRP), lactate (Lac), tumor necrosis factor-alpha (TNF-α) and interleukin-6 (IL-6), and dose-dependently improved the survival of septic mice. Organ-specific analysis confirmed the effects of ALD-R491 in mitigating hyperinflammation and multi-organ injury. The treatment reduced pulmonary edema and inflammation; preserved liver tissue architecture and improved hepatic function with lowered alanine aminotransferase/aspartate aminotransferase (ALT/AST); decreased kidney tubular damage; and improved renal function with lowered creatinine/blood urea nitrogen (BUN). These preclinical findings indicate that the vimentin-targeting agent ALD-R491 represents a promising therapeutic candidate for sepsis and merits further clinical investigation. Full article

Goose astrovirus (GAstV) infection has emerged as a prevalent cause of urate deposition and viral gout in major goose farming across China, leading to high mortality and substantial economic losses. However, the molecular mechanisms linking GAstV to gout pathogenesis remain elusive. Here, a total of 10 five-day-old Jiangnan white goslings were selected, and tissue damage and kidney gene expression profiles were investigated. The results showed multi-organ damage in GAstV-infected gosling, including kidney, liver, spleen, and lung. Also, 342 differentially expressed genes were identified in infected kidney tissues after 10 days post-infection using transcriptomic sequencing, including 185 upregulated and 157 downregulated genes. In addition, gene set enrichment analysis revealed significant positive correlations between GAstV infection and bile acid metabolism and fatty acid metabolism pathways. Notably, bile acid metabolism was implicated in uric acid regulation and gout progression. Protein–protein interaction network analysis identified AGXT as a central hub gene within the bile acid metabolic pathway, with key upregulated interactors including PIPOX, ALDH1A1, and CAT. AGXT, a critical enzyme in glyoxylate detoxification, directly modulates uric acid biosynthesis. Our findings propose that GAstV-induced activation of bile acid metabolism, particularly AGXT upregulation, drives hyperuricemia and subsequent gout pathology. This study elucidates a novel mechanism of GAstV-associated metabolic dysregulation and provides actionable genetic targets for antiviral breeding strategies in waterfowl. Full article

Furunculosis caused by Aeromonas salmonicida is one of the most common diseases in aquaculture, leading to significant economic losses. This study comprehensively investigated the dynamics of pathophysiological and histopathological disorders in rainbow trout (Oncorhynchus mykiss) infected with the moderately virulent strain A. salmonicida SL0n. Whole-genome analysis showed that strain SL0n belongs to the A. salmonicida species complex, possessing a single circular chromosome. The genome encodes a wide range of virulence factors, including adhesion systems (type IV pili, fimbriae), toxins (aerolysin, hemolysins), and a type II secretion system (T2SS), but notably lacks plasmids and a type III secretion system (T3SS). This genomic profile likely dictates a pathogenic mechanism reliant on secreted exotoxins (via T2SS), explaining the observed systemic cytotoxic damage. In an acute experiment, the 4-day LD₅₀ was determined to be 1.63 × 10⁶ CFU/fish. In a prolonged experiment, fish were injected with a sublethal dose (1.22 × 10⁶ CFU/fish—75% of LD50). The disease progressed through three consecutive stages. The early stage (1–2 DPI) was characterized by maximal bacterial load and activation of nonspecific immunity. The acute stage (4 DPI) manifested as severe septicemia and anemia, associated with systemic organ damage, which correlated with peak AST and ALT enzyme activity. The recovery stage (6 DPI) was marked by partial regression of inflammation, key biochemical and histological parameters indicated persistent liver and kidney dysfunction, signifying an incomplete recovery. These results demonstrate the pathogenesis of acute furunculosis and reveal that the genomic profile of the SL0n strain causes a sequential, systemic infection characterized by severe organ dysfunction. Full article

Acute kidney injury (AKI) is a frequent and severe complication in trauma patients, affecting up to 28% of intensive care unit (ICU) admissions and contributing significantly to morbidity, mortality, and long-term renal impairment. Trauma-related AKI (TRAKI) arises from diverse mechanisms, including hemorrhagic shock, ischemia–reperfusion injury, systemic inflammation, rhabdomyolysis, nephrotoxicity, and complex organ crosstalk involving the brain, lungs, and abdomen. Pathophysiologically, TRAKI involves early disruption of the glomerular filtration barrier, tubular epithelial injury, and renal microvascular dysfunction. Inflammatory cascades, oxidative stress, immune thrombosis, and maladaptive repair mechanisms mediate these injuries. Trauma-related rhabdomyolysis and exposure to contrast agents or nephrotoxic drugs further exacerbate renal stress, particularly in patients with pre-existing comorbidities. Traditional markers such as serum creatinine (sCr) are late indicators of kidney damage and lack specificity. Emerging structural and stress response biomarkers—such as neutrophil gelatinase-associated lipocalin (NGAL), kidney injury molecule 1 (KIM-1), liver-type fatty acid-binding protein (L-FABP), interleukin-18 (IL-18), C-C motif chemokine ligand 14 (CCL14), Dickkopf-3 (DKK3), and the U.S. Food and Drug Administration (FDA)-approved tissue inhibitor of metalloproteinases-2 × insulin-like growth factor-binding protein 7 (TIMP-2 × IGFBP-7)—allow earlier detection of subclinical AKI and better predict progression and the need for renal replacement therapy. Together, functional indices like urinary sodium and fractional potassium excretion reflect early microcirculatory stress and add clinical value. In parallel, risk stratification tools, including the Renal Angina Index (RAI), the McMahon score, and the Haines model, enable the early identification of high-risk patients and help tailor nephroprotective strategies. Together, these biomarkers and risk models shift from passive AKI recognition to proactive, personalized management. A new paradigm that integrates biomarker-guided diagnostics and dynamic clinical scoring into trauma care promises to reduce AKI burden and improve renal outcomes in this critically ill population. Full article

Diabetic nephropathy (DN) is a consequence of diabetes mellitus (DM), in which hyperglycemia triggers osmotic and oxidative stress and activates inflammatory pathways. These processes damage kidney cells, with mesangial cells (MCs) undergoing mesangial expansion. Antihyperglycemic drugs prevent the progression of renal disease. Although tamsulosin is not conventionally used for the treatment of DN, its previously reported anti-fibrotic and anti-inflammatory effects in liver and lung injury models suggest that it may exert renoprotective actions like those of pioglitazone, which has also been shown to improve cellular carbohydrate and lipid metabolism. MCs were exposed to 20 mM glucose medium and treated with either 50 nM tamsulosin or 100 nM pioglitazone. Subsequently, cell proliferation, inflammatory markers (NF-κB, IL-1β, IL-17), fibrogenic markers (TGF-β, collagen I), oxidative stress parameters (NRF2, superoxide), and indicators of mesangial activation (α-SMA, rhodamine–phalloidin) were assessed in vitro. Both treatments reduced cellular proliferation and hypertrophy, attenuated the release of reactive oxygen species (ROS), decreased IL-17 and α-SMA expression, and reduced mesangial activation and hypertrophy. In an in vivo model of DN in Wistar rats, both treatments decreased mesangial cell activation and expansion. In conclusion, tamsulosin and pioglitazone exert anti-fibrogenic and anti-inflammatory effects in MCs exposed to HG, thereby limiting mesangial activation and expansion. Full article

Histotripsy is a novel, non-invasive ultrasound-based ablative therapy that destroys tissue through focused cavitation. As solid tumors continue to be a major global health burden, there is interest in image-guided ablation techniques that reduce collateral damage and promote immune activation. This narrative review aims to synthesize current advancements, clinical applications, limitations, and future directions of histotripsy in both oncologic and non-oncologic contexts. A comprehensive literature search was conducted from database inception to July 2025. Search terms included combinations of subject headings and keywords such as “histotripsy,” “mechanical ablation,” “ultrasound,” and “solid tumors.” Boolean operators and truncation were used to increase sensitivity. Peer-reviewed studies were included, encompassing preclinical, clinical, and review articles. Reference lists of relevant articles were examined to identify additional sources. Histotripsy has shown strong potential in the treatment of tumors involving the liver, pancreas, kidney, brain, and cardiovascular system. It offers real-time imaging guidance, sharp lesion boundaries, and minimal damage to surrounding structures. Early clinical trials have demonstrated encouraging safety and efficacy, particularly in liver and kidney tumors. Its ability to preserve critical anatomy and stimulate innate and adaptive immune responses through the release of cellular debris and cytokines offers advantages over thermal ablation. Limitations include acoustic aberration, motion-related targeting challenges, and the need for further long-term clinical data. Histotripsy represents a promising advancement in noninvasive tumor ablation. Continued clinical investigation and technological refinement are necessary to validate its therapeutic value and define its role within comprehensive cancer care. Full article

Immune-mediated inflammatory diseases (IMIDs) encompass a wide range of disorders, including autoimmune, acute, and chronic inflammatory conditions, which are often characterized by immune dysregulation and excessive oxidative stress. Oxidative stress plays a pivotal role in the initiation and progression of these diseases by promoting tissue damage and sustaining inflammation. However, conventional antioxidant therapies are limited by poor bioavailability, inadequate targeting, and short-lived efficacy. In recent years, nano-antioxidants have emerged as a promising therapeutic approach due to their enhanced stability, targeted delivery capabilities, and multifunctional therapeutic effects. This review provides a comprehensive overview of recent advances in the application of nano-antioxidants in the treatment of IMIDs. Their therapeutic roles are categorized into three major groups: autoimmune diseases, acute inflammatory diseases, and chronic inflammatory diseases. In autoimmune disorders such as alopecia areata and multiple sclerosis, nano-antioxidants have demonstrated the ability to reduce oxidative damage, modulate immune responses, and alleviate clinical symptoms. In acute inflammatory conditions, including acute kidney injury and acute liver injury, these nanomaterials exert protective effects by scavenging ROS, mitigating tissue injury, and restoring organ function. In chronic inflammatory diseases such as inflammatory bowel disease and ulcerative colitis, nano-antioxidants contribute to maintaining mucosal integrity, suppressing chronic inflammation, and improving therapeutic outcomes through localized delivery and sustained release. In summary, nano-antioxidants represent a novel and promising therapeutic strategy for the management of IMIDs. Their unique physicochemical properties offer significant advantages over traditional treatments. Further research is needed to optimize their delivery platforms, evaluate long-term safety, and facilitate clinical translation. Full article

Background: Cardiovascular disease (CVD) is the leading cause of mortality in obese patients with type 2 diabetes mellitus (T2DM). Conventional biomarkers often fail to detect early endothelial dysfunction and oxidative stress. Haptoglobin (Hp), an acute-phase protein with antioxidant and hemoglobin-binding properties, may indicate vascular injury. While plasma Hp (pl-Hp) reflects systemic inflammation, urinary Hp (u-Hp) could signal renal and microvascular damage. We hypothesize that elevated u-Hp and altered pl-Hp levels are associated with increased oxidized LDL and may serve as sensitive indicators of early vascular injury, thereby identifying obese patients with T2DM at higher cardiovascular risk. This study aims to investigate the associations between u-Hp, pl-Hp, and oxidized LDL (ox-LDL) in obese patients with T2DM, and to evaluate the potential role of Hp as an early biomarker of cardiovascular risk in this high-risk population. Methods and Results: The study included 57 patients with T2DM (mean age 61 ± 10 years, HbA1c 8.66 ± 1.60%, and BMI 35.15 ± 6.65 kg/m²). Notably, 95% of the patients had hypertension, 82% had dyslipidemia, and 59% had an estimated glomerular filtration rate (eGFR) < 60 mL/min/1.73 m². Pl-Hp and u-Hp concentrations, as well as ox-LDL levels, were assessed using an enzyme-linked immunosorbent assay (ELISA). Correlations and multivariate regression analyses were employed to investigate the associations between Hp, ox-LDL, and clinical cardiovascular risk factors. Pl-Hp was positively correlated with ox-LDL (r = 0.358, p < 0.006) and negatively correlated with C-reactive protein (CRP) (r = −0.364, p < 0.013), while u-Hp correlated positively with HbA1C and apoB levels (r = 0.298, p < 0.030 and r = 0.310, p < 0.021, respectively). Multivariate analysis indicated that pl-Hp, but not u-Hp, was independently associated with ox-LDL (β = 0.536, p < 0.027) after adjusting for potential confounding factors, including age, gender, BMI, HbA1c, liver enzymes, hs-CRP and creatinine. The Stepwise analysis identified IL-6 as the most significant predictor of cardiovascular disease risk, suggesting its pivotal role in subclinical vascular inflammation among obese individuals with T2DM. Furthermore, the significant positive association between pl-Hp and ox-LDL was stronger in patients with declining renal function as expressed by the estimated glomerular filtration rate (eGFR) (eGFR < 30 mL/min/1.73 m²: β = 2.173, p < 0.031 and eGFR 30–59 mL/min/1.73 m²: β = 1.318, p < 0.002). This association also appeared in early and low-normal ranges of serum albumin: creatinine ratio (s-ACR) (s-ACR < 0.2714 mg/mmol: β = 2.304, p < 0.005 and s-ACR 0.2714–0.3649 mg/mmol: β = 1.000, p < 0.041), suggesting that pl-Hp and ox-LDL rise before overt kidney damage. Elevated IL-6 (≥32.93 pg/mL) further strengthened this link (β = 1.037, p < 0.005), highlighting the role of inflammation in amplifying oxidative stress and acute-phase responses. Conclusions: Taken together, these findings emphasize the interconnected contributions of renal impairment, inflammation, and oxidative stress to vascular injury. While these results need to be confirmed in larger prospective longitudinal studies, monitoring pl-Hp levels in conjunction with inflammatory and kidney function markers could be a sensitive and non-invasive way to identify early CVD risk in high-risk groups, such as obese patients with T2DM. Full article

Salinity, a critical environmental factor for fish survival, remains poorly understood in terms of how Triplophysa strauchii, a characteristic fish in Northwest China, physiologically responds to salinity stress. This study aimed to determine its salinity tolerance threshold and explore the associated physiological damage mechanisms. Six salinity gradients (11, 11.7, 12.5, 13.3, 14.3, 15.1 ppt) and a freshwater control group were established. Acute toxicity tests recorded mortality and behavior, while physiological–biochemical assays measured ion concentrations and enzyme activities in gills, kidneys, liver, intestines, and plasma over 96 h. The results showed a 96-hour median lethal concentration of 13.31 ppt and a safe concentration of 4.05 ppt. Gills and kidneys, as primary osmoregulatory organs, responded rapidly, whereas the liver and intestine lagged. Salinity ≤ 13.3 ppt allowed the fish to maintain homeostasis via physiological adjustments, but ≥14.3 ppt caused ion imbalance, immune function was significantly suppressed, and irreversible damage. These findings clarify the species’ salinity adaptation strategies, providing a basis for further research on chronic salinity stress. Full article

Ischemia-reperfusion (I/R) injury refers to the exacerbation of tissue or organ damage upon the restoration of blood flow after an ischemic event. Despite its widespread clinical occurrence, therapeutic interventions for I/R injury remain limited in efficacy, presenting a significant challenge in modern medicine. Garlic, traditionally consumed as a food, has gained considerable attention for its medicinal properties. Numerous animal studies have shown that garlic-derived organic polysulfides significantly improve nerve function scores post-I/R, reduce infarct size, mitigate inflammatory responses, and inhibit cellular apoptosis. Thus, understanding the role of garlic-derived organic polysulfides in I/R injury may unveil novel therapeutic targets. This review explores the protective effects and mechanisms of garlic-derived organic polysulfides on I/R injury in various organs, including the brain, spinal cord, myocardium, lungs, liver, kidneys, and testes, highlighting their potential in advancing treatment strategies for affected patients. Full article

Polytrauma is a critical global health concern characterized by immune dysregulation and a high risk of multiple organ dysfunction syndrome (MODS). Early molecular mechanisms linking trauma severity to organ injury are poorly understood. We used two rat blast-polytrauma models: a tourniquet-induced ischemia/reperfusion injury (tIRI) model and a non-ischemia/reperfusion injury (non-IRI) model. Naïve animals served as controls. RT-qPCR of 120 inflammatory genes in the lung, kidney, and liver, combined with STRING protein–protein interaction analysis, revealed distinct yet overlapping inflammatory gene signatures across all the organs. A core set of genes (Il6, Lbp, Nos2, and Lcn2) was consistently upregulated, indicating shared inflammatory pathways. Transcriptomic responses were most pronounced in the tIRI group, with greater magnitude and altered temporal dynamics, uniquely amplifying pro-inflammatory cytokines, immune cell activators, chemokines, and tissue damage markers. Lipocalin-2 (Lcn2/NGAL) emerged as a shared hub gene across all the organs within 24 h post-injury. Its expression significantly correlated with MODS activity and adverse outcomes, independent of the injury model. At 168 h, Lcn2 expression correlated with increased liver damage and NGAL levels correlated with tissue trauma severity. These findings elucidate distinct pro-inflammatory mediators and networks underlying secondary organ dysfunction, highlighting NGAL as a potential universal biomarker of trauma-induced inflammation and MODS activity, suggesting it as a therapeutic target. Full article

In recent years, irisin has garnered significant interest among researchers. It is a myokine released by skeletal muscles during physical exercise. Its expression occurs not only in skeletal muscles but also in other organs such as the liver, kidneys, and lungs, where it fulfills important metabolic and protective functions. Irisin is involved in the regulation of energy homeostasis, promotes the browning of adipose tissue, plays a protective role, and influences the body’s adaptation to physical exercise. In the context of internal organ function, studies suggest its potential role in protecting the kidneys from damage, modulating inflammatory processes in the lungs, and supporting liver regeneration. This literature review focuses on analyzing the therapeutic effects of irisin in these organs in relation to the role of physical exercise. Full article

Barium chloride (BaCl₂), a known environmental pollutant, induces organ-specific oxidative stress through disruption of redox homeostasis. This study evaluated the protective effects and safety profile of sodium copper chlorophyllin (SCC) and ascorbic acid (ASC) against BaCl₂-induced oxidative damage in the liver and brain of mice using a two-phase experimental protocol. Animals received either SCC (40 mg/kg), ASC (160 mg/kg), or their combination for 14 days prior to BaCl₂ exposure (150 mg/L in drinking water for 7 days), allowing evaluation of both preventive and therapeutic effects. Toxicological and behavioral assessments confirmed the absence of systemic toxicity or neurobehavioral alterations following supplementation. Body weight, liver and kidney indices, and biochemical markers (Aspartate Aminotransferase (ASAT), Alanine Aminotransferase (ALAT), creatinine) remained within physiological ranges, and no anxiogenic or locomotor effects were observed. In the brain, BaCl₂ exposure significantly increased SOD (+49%), CAT (+66%), GPx (+24%), and GSH (+26%) compared to controls, reflecting a robust compensatory antioxidant response. Although lipid peroxidation (MDA) showed a non-significant increase, SCC, ASC, and their combination reduced MDA levels by 42%, 37%, and 55%, respectively. These treatments normalized antioxidant enzyme activities and GSH, indicating an effective neuroprotective effect. In contrast, the liver exhibited a different oxidative profile. BaCl₂ exposure increased MDA levels by 80% and GSH by 34%, with no activation of SOD, CAT, or GPx. Histological analysis revealed extensive hepatocellular necrosis, vacuolization, and inflammatory infiltration. SCC significantly reduced hepatic MDA by 39% and preserved tissue architecture, while ASC alone or combined with SCC exacerbated inflammation and depleted hepatic GSH by 71% and 78%, respectively, relative to BaCl₂-exposed controls. Collectively, these results highlight a differential, organ-specific response to BaCl₂-induced oxidative stress and the therapeutic potential of SCC and ASC. SCC emerged as a safer and more effective agent, particularly in hepatic protection, while both antioxidants demonstrated neuroprotective effects when used individually or in combination. Full article

With ketamine gaining attention as a therapeutic drug, oral administration offers an effective alternative to traditional parenteral routes. However, a significant gap remains in understanding its use via voluntary ingestion. This preliminary study aimed to explore the feasibility of oral ketamine self-administration in mice (Mus musculus), while investigating the effects of low concentrations on the brain, liver, and kidney. Adult mice were divided into three groups and received ketamine in their drinking water for 16 days at 0 (control), 5 (K5), or 10 mg/L (K10). A transient decrease in water consumption was observed in both sexes in the K10 group; however, only females in this group showed differences in ketamine intake between groups on some days. Oxidative stress markers measured in the brain, liver, and kidney only revealed higher catalase activity in the brains of females. No significant alterations were observed in liver and kidney function in either sex, nor in inflammation, apoptosis, or DNA damage in kidney tissues. Overall, these findings support the viability of voluntary oral ketamine administration and accentuate the need to refine the proposed model, not only to prevent water consumption inhibition but also to extend the exposure period, explore potential sex-related differences in ketamine intake, and further confirm the safety of oral ketamine administration. Full article