Ulcerative colitis （UC） is a chronic， non-specific intestinal inflammatory disease. Its pathogenesis is complex， involving interactions among genetic， immune， and environmental factors， and remains incompletely elucidated. Mitochondrial damage can trigger the abnormal release of mitochondrial damage-associated molecular patterns （mtDAMPs）， activating inflammatory pathways and thereby exacerbating the inflammatory response in UC. Mitophagy， a core mitochondrial quality control mechanism， can clear damaged mitochondria and effectively reduce the abnormal release of mtDAMPs and the accumulation of harmful substances， thereby mitigating inflammatory damage resulting from mitochondrial dysfunction. Mitophagy plays a crucial role in maintaining the integrity of the intestinal epithelial barrier function and in the prevention and intervention of UC. Notably， the function of the spleen governing transportation and transformation in traditional Chinese medicine shares similarities with the role of mitochondria in energy transformation and substance metabolism. Furthermore， the pathological state of the spleen failing in transportation and transformation may be related to mitochondrial dysfunction， while the pathogenic characteristics of "endogenous turbid pathogen" align with the inflammatory cascade responses triggered by abnormal release of mtDAMPs. Based on this theoretical correlation， this paper aims to explore the correlation between the traditional Chinese medicine theory of "spleen dysfunction in essence distribution leading to endogenous turbid pathogens" and mitophagy. Using the correlation as an entry point， the potential role of mitophagy in the pathogenesis of UC was elucidated. Additionally， by considering the epidemiological characteristics of UC in the Southwest region of China， a new thinking for the treatment of UC from the perspective of turbid pathogens was proposed based on the "fortifying the spleen and resolving turbidity" method to provide theoretical support and research enlightenment for further exploring the prevention and treatment of UC with traditional Chinese medicine.

OBJECTIVE: Circadian rhythm disruption (CRD) is a risk factor that correlates with poor prognosis across multiple tumor types, including hepatocellular carcinoma (HCC). However, its mechanism remains unclear. This study aimed to define HCC subtypes based on CRD and explore their individual heterogeneity. METHODS: To quantify CRD, the HCC CRD score (HCCcrds) was developed. Using machine learning algorithms, we identified CRD module genes and defined CRD-related HCC subtypes in The Cancer Genome Atlas liver HCC cohort (n = 369), and the robustness of this method was validated. Furthermore, we used bioinformatics tools to investigate the cellular heterogeneity across these CRD subtypes. RESULTS: We defined three distinct HCC subtypes that exhibit significant heterogeneity in prognosis. The CRD-related subtype with high HCCcrds was significantly correlated with worse prognosis, higher pathological grade, and advanced clinical stages, while the CRD-related subtype with low HCCcrds had better clinical outcomes. We also identified novel biomarkers for each subtype, such as nicotinamide n-methyltransferase and myristoylated alanine-rich protein kinase C substrate-like 1. CONCLUSION We classify the HCC patients into three distinct groups based on circadian rhythm and identify their specific biomarkers. Within these groups greater HCCcrds was associated with worse prognosis. This approach has the potential to improve prediction of an individual's prognosis, guide precision treatments, and assist clinical decision making for HCC patients. Please cite this article as: Li XJ, Chang L, Mi Y, Zhang G, Zhu SS, Zhang YX, et al. Integrated-omics analysis defines subtypes of hepatocellular carcinoma based on circadian rhythm. J Integr Med. 2025; 23(4): 445-456.
Humans ; Carcinoma, Hepatocellular/pathology* ; Liver Neoplasms/pathology* ; Circadian Rhythm/genetics* ; Prognosis ; Male ; Female ; Biomarkers, Tumor/genetics* ; Middle Aged ; Machine Learning ; Computational Biology

Long-term hypertension causes excessive vascular remodeling and leads to adverse cardiovascular events. Balance of ubiquitination and deubiquitination has been linked to several chronic conditions, including pathological vascular remodeling. In this study, we discovered that the expression of ubiquitin-specific protease 25 (USP25) is significantly up-regulated in angiotensin II (Ang II)-challenged mouse aorta. Knockout of Usp25 augments Ang II-induced vascular injury such as fibrosis and endothelial to mesenchymal transition (EndMT). Mechanistically, we found that USP25 interacts directly with Forkhead box O3 (FOXO3) and removes the K63-linked ubiquitin chain on the K258 site of FOXO3. We also showed that this USP25-mediated deubiquitination of FOXO3 increases its binding to light chain 3 beta isoform and autophagosomic-lysosomal degradation of FOXO3. In addition, we further validated the biological function of USP25 by overexpressing USP25 in the mouse aorta with AAV9 vectors. Our studies identified FOXO3 as a new substrate of USP25 and showed that USP25 may be a potential therapeutic target for excessive vascular remodeling-associated diseases.

Local anesthetics (LAs), such as articaine (AT), exhibit limited efficacy in inflammatory environments, which constitutes a significant limitation in their clinical application within oral medicine. In our prior research, we developed AT-17, which demonstrated effective properties in chronic inflammatory conditions and appears to function as a novel oral LA that could address this challenge. In the present study, we further elucidated the beneficial effects of AT-17 in acute inflammation, particularly in oral acute inflammation, where mitochondrial-related apoptosis played a crucial role. Our findings indicated that AT-17 effectively inhibited lipopolysaccharide (LPS)-induced nerve cell apoptosis by ameliorating mitochondrial dysfunction in vitro. This process involved the inhibition of mitochondrial reactive oxygen species (mtROS) production and the subsequent activation of the NRF2 pathway. Most notably, improvements in mitochondria-related apoptosis were key contributors to AT-17's inhibition of voltage-gated sodium channels. Additionally, AT-17 was shown to reduce mtROS production in nerve cells through the Na⁺/NCLX/ETC signaling axis. In conclusion, we have developed a novel local anesthetic that exhibits pronounced anesthetic functionality under inflammatory conditions by enhancing mitochondria-related apoptosis. This advancement holds considerable promise for future drug development and deepening our understanding of the underlying mechanisms of action.

AIM:To measure preoperative corneal curvature in elderly cataract patients using five different systems, including Keratograph 5M, Pentacam, KR.800 autorefractor, IOL Master, and KR-1W wavefront aberrometer, analyze its discrepancy and consistency, and provide a reference for accurate intraocular lens(IOL)power calculation in elderly patients before cataract surgery.METHODS:This prospective study included 53 elderly cataract in-patients(90 eyes)who were admitted to our ophthalmology department between October 2022 and November 2024. The corneal curvature values(K1, K2)of postoperative eyes were measured using Keratograph 5M, Pentacam, KR.800, IOL Master, and KR-1W, and the mean keratometry(Km)was calculated.RESULTS:Statistically significant differences were observed in K1, K2, and Km values between Keratograph 5M and Pentacam, as well as between Keratograph 5M and IOL Master(all P<0.05), whereas no significant differences were found in K1, K2 and Km between Keratograph 5M and KR.800 or KR-1W(all P>0.05). Pearson correlation analysis showed a certain correlation of K1, K2 and Km obtained from Keratograph 5M with those from KR.800, Pentacam, IOL Master, and KR-1W(r=0.913-0.987, all P<0.001). Bland-Altman scatter plots demonstrated good consistency between Keratograph 5M and KR.800 or KR-1W, while its consistency with Pentacam and IOL Master was relatively poor.CONCLUSION:As an ocular surface analyzer, Keratograph 5M offers advantages such as simplicity, rapid measurement, strong repeatability, and low patient cooperation requirements. In elderly patients, corneal curvature measurements obtained by Keratograph 5M demonstrated good consistency with those from KR.800 and KR-1W, making them interchangeable based on individual conditions and cooperation levels of patients. However, its consistency with Pentacam and IOL Master was relatively poor; therefore, clinical practical situation should be considered when selecting such measurement devices.

Objective:To evaluate the levels and source of cadmium exposure by dietary pathway among middle-aged and elderly people ≥40 in cadmium-contaminated areas of China.Methods:A total of 7 193 people aged 40-89 years from four typical cadmium-contaminated areas in China were selected as the study subjects. Food Frequency Questionnaire (FFQ), Total Diet Study (TDS) and a 3-day-24-hour dietary recall survey were conducted. Dietary cadmium intake and food sources through dietary pathways were assessed based on cadmium content in foods, consumption amounts and intake frequencies.Results:The mean age of the participants was 63.39±12.21 years, with 50.05% being males. The average monthly dietary cadmium intake was 7.39 μg/(kg·BW). Staple foods and vegetables were the primary sources of dietary cadmium intake, accounting for 57.51% and 32.48%, respectively. The monthly dietary cadmium intake in all surveyed regions did not exceed the Provisional Tolerable Monthly Intake (PTMI) recommended by the Joint FAO/WHO Expert Committee on Food Additives (JECFA).Conclusion:The monthly dietary cadmium intake among middle-aged and elderly people in cadmium-contaminated areas of China is relatively low, with the risk remaining at an acceptable level. Staple foods and vegetables are the most significant contributors to dietary cadmium intake.

Objective To investigate the differences of perineuronal net(PNN)and parvalbumin(PV)-positive neuron distribution across specific brain regions between young and aged mice.Methods Brains from young(45 days)and aged(350 days)mice(n=4 per group)were fixed with 4％paraformaldehyde,sectioned(50 μm)using a vibratome,and stained with Wisteria floribunda agglutinin(WFA)and PV immunofluorescence.Quantitative analyses of PNN-positive and PV-positive neurons,along with PNN encapsulation of PV-positive neurons,were performed in the anterior cingulate cortex(ACC),somatosensory cortex barrel field layer 4(S1BF L4),striatum(STR),and hippocampal CA2 region.Results Aged mice exhibited no significant changes in PNN-positive or PV-positive neuron counts in ACC,S1BF L4,or STR compared to young mice,but showed significantly increased PNN encapsulation of PV-positive neurons.In hippocampal CA2,PNN-positive neurons increased significantly without PV-positive neuron alterations.Conclusion The differences in PNN-PV neuron interactions and PNN density exist in specific brain regions of young and aged mice.

Objective To develop a method of combining electroencephalogram(EEG)/electromyography(EMG)with multi-regional fiber photometry recording to simultaneously capture the changes of neuronal activity in the whole brain and specific brain regions during epileptic seizures.Methods The mouse head was divided into left and right regions based on the middle suture of the skull.EEG electrodes(EEG/EMG)were implanted in one side,while optical fibers were implanted in the striatum,hippocampus,entorhinal cortex,and thalamus on the contralateral side to simultaneously monitor EEG,EMG,and calcium signal dynamics.Results By combining EEG/EMG with multi-regional fiber photometry recording,differences in neuronal activity across brain regions,alongside EEG and EMG,were observed during different behavioral states.In a kainic acid(KA)-induced epilepsy model,abnormal synchronous neuronal discharges in the mouse brain were accompanied by calcium signal changes in the striatum,hippocampus,entorhinal cortex,and thalamus,with the earliest changes occurring in the hippocampus.Conclusion The combined use of EEG/EMG and multi-brain-region fiber photometry is successfully implemented in mice.This method synchronously recordes abnormal calcium signal changes across multiple brain regions,along with EEG and EMG,in the KA-induced epilepsy model.

Atherosclerosis(AS)is the major pathologic basis of cardiovascular disease,and its complications,such as myocardial infarction and stroke,are primarily triggered by rupture of atherosclerotic vulnerable plaques(VASPs).Conventional imaging techniques rely on anatomical changes,making it difficult to assess plaque vulnerability at an early stage.In recent years,molecular imaging combined with nanoprobe technology has enabled precise visualization at the cellular and molecular levels by targeting pathological features of plaques(e.g.,lipid core,inflammation,thin fibrous cap,etc.).This article reviews the pathological features of VASPs,the limitations of existing imaging techniques,and the design principles and application progress of molecular imaging probes and discusses the challenges and future directions for their clinical translation.

Atherosclerosis(AS)is the major pathologic basis of cardiovascular disease,and its complications,such as myocardial infarction and stroke,are primarily triggered by rupture of atherosclerotic vulnerable plaques(VASPs).Conventional imaging techniques rely on anatomical changes,making it difficult to assess plaque vulnerability at an early stage.In recent years,molecular imaging combined with nanoprobe technology has enabled precise visualization at the cellular and molecular levels by targeting pathological features of plaques(e.g.,lipid core,inflammation,thin fibrous cap,etc.).This article reviews the pathological features of VASPs,the limitations of existing imaging techniques,and the design principles and application progress of molecular imaging probes and discusses the challenges and future directions for their clinical translation.