The current criterion of biochemical response to ursodeoxycholic acid in primary biliary cholangitis is an alkaline phosphatase (ALP) level of ≤1.67 × the upper limit of normal (ULN) after 12 months of treatment. However, a proportion of patients who meet this parameter may still progress to liver decompensation. This study aimed to optimize the clinical management of primary biliary cholangitis by (1) establishing ALP normalization as a core treatment target, (2) identifying early intervention windows, and (3) developing risk stratification criteria.

This multicenter retrospective study included an internal cohort and an external validation cohort. We assessed the prognostic impact of ALP normalization with Kaplan-Meier and Cox regression. Sankey diagrams and segmented Poisson regression analysis mapped dynamic risk transitions to identify critical intervention windows. Predictive performance (sensitivity/specificity/positive predictive value/negative predictive value (NPV)) of Mayo, Paris II, and Toronto criteria for 12-month ALP normalization was compared.

Patients achieving ALP normalization showed significantly higher complication-free survival versus those with ALP 1.0–1.67 × ULN (89.8% vs. 79.8%; P = 0.016). Segmented Poisson regression identified significant change points at 3.73 and 5.5 months for high-to-medium and medium-to-low risk transitions, respectively. Failure to meet the Toronto criteria at month 3 predicted non-normalization with 95% NPV, whereas Paris II criteria at month 6 provided optimal specificity (73%) for identifying patients who failed to achieve ALP normalization.

ALP normalization significantly improves clinical outcomes. Two subgroups demonstrate low normalization probability and warrant early intervention: (1) patients with ALP ≥ 1.67 × ULN after 3 months and (2) those not meeting Paris II criteria by month 6.

Adeno-associated virus (AAV) vectors have favorable safety and durable transgene expression but are limited in oncology by insufficient tumor specificity and off-target expression. Tumor hypoxia and non-small cell lung cancer (NSCLC)-associated surface ligands offer complementary layers of biological selectivity for more precise gene delivery. This study proposes an NSCLC-directed, hypoxia-responsive AAV architecture that integrates MGS4-guided capsid targeting with dual hypoxia-responsive element (HRE)-gated promoters driving glutamine-modified C-X-C motif chemokine ligand 9-fragment crystallizable region fusion protein (Q-CXCL9-Fc) expression and baculoviral IAP repeat containing 5 (BIRC5)-linked mesothelin (MSLN) silencing. We conceptually designed an AAV vector that combines three layers of NSCLC selectivity: MGS4-guided capsid targeting, hypoxia-gated transcription, and tumor-active promoter control. The capsid displays the MGS4 peptide, isolated by phage display biopanning as a high-affinity ligand for the lung squamous cell carcinoma cell line HCC15 and later shown to internalize into a substantial fraction of NSCLC cell lines and bind a subset of human NSCLC biopsy samples, indicating activity across multiple NSCLC subtypes. The genome encodes Q-CXCL9-Fc under a 4× HRE-cytomegalovirus promoter to sustain C-X-C motif chemokine receptor 3-dependent T-cell recruitment and a miR-30-based short hairpin RNA targeting MSLN under a 4× HRE-BIRC5 promoter to inhibit tumor progression. This architecture is hypothesized to enrich AAV entry into NSCLC lesions via MGS4 while restricting Q-CXCL9-Fc secretion and MSLN silencing to hypoxic, BIRC5-active tumor regions, enabling synergistic enhancement of antitumor immunity and suppression of tumor-intrinsic pathways. The proposed multimodal, hypoxia-responsive AAV platform represents a conceptual precision oncology strategy that couples environmental sensing, tumor-specific transcription, and peptide-defined tropism within a single vector and could inform next-generation NSCLC-directed AAV systems.

The pathogenic role of MIR142 genetic abnormalities in the development of primary diffuse large B-cell lymphoma (DLBCL) of the central nervous system (CNS) is unexplored. The objective of this study was to investigate the frequency, spectrum, and functional significance of mutations in the MIR142 gene in primary CNS DLBCL.

Direct Sanger sequencing of the MIR142 gene was performed in tumor tissue from 35 patients with primary DLBCL of the CNS. In silico prediction of microRNA (miRNA)–target interactions, enrichment analysis of target gene ontologies, and prediction of the secondary structure and minimum free energy of the miRNA hairpin were performed.

The mutation frequency was 37.1% (95% confidence interval: 23.2–53.7%). The vast majority of the identified single-nucleotide variants were located outside the regions encoding mature miRNA chains. In silico analysis showed that the n.29A>G mutation located in the seed sequence of miR-142-5p resulted in a significant reduction in the number of potential targets and alterations to the interaction spectrum. All single-nucleotide variants identified in the study patients caused a change in minimum free energy and affected the shape and length of the hairpin stem of pri-miRNA. The results indicate the fragility of the pri-miR-142 hairpin.

The frequency of gene mutations in primary DLBCL of the CNS significantly exceeds that reported for systemic DLBCL.

Metabolic dysfunction–associated steatotic liver disease (MASLD), defined by the American Association for the Study of Liver Diseases as hepatic steatosis with at least one cardiometabolic risk factor, affects approximately 30–40% of adults worldwide. This condition may progress to fibrosis, cirrhosis, and hepatocellular carcinoma. The rising prevalence, alongside obesity and type 2 diabetes, underscores the need for early risk stratification and integrated therapeutic strategies. Circadian homeostasis, orchestrated by the suprachiasmatic nucleus and core clock gene feedback loops, synchronizes hepatic metabolic pathways with environmental light–dark cycles. The objective of this review is to evaluate the role of circadian disruption and metabolic dysfunction in the development of hepatic steatosis, as well as to assess current and potential treatment modalities for both disorders. Circadian disruption through shift work, artificial light at night, sleep restriction, and chrono-nutritional misalignment destabilizes hepatic clocks, promoting insulin resistance, dyslipidemia, inflammation, and steatosis. Experimental models demonstrate that clock gene dysfunction alone can induce steatohepatitis, while progressive MASLD further impairs central circadian regulation, establishing a self-reinforcing chrono-metabolic cycle. Pharmacologic therapies, including glucagon-like peptide-1 receptor agonists and thyroid hormone receptor-β agonists, improve histologic endpoints and fibrosis regression, although heterogeneity among clinical trials precludes direct comparison. Recent evidence characterizing MASLD as a predominantly nocturnal metabolic disorder further highlights persistent nighttime insulin dysregulation despite weight loss, emphasizing the potential role of circadian-targeted interventions such as melatonin. In conclusion, the peripheral circadian clock is intricately linked with MASLD pathogenesis, and metabolic dysfunction, in turn, disrupts circadian pathways. Several pharmacologic therapies offer potential for the treatment of MASLD and circadian dysfunction.

Irinotecan is a camptothecin derivative that exerts its antitumor effects after conversion into the active metabolite 7-ethyl-10-hydroxycamptothecin (SN-38), and it is widely used for the treatment of various advanced solid tumors. However, irinotecan-induced neutropenia (IIN) remains one of its most common and clinically significant hematological toxicities, increasing the risk of infection, treatment interruption, dose reduction, and poor therapeutic outcomes. This review aims to summarize the pathogenesis, risk factors, and management strategies of IIN to provide practical guidance for its clinical prevention and standardized management. Current evidence suggests that IIN is mainly associated with SN-38-mediated topoisomerase I inhibition and mitochondrial injury in hematopoietic stem cells, leading to impaired neutrophil production. The risk of IIN is influenced by irinotecan dosage, UGT1A and transporter gene polymorphisms, baseline patient characteristics, organ function, and concomitant chemotherapy. Preventive and therapeutic strategies include genotype-guided dose adjustment, careful dose optimization, oral alkalinizing agents, granulocyte colony-stimulating factor support, and modulation of intestinal microbiota. In conclusion, IIN is a multifactorial and potentially manageable adverse reaction. Integrating pharmacogenetic testing, individualized dosing, supportive care, and emerging approaches such as microbiota-based interventions may improve the safety and continuity of irinotecan-based chemotherapy.