International Journal of Molecular Sciences

COVID-19 and influenza A (FluA) cause severe respiratory infections in elderly patients, with cytokine dysregulation playing a central role. Direct comparative data in older adults remains limited. We aimed to characterize cytokine dynamics and their prognostic value in hospitalized elderly patients with COVID-19 vs. FluA. We performed a prospective cohort study including adults ≥ 60 years hospitalized with respiratory failure due to COVID-19 or FluA between March 2023 and March 2024. Serum IL-1β, IL-6, IL-10, IL-17A, IL-34, MCP-1, and CXCL10 were measured on Day 1 and Day 5 of hospitalization using Luminex^®. Cytokines and associations with non-invasive ventilation (NIV) were assessed by ROC analysis and multivariate logistic regression. 83 patients were included (39 COVID-19, median age 79 years; 44 FluA, median 77 years). At Day 1, COVID-19 exhibited significantly higher IL-6, IL-10, and CXCL10; FluA showed an attenuated cytokine response. At Day 5, cytokines declined in both groups. Baseline IL-6 independently predicted NIV (adjusted OR 3.02), whereas higher MCP-1 was associated with reduced NIV requirement. Early cytokine differences between COVID-19 and FluA are evident in elderly patients, but values converged by Day 5. IL-6 remains an informative early predictor of respiratory deterioration; MCP-1 may reflect a regulated innate response.

Developmental biology is focused on the study of all phenotypic traits responsible for the timely and adequate progression of all molecular genetic, biochemical, and morphogenetic processes as the norm of the corresponding biological species in an individual living organism (ontogenesis) from either fertilization during sexual reproduction or separation from the maternal organism during asexual reproduction to the end of its life [...]

The neurovascular unit (NVU) is an essential, dynamic multicellular unit that maintains the homeostasis and function of the brain, with the integrity of the NVU having a tremendous impact on the pathogenic progression of ischemic stroke (IS). MicroRNAs (miRNAs) are essential regulators of gene expression and promote intercellular communication and functional unity in the NVU. This narrative review assesses the regulatory process mediated by miRNAs that help maintain homeostasis of the NVU, particularly during IS, with particular emphasis on their modulation of tight-junction (TJ) proteins, basement membrane (BM) and glial–vascular. These regulatory actions are essential for blood–brain barrier (BBB) integrity and neuronal survival. The analysis also exposes the intercommunication networks established by key miRNAs between various cells of the NVU, highlighting their complex and dynamic regulatory properties. Moreover, it investigates therapeutic strategies predicated on miRNA regulatory mechanisms, highlighting the optimistic prospects as well as the present limitations pertaining to effective IS intervention.