Alterations in brain morphology and functional connectivity mediate cognitive decline in carotid atherosclerotic stenosis.

Background: Patients with carotid atherosclerotic stenosis (CAS) often have varying degrees of cognitive decline. However, there is little evidence regarding how brain morphological and functional abnormalities impact the cognitive decline in CAS patients. This study aimed to determine how the brain morphological and functional changes affected the cognitive decline in patients with CAS. Methods: The brain morphological differences were analyzed using surface and voxel-based morphometry, and the seed-based whole-brain functional connectivity (FC) abnormalities were analyzed using resting-state functional magnetic resonance imaging. Further, mediation analyses were performed to determine whether and how morphological and FC changes affect cognition in CAS patients. Results: The CAS-MCI (CAS patients with mild cognitive impairment) group performed worse in working memory, verbal fluency, and executive time. Cortical thickness (CT) of the left postcentral and superiorparietal were significantly reduced in CAS-MCI patients. The gray matter volume (GMV) of the right olfactory, left temporal pole (superior temporal gyrus) (TPOsup.L), left middle temporal gyrus (MTG.L), and left insula (INS.L) were decreased in the CAS-MCI group. Besides, decreased seed-based FC between TPOsup.L and left precuneus, between MTG.L and TPOsup.L, and between INS.L and MTG.L, left middle frontal gyrus, as well as Superior frontal gyrus, were found in CAS-MCI patients. Mediation analyses demonstrated that morphological and functional abnormalities fully mediated the association between the maximum degree of carotid stenosis and cognitive function. Conclusion: Multiple brain regions have decreased GMV and CT in CAS-MCI patients, along with disrupted seed-based FC. These morphological and functional changes play a crucial role in the cognitive impairment in CAS patients.

[Frontal pole iron deposition is associated with cognitive decline in patients with carotid atherosclerosis stenosis: a quantitative susceptibility mapping study].

Objective: To investigate the correlation between brain iron deposition and cognitive function in patients with carotid atherosclerosis stenosis (CAS) based on quantitative susceptibility mapping (QSM). Methods: This single-center prospective study was performed at the Department of Vascular Surgery, Nanjing Drum Tower Hospital from January 2022 to June 2022. Patients who met the ataxation criteria were divided into the CAS group (n=16) and the CAS with mild cognitive impairment (CAS-MCI) group (n=17) according to the Montreal Cognitive Assessment (MoCA) scores. All patients completed QSM imaging and whole-brain analyses were performed for absolute susceptibility values in cortical regions. Age, sex, education years, hypertension, and diabetes mellitus were included as covariates in all analyses. Partial correlation analyses were used to determine the correlation between bilateral CAS degrees and cortical susceptibility values. Further, mediation analyses were performed to determine whether and how cortical susceptibility values affect cognition in CAS patients. Receiver operating characteristic (ROC) curve analysis was also performed to evaluate the predictive worth of differential brain region susceptibility values for cognitive decline. Independent sample t test and Mann-Whitney U test was used to compare quantitative variables. The comparison of categorical variables was conducted using χ2 test, Fisher's exact test or Wilcoxon rank sum test. Results: A total of 33 patients were included in the study, including 16 in the CAS group and 17 in the CAS-MCI group. There were 23 males and 10 females, aged (62.8±9.0) years (range: 48 to 88 years). CAS-MCI group showed higher right CAS grades (Z=-2.037, P=0.042). Whole-brain cortical QSM analyses showed higher susceptibility values in the frontal pole ((-0.210±0.080)×10-8 vs.(-0.130±0.120)×10-8;t=-2.187, P=0.037), superior frontal gyrus ((-0.604±0.243)×10-8 vs. (-0.428±0.203)×10-8;t=-2.223,P=0.034), and temporal pole ((-0.081±0.115)×10-8 vs. (0.054±0.190)×10-8;t=-2.417, P=0.022) in CAS-MCI group compared to CAS group. The susceptibility value of the frontal pole showed a positive correlation with the right CAS grade (r=0.424, P=0.009),while a quasi-significant positive correlation with the left CAS (r=0.313, P=0.070). The susceptibility values of the frontal and temporal poles were negatively correlated with the MoCA score (frontal pole: r=-0.391, P=0.027; temporal pole: r=-0.410, P=0.020). Mediation analysis showed the effect of right CAS on cognition was fully mediated by the susceptibility value of the frontal pole. The ROC curve revealed that the area under the curve of using hypertension combined with the susceptibility value of the frontal pole to predict cognitive decline was 0.882 (95% CI:0.763 to 0.989) with 82% of sensitivity and 83% of specificity. Conclusions: Multiple cortical regions show iron deposition in CAS-MCI patients. Right CAS plays an important role in cognitive decline, frontal pole iron deposition mediates the effect of right CAS on cognitive function. Quantified frontal pole susceptibility is useful for the diagnosis of cognitive decline in patients with CAS.

Tumor-Promoting Actions of HNRNP A1 in HCC Are Associated with Cell Cycle, Mitochondrial Dynamics, and Necroptosis.

Hepatocellular carcinoma (HCC) is one of the most frequent malignancies in the world. Although increasing evidence supports the role of heterogeneous ribonucleoprotein particle A1 (HNRNP A1) in tumor progression, the function of HNRNP A1 in HCC remains unclear. Here, we focused on the role of HNRNP A1 in the development of HCC. In this study, we found HNRNP A1 participates in many aspects of HCC, such as progression and prognosis. Our results showed that HNRNP A1 is upregulated in human HCC tissues and cell lines. High expression of HNRNP A1 can promote the proliferation, migration, and invasion in HCC cells and accelerate tumor progression in mice. Moreover, we found that HNRNP A1 prevents the senescence process of HCC cells. Knocking down of HNRNP A1 promotes the expression of P16INK4, which arrests the cell cycle and then induces the senescence phenotype in HCC cells. Furthermore, we found that HNRNP A1 regulated necroptosis and mitochondrial dynamics. In summary, our study indicates that HNRNP A1 promotes the development of HCC, which suggests a potential therapeutic target for HCC.