Physical inactivity is a health concern for children and adolescents with neurodevelopmental disorders (NDDs) as it directly increases their risk of developing various health problems. Evidence on dif Show more
Physical inactivity is a health concern for children and adolescents with neurodevelopmental disorders (NDDs) as it directly increases their risk of developing various health problems. Evidence on differences in accelerometer-assessed physical activity between children and adolescents with and without NDDs is inconclusive. And age- and body mass index (BMI)-related effects on physical activity remain unclear. The systematic literature searches were performed in 6 databases up to March 2025. Methodological quality was evaluated by the Newcastle-Ottawa Scales. Data were pooled using a random-effects model. Hedges' g was used to express the effect size index with 95β―% confidence interval (CI). Meta-regression on age and BMI was also performed to investigate the potential moderating effects. Out of the 2167 studies initially identified, 28 were included in the analysis, which comprised total physical activity (TPA), moderate-to-vigorous physical activity (MVPA), and light physical activity (LPA) included in the meta-analysis, respectively. These studies involved 1060 children and adolescents with NDDs and 1820 without, aged 6.6-16.9 years. A small-to-moderate effect size exists for the difference in TPA (g=-0.299) and MVPA (g=-0.479) between children and adolescents with and without NDD, particularly indicating a difference in 12.7β―min of MVPA daily. The difference in LPA was not significant (g=0.450, pβ―=β―0.125). The decline in MVPA with age was more pronounced in those with NDDs, and the difference in MVPA was smaller for those with lower BMI. The variation in MVPA differences by age and BMI highlights the need to develop better physical activity habits and reduce these disparities for children and adolescents with NDDs. Show less
Gastric intestinal metaplasia ( This study was based on clinical and genomic data from four cohorts: 1) GAPS, a GIM cohort with detailed OLGIM severity scoring (N=303 samples); 2) the Cancer Genome At Show more
Gastric intestinal metaplasia ( This study was based on clinical and genomic data from four cohorts: 1) GAPS, a GIM cohort with detailed OLGIM severity scoring (N=303 samples); 2) the Cancer Genome Atlas (N=198); 3) a collation of in-house and publicly available scRNA-seq data (N=40), and 4) a spatial validation cohort (N=5) consisting of annotated histology slides of patients with either GC or advanced GIM. We used a multi-omics pipeline to identify, validate and sequentially parse a highly-refined signature of 26 genes which characterize high-risk GIM. Using standard RNA-seq, we analyzed two separate, non-overlapping discovery (N=88) and validation (N=215) sets of GIM. In the discovery phase, we identified 105 upregulated genes specific for high-risk GIM (defined as OLGIM III-IV), of which 100 genes were independently confirmed in the validation set. Spatial transcriptomic profiling revealed 36 of these 100 genes to be expressed in metaplastic foci in GIM. Comparison with bulk GC sequencing data revealed 26 of these genes to be expressed in intestinal-type GC. Single-cell profiling resolved the 26-gene signature to both mature intestinal lineages (goblet cells, enterocytes) and immature intestinal lineages (stem-like cells). A subset of these genes was further validated using single-molecule multiplex fluorescence using an integrated multi-omics approach, we identified a novel 26-gene expression signature for high-OLGIM precursors at increased risk for GC. We found this signature localizes to aberrant intestinal stem-like cells within the metaplastic microenvironment. These findings hold important translational significance for future prevention and early detection efforts. Show less
Painful Diabetic Neuropathy (PDN) is a debilitating syndrome present in a quarter of diabetic patients that has a substantial impact on their quality of life. Despite this significant prevalence and i Show more
Painful Diabetic Neuropathy (PDN) is a debilitating syndrome present in a quarter of diabetic patients that has a substantial impact on their quality of life. Despite this significant prevalence and impact, current therapies for PDN are only partially effective. Moreover, the cellular mechanisms underlying PDN are not well understood. Neuropathic pain is caused by a variety of phenomena including sustained excitability in sensory neurons that reduces the pain threshold so that pain is produced in the absence of appropriate stimuli. Chemokine signaling has been implicated in the pathogenesis of neuropathic pain in a variety of animal models. We therefore tested the hypothesis that chemokine signaling mediates DRG neuronal hyperexcitability in association with PDN. We demonstrated that intraperitoneal administration of the specific CXCR4 antagonist AMD3100 reversed PDN in two animal models of type II diabetes. Furthermore DRG sensory neurons acutely isolated from diabetic mice displayed enhanced SDF-1 induced calcium responses. Moreover, we demonstrated that CXCR4 receptors are expressed by a subset of DRG sensory neurons. Finally, we observed numerous CXCR4 expressing inflammatory cells infiltrating into the DRG of diabetic mice. These data suggest that CXCR4/SDF-1 signaling mediates enhanced calcium influx and excitability in DRG neurons responsible for PDN. Simultaneously, CXCR4/SDF-1 signaling may coordinate inflammation in diabetic DRG that could contribute to the development of pain in diabetes. Therefore, targeting CXCR4 chemokine receptors may represent a novel intervention for treating PDN. Show less
Liu Yang, Wing Sum Hui, Wilson C W Chan+10 more Β· 2010 Β· Journal of orthopaedic research : official publication of the Orthopaedic Research Society Β· Wiley Β· added 2026-04-24
Multiple osteochondromas (MO) is an autosomal-dominant disorder and mutations in EXT1 and EXT2 account up to 78% of the cases studied, including missense, nonsense, frameshift, and splice-site mutatio Show more
Multiple osteochondromas (MO) is an autosomal-dominant disorder and mutations in EXT1 and EXT2 account up to 78% of the cases studied, including missense, nonsense, frameshift, and splice-site mutations. EXT1 and EXT2 encode glycosyltransferases required for the synthesis of heparan sulfate (HS) chains. The molecular pathogenesis underlying these mutations is still largely unknown. A heterozygous c.1173β+ 1G > T (EXT2) mutation was identified in a three-generation 34-member MO family and is present in all 19 affected members. The consequence of this mutation is exon 7 being spliced out, and the result is a shift in the codon-reading frame from position 360 (R360) of the amino acid sequence leading to a premature termination codon, and the mutant mRNA is degraded to an undetectable level. Interestingly, HS glycosaminoglycans were also undetectable in the cartilage cap of the tumors by immunostaining. Full penetrance of this mutation in all affected members ranging from 5 to 70 years of age suggests this primary defect in EXT2 mRNA level, in conjunction with other cellular changes such as enhanced heparanase expression, can produce profound effect on the synthesis of HS chains in cartilage, the consequence of which impacts on the regulation of chondrocyte proliferation and differentiation. Show less