Diversity and disparities in research studies and career trajectories in psychiatry.

It is well recognized that underrepresented and systematically minoritized groups do not have balanced access to clinical trials as study participants or as research Investigators. However, comprehensive data on the perspective of expert clinicians is largely lacking in the current literature. In this pilot exploration, we collected the opinions of 33 subject matter experts (SME) to identify and explore potential barriers to diversification in clinical trials. The majority of respondents live in North America or Central or Western Europe and identified as not a member of an underrepresented or marginalized group (UMB), with about 15% of respondents being a member of a UMB. Overall, about a quarter of respondents reported making an intentional effort to recruit members of UMB as study participants and identified recruitment challenges linked to two areas: psycho-social barriers and practical barriers. A variety of strategies were employed to improve recruitment including engagement with community leaders, targeted advertising, utilizing databases, and social media campaigns. About half of respondents reported difficulties recruiting Investigators from UMB backgrounds, stating culture and language barriers, perceived lack of interest in the field among individuals from UMB, and lack of information as possible reasons for the challenges.

Microarray analysis identifies defects in regenerative and immune response pathways in COPD airway basal cells.

BACKGROUND: Airway basal cells are specialised stem cells and regenerate airway epithelium. Airway basal cells isolated from patients with COPD regenerate airway epithelium with an abnormal phenotype. We performed gene expression analysis to gain insights into the defective regenerative programme in COPD basal cells. METHODS: We conducted microarray analysis and compared COPD versus normal basal cells to identify differentially regulated genes (DEGs) and the enriched biological pathways. We determined the correlation of DEGs with cell polarisation and markers of ciliated and goblet cells. HOXB2 was knocked down in 16HBE14o- cells and monitored for polarisation of cells. HOXB2 expression in the lung sections was determined by immunofluorescence. RESULTS: Comparison of normal and COPD basal cell transcriptomic profiles highlighted downregulation of genes associated with tissue development, epithelial cell differentiation and antimicrobial humoral response. Expression of one of the tissue development genes, HOXB2 showed strong correlation with transepithelial resistance and this gene was downregulated in COPD basal cells. Knockdown of HOXB2, abrogated polarisation of epithelial cells in normal cells. Finally, HOXB2 expression was substantially reduced in the bronchial epithelium of COPD patients. CONCLUSIONS: Defect in gene signatures involved in tissue development and epithelial differentiation were implicated in COPD basal cells. One of the tissue developmental genes, HOXB2, is substantially reduced in bronchial epithelium of COPD patients. Since HOXB2 contributes to airway epithelial cell polarisation, we speculate that reduced expression of HOXB2 in COPD may contribute to abnormal airway epithelial regeneration in COPD.

Rhinovirus and COPD airway epithelium.

Chronic Obstructive Pulmonary Disease (COPD) is characterized by irreversible airflow limitation. It is a global disease and expected to be the third leading cause of death. Respiratory exacerbations are associated with increased mortality and morbidity in this patient population. Respiratory viruses were isolated from at least 30 to 50% of the infectious respiratory COPD exacerbations with rhinovirus being most commonly isolated pathogen. Although rhinovirus does not cause airway epithelial damage like influenza and other respiratory viruses, it may further impair innate immunity of airway epithelium, which is the first line of defense in the lungs. This may increase susceptibility to secondary bacterial infections leading to progression of lung disease. Currently, there arc no therapies available to treat rhinovirus infection in COPD and therefore understanding the mechanisms underlying RV pathogenesis in COPD is essential to identify molecular target to develop new therapeutic strategies. Quercetin, a plant polyphenol, which modulates innate immunity and effectively blocks viral replication may be useful in treating rhinovirus associated COPD exacerbations.