Calcific aortic valve disease (CAVD) is a major cardiovascular disorder in the developed countries. Male is a known risk factor in this disease; unfortunately, how sex contributes to CAVD is mostly unknown. The objective of this study is to determine whether valvular interstitial cells (VICs) isolated from male versus female aortic valves demonstrate difference in osteogenic differentiation and/or extracellular matrix (ECM) remodeling. VICs were isolated from male and female rat or porcine aortic valves and cultured in osteogenic media for 10, 15 and 20 days. The proliferation among male and female VICs was assessed by a cell growth assay. The matrix remodeling of the VIC samples was quantified using glycosaminoglycan (GAG), collagen type I and gelatin zymography assays. Early osteogenic marker expression was assessed using alkaline phosphatase (ALP) staining and enzyme activity assay and Alizarin Red S staining. Our result showed that proliferation of VICs was significantly greater in female than male after 12 days of culture in regular media. Additionally, male VICs showed elevated amounts of normalized GAG, collagen I, and activated matrix metallopreoteniase-2 expression compared to female. Similarly, ALP content was greater in male VICs than female at all time points. In addition, male VICs formed calcific nodules with greater size, % area and integrated density than females. The results from this research suggest that there is a sex-related difference in the events associated with osteogenic differentiation of the aortic VICs, where male VICs are more prone to calcification.
Larger clinical trial enrollments and a greater understanding of biological heterogeneity have led to improved survival rates for children diagnosed with brain tumors in the last 50 years. However, reducing long‐term morbidities and improving survival rates of high‐risk tumors remain major challenges. Chemotherapy can reduce tumor burden, but effective drug penetration at the tumor site is limited by barriers in the route of drug administration and within the tumor microenvironment. Bioavailability of drugs is impeded by the blood‐brain barrier, plasma protein binding, and structural components by the tumor including the matrix and vasculature contributing to increased interstitial fluid pressure, hypoxia, and acidity. Designing drug delivery systems to circumvent these barriers could lead to improved drug penetration at the tumor site and reduce adverse systemic side effects. In this review, we expand on how systemic and local barriers limit drug penetration and present potential methods to enhance drug penetration in pediatric brain tumors.
Research on heterosexual mating has demonstrated that acoustic parameters (e.g., pitch) of men’s voices influence their attractiveness to women and appearance of status and formidability to other men. However, little is known about how men’s tendency to clearly articulate their speech influences these important social perceptions. In the current study, we used a repeated-measures design to investigate how men’s articulatory clarity or conformity influenced women’s (N = 45) evaluations of men’s attractiveness for both short- and long-term relationships, and men's (N = 46) evaluations of physical formidability and prestige. Results largely supported our hypotheses: men who enunciated phonemes more distinctly were more attractive to women for long-term relationships than short-term relationships and were perceived by other men to have higher prestige than physical dominance. These findings suggest that aspects of articulatory behavior that influence perceptions of prestige and long-term mating attractiveness may indicate an early social history characterized by high socioeconomic status, likely owing to crystallization of articulatory patterns during the critical period of language development. These articulatory patterns may also be honest signals of condition or disposition owing to the nature of complex, multicomponent traits, which deserve further empirical attention.
Improving unacceptable low response rates and reducing acute and long-term morbidities remain significant challenges in pediatric neuro-oncology. Chemotherapy is an effective primary or adjuvant treatment for pediatric disease, but current administration approaches hinder the pharmacological activity exerted by chemotherapy treatments. Barriers in the route of drug administration and in the tumor microenvironment limit anticancer drugs from penetrating tissue efficiently and reaching all cancer cells. Strategies have been proposed to overcome these barriers with hope of leading to sustained and elongated drug exposure in solid tumors. However, few methods have been explored to design drug delivery systems to circumvent these barriers with potential to enhance drug penetration and reduce adverse systemic side effects in treating pediatric brain tumors. In this study, we validate an injectable polysaccharide hydrogel capable of releasing drugs locally at tumor site, sustaining drug concentration, and eliciting tumor response. We synthesized a hydrogel with dimethyl sulfoxide (DMSO) incorporating amylopectin, a polysaccharide found in starch, loaded with doxorubicin. We determined the structure of doxorubicin is not altered when released from the hydrogel through characterization of drug-loaded and unloaded hydrogels, suggesting drug is encapsulated in the hydrogel network and is able to maintain structure to induce mechanism of action. We tested sustained release of drug and therapeutic efficacy in vitro with DAOY, a medulloblastoma cell line. Our approach demonstrates that local drug delivery presents potential to enhance drug penetration in pediatric brain tumors by sustaining drug concentration at tumor site for an extended period of time. Local drug delivery systems have been investigated for decades but few have been investigated for treatment of pediatric brain tumors. For researchers, physicians, and clinicians, this research can lead to a greater effort to improve current outcomes of conventional drug treatment and provide an opportunity to address current challenges in pediatric oncology.
Accurate assessment of antigen-specific immune responses is critical in the development of safe and efficacious biotherapeutics and vaccines. Endosomal processing of a protein antigen followed by presentation on major histocompatibility complex (MHC) class II constitute necessary steps in the induction of CD4+ T cell immune responses. Current preclinical methods for assessing immunogenicity risk consist of in vitro cell-based assays and computational prediction tools. Cell-based assays are time and labor-intensive while in silico methodologies have limitations. Here, we propose a novel cell-based assay capable of investigating an antigen's endosomal processing and MHC class II presentation capabilities. This novel assay relies on competition between epitopes for MHC class II binding and employs labeled soluble T cell receptors (sTCRs) as detectors of epitope presentation.
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