CU Defense - Lightweight Cranial Protection and Low Altitude Parachute Systems

The Clemson family proudly embraces its school\u27s rich military heritage and students in every department regularly demonstrate patriotism and respect for our nation\u27s armed forces. Our multidisciplinary team of undergraduates has sought to study and improve currently used technology to give soldiers an advantage in the field. We currently have two active projects, as described below. Lightweight Cranial Protection Current standard-issue combat helmets weigh more and offer less protection than desired. Equipment weight reduction is a constant goal for the armed forces, and enhanced safety is always favored. With recent technological developments in the application of dilatants, or shear-thickening fluids (STF), it appears that a helmet\u27s design and construction can be improved. We intend to apply several STF compositions to selected ballistic fibers using multiple impregnation methods. The resulting fibers will be tested for variations in ballistic performance. Low Altitude Parachute System currently used parachutes are designed to inflate slowly to avoid injury on opening. As a result, there is a range of heights that are too low for current parachutes to behave effectively. Using past current research and simulation software, we intend to study the various shapes and sizes of parachutes used throughout history and design a parachute system that will be effective at these low altitudes. This research could lead to the development of products that vastly increase the quality of life and safety of military, law enforcement, and rescue operations

Modelling esophageal adenocarcinoma and Barrett’s esophagus with patient-derived organoids

Currently, esophageal adenocarcinoma (EAC) research is hindered by a dearth of adequate models to study this disease. Traditional cell line and genetically engineered mouse models are lacking in biological and physiological significance, whilst the inefficiency of patient-derived xenografts limit their potential applications. This review describes the landscape of EAC research using patient-derived organoids (PDOs). Here, we detail the methods of establishment and optimization of EAC PDO cultures, as well as current and prospective applications of these models. We further highlight a crucial knowledge gap in the mechanisms of EAC transformation from its precursor lesion, Barrett’s esophagus (BE). As such, we also describe the culture requirements of BE PDOs and attempts to model tumorigenesis using PDO models

Cancer associated fibroblasts predict for poor outcome and promote periostin-dependent invasion in oesophageal adenocarcinoma

Interactions between cancer cells and cancer-associated fibroblasts (CAF) play an important role in tumour development and progression. In this study we investigated the functional role of CAF in oesophageal adenocarcinoma (EAC). We used immunochemistry to analyse a cohort of EAC patients (183 patients) for CAF markers related to disease mortality. We characterized CAF and normal oesophageal fibroblasts (NOF) using western blotting, immunofluorescence and gel contraction. Transwell assays, 3-D organotypic culture and xenograft models were used to examine effects on EAC cell function, and dissect molecular mechanisms regulating invasion. Most EAC (93%) contained CAF with a myofibroblastic (?-SMA-positive) phenotype, which correlated significantly with poor survival (p?=?0.016; HR 7. 1 (1.7-29.4). Primary CAF, isolated from EAC, have a contractile, myofibroblastic phenotype, and promote EAC cell invasion in vitro (Transwell assays, p?=?<0.05; organotypic culture, p?<?0.001) and in vivo (p?=?<0.05). In vitro, this pro-invasive effect is modulated through the matricellular protein periostin. Periostin is secreted by CAF, and acts as a ligand for EAC cell integrins ?v?3 and ?v?5, promoting activation of the PI3kinase/Akt pathway. In patient samples, periostin expression at the tumour cell/stromal interface correlates with poor overall and disease-free survival. Our study highlights the importance of the tumour stroma in EAC progression. Paracrine interaction between CAF-secreted periostin and EAC-expressed integrins results in PI3 kinase/Akt activation and increased tumour cell invasion. Most EAC contain a myofibroblastic CAF-rich stroma; this may explain the aggressive, highly infiltrative nature of the disease, and suggests that stromal targeting may produce therapeutic benefit in EAC patient

ABCC5 supports osteoclast formation and promotes breast cancer metastasis to bone

INTRODUCTION: Bone is the most common site of breast cancer metastasis, and complications associated with bone metastases can lead to a significantly decreased patient quality of life. Thus, it is essential to gain a better understanding of the molecular mechanisms that underlie the emergence and growth of breast cancer skeletal metastases. METHODS: To search for novel molecular mediators that influence breast cancer bone metastasis, we generated gene-expression profiles from laser-capture microdissected trephine biopsies of both breast cancer bone metastases and independent primary breast tumors that metastasized to bone. Bioinformatics analysis identified genes that are differentially expressed in breast cancer bone metastases compared with primary, bone-metastatic breast tumors. RESULTS: ABCC5, an ATP-dependent transporter, was found to be overexpressed in breast cancer osseous metastases relative to primary breast tumors. In addition, ABCC5 was significantly upregulated in human and mouse breast cancer cell lines with high bone-metastatic potential. Stable knockdown of ABCC5 substantially reduced bone metastatic burden and osteolytic bone destruction in mice. The decrease in osteolysis was further associated with diminished osteoclast numbers in vivo. Finally, conditioned media from breast cancer cells with reduced ABCC5 expression failed to induce in vitro osteoclastogenesis to the same extent as conditioned media from breast cancer cells expressing ABCC5. CONCLUSIONS: Our data suggest that ABCC5 functions as a mediator of breast cancer skeletal metastasis. ABCC5 expression in breast cancer cells is important for efficient osteoclast-mediated bone resorption. Hence, ABCC5 may be a potential therapeutic target for breast cancer bone metastasis

C5b-9 membrane attack complex formation and extracellular vesicle shedding in Barrett's esophagus and esophageal adenocarcinoma

The early complement components have emerged as mediators of pro-oncogenic inflammation, classically inferred to cause terminal complement activation, but there are limited data on the activity of terminal complement in cancer. We previously reported elevated serum and tissue C9, the terminal complement component, in esophageal adenocarcinoma (EAC) compared to the precursor condition Barrett’s Esophagus (BE) and healthy controls. Here, we investigate the level and cellular fates of the terminal complement complex C5b-9, also known as the membrane attack complex. Punctate C5b-9 staining and diffuse C9 staining was detected in BE and EAC by multiplex immunohistofluorescence without corresponding increase of C9 mRNA transcript. Increased C9 and C5b-9 staining were observed in the sequence normal squamous epithelium, BE, low- and high-grade dysplasia, EAC. C5b-9 positive esophageal cells were morphologically intact, indicative of sublytic or complement-evasion mechanisms. To investigate this at a cellular level, we exposed non-dysplastic BE (BAR-T and CP-A), high-grade dysplastic BE (CP-B and CP-D) and EAC (FLO-1 and OE-33) cell lines to the same sublytic dose of immunopurified human C9 (3 µg/ml) in the presence of C9-depleted human serum. Cellular C5b-9 was visualized by immunofluorescence confocal microscopy. Shed C5b-9 in the form of extracellular vesicles (EV) was measured in collected conditioned medium using recently described microfluidic immunoassay with capture by a mixture of three tetraspanin antibodies (CD9/CD63/CD81) and detection by surface-enhanced Raman scattering (SERS) after EV labelling with C5b-9 or C9 antibody conjugated SERS nanotags. Following C9 exposure, all examined cell lines formed C5b-9, internalized C5b-9, and shed C5b-9+ and C9+ EVs, albeit at varying levels despite receiving the same C9 dose. In conclusion, these results confirm increased esophageal C5b-9 formation during EAC development and demonstrate capability and heterogeneity in C5b-9 formation and shedding in BE and EAC cell lines following sublytic C9 exposure. Future work may explore the molecular mechanisms and pathogenic implications of the shed C5b-9+ EV

Modulation of death receptor-induced apoptosis by Hsp72

© 2004 Dr. Nicholas J ClemonsThe inducible heat shock protein Hsp72 inhibits apoptosis and promotes long term survival after a number of stresses but the mechanism by which this is achieved remains unclear. A role for Hsp72 in modulating apoptosis mediated through members of the TNF-receptor super family other than TNF-R1 has not been clearly established. Given the observations of high levels of Hsp72 in tumours of poor prognosis, we set out to determine whether Hsp72 could specifically modulate apoptosis induced through the death receptor pathways mediated by Fas and the TRAIL receptors. Both these pathways are of relevance in tumour surveillance. (For complete abstract open document

Opportunities for Ferroptosis in Cancer Therapy

A critical hallmark of cancer cells is their ability to evade programmed apoptotic cell death. Consequently, resistance to anti-cancer therapeutics is a hurdle often observed in the clinic. Ferroptosis, a non-apoptotic form of cell death distinguished by toxic lipid peroxidation and iron accumulation, has garnered substantial attention as an alternative therapeutic strategy to selectively destroy tumours. Although there is a plethora of research outlining the molecular mechanisms of ferroptosis, these findings are yet to be translated into clinical compounds inducing ferroptosis. In this perspective, we elaborate on how ferroptosis can be leveraged in the clinic. We discuss a therapeutic window for compounds inducing ferroptosis, the subset of tumour types that are most sensitive to ferroptosis, conventional therapeutics that induce ferroptosis, and potential strategies for lowering the threshold for ferroptosis

Inhibiting system xC− and glutathione biosynthesis – a potential Achilles' heel in mutant-p53 cancers

Effective therapeutic strategies to target mutant tumor protein p53 (TP53, best known as p53) cancers remain an unmet medical need. We found that mutant p53 impairs the function of nuclear factor (erythroid-derived 2)-like 2 (NFE2L2, commonly known as NRF2), suppresses solute carrier family 7 member 11 (SLC7A11) expression, and diminishes cellular glutamate/cystine exchange. This decreases glutathione biosynthesis, resulting in redox imbalance. Mutant p53 tumors are thus inherently susceptible to further perturbations of the SLC7A11/glutathione axis

Preclinical models for the study of Barrett's carcinogenesis

Barrett's esophagus (BE) is clinically significant, as it is the only known precursor lesion for esophageal adenocarcinoma. To develop improved therapies for the treatment of BE, a greater understanding of the disease process at the molecular genetic level is needed. However, achieving a greater understanding will require improved preclinical models so that the disease process can be more closely studied and novel therapies can be tested. Our concise review highlights progress in the development of preclinical models for the study of BE and identifies the most suitable model in which to test novel therapies