Coronavirus disease 2019 (COVID-19) continues to have a devastating effect on a global scale. COVID-19 variants continue to arise and counteract vaccination efficacy. As such, preventative health measures, such as social distancing and stay at home mandates, will continue for the foreseeable future. Evidence on those at greatest risk for poor outcomes if infected with COVID-19 has rapidly come to light. It has become clear that those with unhealthy lifestyle characteristics, chronic disease risk factors and/or a confirmed diagnosis of one or more chronic conditions are at greatest risk for hospitalization, intensive care unit admission, mechanical ventilation, and death if infected with COVID-19. The cytokine storm is a phenomenon that has been posited as a pathophysiologic response to COVID-19 infection that leads to poor outcomes. The current graphical review illustrates the association between unhealthy lifestyle characteristics and increased vulnerability to the cytokine storm as well as the physiologic mechanisms healthy living behaviors elicit and decrease risk for the cytokine storm. Through this graphical review, we will demonstrate unhealthy lifestyle characteristics, chronic disease risk factors and diagnoses, and COVID-19 outcomes are intricately linked, creating a new global syndemic. It is also clear that a primary way to uncouple this syndemic is through increasing healthy living behaviors, as illustrated in this graphical review. Moving forward, healthy living medicine should be practiced with renewed vigor to improve human resiliency to health threats posed by both chronic disease and viral infections.
Patient-derived pancreatic ductal adenocarcinoma (PDAC) organoid systems show great promise for understanding the biological underpinnings of disease and advancing therapeutic precision medicine. Despite the increased use of organoids, the fidelity of molecular features, genetic heterogeneity, and drug response to the tumor of origin remain important unanswered questions limiting their utility. To address this gap in knowledge, we created primary tumor- and PDX-derived organoids, and 2D cultures for in-depth genomic and histopathological comparisons to the primary tumor. Histopathological features and PDAC representative protein markers showed strong concordance. DNA and RNA sequencing of single organoids revealed patient-specific genomic and transcriptomic consistency. Single-cell RNAseq demonstrated that organoids are primarily a clonal population. In drug response assays, organoids displayed patient-specific sensitivities. Additionally, we examined the in vivo PDX response to FOLFIRINOX and Gemcitabine/Abraxane treatments, which was recapitulated in vitro by organoids. The patient-specific molecular and histopathological fidelity of organoids indicate that they can be used to understand the etiology of the patient’s tumor and the differential response to therapies and suggests utility for predicting drug responses.
Advances in 3D cell culture over the last decade have enabled the establishment of organoid models from a multitude of organs in varying stages of development and disease. Organoids recapitulate the tissue-specific cell types and exhibit similar morphology and spatial organization as the organ it is derived from. However, to the best of our knowledge, tumor organoids have never been profiled at a single cell level. In this study, we applied Drop-seq, a high throughput single cell RNA-seq platform, to characterize the different cell types present in pancreatic cancer organoids. We sequenced the transcriptomes of 5494 single cells from organoids derived from a patient undergoing a Whipple procedure for pancreatic ductal adenocarcinoma (PDAC). We then developed a novel clustering approach based on a class of probabilistic generative models called topic models, leading to the identification of two subpopulations of cells. One subgroup expressed marker genes known to play important roles in PDAC biology, such as MUC1, CLDN4 and GAS5. Interestingly, this subgroup also bore markers for cancer stem cells (HES1 and SQSTM1) that have been found by multiple studies to mediate chemoresistance in PDAC. The other subpopulation differentially expressed AGR2 and TMBIM6, which are associated with endoplasmic reticulum (ER) stress and correlates with invasiveness of PDAC cell lines. Functional studies are underway to determine the exact role of these subgroups, but our preliminary findings are suggestive of a subpopulation of cells that maybe involved in resistance to chemotherapy. This is consistent with the clinical progression of this patient's cancer, suggesting that rapid, inexpensive single cell transcriptomics might provide more precise molecular information to personalized medicine programs than traditional RNA-seq alone. Citation Format: Mohana Ray, Rajib K. Nandi, Isabel Romero Calvo, Kori Kirby, Christopher Weber, Hedy L. Kindler, Mary Buschmann, Kevin Roggin, Kevin P. White. Single cell RNA-seq reveals transcriptionally distinct subpopulations within patient-derived pancreatic cancer organoids [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 5350.
Due to the rapid evolution of biomedical research, it is crucial to effectively communicate new technological advances in topics such as organoid models in cancer therapeutics to help improve health outcomes. Visual communication, including animation, has been shown to improve cognition and understanding of complex biological processes. However, there is contradictory information about the amount of detail that should be used for effective communication when utilizing animation.Although it is known that the inclusion of detailed references increases the scientific community’s perceived credibility of the visualization, the effect of including visual scientific data is unknown. This research examines the impact of including visual scientific data in an educational animation by analyzing biomedical researchers’ perception of credibility and learning outcomes with respect to cancer organoid research.
Pancreatic ductal adenocarcinoma (PDAC) is the fourth leading cause of cancer death, with a 5-year overall survival rate <7%. Several active systemic therapies are now available for PDAC. Personalizing therapy may be improved with the development of realistic tumor models from a patient's explanted tumoral tissue. Human pancreatic tumor patient-derived xenografts (PDX) implanted into immunodeficient mice and tumor organoids grown in vitro 3D culture are two promising models. However, it is uncertain if these models are histopathologically and genetically similar to the primary PDAC. Histopathological comparison of sections from PDX tumor, organoids, and primary PDAC from a 63-year-old female patient were performed on paraffin embedded tissue. H&E and immunohistochemical staining for cytokeratins (CK7, CK20), p53, Claudin-4, and CEA were performed. DNA and mRNA sequencing was performed. Both PDX and organoids exhibited histopathological features remarkably consistent with the original patient tumor including the histologic grade (moderately differentiated), cytological appearance (irregular nuclear membranes, open chromatin and prominent nucleoli), mitotic activity (5 -7/10 HPF), and immunohistochemical profile. The PDX and organoids demonstrated diffuse moderate-to-strong positivity for CK7, CEA, p53, and Claudin-4 and focal weak positivity for CK20 - all similar to the primary tumor. The immunohistochemical staining pattern was consistent with mRNA sequencing of the primary tumor which showed that CEA, Claudin-4 and p53 expression were ∼960-fold, ∼27-fold and ∼3 fold higher respectively (vs. benign pancreatic tissue). DNA sequencing revealed somatic mutations in KRAS and TP53 genes seen in >90% and ∼70% of PDACs respectively, and a few rare somatic mutations, such as a sodium leak channel (NALCN) mutation, seen in ∼3% of PDAC. Both PDX and organoid models of PDAC maintain key histological features, immunohistochemical profile and basic gene expression pattern akin to the primary tumor. These findings suggest that PDXs and organoids have the potential to serve as reliable pathophysiological models for optimizing individual therapy for patients with PDAC. Citation Format: Isabel Romero Calvo, Ashwin Akki, Andrey Ugolkov, Mary M. Buschmann, Samantha M. Sparrow, Teresa Barry, Margaret Eber, Tongjun Gu, Shuang Qin Zhang, Hedy Kindler, William Dale, Kevin Roggin, Andrew P. Mazar, Kevin P. White, Christopher R. Weber. Organoids and patient-derived tumor xenograft of pancreatic adenocarcinoma share morphological and genetic features with the primary tumor. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4272.
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