Calendar

1:00pm-2:00pm: Presentation and Q&A
2:00pm-2:30pm: Light Refreshments

Talk title: Precision Imaging Guides Cancer Therapy

Historically, many of the gains in medicine have been achieved by uniformly applying medical insights to large groups of patients. A combination of increasing biological understanding of the heterogeneity of disease processes and the concurrent expansion of available selective therapeutic interventions has provided the opportunity to improve group outcomes by optimizing treatment on an individual basis. In many cases, molecular imaging is ideally suited to serve as a biomarker to guide therapy selection and dosing, and to provide an early assessment of efficacy. This presentation highlights by example several areas in which imaging helps determine target engagement, dynamic cellular response to treatment, and the effectiveness of immune modulation in oncologic treatment.

Special PHIND Seminar presented by Dr. Ann Hsing

Title: Stanford WELL for Life Study: A Global Study of Precision Well-being

Speaker: Ann Hsing, PhD
Professor of Medicine
Stanford Prevention Research Center
Stanford Cancer Institute
Department of Health Policy and Research (Epidemiology), by courtesy

Bio: Dr. Ann Hsing is a professor of medicine at Stanford University and co-leader of the population Sciences Program at Stanford Cancer Institute. She is also a professor at Stanford Prevention Research Center and in the Department of Health Research and Policy (Epidemiology, by courtesy). In addition, Dr. Hsing is a faculty fellow for the Center for Innovation in Global Health as well as the Center for Population Health Sciences (PHS) at Stanford Medicine, where she chairs the Pacific Rim Alliance for Population Health, a new multidisciplinary initiative aimed at improving health in the Pacific Rim. Prior to joining Stanford Medicine, Dr. Hsing served as Chief Scientific Officer at the Cancer Prevention Institute of California, a role she assumed after retiring from her post as a tenured intramural investigator at the National Cancer Institute where she served for 23 years. Dr. Hsing received her PhD in epidemiology from the Johns Hopkins University and her master’s degree in biostatistics from the University of California at Los Angeles. At Stanford, she serves as the Principal Investigator of WELL Asia, including longitudinal cohorts in China, Taiwan, and Singapore to investigate socio-behavioral, biochemical, and molecular determinants of well-being. Dr. Hsing has published over 295 peer-reviewed papers and mentored over 65 post-doctoral fellows and junior faculty. In addition to science, Dr. Hsing’s passion is training the next generation of scientists and helping young people succeed in realizing their dreams.

Abstract: As the leader in well-being research, Stanford Prevention Research Center (SPRC) defines well-being as the holistic synthesis of a person’s biological, psychological, and spiritual experiences, resulting from interplay between individuals and their social, economic, and physical environments, that promote living a fulfilling life. Our vision is to improve and sustain health and well-being globally and our mission is to accelerate the science to enhance well-being. To accomplish this, we established the Stanford WELL for Life Study, an international study that uses novel methods to define, assess, and promote the multiple dimensions of well-being in the U.S. and globally. The Stanford WELL for Life Study uses a data-driven approach to define and measure well-being, identify factors related to well-being, and evaluate the impact of interventions on well-being. Currently, there are five study sites—the San Francisco Bay Area, China (Hangzhou), Taiwan (Taipei), Singapore, and Thailand (Bangkok)—with more than 24,000 individuals enrolled to date. We have collected data on 400-1,000 variables per individual and obtained biospecimens from 80% of participants for future molecular investigations. To assess well-being, SPRC developed a de novo multi-dimension survey (the Stanford WELL for Life Scale) that measures ten domains of well-being and a total well-being score. These ten domains, which emerged from our unique and extensive qualitative data, include: social connectedness, lifestyle and daily practices, stress and resilience, experience of emotions, physical health, purpose and meaning, sense of self, financial security and satisfaction, spirituality and religiosity, exploration and creativity. At the PHIND seminar, I will share with you the genesis and evolution of the Stanford WELL for Life Study and our exciting preliminary data.

A.I.-Based Decision Support Systems for Precision & Participative Medicine:

Focus on Oncology and Radiomics

Join via Zoom: https://stanford.zoom.us/j/499245954

Abstract:
Precision medicine is the future of health care: please watch the animation at https://vimeo.com/241154708. As a technology-intensive and -dependent medical discipline, oncology will be at the vanguard of this impending change. However, to bring about precision medicine, a fundamental conundrum must be solved: Human cognitive capacity, typically constrained to five variables for decision making in the context of the increasing number of available biomarkers and therapeutic options, is a limiting factor to the realization of precision medicine. Given this level of complexity and the restriction of human decision making, current methods are untenable. A solution to this challenge is multifactorial decision support systems (DSSs), continuously learning artificial intelligence platforms that integrate all available data-clinical, imaging, biologic, genetic, cost-to produce validated predictive models. DSSs compare the personalized probable outcomes-toxicity, tumor control, quality of life, cost effectiveness-of various care pathway decisions to ensure optimal efficacy and economy. DSSs can be integrated into the workflows both strategically (at the multidisciplinary tumor board level to support treatment choice, eg, surgery or radiotherapy) and tactically (at the specialist level to support treatment technique, eg, prostate spacer or not). In some countries, the reimbursement of certain treatments, such as proton therapy, is already conditional on the basis that a DSS is used. DSSs have many stakeholders-clinicians, medical directors, medical insurers, patient advocacy groups-and are a natural consequence of big data in health care. Here, we provide an overview of DSSs, their challenges, opportunities, and capacity to improve clinical decision making, with an emphasis on oncology and radiomics.

About:
Philippe Lambin is a Clinician, Radiation Oncologist, with a PhD in Molecular Radiation Biology, “ERC advanced grant laureate”, co-inventor of Radiomics, multifactorial Decision Support Systems, Distributed learning, the use of immunocytokines with Radiation and pioneer in translational research with a focus on tumour hypoxia and immunotherapy. He is/has been leading 30 clinical trials. He has and is Professor at the University of Maastricht (head of the new Dpt of Precision Oncology: The D-Lab & The M-Lab, focusing on “Convergence Sciences” and Decision Support Systems. He is co-author of more than 488 peer reviewed scientific papers (Hirsch Index: 94 Google scholar), co-inventor of more than 17 patents (filed or submitted) of which 5 are in the (pre)commercialization phase and (co) promoter of more than 59 completed PhD’s.

Refreshments will be provided.

PHIND Seminar August

Mehmet Ozgun

“Extracellular Vesicles for Broad Applications in Medicine and Cancer”

About Mehmet O. Ozen, PhD

Dr. Ozen is a Postdoctoral Research Fellow at Canary Center for Cancer Early Detection / Radiology Department at Stanford University. He works with Prof. Utkan Demirci on simple solutions for complex problems in medicine, combining microfluidics and bioengineering principles. He received his BS and PhD in Bioengineering from Ege University.

Abstract

Extracellular vesicles (EVs) are lipid bi-layered nanoparticles shed from the cells that carry RNA, DNA, transmembrane and cytosolic proteins. The variety in EV size, cargo and origin attracted researchers to decipher the mechanisms that have been involved in packaging, secretion, uptake and roles of EVs on cells in vivo and in vitro, lightening the path for biomarker studies for diagnosis, prognosis, therapy and therapy monitoring. They are one of the many means that cells use to communicate with neighboring and distant cells and tissues. With improvements in next-generation sequencing technologies and increased resolution of mass spectrometry for proteomic analysis, EVs have been shown to take role in angiogenesis, epithelial-to-mesenchymal transition, stemness in cancer, malignancy, metastasis and drug resistance.

Although exosomes show unprecedented promising advantages over other biotargets in the circulation for clinical use, a major challenge rapidly emerging in the field of EV utilization for clinical and non-clinical applications is the absence of reproducible, inexpensive and robust tools for efficient sorting and isolation of EV populations at a high yield. The field lacks a clear consensus over an optimum approach or a tool for isolation of EVs avoiding contamination with many other proteins and such other biostructures and reproducible procedures for downstream analysis of EV cargo and content. Existing approaches for EV isolation include a variety of methods. Additionally, methods for the exosome-derived analyte isolation, library preparation for sequencing, and downstream analysis including genomic, proteomic and metabolic analysis are highly varied. Hence, there is a need for well-developed experimental tools, interlaboratory evaluations and in-depth descriptions of experimental steps and designs to ensure reliable, robust and reproducible experiments and tools.

In this talk, we will describe a new technique, i.e., Exosome Total Isolation Chip (ExoTIC), that is developed in our lab to isolate EVs and EV subpopulations from a variety of sample types including plasma and culture media. We will present further downstream genomic and proteomic analysis of these EVs focusing on applications in cancer and cardiovascular disorders.

Alex K. Shalek, PhD
Pfizer-Laubach Career Development Associate Professor
Institute for Medical Engineering & Science
Department of Chemistry and Koch Institute
Massachusetts Institute of Technology

Abstract: While several methods exist for sampling tissues in clinical contexts, without high-fidelity tools for comprehensively profiling them, we are both limited in our capacity to understand how constituent cells and their interactions impact prognosis, and to select and develop precision therapeutics. Recent years have witnessed transformative and intersecting advances in nanofabrication and molecular biology that now enable deep profiling of low-input samples. Collectively, these afford new and exciting opportunities to study cellular heterogeneity, starting from the level of the single cell, and may unlock the diagnostic, prognostic, and discovery potential of clinical isolates. Illustratively, I will introduce how we can leverage single-cell genomic approaches – and, in particular, single-cell RNA-Seq – to explore the extensive functional diversity between cells, uncovering, from the “bottom-up,” distinct cell states and their molecular drivers. Moreover, I will discuss high-throughput experimental strategies and demonstrate, in the context of Acute Lymphoblastic Leukemia, how they can be leveraged to achieve the statistical power necessary to reconstruct intracellular circuits, enumerate and redefine cell states and types, and transform our understanding of cellular decision-making in health and disease on a genomic scale.

Bio: Alex K. Shalek is currently the Pfizer-Laubach Career Development Associate Professor at MIT, as well as a Core Member of the Institute for Medical Engineering and Science (IMES), an Associate Professor of Chemistry, and an Extramural Member of The Koch Institute for Integrative Cancer Research. He is also an Institute Member of the Broad Institute, an Associate Member of the Ragon Institute, an Assistant in Immunology at MGH, and an Instructor in Health Sciences and Technology at HMS. His research is directed towards the development and application of new technologies that facilitate understanding of how cells collectively perform systems-level functions in healthy and diseased states. Dr. Shalek received his bachelor’s degree summa cum laude from Columbia University and his Ph.D. from Harvard University in chemical physics under the guidance of Hongkun Park, and performed postdoctoral training under Hongkun Park and Aviv Regev (Broad/MIT). To date, his interdisciplinary research has focused on realizing and utilizing nanoscale manipulation and measurement technologies to examine how small components (molecules, cells) drive systems of vast complexity (cellular responses, population behaviors).