Results for CHPR

The material in this course is an introduction to the field and the target audience is undergraduates. It may be of interest to graduate students unfamiliar with the field. The class examines the array of forces that affect the foods human beings eat, and when, where, and how we eat them, including human labor, agriculture, environmental sustainability, politics, animal rights/welfare, ethics, policy, culture, economics, business, law, trade, and ideology, and psychology. The class addresses the impact of current policies and actions that might be taken to improve human nutrition and health; macro-scale influences on food, nutrition, and eating behavior. . Undergraduate Prerequisite: Human Biology Core or Biology Foundations or consent of instructor.

Students undertake investigations sponsored by individual faculty members. Prerequisite: consent of instructor.

Focus is on research on prevention of chronic disease and related topics. Guest speakers present material. May be repeat for credit

This introductory course is a practicum in which students will learn the basics of R and use the programming language to analyze health datasets by application of classical statistical methods. A familiarity with basic descriptive and inferential statistics is required. It is assumed that students will have no (or very little) prior experience with R. Class sessions will include some lecture content and hands-on coding by each student on their own computers. Students will practice using R with open-source and simulated datasets. The primary goal of the course is to equip students with a basic and fundamental understanding of R's capabilities, experience using R with practice datasets, and the ability to extend their facility with R as their needs dictate.

How can one practice Evidence Based Medicine (EBM) and make evidence-based decisions for clinical practice and policy making? In this course we will teach the principles of EBM using examples from pivotal papers published in recent scientific literature in major journals addressing important clinical questions on diverse medical topics. We will probe a wide range of types of studies, targeted therapeutic or preventive interventions, and studies outcomes, including randomized controlled trials, observational studies, epidemiologic surveillance studies, systemic reviews, meta-analyses, mate-analyses of individual patient data, studies on the evaluation of diagnostic test and prognostic models, economic analyses studies, and guidelines. MD studies enroll for +/-. GR students enroll for Letter grade.

Open to graduate, medical, and undergraduate students. Appraisal of the quality and credibility of research findings; evaluation of sources of bias. Meta-analysis as a quantitative (statistical) method for combining results of independent studies. Examples from medicine, epidemiology, genomics, ecology, social/behavioral sciences, education. Collaborative analyses. Project involving generation of a meta-research project or reworking and evaluation of an existing published meta-analysis. Prerequisite: knowledge of basic statistics.

Preference given to postgraduate fellows and graduate students. Focus is on implementation science and evaluation of health care delivery innovations. Topics include implementation science theory, frameworks, and measurement principles; qualitative and quantitative approaches to designing and evaluating new health care models; hybrid design trials that simultaneously evaluate implementation and effectiveness; distinction between quality improvement and research, and implications for regulatory requirements and publication; and grant-writing strategies for implementation science and evaluation. Students will develop a mock (or actual) grant proposal to conduct a needs assessment or evaluate a Stanford/VA/community intervention, incorporating concepts, frameworks, and methods discussed in class. Priority for enrollment for CHPR 212 will be given to CHPR master's students.

The Science of Community Engagement in Health Research course will focus on how the science of community engagement can be applied to diverse health-related research topics across the translational spectrum with the ultimate goal of high quality research that transforms human health and addresses health disparities. The course will provide historical context, theoretical frameworks, foundational skills in diverse community engagement methodologies, and tools for examining the effectiveness of various engagement strategies aimed. Specifically, the course will cover: 1) Historical context for community engagement in health-related research; 2) Evolution of community engagement as a science; 3) Theoretical frameworks for various community engagement approaches; 4) Community-Based Participatory Research (CBPR); 5) Community engagement strategies for different stages of translational research; and 6) Evaluation of various engagement strategies; and 7) Ethics of community engagement. Students will gain practical experience in various community engagement tools and strategies to help guide the development of a community engagement plan responsive to community needs. Challenges and benefits of establishing community partnerships will be highlighted by real-world examples. nThe course will include lectures; interactive student-led presentations and guided exercises; class discussions among invited speakers, students and instructors; individual and group assignments; and organized small-group and experiential activities. Course readings will demonstrate the need and opportunity for interdisciplinary community engagement approaches and will illustrate how to conduct innovative community-engaged research. nThe Science of Community Engagement course is intended to reach students with diverse research interests, including clinical research, community health, health research and policy, epidemiology, prevention research, environmental health, etc.

This course provides an introduction to epigenetics, the study of how lifestyle factors can change gene activity without actually modifying the underlying DNA. With that basic foundation in place, students will then discover how food in particular is a powerful signal to our genes that can have a positive impact on our metabolism, longevity, and mental well-being. Along the way, we will specifically explore basic concepts in nutrigenomics, the study of how gene expression can be modified by certain nutrients and bioactive food compounds.

Coordinated seminar series presenting evidence-based health promotion and disease prevention guidelines by research and clinical faculty of multiple divisions of Stanford's Department of Medicine, including cardiovascular medicine, oncology, nephrology, immunology and rheumatology, infectious diseases, endocrinology, gerontology and metabolism, gastroenterology and hepatology, hematology, blood and marrow transplantation, pulmonary and critical care medicine, general medical disciplines (including family medicine). Key prevention issues addressed in primary care and outcomes research, biomedical informatics research and the Stanford Prevention Research Center also presented. Enrollment priority given to CHPR Master's students. CHPR students must enroll for letter grade.Prerequisite: CHPR 201 or HUMBIO 126/CHPR 226 or equivalent or consent of instructor.

For genetic counseling students, graduate students in genetics, medical students, residents and fellows. Case-based scenarios and guest expert lectures. Students learn skills in case preparation, management, and presentation, as well as content around common genetic disorders.

Online course for genetic counseling students, graduate students in genetics, medical students, residents, fellows, and nurses interested in prenatal genetics. Genetic counseling students should take this course in conjunction with their initial prenatal genetics rotation. Topics include: prenatal screening and diagnostic testing, ultrasound, genetic carrier screening, teratology, fetal treatment and intervention, perinatal loss, termination, and infertility.

Internet based course for genetic counseling students, graduate students in genetics, medical students, residents, and fellows; genetic counseling students should take this course in conjunction with their initial general genetics rotation. Topics include: common genetic conditions, assessment of child development and medical history in the context of a genetic workup, the pediatric genetics medical examination, dysmorphology, introduction to laboratory genetic testing, development of a differential diagnosis, and resources for case management and family support.

Internet based course for genetic counseling students, graduate students in genetics, medical students, residents, and fellows genetic counseling students should take this course in conjunction with their metabolic genetics rotation. Topics include: overview of metabolic diseases; common pathways; diagnosis, management, and treatment of metabolic disorders; and newborn screening.

Internet based course for genetic counseling students, graduate students in genetics, medical students, residents, and fellows; genetic counseling students should take this course in conjunction with their initial cancer genetics rotation. Topics include: cancer biology and cytogenetics; diagnosis and management of common cancer genetic syndromes¿ predictive testing; psychology of cancer genetic counseling; and topics recommended by ASCO guidelines.

Presentation of genetics research and cases from the medical genetics and biochemical genetics services. Course may be completed online or in person. Non-GC students: please contact the instructor when you enroll.

Online course for genetic counseling students, graduate students in genetics, medical students, residents, fellows, and nurses interested in inherited cardiovascular conditions. Genetic counseling students should take this course in conjunction with their cardiovascular genetics rotation. Topics include: Basic cardiology principles, including relevant anatomy and physiology; diagnosis, management and genetic testing as it relates to common inherited cardiovascular conditions in both the pediatric and adult setting; predictive genetic testing issues specific to inherited cardiovascular conditions; psychological issues related to sudden death conditions.

CHPR masters students enroll for a letter grade in your mentor's section. Before the end of the second week of the quarter, enrolled students must submit a description of the expected learning outcomes and deliverables for each unit to the CHPR office. One unit= three hours of work per week (30 hours for the quarter). CHPR 290 is also the CPT Course required for international students completing degree requirements.

Prerequisite: consent of instructor. Before the end of the second week of the quarter, enrolled students must submit a description of the expected learning outcomes and deliverables for each unit to the CHPR office. One unit= three hours of work per week (10 hours for the quarter).

Thesis writing for Community Health and Prevention Research Program. Students enroll in thesis advisor's section. Non-medical students enroll for a letter grade. Before the end of the second week of the quarter, enrolled students must submit a description of the expected learning outcomes and deliverables for each unit to the CHPR office. One unit= three hours of work per week (30 hours for the quarter).