This course provides students an understanding of important human parasitic diseases, including their life cycles, vectors of transmission, distribution and epidemiology, pathophysiology and clinical manifestations, treatment, and prevention and control. Tropical Parasitology is taught by faculty from an area highly impacted by tropical parasites- the Kilimanjaro Christian Medical University College in Moshi, Tanzania. The faculty include Drs. Frank Mosha and Mramba Nyindo (and two lecturers, Drs. Johnson Matowo and Jovin Kitau). Dr. John Bartlett, Professor of Medicine, Global Health and Nursing at Duke University, joins his faculty colleagues in this effort.

Вводный курс «Расстройства аутистического спектра» содержит в себе ключевую информацию об этой группе расстройств. Опираясь на материал современных исследований расстройств аутистического спектра (РАС), курс рассматривает как исторический контекст изучения, так и современные подходы к диагностике, вмешательству и поддержке людей с РАС. Особое внимание уделяется проблемам, с которыми приходится сталкиваться людям с расстройствами аутистического спектра и их семьям, и опыту решения этих проблем в развитых странах, главным образом — в США. Материал курса рассчитан на широкий круг специалистов — психологов, педиатров, детских психиатров, логопедов, педагогов, а также на студентов медицинских, психологических и педагогических факультетов. Курс будет полезным родителям детей с РАС и всем, кто хочет познакомиться с научным пониманием сущности расстройств аутистического спектра, о которых общественность и СМИ говорят все чаще в свете колоссального роста их распространенности в последние несколько десятков лет. Курс был подготовлен при участии фонда «Выход» и поддержке Благотворительного фонда Сбербанка «Вклад в будущее». С курсом интегрированы два сервиса: онлайн-энциклопедия, где собраны все понятия и имена, которые звучат сегодня при описании расстройств аутистического спектра («Аутизм. Энциклопедия»), и пополняемый архив современных научных публикаций с рефератами на русском языке («Аутизм. Исследования»)., а также одноименный печатный учебник к нему, который выпущен издательством «Практика». Автор курса и учебника – Елена Леонидовна Григоренко, профессор Йельского университета и медицинской школы Байлора, заслуженный профессор психологии Хьюстонского университета, ведущий ученый Лаборатории междисциплинарных исследований развития человека СПбГУ, доктор психологических наук, глава экспертного совета фонда «Выход».

Introduction to Genetics and Evolution is a college-level class being offered simultaneously to new students at Duke University. The course gives interested people a very basic overview of some principles behind these very fundamental areas of biology. We often hear about new "genome sequences," commercial kits that can tell you about your ancestry (including pre-human) from your DNA or disease predispositions, debates about the truth of evolution, why animals behave the way they do, and how people found "genetic evidence for natural selection." This course provides the basic biology you need to understand all of these issues better, tries to clarify some misconceptions, and tries to prepare students for future, more advanced coursework in Biology (and especially evolutionary genetics). No prior coursework is assumed.

This course aims to provide the basic knowledge about extracellular vesicles (EV) a generic term including exosomes, microvesicles, microparticles, ectosomes, oncosomes, prostasomes, and many others. It covers areas such as EV history, nomenclature, biogenesis, EV cargo as well as the release and uptake mechanisms, collection and processing prior to isolation, different isolation methods, characterization and quantification techniques. This course is divided into five modules. Module 1 is an introduction to the field and will cover the nomenclature and the history of EVs. Module 2 will focus on the biogenesis, release and uptake mechanisms of EVs as well as the different EV cargos (RNA, protein, lipids). In Module 3, we will focus on the collection and processing of cell culture media and body fluids such as blood, breast milk, cerebrospinal fluid and urine prior to isolation of EVs. Module 4 and 5 will present different isolation methods and characterization/quantification techniques, respectively. Here differential ultracentrifugation, size exclusion chromatography, density gradient, kit based precipitation, electron microscopy (EM), cryo-TEM, flow cytometry, atomic-force microscopy and nanoparticle tracking analysis will be presented. The recommended prerequisites are college-freshman-level biology and biochemistry. After a completed course you should be able to: + Discuss the nomenclature and subgroups of extracellular vesicles. + Describe the RNA, protein and lipid content of extracellular vesicles. + Describe the basic concepts about the most common isolation and characterization techniques and how these techniques are used in the EV field. + State the benefits and limitations of the most common isolation and characterization techniques for extracellular vesicles. + Explain the considerations that are important during the collection and isolation of EVs from different body fluid. + Describe the release and uptake mechanisms of extracellular vesicles All lectures are given in English. Each of the five modules will be followed by an exam. All exams will be in the format of multiple choice questions. The course is organized in collaboration between the International Society for Extracellular Vesicles (ISEV), University of California Irvine (USA), University of Gothenburg (Sweden) and Pohang University of Science and Technology (South Korea).

The course will explore the tone combinations that humans consider consonant or dissonant, the scales we use, and the emotions music elicits, all of which provide a rich set of data for exploring music and auditory aesthetics in a biological framework. Analyses of speech and musical databases are consistent with the idea that the chromatic scale (the set of tones used by humans to create music), consonance and dissonance, worldwide preferences for a few dozen scales from the billions that are possible, and the emotions elicited by music in different cultures all stem from the relative similarity of musical tonalities and the characteristics of voiced (tonal) speech. Like the phenomenology of visual perception, these aspects of auditory perception appear to have arisen from the need to contend with sensory stimuli that are inherently unable to specify their physical sources, leading to the evolution of a common strategy to deal with this fundamental challenge.

The Library of Integrative Network-based Cellular Signatures (LINCS) is an NIH Common Fund program. The idea is to perturb different types of human cells with many different types of perturbations such as: drugs and other small molecules; genetic manipulations such as knockdown or overexpression of single genes; manipulation of the extracellular microenvironment conditions, for example, growing cells on different surfaces, and more. These perturbations are applied to various types of human cells including induced pluripotent stem cells from patients, differentiated into various lineages such as neurons or cardiomyocytes. Then, to better understand the molecular networks that are affected by these perturbations, changes in level of many different variables are measured including: mRNAs, proteins, and metabolites, as well as cellular phenotypic changes such as changes in cell morphology. The BD2K-LINCS Data Coordination and Integration Center (DCIC) is commissioned to organize, analyze, visualize and integrate this data with other publicly available relevant resources. In this course we briefly introduce the DCIC and the various Centers that collect data for LINCS. We then cover metadata and how metadata is linked to ontologies. We then present data processing and normalization methods to clean and harmonize LINCS data. This follow discussions about how data is served as RESTful APIs. Most importantly, the course covers computational methods including: data clustering, gene-set enrichment analysis, interactive data visualization, and supervised learning. Finally, we introduce crowdsourcing/citizen-science projects where students can work together in teams to extract expression signatures from public databases and then query such collections of signatures against LINCS data for predicting small molecules as potential therapeutics.

Learners who complete Science of Exercise will have an improved physiological understanding of how your body responds to exercise, and will be able to identify behaviors, choices, and environments that impact your health and training. You will explore a number of significant adjustments required by your body in order to properly respond to the physical stress of exercise, including changes in carbohydrate, fat and protein metabolism, nutritional considerations, causes of muscle soreness & fatigue, and the effectiveness and dangers of performance enhancing drugs. Active learning assessments will challenge you to apply this new knowledge via nutrition logs, heart rate monitoring, calculations of your total daily caloric expenditure and body mass index (BMI). Finally, learners will examine the scientific evidence for the health benefits of exercise including the prevention and treatment of heart disease, diabetes, cancer, obesity (weight loss), depression, and dementia.

This is a course about addiction to drugs and other behaviors. It will describe what happens in the brain and how this information helps us deal with and overcome addiction. It will also discuss other topics, such as government policy and our vulnerability to take drugs.

Welcome to an Introduction to Breast Cancer! In this course, we’ll learn a bit about the leading cause of cancer in women worldwide – from the basic biology of the disease, to risk factors and prevention, to treatment modalities to survivorship. We’ll talk to leading experts, explore some of the milestone studies that have pushed this field forward, and have interactive discussions on discussion boards and social media. You’ll even have an opportunity to let us know what topics you want to cover on tweetchats, so we can try to make the content fit your interests. There is something in this course for everyone – if you’re a breast cancer survivor or the friend/family member of someone with this disease, this course will help you to better understand this disease, and give you ideas for questions you may want to ask your doctor. Maybe you’re a healthcare provider or studying to be the same, this course is a great refresher on where the state of the science is. If you’re a healthcare administrator wondering about how the interdisciplinary components of breast cancer care fit together, or an entrepreneur thinking about unmet needs in this space, or someone in public health interested in prevention, this course is also for you! Are you ready to learn a lot, and have some fun while we’re at it? If so, I hope you’ll join us! Let’s get started!!!

In this course, we will explore the nature of science and biology. We will discuss what the “biology everywhere” philosophy means and the history of the “biology everywhere” project. We will also discuss what science (and biology) are as a discipline of inquiry and how chemistry is foundational to understanding biology.