Online courses directory (19947)

Lecture Series on Enzyme Science and Engineering by Prof.Subhash Chand, Department of Biochemical Engineering,IIT Delhi.

This is an introductory course in biochemistry, designed for both biology and chemical engineering majors. A consistent theme in this course is the development of a quantitative understanding of the interactions of biological molecules from a structural, thermodynamic, and molecular dynamic point of view. A molecular simulation environment provides the opportunity for you to explore the effect of molecular interactions on the biochemical properties of systems. This course assumes that students have taken introductory chemistry, including basic thermodynamics, as well as introductory organic chemistry. An introductory biology course is not a prerequisite for the course, but students would benefit from some prior exposure to biology, even at the high school level. Required mathematical skills include simple algebra and differential calculus.

This course considers the process of neurotransmission, especially chemicals used in the brain and elsewhere to carry signals from nerve terminals to the structures they innervate. We focus on monoamine transmitters (acetylcholine; serotonin; dopamine and norepinephrine); we also examine amino acid and peptide transmitters and neuromodulators like adenosine. Macromolecules that mediate neurotransmitter synthesis, release, inactivation and receptor-mediated actions are discussed, as well as factors that regulate their activity and the second-messenger systems and ion fluxes that they control. The involvement of particular neurotransmitters in human diseases is considered.

The course, which spans two thirds of a semester, provides students with a research-inspired laboratory experience that introduces standard biochemical techniques in the context of investigating a current and exciting research topic, acquired resistance to the cancer drug Gleevec. Techniques include protein expression, purification, and gel analysis, PCR, site-directed mutagenesis, kinase activity assays, and protein structure viewing.

This class is part of the new laboratory curriculum in the MIT Department of Chemistry. Undergraduate Research-Inspired Experimental Chemistry Alternatives (URIECA) introduces students to cutting edge research topics in a modular format.

Acknowledgments

Development of this course was funded through an HHMI Professors grant to Professor Catherine L. Drennan.

Learn to use tools from the Bioconductor project to perform analysis of genomic data. This is the fifth course in the Genomic Big Data Specialization from Johns Hopkins University.

Nerves, the heart, and the brain are electrical. How do these things work? This course presents fundamental principles, described quantitatively.

Each term, the class selects a new set of professional journal articles on bioengineering topics of current research interest. Some papers are chosen because of particular content, others are selected because they illustrate important points of methodology. Each week, one student leads the discussion, evaluating the strengths, weaknesses, and importance of each paper. Subject may be repeated for credit a maximum of four terms. Letter grade given in the last term applies to all accumulated units of 16.459.

This self-paced course is designed to show that ethical theories can help provide frameworks for moral judgment and decision-making in the wake of recent scientific, technological, and social developments which have resulted in rapid changes in the biological sciences and in health care. This course also presents the academic foundations and historical development of multicultural moral decision-making and helps the student to develop their ability to interrelate reflectively, responsibly, and respectfully with a society of increasing intercultural connections. As grammar first describes how language is used, and then is in a position to prescribe how language ought to be used, is very similar to the approach taken in this course. This course first describes how people do in fact approach moral decision-making, and then is in a position to prescribe how multicultural and intercultural moral decision-making ought to made. Some of the topics to be covered are: Institutional Review Boards (IRB), Moral Development, Kant, Mill, Rawls, Informed Consent, Competency, Information Disclosure, Research on Human subjects, Principlism, and Food Systems. Required materials: Bioethics: Moral Philosophy, by Jeffrey W. Bulger, published by Plato

This course does not seek to provide answers to ethical questions. Instead, the course hopes to teach students two things. First, how do you recognize ethical or moral problems in science and medicine? When something does not feel right (whether cloning, or failing to clone) — what exactly is the nature of the discomfort? What kind of tensions and conflicts exist within biomedicine? Second, how can you think productively about ethical and moral problems? What processes create them? Why do people disagree about them? How can an understanding of philosophy or history help resolve them? By the end of the course students will hopefully have sophisticated and nuanced ideas about problems in bioethics, even if they do not have comfortable answers.

Bioethics provides an overview of the legal, medical, and ethical questions around reproduction and human genetics and how to apply legal reasoning to these questions.

This law course includes interviews with individuals who have used surrogacy and sperm donation, with medical professionals who are experts in current reproductive technologies like In Vitro Fertilization and Preimplantation Genetic Diagnosis, and bioethicists and journalists who study the ownership and use of genetic information within human tissue. Additional Harvard colleagues will also share with you their thoughts on topics such as disability law as it relates to reproductive technology.

While the law and ethics surrounding these technologies are a central component to this course, we also show you examples of the deeply personal and human side of these issues. Throughout the course, and with the help of law students, we will discuss leading legal cases in this field, which will illuminate the types of questions the law has struggled with – stretching and evolving over time. From the famous Baby M surrogacy case, to cases on the paternity of sperm donors, to a case related to the ownership of human tissue turned into a commercial product, and others. We will show you the ethical, legal, and rhetorical underpinnings, which have served as the basis for various court decisions over the past 20 or 30 years. We will also explore potential future technologies and their implications for society: genetic enhancements to increase our intelligence, let us live a hundred years longer, or make us immune to diseases – and the possibility of creating animal-human hybrids, for example a mouse with a humanized brain.

The content within this course is intended to be instructive, and show how legal reasoning has been applied, or could be applied, to questions related to parenthood, reproduction, and other issues surrounding human genetic material. The material organized within this course should be considered an authoritative overview, but is not intended to serve as medical or legal advice.

This course is designed for a diverse audience including, but not limited to, law students, prospective law students, medical professionals, as well as members of the general public interested in questions and topics related to surrogacy, parenthood, genetic and reproductive technology, ownership of genetic material, and more. You do not need any background in law, medicine, philosophy, or really any subject to enjoy this course. This course is meant to be an introduction for anyone interested in these topics.

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Learn how to biohack what you eat, how you exercise and how you feel during each phase of your menstrual cycle.

Use of available (mainly web-based) programs for analyzing biological data. This is an introductory course with a strong emphasis on hands-on methods. Some theory is introduced, but the main focus is on using extant bioinformatics tools to analyze data and generate biological hypotheses.

Use of available (mainly web-based) programs for analyzing biological data. This is Part 2 of an introductory course with a strong emphasis on hands-on methods. Some theory is introduced, but the main focus is on using extant bioinformatics tools to analyze data and generate biological hypotheses.

This course was the first in a two-part series covering some of the algorithms underlying bioinformatics. It has now been split into three smaller courses.

This is the second course in a two-part series on bioinformatics algorithms, covering the following topics: evolutionary tree reconstruction, applications of combinatorial pattern matching for read mapping, gene regulatory analysis, protein classification, computational proteomics, and computational aspects of human genetics.

This course teaches the concepts and computational methods in the exciting interdisciplinary field of bioinformatics and their applications in life sciences. The lectures are taught in both Mandarin Chinese and English with slides in English. 生物信息学是一门新兴的生命科学与计算科学的前沿交叉学科。本课程讲授生物信息学主要概念和方法，以及如何应用生物信息学手段解决生命科学问题。本课程同时提供中文普通话授课和英文授课两个版本，以及英文幻灯片。

What makes bioinformatics education exciting is that people of a variety of education levels can get started quickly, with just a computer and internet access.

Estudio comparativo de los temas fundamentales de los sistemas vivientes tanto en plantas como en animales. Una caracter

Vídeo-aulas, teoria e testes em 15 módulos para aumentar seu conhecimento em Biologia para o ENEM e vestibulares.

¿Te has preguntado cómo funciona tu cuerpo?

En este curso de Biología Humana conocerás la información básica sobre la estructura y función celular, y cómo a partir de la interacción entre células, se forman tejidos, órganos y sistemas. Estos elementos en conjunto, hacen que nuestro cuerpo funcione adecuadamente.

Para que termines con éxito este curso, necesitas empeño y dedicación en el estudio de las metas que hemos diseñado para ti, es importante que dediques 8 horas de estudio a la semana, recuerda que tú eres responsable de administrar dicho tiempo.

Te sugerimos realizar un plan de trabajo para que consideres las fechas límites de las actividades y evitar atrasos. Por otra parte es importante que pongas mucha atención en todos los recursos que te ofrecemos, los cuales refuerzan tu conocimiento para culminar el curso satisfactoriamente.

Para facilitar la comprensión y asimilación de los contenidos del curso hemos diseñado ilustraciones, animaciones, documentos adicionales y ejemplos que debes analizar y relacionar con el funcionamiento de tu cuerpo. Asimismo, pondrás en práctica tus conocimientos mediante actividades que te servirán para conocer tu nivel de dominio de cada apartado y te servirán para acreditar tu curso.