This course is an in-depth adventure through the molecular mechanisms that control the maintenance, expression, and evolution of prokaryotic and eukaryotic genomes. Through lectures and readings of relevant literature, students will explore gene regulation, DNA replication, genetic recombination, transcription, and mRNA translation. The quizzes are designed to build students' experimental design and data analysis skills.
This course, based on the MIT course 7.28/7.58 Molecular Biology taken by enrolled MIT students, was organized as a three-part series on edX by MIT’s Department of Biology. It is self-paced and free as long as you enroll in the Audit Track option, which you can select after creating a free account on edX.

Introduction to the linguistic study of language pathology, concentrating on experimental approaches and theoretical explanations. Discussion of Specific Language Impairment, autism, Down syndrome, Williams syndrome, normal aging, Parkinson's disease, Alzheimer's disease, hemispherectomy and aphasia. Focuses on the comparison of linguistic abilities among these syndromes, while drawing clear comparisons with first and second language acquisition. Topics include the lexicon, morphology, syntax, semantics and pragmatics. Relates the lost linguistic abilities in these syndromes to properties of the brain.

This course studies the relations of affect to cognition and behavior, feeling to thinking and acting, and values to beliefs and practices. These connections will be considered at the psychological level of organization and in terms of their neurobiological and sociocultural counterparts.

This course is an investigation of affective priming and creation of rigorously counterbalanced, fully computerized testing paradigm. Includes background readings, study design, counterbalancing, study execution, data analysis, presentation of poster, and final paper.

This course is offered to undergraduates and addresses several algorithmic challenges in computational biology. The principles of algorithmic design for biological datasets are studied and existing algorithms analyzed for application to real datasets. Topics covered include: biological sequence analysis, gene identification, regulatory motif discovery, genome assembly, genome duplication and rearrangements, evolutionary theory, clustering algorithms, and scale-free networks.

This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling.

This is the laboratory component of Anatomy & Physiology I. The concepts covered range from anatomical terminology, directional terms, body orientation to exercises on tissues, the integumentary, skeletal, muscular and nervous systems.

This is the open educational resource for BIO2311: Anatomy & Physiology I. This site provides all you will need for the course including a syllabus, link to the textbook, lecture notes, assignments, and all other related resources.

Anatomy and Physiology II syllabi and supplemental materials. This course covers a survey of the human body that stresses biological principles, chemical interpretations, and physical applications at the various levels of organization. The class lectures cover embryonic and physiologic theories of muscular, nervous, integument, skeletal, and endocrine systems. The class laboratories examine the integument, skeletal, and nervous systems. The department encourages students to complete Principles of Biology II/Lab (BIO102) and/or Chemical Science I/Lab (CHM110) before enrolling in this course. Course meets: 3 hrs. lecture; 3 hrs. lab. Course materials by Dr. Phillip T. Wong and Dr. Mark Beaumont, content added to OER Commons by Victoria Vidal.

This Open Course is an adaptation of OpenStax Anatomy and Physiology and was created under a Round Nine ALG Textbook Transformation Grant.

Topics covered include:

Chemical Organization
Cellular Organization
Tissue Organization
Integumentary System
Skeletal System
Muscular System
Nervous System
Endocrine System
Cardiovascular System
Lymphatic System
Respiratory System
Digestive System
Reproductive System

Syllabi and Lab Exercises for SCI 201: Anatomy and Physiology I. This course is designed to provide students with a basic understanding of the structure, function and disorders of the human body. Topics include an overview of the integumentary, skeletal, muscular, and nervous systems, as well as a discussion of tissues and special senses. A three-hour lab session is required each week. Course materials written by Maria Carles and Georgia Thoidis, content uploaded to OER Commons by Victoria Vidal.

This course is the first part of the two semester course of Anatomy and Physiology. It integrates the anatomy and physiology of cells, tissues, organs and human body systems, It includes the study of the gross and microscopic structure of the systems of the human body with special emphasis on the relationship between structure and function. It is based on OpenStax Anatomy and Physiology book and is supplemented by content from the Open Learning Initiative (Carnegie Mellon University Open Learning Initative) and Boundless Physiology Open Book.

The introductory topics will cover various approaches to the study of animals and their behavior. Key concepts in studies of animal behavior, emphasizing ethology, are covered in class and in the assigned readings from Scott (2005), supplemented by selections from other books, especially from classics in the field as well as selected videos. Next, key concepts in sociobiology are covered using readings from Alcock (2001), supplemented by selections from additional books and some video presentations.

Animal welfare has been described as a complex, multi-faceted public policy issue which includes important scientific, ethical, and other dimensions. Improving our understanding of animal welfare, involves the fascinating study of animal behavior as well as the challenge of accessing the emotions of animals.

This is the On-Demand version of this course, which means you can start the course at any time and work through the course materials at your own pace. The materials and quizzes will always be available to you.

You can come and talk about the course on Twitter using the hashtag #EdAniWelf

The lethal poison Ricin (best known as a weapon of bioterrorism), Diphtheria toxin (the causative agent of a highly contagious bacterial disease), and the widely used antibiotic tetracycline have one thing in common: They specifically target the cell's translational apparatus and disrupt protein synthesis.
In this course, we will explore the mechanisms of action of toxins and antibiotics, their roles in everyday medicine, and the emergence and spread of drug resistance. We will also discuss the identification of new drug targets and how we can manipulate the protein synthesis machinery to provide powerful tools for protein engineering and potential new treatments for patients with devastating diseases, such as cystic fibrosis and muscular dystrophy.
This course is one of many Advanced Undergraduate Seminars offered by the Biology Department at MIT. These seminars are tailored for students with an interest in using primary research literature to discuss and learn about current biological research in a highly interactive setting. Many instructors of the Advanced Undergraduate Seminars are postdoctoral scientists with a strong interest in teaching.

BI 101 is an introductory lab science course intended for majors in disciplines other than the biological sciences. This course is designed to help you discover the applications of science to your everyday life, as well as provide elements of critical thinking. This course has four Credit Units that emphasize a variety of topics including ecological principles, biodiversity, and impact of human activities on the environment.

Course Outcomes:
1. Discuss biological community interactions.
2. Explain how changes in human population and/or actions impact natural ecosystems.
3. Describe the movement of energy & nutrients through trophic levels.
4. Recognize the appropriate taxonomic level of an organism based on key characteristics or traits.

This is an introductory lab science course intended for majors in disciplines other than the biological sciences. The topics presented include biological molecules, cellular biology, genetics and inheritance, biotechnology, and evolutionary processes. Additionally, the course is designed to help you discover the applications of science in your everyday life, as well as provide elements of critical thinking.

Course Outcomes:
1. Explain how natural selection drives evolution.
2. Express how changes in the genome can affect the phenotype or traits within a population.
3. Be able to describe the patterns of inheritance.
4. Be able describe selected key cell processes.
5. Distinguish between the groups of biomolecules.

This course is designed to be taught using the textbook Cell Biology for Health Occupations, adapted from OpenStax.

(http://cnx.org/contents/Th3V8ojZ@3.1:zMTtFGyH@4/Introduction).

This course is designed for students who want to learn about and appreciate basic biological topics while studying the smallest units of biology: molecules and cells.

Patterns of diversity, ecology, and evolutionary biology. Emphasis is on the Tree of Life and how its members are distributed and interact. Partial Course.