This 6-minute video lesson provides an introduction to the neuron and its anatomy. [Biology playlist: Lesson 41 of 71].

The mission of the Department of Biology is to provide high quality education in biological sciences to our students, to advance the body of scientific knowledge through scholarly research, and to provide technical and educational expertise locally, nationally and internationally.

This course presents the fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. It covers principles and algorithms for processing both deterministic and random signals. Topics include data acquisition, imaging, filtering, coding, feature extraction, and modeling. The focus of the course is a series of labs that provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging. The labs are done on the MIT Server in MATLABĺ¨ during weekly lab sessions that take place in an electronic classroom. Lectures cover signal processing topics relevant to the lab exercises, as well as background on the biological signals processed in the labs.

This course provides an outline of vertebrate functional neuroanatomy, aided by studies of comparative neuroanatomy and evolution, and by studies of brain development. Topics include early steps to a central nervous system, basic patterns of brain and spinal cord connections, regional development and differentiation, regeneration, motor and sensory pathways and structures, systems underlying motivations, innate action patterns, formation of habits, and various cognitive functions. In addition, lab techniques are reviewed and students perform brain dissections.

Medical Terminology and Body Systems I prepares you to use appropriate medical terminology to identify the structural organization of the body, identify body systems, and describe body special orientation. You will identify the normal function of each body system. You will identify word parts and abbreviations as they relate to body systems. This course has 4 Credit Units that will assist you in learning the course objectives.

NOTE: This is a Terminology course which will require you to properly pronounce words. You will need a set of headphones with a microphone attached in order to complete some assignments. Ear buds with microphone work just fine.

Course Outcomes:
1. Describe the structural organization of the human body and to identify Body Systems.
2. Describe Body Planes, Directional terms, quadrants, and cavities.
3. Describe the normal function of each body system, identify its major organs as well as their anatomical location.
4. Identify medical terms, labeling the word parts and define both medical terms and abbreviations related to all body systems.
5. Identify and analyze treatment modalities, normal function, organization, and diagnostic measures, for the following body systems: a. Integumentary System b. Skeletal System c. Muscles and Joints d. Nervous System e. Blood and Lymphatic Systems

Medical Terminology and Body Systems II prepares you to list major organs in each body system, describe their function, and identify and analyze pathologies related to each system. You will be able to discuss implications for disease and disability as it relates to each system, as well as issues related to treatment for each pathology and how it changes throughout the lifespan. This course has 4 Credit Units that will assist you in learning the course objectives.

Course Outcomes:
1. Describe the normal function of the following body systems, identifying major organs as well as their anatomical location: a. Cardiovascular b. Respiratory c. Digestive d. Endocrine e. Eyes and Ears f. Urinary g. Male and Female Genital and Reproductive Systems h. Obstetrics
2. Identify major organs as well as their anatomical location in the following body systems: a. Cardiovascular b. Respiratory c. Digestive d. Endocrine e. Eyes and Ears f. Urinary g. Male and Female Genital and Reproductive Systems h. Obstetrics
3. Analyze treatment modalities and diagnostic measures for the following body systems: a. Cardiovascular b. Respiratory c. Digestive d. Endocrine e. Eyes and Ears f. Urinary g. Male and Female Genital and Reproductive Systems h. Obstetrics

This course prepares the student to list major specialties in medicine, allied health, and their qualifications as well as their contribution to the overall health care system. The student will be able to discuss acute and chronic body system diseases, processes, and failures addressed by these major specialties and branches of allied health, as well as common treatment modalities for each system and how these might change throughout the lifespan.

Course Outcomes:
1. Describe the normal scope of practice of the following disciplines: a. Pediatrics b. Diagnostic Imaging c. Oncology d. Pharmacology e. Mental Health f. Gerontology
2. Analyze treatment modalities and diagnostic measures for the following disciplines: a. Pediatrics b. Diagnostic Imaging c. Oncology d. Pharmacology e. Mental Health f. Gerontology
3. Demonstrate the coordination of necessary care planning for chronic disease management in all body systems.

Cell Biology, Genetics, and Biochemistry for Pre-Clinical Students is an undergraduate medical-level resource for foundational knowledge across the disciplines of genetics, cell biology and biochemistry. This USMLE-aligned text is designed for a course in first-year undergraduate medical course that is delivered typically before students start to explore systems physiology and pathophysiology. The text is meant to provide the essential information from these content areas in a concise format that would allow learner preparation to engage in an active classroom. Clinical correlates and additional application of content is intended to be provided in the classroom experience. The text assumes that the students will have completed medical school prerequisites (including the MCAT) in which they will have been introduced to the most fundamental concepts of biology and chemistry that are essential to understand the content presented here. This resource should be assistive to the learner later in medical school and for exam preparation given the material is presented in a succinct manner, with a focus on high-yield concepts.

The 276-page text was created specifically for use by pre-clinical students at Virginia Tech Carilion School of Medicine and was based on faculty experience and peer review to guide development and hone important topics.

Instructors reviewing, adopting, or adapting parts or the whole of the text are requested to register their interest at: https://bit.ly/interest-preclinical.

Instructors and subject matter experts interested in and sharing their original course materials relevant to pre-clinical education are requested to join the instructor portal at https://www.oercommons.org/groups/pre-clinical-resources/10133.

Surveys the molecular and cellular mechanisms of neuronal communication. Covers ion channels in excitable membrane, synaptic transmission, and synaptic plasticity. Correlates the properties of ion channels and synaptic transmission with their physiological function such as learning and memory. Discusses the organizational principles for the formation of functional neural networks at synaptic and cellular levels.

This course is designed to provide an understanding of how the human brain works in health and disease, and is intended for both the Brain and Cognitive Science major and the non-Brain and Cognitive Science major. Knowledge of how the human brain works is important for all citizens, and the lessons to be learned have enormous implications for public policy makers and educators. The course will cover the regional anatomy of the brain and provide an introduction to the cellular function of neurons, synapses and neurotransmitters. Commonly used drugs that alter brain function can be understood through a knowledge of neurotransmitters. Along similar lines, common diseases that illustrate normal brain function will be discussed. Experimental animal studies that reveal how the brain works will be reviewed. Throughout the seminar we will discuss clinical cases from Dr. Byrne's experience that illustrate brain function; in addition, articles from the scientific literature will be discussed at each class.

" This course provides an exciting, eye-opening, and thoroughly useful inquiry into what it takes to live an extraordinary life, on your own terms. The instructors address what it takes to succeed, to be proud of your life, and to be happy in it. Participants tackle career satisfaction, money, body, vices, and relationship to themselves and others. They learn how to address issues in their lives, how to live life, and how to learn from it. This course is offered during the Independent Activities Period (IAP), which is a special 4-week term at MIT that runs from the first week of January until the end of the month. This not-for-credit course is sponsored by the Department of Science, Technology, and Society. A similar, semester-long version of this course is taught in the Sloan Fellows Program. A semester-long extension of the IAP course is also taught to the population at large of MIT (please see PE.550, Spring). Acknowledgment The instructors would like to thank Prof. David Mindell for his sponsorship of this course, his intention for its continued expansion, and his commitment to the well-being of MIT students."

Series of interactive learning activities for Anatomy and Physiology for most body systems. Page is updated regularly with new activities.

This course is intended to provide students with the fundamentals of fencing, including footwork, bladework, bouting and refereeing. It will allow students to develop the ability to analyze a fencing bout, and promotes creativity in applying acquired skills in a fencing bout.

Foundations of Neuroscience is aimed at undergraduate students new to the field of neuroscience. The first edition specifically targets students enrolled in Neurobiology at Michigan State University and primarily contains topics covered in that course.

" We are now at an unprecedented point in the field of neuroscience: We can watch the human brain in action as it sees, thinks, decides, reads, and remembers. Functional magnetic resonance imaging (fMRI) is the only method that enables us to monitor local neural activity in the normal human brain in a noninvasive fashion and with good spatial resolution. A large number of far-reaching and fundamental questions about the human mind and brain can now be answered using straightforward applications of this technology. This is particularly true in the area of high-level vision, the study of how we interpret and use visual information including object recognition, mental imagery, visual attention, perceptual awareness, visually guided action, and visual memory. The goals of this course are to help students become savvy and critical readers of the current neuroimaging literature, to understand the strengths and weaknesses of the technique, and to design their own cutting-edge, theoretically motivated studies. Students will read, present to the class, and critique recently published neuroimaging articles, as well as write detailed proposals for experiments of their own. Lectures will cover the theoretical background on some of the major areas in high-level vision, as well as an overview of what fMRI has taught us and can in future teach us about each of these topics. Lectures and discussions will also cover fMRI methods and experimental design. A prior course in statistics and at least one course in perception or cognition are required."

" This team-taught multidisciplinary course provides information relevant to the conduct and interpretation of human brain mapping studies. It begins with in-depth coverage of the physics of image formation, mechanisms of image contrast, and the physiological basis for image signals. Parenchymal and cerebrovascular neuroanatomy and application of sophisticated structural analysis algorithms for segmentation and registration of functional data are discussed. Additional topics include: fMRI experimental design including block design, event related and exploratory data analysis methods, and building and applying statistical models for fMRI data; and human subject issues including informed consent, institutional review board requirements and safety in the high field environment. Additional Faculty Div Bolar Dr. Bradford Dickerson Dr. John Gabrieli Dr. Doug Greve Dr. Karl Helmer Dr. Dara Manoach Dr. Jason Mitchell Dr. Christopher Moore Dr. Vitaly Napadow Dr. Jon Polimeni Dr. Sonia Pujol Dr. Bruce Rosen Dr. Mert Sabuncu Dr. David Salat Dr. Robert Savoy Dr. David Somers Dr. A. Gregory Sorensen Dr. Christina Triantafyllou Dr. Wim Vanduffel Dr. Mark Vangel Dr. Lawrence Wald Dr. Susan Whitfield-Gabrieli Dr. Anastasia Yendiki "

The University of Southern Queensland (USQ) is committed to advancing the use of open textbooks in higher education. This textbook is a tool to support first year anatomy and physiology courses taught in Australia, aiming to provide students with an increased access to free, high-quality learning materials.

Presents the anatomy, physiology, biochemistry, biophysics, and bioengineering of the gastrointestinal tract and associated pancreatic, liver, and biliary systems. Emphasis on the molecular and pathophysiological basis of disease where known. Covers gross and microscopic pathology and clinical aspects. Formal lectures given by core faculty, with some guest lectures by local experts. Selected seminars conducted by students with supervision of faculty. Permission of instructor required. (Only HST students may register under HST.120, graded P/D/F.) The most recent knowledge of the anatomy, physiology, biochemistry, biophysics, and bioengineering of the gastrointestinal tract and the associated pancreatic, liver and biliary tract systems is presented and discussed. Gross and microscopic pathology and the clinical aspects of important gastroenterological diseases are then presented, with emphasis on integrating the molecular, cellular and pathophysiological aspects of the disease processes to their related symptoms and signs.

An integrated course stressing the principles of biology. Life processes are examined primarily at the organismal and population levels. Intended for students majoring in biology or for non-majors who wish to take advanced biology courses.

BI101: Survey of Cellular Biology is intended for one term of the introductory biology course for non-science majors taught at many two- and four-year colleges. The concepts of cellular biology, as they apply to the study of life, are introduced, including parts of a cell, metabolism, and homeostasis.

This textbook incorporates the mandates found in Vision and Change and focuses on the non-content aspects of biology education that are just as important. Additionally, this book explicitly teaches the general education outcomes that we have identified as important for this class. This textbook pulls together biology content resources that are accessible for our community college non-major biology students, as well as resources to provide them with explicit instruction in the quantitative literacy, communication, and information literacy general education outcomes as they relate to the biology content they are learning.