This Course at MIT pages provide context for how the course materials published on OCW were used at MIT. They are part of the OCW Educator initiative, which seeks to enhance the value of OCW for educators.
This page focuses on the course 9.14 Brain Structure and Its Origins as it was taught by professor Gerald E. Schneider in Spring 2014.
This class is taken by MIT undergraduates with a special interest in learning about brain structure and how this structure underlies brain functions. The lectures are designed to teach key concepts as well as definitions of specialized terms used commonly by neuroscientists. Brain development and evolution are discussed to help students gain an understanding of why the central nervous systems of mammals (including humans) are put together the way they are.
Many students enrolled in this course go on to medical schools or to graduate schools. The latter most commonly enter neuroscience departments, but not all. Some pursue degrees in psychology, electrical engineering, and occasionally even the humanities or physics.
9.14 can be applied toward a Bachelor of Science in Brain and Cognitive Sciences, but is not required.
Every spring semester
The students' grades were based on the following activities:
1/3 sophomores, 1/3 juniors, 1/3 seniors
1/2 Brain and cognitive sciences, 1/4 Biology, 1/4 Electrical Engineering.
Students have met basic MIT undergraduate requirements in physics, mathematics, chemistry and biology, and most have taken a basic neuroscience class in addition to introductory psychology.
During an average week, students were expected to spend 12 hours on the course, roughly divided as follows:
Below, Professor Schneider describes various aspects of how he taught 9.14 Brain Structure and Its Origins.
The content of the course has evolved over the past 14 years. It began with a focus on the anatomy of model systems used in neuroscience research and in studies of brain development. This focus was designed to help students learn the relevant neuroanatomy. Since then, I’ve introduced more and more comparative anatomy. I’ve also added more and more content about brain development.
My experiences teaching this course are what inspired me to write Brain Structure and Its Origins in Development and in Evolution of Behavior and the Mind (2014). The material for the book, just like the material for the class sessions, was prepared over my many years of teaching and involvement in laboratory research on brain anatomy and function. The book will be required reading for residential learners beginning in Spring 2015; it may also serve as a helpful resource for independent learners studying the material through OpenCourseWare.
One challenge students face in this course is learning a large number of new terms. I help students meet this challenge by providing them with online access to a glossary written especially for this course. I also define the most important terms in class, and ask questions during lectures to trigger students’ active participation.
Another strategy I use to help students learn the complex material in this course is to begin the discussion of brain structure with what we believe to be the simplest nervous systems of some of the first chordate animals—animals that preceded all the vertebrates. Detailed discussion of large primate brains occurs only in the final part of the class and textbook. I simplify diagrams to emphasize major concepts.
Dissecting a sheep’s brain helps students gain a better sense of the brain’s three-dimensional structure, which makes the course material more concrete. This is important because, during class sessions, we view and discuss many illustrations; relating the illustrations to a real brain is crucial. The dissection experience increases students’ ability to think dynamically about brain illustrations, and for this reason, I would prefer to include at least two dissection sessions instead of only one.