The course provides an introduction to deductive and inductive logic. It introduces classical Aristotelian and modern truth-functional logic; explains the relationship between truth-functional logic, information science and probability; and it introduces basic features of statistical and causal reasoning in the sciences. This course is designed for students who are uncomfortable with symbolic systems. It is not a follow-up to PHI 102. Restrictions: Not open to students who have taken PHI 102. Enrollment limited to 24.

In this class students learn two approaches for conducting neuroscience experiments in human subjects. Students first learn about ethical considerations for working in human subjects. Students then learn to collect and analyze neural data from human subjects performing behavioral tasks using functional near-infrared spectroscopy. In the second portion of the class students learn tools for processing and analyzing publicly available fMRI data. This class provides two opportunities to complete projects utilizing the tools learned to answer questions of student interest.

This is an interactive lab class giving students hands-on experience working with techniques used in the study of cellular neuroscience. Techniques include: sterile cell culture, transfection (overexpression and siRNA), immunocytochemistry, cellular signaling assays and a variety of cellular functional assays. Major physiological mechanisms that underlie cellular signaling mechanisms are explored through the discussion of recent scientific literature with an emphasis on innovative techniques and strategies which allow researchers to test hypotheses and advance new concepts.

In this course students journey into how sex (and where relevant, gender) can and should be considered as a variable in biomedical research, with a focus on brain function and health. The course covers how and why the sex of research subjects has historically been overlooked and how males have been considered the “default” model systems for whole species and beyond. The class discusses the dimensionality of sex as a variable, learning about sex-related factors (such as chromosomes and hormones) that impact humans dynamically.

Systems neurobiology is the study of how networks of neurons function and how these networks mediate sensation, movement and higher-order functions such as language. The development of new technologies to image the brain, measure and manipulate neural activity, and understand whole-brain patterns of gene expression means our knowledge of systems neurobiology is growing rapidly. Thus, the major goal of this class is to teach what types of questions to ask and what approaches to use to find their answers.

Molecular level structure-function relationships in the nervous system. Topics include development of neurons and glia, neuron-specific gene expression, molecular biology of neurological disorders and the mechanisms of nervous system plasticity and repair. Prerequisites: BIO 200 and NSC 210 or equivalent. Enrollment limited to 20.

A laboratory course exploring anatomical research methods, neurochemical techniques, behavioral testing, design of experiments and data analysis. Prerequisites: CHM 111 or CHM 118; and NSC 130/ PSY 130 or NSC 210 (may be concurrent), or equivalent. Restrictions: Not open to seniors. Enrollment limited to 16.

A laboratory course exploring anatomical research methods, neurochemical techniques, behavioral testing, design of experiments and data analysis. Prerequisites: CHM 111 or CHM 118; and NSC 130/ PSY 130 or NSC 210 (may be concurrent), or equivalent. Restrictions: Not open to seniors. Enrollment limited to 16.