This course begins with discussion of pharmacological principles and normal function of the nervous and endocrine system. As we continue, we will describe how exogenous substances derived from plants (like drugs) impact the nervous system to restore normal or near-normal function, or alter normal function, in humans. The use of agents from plants in the alleviation of depression and anxiety will be emphasized.

This course addresses the impact of the human genome project on understanding human genetic disease, focusing on the invaluable role for animal models of diseases in augmenting evaluation of genomic information to develop strategies for precision medicine. Animal models are an invaluable asset in reaching this goal because they allow experimental manipulations that go far beyond what is possible in human patients.

Imagine a world where your DNA is sequenced for free and any human gene can be altered at will. The goal of this course is to address the question: can our society be better prepared for this transformation in science? Is genetic privacy achievable or genetic discrimination avoidable? Who owns your genes? Do your genes drive your medical future? Classes involve student perspectives and discussions with experts in science, policy, ethics and law.

The goal of this course is to provide an original, unknown outcome research experience in developmental biology. After training in basic methods and descriptions of selected research problems, students form teams and investigate a problem of their choosing. Team members work together in the lab, but each writes an independent research proposal, a notebook, and a final project report on which they are graded. Recommended prerequisites: BIOL 3000 and 3010.

Introduction to the fundamental principles of conservation biology (e.g., global species numbers, value of biodiversity, causes of extinction, genetic diversity, island biogeography, priority setting) and current topics of debate (including zoo versus field conservation, effects of global change on species extinction). Conservation case studies will allow students to judge the relevance of biological theory to practical problems in conservation.

This course, the first in a two-course sequence, is an introduction to the structure and function of the human body. Review of the structure and physiology of cells and tissues leads to in-depth study of the musculoskeletal and nervous systems. Control mechanisms and the contributions of each system to overall homeostasis are emphasized.

New course in the subject of biology.

Examines the mechanisms of evolutionary change, with an emphasis on the genetic and evolutionary principles needed to understand the diversification of life on earth.  Covers the ecology of individuals and population dynamics.  Major topics include the genetics and ecology of natural populations, adaptation, molecular evolution and macroevolution, and the application of evolutionary and ecological concepts to conservation biology.  Required for all Biology majors. Prerequisite: Must have completed BIOL 2200. BIOL 3020 is not repeatable.

BIOL 2200 is one of two semester courses that together provide an intensive introduction to biology for prospective Biology majors and pre-health (med, vet, dental) students. This course focuses on evolution, physiology and development. Lecture topics and concepts are reinforced and extended during once-weekly laboratory/small group discussions. The Introductory courses are not sequenced and may be taken in either order.

Analyzes the concepts of general neurobiology, including basic electrophysiology and electrochemistry, origin of bioelectric potentials, sensory, motor, integrative and developmental neurobiology, and conceptual models of simple learning. Prerequisites: BIOL 2100 (or BME 2104) and BIOL 2200. Recommended:  Prior completion of BIOL 3000