This course is an introduction to environmental issues – the interactions of humanity and industrial civilization with the natural environment of Earth. The course draws on scientific, technological, and social perspectives to examine current and future environmental challenges, including the impacts of human actions on natural ecosystems, natural resources, pollution, and climate change.
Everyone knows someone who has been impacted by cancer. By merely surviving, our bodies are primed with the capacity to develop this disease. This course will explore the ‘war on cancer’ in the context of human history, cell biology, and dramatic storytelling. Laboratory exercises will explore the biological basis of this disease. Not open to students who are enrolled in or who have taken and passed IBC 200 with at least a grade of C- or P.
The human body is an amazing product of 3.5 billion years of evolution. From our cells to our organ systems, our bodies are beautifully designed to thrive on planet Earth. In this course, we will explore the structure and function of various human organ systems including the circulatory system, respiratory system, digestive system, reproductive system, and portions of the endocrine system (kidneys and adrenal glands). Along the way, we will discuss challenges faced by each of these organ systems in this modern age that can result in disease such as air pollution, endocrine disrupting chemicals, overuse of antibiotics, chronic stress, and a highly-processed industrial diet. Students will perform various hands-on laboratory activities that will reinforce how their bodies function and how they can live a healthy life. Not open to students who are enrolled in or who have taken and passed BIO 303 with at least a grade of C- or P.
This course focuses on the following marine habitats: fouling communities, rocky intertidal, deep sea, coral reefs, and open oceans. You will learn the abiotic factors that define each habitat (e.g. light, temperature, nutrients), which species live in each habitat, and how these species interact with each other and with humans. The coral reef and open ocean habitats in particular are under threat from global warming, overfishing, and pollution. We will learn about these challenges, as well as solutions.
Have you ever wondered about DNA and how slight alterations to the genetic code have produced the amazing variety of life forms that inhabit our planet? This class will explore exciting topics in both genetics and evolutionary biology, some of which include: the genetics of cancer, reproduction and inheritance, epigenetics, GMOs, DNA forensics, antibiotic resistance, evolution of the “fat gene,” and how to build evolutionary trees. Students will explore these topics through lectures, case study work, and hands-on laboratory exercises. Not open to students who are enrolled in or who have taken and passed IBC 200 with at least a grade of C- or P.
This course explores the anatomical form and function of representatives from major animal phyla. Students will first learn about evolutionary processes that have generated the tremendous variety of form and function present in the animal kingdom. They will then learn about different lines of evidence that support the theory of common descent and examine how major lineages within the animal kingdom were created from key morphological innovations. Students will then take a tour of the major animal phyla. Students will explore these topics through lectures and hands-on laboratory activities that include live animal observations, dissections, field trips, and case studies. Not open to students who are enrolled in or who have taken and passed BIO 306 with at least a grade of C- or P.
This course offers a fundamental introduction to evolutionary biology, patterns of diversity, and ecology. We will discuss evolutionary processes such as natural selection and genetic drift and explore how those processes can lead to genetic diversity within species as well as the creation of new species. We will also explore the form and function of various phyla from the tree of life and discuss how they interact within communities and ecosystems.
This interdisciplinary course will focus on the molecular biology of cancer and the underlying chemistry of cell biology. Students will learn how proteins are encoded and the impact of genomic instability on protein structure and function; alterations of normal metabolism in cancer cells; and basic pathways of cell division and death. Complementary chemistry topics include chemical structure and bonding, biological polymerization, thermodynamics, enzyme kinetics, and redox reactions. Laboratory research will use model systems to understand cancer biology. Prevents co- or later enrollment in BIO 115 and BIO 130.
