300

An introduction to the biology of the prokaryotes (bacteria and archaea) and the animal viruses. Course topics include bacterial cell structure, nutrition and metabolism, growth, genetics, traditional and molecular systematics, ecology of microorganisms, genetic engineering and biotechnology, antimicrobial agents, host parasite interactions, and major infectious diseases. Current methods in bacteriology are used in the identification of bacteria and the conducting of experiments.

An introduction to the biology of the prokaryotes (bacteria and archaea) and the animal viruses. Course topics include bacterial cell structure, nutrition and metabolism, growth, genetics, traditional and molecular systematics, ecology of microorganisms, genetic engineering and biotechnology, antimicrobial agents, host parasite interactions, and major infectious diseases. Current methods in bacteriology are used in the identification of bacteria and the conducting of experiments.

An advanced course focusing on the evolutionary history of plants, plant anatomy and physiology, and plant ecology. The topics are diverse and emphasize recognizing reproductive and anatomical differences among major plant taxa (from algae to flowering plants), learning how to identify seed plants (gymnosperms and angiosperms)to the family level, and phyisological and ecological functions of plants.

The laboratory exercises are diverse and emphasize recognizing reproductive and anatomical differences among major plant taxa (from algae to flowering plants), learning how to identify seed plants (gymnosperms and angiosperms) to the family level, and physiological experiments.

A study of the vertebrate organ systems which are most intimately involved in maintaining homeostasis: Nervous, Endocrine, Cardiovascular, Respiratory and Excretory. Regulation and integration of the systems will be emphasized. Individual study of assigned journal articles which complement the lecture material constitutes a major part of the learning experience. The laboratory offers the student experience using a variety of preparations and instrumentation.

A study of the vertebrate organ systems which are most intimately involved in maintaining homeostasis: Nervous, Endocrine, Cardiovascular, Respiratory and Excretory. Regulation and integration of the systems will be emphasized. Individual study of assigned journal articles which complement the lecture material constitutes a major part of the learning experience. The laboratory offers the student experience using a variety of preparations and instrumentation.

An advanced course focusing on the principles of the interactions and relationships among organisms and between organisms and their environment. The topics combine basic ecological foundations such as population growth and competition with applied ecology in fields of importance such as forestry, agriculture, climate change, and conservation.

An introductory course focusing on the basic principles of the interactions and relationships among organisms and between organisms and their environment. The laboratory includes field observations, computer simulations, and statistical analysis of experimental data.

This course will provide a scientific foundation for understanding the causes and effects of major types of human-caused global change. Topics will include anthropogenic climate change, land-use change, nutrient cycling, invasive species, and others. The course will introduce students to global-scale ecological questions and research methods through a focus on current primary research. Students will also be introduced to the links between global change sciences and other disciplines through the discussion of possible solutions to these human-caused problems.

A comparative study of the evolution of the anatomical structures of vertebrates. The course will emphasize the basic structures of vertebrates, the functional role of anatomical structures, and the adaptive changes that have occurred in vertebrate evolution.

A comparative study of the evolution of the anatomical structures of vertebrates. The course will emphasize the basic structures of vertebrates, the functional role of anatomical structures, and the adaptive changes that have occurred in vertebrate evolution.

This course covers the molecular basis of biological activity through in-depth study of DNA. RNA and protein biosynthesis, regulation, and functional interactions. Particular emphasis is placed on the processes of DNA replication and repair, RNA transcription and processing, protein synthesis and post-translational modifications, and the regulation of gene expression. Students will also be introduced to various cell and molecular laboratory techniques, including PCR, gel electrophoresis, cloning, DNA sequencing, bacterial transformation, and gene knockouts. In addition to learning the fundamentals of how the cell works at the molecular level, students in this course will also be exposed to primary research articles within this area of study.

This lab course explores the interaction between the environment and gene expression in the single-celled protist, Tetrahymena thermophila. Students enrolled in this course will design an independent research project devoted to understanding how a particular environmental stressor impacts gene expression and behavior in Tetrahymena. To facilitate this investigation, students will be exposed to various molecular and cellular techniques including cell culture, RNA extraction, Reverse Transcription and quantitative PCR, as well as a variety of growth and feeding assays. Students in this course will also gain experience in researching a particular area of study, developing a scientific research proposal, and preparing a poster presentation based on their final results.

This course will introduce students to fundamental anatomical and mechanical principles and their application to biological systems to understand organismal movement. Emphasis will be placed on the biomechanics of the human body and movement. Topics will include biological tissue form and function, mechanical properties of biological tissues, kinematics, and kinetics.

This course will introduce students to fundamental anatomical and mechanical principles and their application to biological systems to understand organismal movement. Emphasis will be placed on the biomechanics of the human body and movement. Topics will include biological tissue form and function, mechanical properties of biological tissues, kinematics, and kinetics. The laboratory will expose students to basic experimental tools and techniques for biomechanical applications.

Developmental biology is a field concerned with the progressive changes that result in the formation of a multicellular organism. The nature of the changes and when, where, and how they occur are all included within Developmental biology's scope. This course focuses on the changes that occur during the embryonic period, broadly defined as the period extending from fertilization to birth or hatching in animals. The course includes both a survey of the anatomical changes that occur during this period and an examination of the molecular and cellular mechanisms thought to be responsible for bringing these changes about. Students in this course will also be exposed to the primary research within the field of Developmental Biology.

This course explores the cellular and molecular biology of the nervous system. Topics covered include the cellular and anatomical organization of the nervous system, electrical signaling, synaptic transmission, neurotransmitters and receptors, and synaptic plasticity. Students in this course will also be exposed to a wide variety of primary literature related to field of cellular and molecular Neuroscience.

This lab course explores the interaction between the environment and behavior in the model organism, Drosophila melanogaster (fruit fly). Students enrolled in this course will design an independent research project devoted to understanding how a particular environmental stressor impacts behavior in Drosophila. To facilitate this investigation, students will be exposed to various behavioral assays and fly culturing techniques. Students in this course will also gain experience in researching a particular area of study, developing a scientific research proposal, and preparing a poster presentation based on their final results.

This course explores the underlying principles of evolutionary change (natural selection, genetic drift, mutation, and gene flow) from an analytical perspective. The relevance of evolutionary change to real world concerns is emphasized while traditional and modem methods of analysis are explored and evaluated.

This laboratory experience explores some of the molecular methods used to study principles of evolutionary change. The laboratory will include hands-on experience with molecular techniques (including exposure to current next-generation sequencing technology) and phylogenetic analysis using real world experimental datasets. The scientific method, data analysis, interpretation within an evolutionary context, and scientific communication will be emphasized.

This upper-division course focuses on the cell as the basic unit of structure and function in living things. Topics include cellular organization, the structures and functions of cellular organelles and the cytoskeleton, energy transformations, communication between cells, and the cell cycle. Methods used to study cells and their component parts will be introduced through critical reading of peer-reviewed journal articles. Lectures will integrate material from genetics, chemistry, and introductory biology to understand cellular processes.

Special Topics courses include ad-hoc courses on various selected topics that are not part of the regular curriculum, however they may still fulfill certain curricular requirements. Special topics courses are offered at the discretion of each department and will be published as part of the semester course schedule - view available sections for more information. Questions about special topics classes can be directed to the instructor or department chair.

Special Topics courses include ad-hoc courses on various selected topics that are not part of the regular curriculum, however they may still fulfill certain curricular requirements. Special topics courses are offered at the discretion of each department and will be published as part of the semester course schedule - view available sections for more information. Questions about special topics classes can be directed to the instructor or department chair.

Advanced Writing. Research Experience in Plant Ecology. The primary goal of an Advanced Research Experience (ARE) is to engage all students in an authentic research opportunity as part of their undergraduate course work. Throughout the ARE course, students will be tasked with designing and implementing experiments to test a novel hypothesis that builds upon an area of knowledge. During the analysis process, collected data will be evaluated using descriptive and inferential statistics in order to develop meaningful conclusions. At the end of the ARE, each group will disseminate their findings to a broader audience through the presentation of their research project at Carroll's Student Undergraduate Research Festival. Furthermore, these projects will be uploaded to Carroll's Institutional Repository where they will be available to the general population. Each 2-credit ARE course will consist of two 3 hour labs per week.

Advanced Writing. Research Experience in Molecular Biology. The primary goal of an Advanced Research Experience (ARE) is to engage all students in an authentic research opportunity as part of their undergraduate course work. Throughout the ARE course, students will be tasked with designing and implementing experiments to test a novel hypothesis that builds upon an area of knowledge. During the analysis process, collected data will be evaluated using descriptive and inferential statistics in order to develop meaningful conclusions. At the end of the ARE, each group will disseminate their findings to a broader audience through the presentation of their research project at Carroll's Student Undergraduate Research Festival. Furthermore, these projects will be uploaded to Carroll's Institutional Repository where they will be available to the general population. Each 2-credit ARE course will consist of two 3 hour labs per week.

Advanced Writing. Research Experience in Cell & Molecular Neuroscience. The primary goal of an Advanced Research Experience (ARE) is to engage all students in an authentic research opportunity as part of their undergraduate course work. Throughout the ARE course, students will be tasked with designing and implementing experiments to test a novel hypothesis that builds upon an area of knowledge. During the analysis process, collected data will be evaluated using descriptive and inferential statistics in order to develop meaningful conclusions. At the end of the ARE, each group will disseminate their findings to a broader audience through the presentation of their research project at Carroll's Student Undergraduate Research Festival. Furthermore, these projects will be uploaded to Carroll's Institutional Repository where they will be available to the general population. Each 2-credit ARE course will consist of two 3 hour labs per week.

Advanced Writing. Research Experience in Cellular Mechanotransduction. The primary goal of an Advanced Research Experience (ARE) is to engage all students in an authentic research opportunity as part of their undergraduate course work. Throughout the ARE course, students will be tasked with designing and implementing experiments to test a novel hypothesis that builds upon an area of knowledge. During the analysis process, collected data will be evaluated using descriptive and inferential statistics in order to develop meaningful conclusions. At the end of the ARE, each group will disseminate their findings to a broader audience through the presentation of their research project at Carroll's Student Undergraduate Research Festival. Furthermore, these projects will be uploaded to Carroll's Institutional Repository where they will be available to the general population. Each 2-credit ARE course will consist of two 3 hour labs per week.

Advanced Writing. Research Experience in Animal Physiology. The primary goal of an Advanced Research Experience (ARE) is to engage all students in an authentic research opportunity as part of their undergraduate course work. Throughout the ARE course, students will be tasked with designing and implementing experiments to test a novel hypothesis that builds upon an area of knowledge. During the analysis process, collected data will be evaluated using descriptive and inferential statistics in order to develop meaningful conclusions. At the end of the ARE, each group will disseminate their findings to a broader audience through the presentation of their research project at Carroll's Student Undergraduate Research Festival. Furthermore, these projects will be uploaded to Carroll's Institutional Repository where they will be available to the general population. Each 2-credit ARE course will consist of two 3 hour labs per week.