Program Coordinator/Contact
Douglas Raynie, Department Head
Nicole Grove, Coordinator of Undergraduate Programs
Department of Chemistry and Biochemistry
Avera Health and Science Center 247, Box 2202
605-688-5151
Program Information
One of the fastest growing scientific disciplines is also one of the youngest – biochemistry. Biochemistry is the application of atomic and molecular principles to the function of plant and animal life processes. This multifaceted science includes the study of all life forms and depends on basic concepts derived from chemistry, biology, physics, and mathematics. Training in biochemistry at the undergraduate level positions students well for careers in biotechnology, pharmaceutical development, government laboratories, and is very appropriate as a pre-professional course of study. The B.S. in Biochemistry curriculum at SDSU builds upon a solid foundation in chemistry, and incorporates selected aspects of biology, physics, and mathematics to complete the undergraduate degree. In addition to completing the degree requirements listed below, biochemistry students engage in undergraduate research with faculty members in the department.
Student Learning Outcomes
- Students will understand the basic concepts fundamental to chemistry.
- Students will be properly prepared for laboratory investigations.
- Students will understand the nature of biological energy.
- Students will understand catalysis.
- Students will be able to describe energetic coupling of chemical processes in metabolic pathways.
- Students will be able to describe biological macromolecules.
- Students will describe the factors which determine the structure of biological macromolecules.
- Students will be able to relate structure and function.
- Students will be able to describe macromolecular interactions.
- Students will understand that macromolecular structure is dynamic.
- Students will be able to discuss regulation of the biological activity of macromolecules.
- Students will be able to relate the structure (and hence function) with the foundational principles of chemistry and physics.
- Students will be able to use a variety of experimental and computational approaches to observe and quantitatively measure the structure, dynamics and function of biological macromolecules.
- Students will be able to describe the genome.
- Students will be able to discuss the relationship between nucleotide sequence and biological function.
- Students will be able to explain gene transmission from one generation to the next.
- Students will be able to describe genome maintenance.
- Students will understand the scientific process.
- Students will be able to assess, comprehend, and communicate science.
- Students will be able to rely on collaboration, effective teamwork, safety, and ethical practices.
- Students will be able to describe the biological need for homeostasis.
- Students will be able to link steady state processes and homeostasis.
- Students will be able quantify homeostasis.
- Students will be able to describe control mechanisms.
- Students will be able to describe cellular and organismal homeostasis.
- Students will be able to synthesize the curricular knowledge and skills in a capstone (research) experience.
Academic Requirements
A grade of “C” or better is required in all courses required for the major.
Accreditation, Certification, and Licensure
The B.S. in Biochemistry is accredited by the American Society of Biochemistry and Molecular Biology (ASBMB), whose certification serves as recognition of a high quality and rigorous curriculum.
Course Delivery Format
Courses offered in the Biochemistry curriculum are taught in a variety of formats which address student learning outcomes. Didactic (lecture) methods ensure the development of foundational knowledge of chemistry. Practical (laboratory) methods ensure the development of laboratory skills and training; A combination of didactic and practical methods ensure the successful completion of the undergraduate research project.