Bachelor of Science, Major in Biotechnology

at South Dakota State University USA

The Data Science major prepares students to use the power of data to help organizations of all sorts and society as a whole to make better decisions.  Students learn to use mathematics, statistics, and computational tools to analyze data of all sorts, and learn to communicate the results of their analysis in order to produce the greatest positive impact.  Graduates are prepared for any post-graduation outcome including immediate entry into the professional world or further study in a pursuit of a M.S. in Data Science.

Student Learning Outcomes
Upon completion of the Data Science major, students should be able to:

• Apply concepts and methods from Calculus and Linear Algebra. (Cross-curricular Skill: Inquiry and Analysis; Information Literacy)
• Work as part of a team to solve a complex Data Science problem. (Cross-curricular Skill: Teamwork)
• Gather requirements from professional contexts and translate them into a clearly articulated data analysis problem. (Cross-curricular Skill: Inquiry and Analysis; Critical and Creative Thinking; Problem Solving)
• Identify, gather, and prepare data necessary for analysis (Cross-curricular Skill: Inquiry and Analysis)
• Select the optimal combination of mathematical, statistical, and computing techniques necessary to solve a problem. (Cross-curricular Skill: Inquiry and Analysis; Critical and Creative Thinking; Information Literacy; Problem Solving)
• Conduct analysis in a manner that produces well-understood and reproducible results and avoids common analytical and ethical problems associated with data analysis. (Cross-curricular Skill: Inquiry and Analysis; Critical and Creative Thinking; Information Literacy; Problem Solving)
• Interpret and communicate results in the optimal combination of written, graphical/visual, and verbal means, to provide actionable intelligence to the stakeholder. (Cross-curricular Skill: Problem Solving)
• Appreciate the value of and work efficiently with a diverse group of individuals. (Cross-curricular Skill: Diversity, Inclusion and Equity)

SDSU, in partnership with the University of Minnesota (U of MN), is offering a collaborative Professional Program in Veterinary Medicine leading to a Doctor of Veterinary Medicine (DVM) degree. Students must first complete all their pre-veterinary requirements and then can apply to the new professional program.  Students admitted to the professional program will be allowed to dual-enroll in the Biological Sciences (M.S.) - Veterinary Medicine Specialization, thus having the opportunity to simultaneously earn an M.S. degree while completing the PPVM coursework needed for transitioning to the University of Minnesota to complete the final two years of the DVM degree. For more information visit the Association of American Veterinary Medical Colleges, Veterinary Medical College Application Service (VMCAS).

Student Learning Outcomes

Students will:

• Demonstrate understanding of central biological principles and mechanisms that underlie animal health and disease from the molecular to histologic to gross levels.
• Demonstrate knowledge of normal function and behavior, pathophysiology, clinical manifestations, diagnosis, treatment, and management or control of important domestic and foreign animal diseases.
• Demonstrate understanding of food safety, zoonotic disease, and public health issues.
• Retrieve and integrate information from the veterinary literature.
• Ability to understand and interpret research related to mechanisms of disease, diagnostic technology, and treatments.

The goal of the online M.S. specializing in Family and Community Services (FCS) is to provide advanced, professional education and research expertise that focuses on improving individual, family, and community well-being. This specialization is delivered entirely online through Great Plains Interactive Distance Education Alliance (Great Plains IDEA) and is designed to meet the educational needs of military service members and their spouses. Students who successfully complete this specialization will earn a Master of Science in Human Sciences specializing in Family and Community Services.

Student Learning Outcomes

• Research-based perspective: Student will be able to use a research-based perspective on individual, family, interpersonal and community dynamics across the lifespan.
• Design, implement and sustain program: Student will have the knowledge and skills to design, implement, and sustain family and community service programs.
• Leadership and management: Student will have the knowledge and skills for leadership and management of family and community service programs.

The Department’s chemistry faculty research programs fall into the thematic focus areas of environmental chemistry and green chemistry, chemical sensor development, organic synthesis, materials chemistry, natural products chemistry, and chemical education. Within these multidisciplinary and interdisciplinary focus areas, students can select research projects that involve the traditional subdisciplines of chemistry – analytical, biochemistry, inorganic, organic and physical. Currently active research projects in the Department focus on various aspects of analytical chemistry, drug discover and delivery, synthesis or photoactive materials including polymers, materials chemistry and self assembly, chromatography, the chemistry of cell membranes, cancer biology, environmental and green chemistry, chemistry of climate change, photo-physical chemistry, natural products synthesis, biophysical chemistry, computational chemistry, and solid-state NMR. For additional information about these options review the descriptions of current faculty research interests on the Department.

In addition to a traditional thesis-based (Option A) M.S. degree, the Department also offers a predominantly online Chemistry M.S. with chemical education specialization. This is a non-thesis (Option B) degree that focuses on the content necessary for practicing high school teachers to achieve highly qualified status. Admission in this program is limited to practicing high school science teachers. Students interested in thesis-based M.S. degree in the sub-disciplinary area of chemical education should select the Chemistry (M.S.) program in their application for admission.

Student Learning Outcomes

• Comprehensive knowledge: Graduate degree recipients will possess comprehensive disciplinary knowledge with high competence.
  • M.S. degree recipients will be able to demonstrate chemistry knowledge and advanced technical skills.
  • Graduate degree recipients will be prepared to demonstrate knowledge and technical skills in a large variety of professional fields, careers and endeavors.
  • Graduate degree recipients will communicate effectively in an oral, written and visual manner to technical audiences and stakeholders.
  • Graduate degree recipients will possess and practice high standards of scientific integrity and professional ethics.
• Trans-disciplinary professional skills: Graduate degree recipients will possess trans-disciplinary professional skills.
  • Graduate degree recipients will apply creativity to innovation.
  • Graduate degree recipients will recognize the importance of workplace diversity in culture, gender, perspective, and experience.
  • Graduate degree recipients will work effectively with peers and develop mentoring skills.
  • Graduate degree recipients will develop an understanding of the intellectual property process and the business needs of their workplace.
• Students will be familiar with the research literature of their chemistry subdiscipline and have the ability to keep abreast of major developments to acquire a working background in any area.
• Students will be able to demonstrate skill in the recognition of meaningful problems and questions for research.
• Students will possess technical skill in laboratory manipulation.
• Students will be able to demonstrate skill in designing experimental protocols and in conducting productive self-directed research.

A degree in Studio Art prepares majors for careers as fine artists, graduate study in fine arts, and entry-level positions in art and graphic design. The degree focuses on the breadth of general studies combined with visual arts studies where majors receive certificates in one or more of the following areas: Animation, Art History, Ceramics, Painting, Printmaking, Sculpture. A 30-hour visual arts core supports the degree and creates a foundation of success in art related fields.

Student Learning Outcomes
Upon completion of the Studio Art program, students will be able to:

• Apply the basic principles of visual organization, in two and three dimensions, to the creation and the analysis of works of art. This includes the application of fundamental drawing skills, design concepts, color theory, and studio specific applications. (Cross-Curricular Skills: Inquiry and Analysis; Integrative Learning)
• Generate a body of original works of art in their chosen area of specialization that exhibits a coherent set of artistic/intellectual goals. This includes the application of the relevant technologies and media associated with their area of specialization as well as other studio disciplines. (Cross-Curricular Skills: Foundation of Lifelong Learning Skills; Critical and Creative Thinking; Problem Solving; Integrative Learning)
• Analyze and critically evaluate works of art and design from various cultures and historical periods as well as the ability to apply art historical context to their own work. (Cross-Curricular Skills: Inquiry and Analysis; Critical and Creative Thinking; Diversity, Inclusion, and Equity)
• Articulate, both orally and written, a critical discourse on their artwork and processes, the artwork of others, and art history through the appropriate application of art and design language and concepts. (Cross-Curricular Skill: Integrative Learning)
• Demonstrate the skills required by professional artists in the communication, documentation, and exhibition of their artwork and experience. (Cross-Curricular Skill: Integrative Learning)

Learning one or more foreign languages is about much more than just grammar and structure of languages.  To learn a language is to engage with the heritage of entire civilizations, as well as with the contemporary norms that structure societies’ politics, religions, identities, and workplace, in order to communicate more effectively.  Furthermore, language study provides models for dealing with cultural differences that are applicable in any part of the world, including the U.S., taken together, courses offered in Spanish at SDSU prepare students with the skills to function and communicate effectively in any environment.

Student Learning Outcomes
Upon the completion of the Spanish major, students should be able to:

• Speak, read and write Spanish at the Intermediate-High or Advanced level, developing solid competence in the language needed for everyday life and advanced narrative skills in the past, present, and future. (Cross-curricular Skills: Intercultural Knowledge; Inquiry & Analysis; Information Literacy)
• Demonstrate understanding of and growth in the skills required for intercultural communication and competence and life-long learning. (Cross-curricular Skill: Intercultural Knowledge; Diversity, Inclusion and Equity; Critical & Creative Thinking)
• Identify the cultural perspectives of the Spanish-speaking world’s civilizations and their cultural products, such as literatures, arts, institutions, pop cultures, etc. and compare the cultural frames that determine everyday life in French- speaking cultures and the U.S. (Cross-curricular Skills: Intercultural Knowledge; Critical & Creative Thinking; Inquiry & Analysis; Information Literacy)
• Adapt behavior to a variety of cultural contexts through critical analysis of cultural frames. (Cross-curricular Skills: Intercultural Knowledge; Creative & Critical Thinking; and Diversity, Inclusion and Equity)
• Articulate the value of their language and cultural studies and apply this knowledge in future employment. (Cross-curricular Skill: Intercultural Knowledge; Diversity, Inclusion and Equity)

The department has three academic components:

• The first year School of Design cross-disciplinary experience.
• The three semester pre-professional building arts and public works design experience.
• The seven semester professional program experience.

A Bachelor of Fine Arts in Architecture degree (BFA-Arch) is recommended for those who want a studio-based liberal arts education in architecture as their first post-secondary experience.  Students in this program typically come from high school, community colleges / technical institutes, and transfer from other majors.  The B.F.A. in Architecture is 120 credit hours in eight semesters that can be completed in four regular (Fall & Spring only) academic years.  Students completing the B.F.A. can apply to the two year Master of Architecture program to cap the education as NAAB accredited professional training in architecture.  One must hold an NAAB accredited degree to become an architect.

Student Learning Outcomes

Upon completion of the architecture major, students will be able to:

• Move ideas from abstract to concrete through graphical methods.
• Measure and understand the impact of ideas on theoretical, social, political, economic, cultural, and environmental contexts.
• Use a diverse range of mediated practices to think about and convey architectural ideas, including writing, investigating, speaking, drawing, and modeling.
• Comprehend the technical aspects of both construction and mediating technologies and be able to apply that comprehension to architectural solutions.
• Capacity to synthesize a wide range of variables into an integrated design solution.
• Understand business principles for the practice of architecture, including management, advocacy, and the need to act legally, ethically, and critically for the good of the client, society, and the public. (Cross-curricular Skill: Ethical Reasoning)

Chemistry is often referred to as the central science because of its strong connections to the other natural sciences and mathematics. Chemistry is therefore an area of study that allows students vast opportunity to explore the unknown and to address some of human society’s most pressing scientific problems. The Chemistry Education program will prepare students for careers in high-quality teaching of chemistry at the secondary/high school level. The curriculum consists of a set of core requirements for students to acquire fundamental chemistry content knowledge and skills shared by all high-quality chemistry teachers, requirements for cognate knowledge development and skills acquisition (e.g., mathematics and other sciences), while meeting the state licensure requirements to teach high school. The core requirements provide foundational understanding in all five sub-disciplines of chemistry (analytical, biochemistry, inorganic, organic, and physical), representing breadth of content knowledge.  The curriculum also allows for exploration into the depth of chemistry content by including elective coursework in chemistry, environmental chemistry, and a capstone research course.

Student Learning Outcomes

Upon completing a major in Chemistry Education, graduates will:

• Understand the basic concepts fundamental to chemistry.
• Be properly prepared for laboratory investigations.
• Develop in-depth knowledge of at least four of the five subdisciplines of chemistry (analytical, biochemistry, inorganic, organic, and physical).
• Demonstrate knowledge of modern chemistry topics, which could include catalysis, environmental chemistry, green/sustainable chemistry, materials science, and toxicology.
• Be able to design and execute experiments, analyze data, and use the chemical literature. (Cross-curricular Skill: Inquiry and Analysis)
• Be able to synthesize the curricular knowledge and skills in a capstone (research) experience. (Cross-curricular Skill: Inquiry and Analysis; Information Literacy)
• Understand the scientific process and develop problem-solving skills. (Cross-curricular Skill: Problem Solving)
• Retrieve information effectively. (Cross-curricular Skill: Information Literacy)
• Develop chemical safety skills.
• Be able to rely on collaboration, effective teamwork, safety, and ethical practices. (Cross-curricular Skill: Teamwork; Diversity, Inclusion and Equity)
• Learn professional ethics. (Cross-curricular Skill: Ethical Reasoning)
• Have proficiency in essential green chemistry competencies.
• Be able to assess, comprehend, and communicate science. (Cross-curricular Skill: Inquiry and Analysis)
• Demonstrate teaching effectiveness. (Cross-curricular Skill: Diversity, Inclusion and Equity)
• Illustrate learner development.
• Recognize learning differences and learning environments. (Cross-curricular Skill: Diversity, Inclusion and Equity)
• Formulate content knowledge.
• Implement uses of multiple methods of assessment to engage learners in their own growth, to monitor learner progress, and to guide the teacher’s and learner’s decision making.
• Create plans of instruction that supports every student in meeting rigorous learning goals by drawing upon knowledge of content areas, curriculum, cross-disciplinary skills, and pedagogy, as well as knowledge of learners and the community context.
• Use a variety of instructional strategies to encourage learners to develop deep understanding of content areas and their connections, and to build skills to apply knowledge in meaningful ways.
• Engage in ongoing professional learning and use evidence to continually evaluate his/her practice, particularly the effects of his/her choices and actions on others (learners, families, other professionals, and the community), and adapt practice to meet the needs of each learner.
• Seek appropriate leadership roles and opportunities to take responsibility for student learning, to collaborate with learners, families, colleagues, other school professionals, and community members to ensure learner growth, and to advance the profession.

The Electronics Engineering Technology Bachelor of Science degree program blends theory with an extensive hands-on, lab-based course sequence. The program has three key components: electronics foundations, advanced electronics applications, and applied management. The goal is to prepare graduates to use be proficient in using, developing, and troubleshooting electronic devices, networks, and controls. Electronics technology courses include circuits, analog and digital systems (intro and advanced), networking, programming, microcontrollers, industrial controls and PLCs, circuit board design, power systems, and communication systems. The program also includes courses in computer programming, project management, quality systems management, and statistics.

Program Educational Outcomes
SDSU Electronics Engineering Technology graduates will become professionals who:

• Achieve positions of increasing responsibility or leadership with employers, professional organizations, or civic organizations as an indicator of professional competence, demonstrate the ability to communicate effectively, and successfully function in team environments;
• Apply principles of mathematics, science and management and use appropriate technology to solve current and future problems in the field of electronics technology; and,
• Complete licensure, certification, short courses, workshops, and/or advanced degrees to be effective technical managers in the global business environment.

Student Learning Outcomes
EET graduates have:

• An ability to apply knowledge, techniques, skills and modern tools of mathematics, science, engineering, and technology to solve broadly-defined engineering problems appropriate to the discipline; (Cross-curricular Skill: Inquiry and Analysis)
• An ability to design systems, components, or processes meeting specified needs for broadly-defined engineering problems appropriate to the discipline; (Cross-curricular Skill: Problem Solving)
• An ability to apply written, oral, and graphical communication in broadly-defined technical and non-technical environments; and an ability to identify and use appropriate technical literature;
• An ability to conduct standard tests, measurements, and experiments and to analyze and interpret the results to improve processes; and
• An ability to function effectively as a member as well as a leader on technical teams. (Cross-curricular Skill: Teamwork)

The program provides coursework on campus, in classroom, laboratory, and in field-based settings.  The EET program has three dedicated electronics labs for bench work, circuit testing, and project fabrication.

The focus of the M.S. in Statistics program is the development of sophisticated statistical models and their implementation on high performance computing platforms. The curriculum features a balance of application, computation, and theory with particular emphasis in the areas of biostatistics/informatics and analytics. Areas of faculty and graduate student research activity include bioinformatics, biostatistics, business and financial analytics, forensic statistics, and general statistics. The program is particularly effective at preparing graduates to work in business, industry, or government as well as preparing students to continue on to the CSS Ph.D. or other Ph.D. program.

Student Learning Outcomes

• Students will understand mathematical or statistical models.
• Students will be able to construct and apply standard mathematical and statistical models.
• Students will be able to solve problems using appropriate software to implement the appropriate models.
• Students will be able to disseminate the results of their work to others.
• Students will be able to apply Argument Deconstruction in mathematics and statistics.