At Queen Mary, you’ll be taught by world-leading researchers in both biology and chemistry, together in one School. You’ll develop advanced scientific understanding of both disciplines, and improve your practical skills with high-level lab work. You’ll learn about key biochemical processes and the chemistry that underpins them, as well as studying real-world applications in biotechnology and medicine. Option modules in the second and third years let you direct your studies to the areas that interest you most. Choose your own pathway through this degree - you can add a year in industry or studying abroad, or carry out an additional year of advanced study to graduate with an MSci.
Most developments in modern biological sciences rely extensively on techniques and principles of chemistry and physics. Undergraduate studies in biochemistry prepares students for advanced study in biochemistry, biophysics, cell biology, genomics, molecular biology, neurobiology, structural biology and genetics-based biotechnology and can provide the basic science background for health professional schools and for prospective science teachers. All majors have the opportunity to do independent research.
The chemistry of life. Behind every living organism is a complex network of molecules and other substances working together to control how cells grow and function. Biochemistry explores this fascinating chemical process. In this program, you will study the structure of proteins, carbohydrates, lipids, nucleic acids and other biomolecules. You will also learn about cellular processes such as DNA replication, protein secretion, energy metabolism and immune responses. The program is excellent preparation for graduate school or for medical, dental, physical therapy, or other allied health programs.
Chemistry, the study of molecules, is a central science interesting for its own sake but also necessary as an intellectual link to the other sciences of biology, physics, and environmental science. Faculty find the various disciplines of chemistry fascinating because they establish intellectual bridges between the macroscopic or human-scale world that we see, smell, and touch, and the microscopic world that affects every aspect of our lives. The study of chemistry begins on the microscopic scale and extends to engage a variety of different macroscopic contexts.
Chemists are architects. They deal with the composition of nonliving things—from textiles to oil and petroleum to the atmosphere—essentially, everything that we touch and see. Their “building blocks” are atoms and molecules. Biochemistry is a bridge between biology and chemistry. This “hybrid” major focuses on the composition of living things. You’ll examine topics like how humans derive nutrients from food, how diseases evolve, and why plants thrive in certain environments.
In order to earn the bachelor of science degree with a major in biochemistry, students must complete a minimum of 124 units with a Pacific cumulative and major/program grade point average of 2.0. I. General Education Requirements Minimum 42 units and 12 courses, including: PACS 001 Pacific Seminar I: What is a Good Society? PACS 002 Pacific II Topical Seminar PACS 003 Pacific Seminar III: The Ethics of Family, Work, and Citizenship Note: 1) Pacific Seminars cannot be taken for Pass/No Credit. 2) Transfer students with 16 or more transfer units complete 2 additional General Education elective courses from below in place of taking PACS 001 and 002.
The Bachelor of Science in Biochemistry degree program will take students on an exploration of the chemical processes within and related to living organisms. It is designed to provide a broad and deep foundation in biological and chemical concepts with plenty of research based projects. By using chemical knowledge and techniques, biochemists can understand and solve biological problems.
Chemistry is the science that deals with the composition of materials, their structures and properties, the transformations they undergo, and the energy changes that accompany these transformations. Areas of study include general, organic, physical, analytical, and inorganic chemistry, as well as biochemistry and earth science. Students are encouraged to participate in research projects at all levels. Approved by the American Chemical Society, the department offers programs leading to the Chemistry (BS), Chemistry (MS), and Biochemistry (BS). Besides training for a career or graduate study in chemistry and biochemistry, undergraduate students are prepared for medical or dental school, engineering programs, and other careers where technical expertise is needed. The department provides a personal, congenial environment where students can develop and pursue a flexible program of study designed to fulfill individual interests and needs. The Department of Chemistry is equipped with standard chemical instrumentation, including spectrometers and chromatographic equipment. Laboratory facilities in the Beeghly building include modern teaching and research laboratories as well as specialized laboratories established for research in biochemistry, polymer chemistry, nanomaterials chemistry, electrochemistry, and carbohydrate chemistry, and for work requiring an inert atmosphere. Graduate and undergraduate students are involved in a variety of research projects using the facilities of the department or through cooperative agreements with many governmental laboratories. Students learn how to design, conduct, and analyze research in advanced laboratory courses as part of their curriculum.
Freshman Fall Hours Spring Hours ENGL 1100 English Composition I 3 ENGL 1120 English Composition II 3 MATH 1610 Calculus I 4 MATH 1620 Calculus II 4 Core History I 3 BIOL 1020 Principles of Biology 3 CHEM 1110 General Chemistry I3 3 BIOL 1021 Principles of Biology Laboratory 1 CHEM 1111 General Chemistry I Laboratory 1 CHEM 1120 General Chemistry for Scientists and Engineers II3 3 CHEM 1121 General Chemistry II Laboratory 1
Biochemistry is a unique discipline that combines chemistry and biology. In this major you will be introduced to biological molecules and learn why they are essential for life through coursework and hands-on laboratory components.
As a biochemistry major at Widener University, students not only study biology and chemistry, but they learn how to be leaders in a growing field. This unique cross discipline provides a solid foundation in the sciences. Through a variety of courses in biology and chemistry, students explore both the living world and understand man-made chemical processes. The curriculum emphasizes the molecular, analytical, and quantitative aspects of living systems and includes research projects that train students to formulate questions, analyze data, and come up with solutions.
Biochemistry links the fields of biology and chemistry, diving into how life functions at its most basic levels. Biochemistry is the science that seeks to understand how molecules work together to in living organisms. Using chemistry and molecular biology, you will study complex molecules found in biological materials and the ways these molecules interact to form cells, tissues, and whole organisms. Biochemistry provides the basis for advances in human and veterinary medicine, agriculture, and biotechnology. This rigorous major, with plenty of hands-on lab experience, is excellent preparation for entering these industries or graduate school.
Biochemistry, the study of the chemical processes occurring in living organisms, is a broad field that offers a wide range of career options. The Bachelor of Science in Biochemistry degree is designed to provide a strong foundation in the chemical and biological sciences meeting standards set forth by the American Chemical Society (ACS). This program prepares students seeking careers in the life/health sciences professions (medicine, physician assistant, pharmacy, dentistry, and veterinary science), biochemical research and biotechnology. Curry College's location, just 7 miles from Boston, a major hub of the pharmaceutical industry, provides opportunities for meaningful internships and career options after graduation.
Biochemistry examines the role of chemistry in the life sciences. Students who study biochemistry as undergraduates at Saint Louis University have the opportunity to earn a Bachelor of Arts degree or a Bachelor of Science degree.SLU’s B.A. in biochemistry will give you a strong foundation for further training in medicine, dentistry or pharmacy, while the B.S. in biochemistry will prepare you for careers in biochemistry, molecular biology or biotechnology research in an industrial or government laboratory. The bachelor of science degree is certified by the American Chemical Society. Both degrees are offered through SLU's Department of Chemistry.
Biochemistry focuses on the chemical processes occurring in the wide variety of living systems and touches essentially all aspects of our own lives. Our Northeastern program engages you in two integrated paths to a career in biochemistry: rigorous coursework that prepares you to interpret the ever-expanding knowledge base and hands-on learning that positions you to leverage cutting-edge technology to solve fundamental problems in the chemistry of life.
Richard L. Conolly College of Liberal Arts and Sciences The undergraduate program leading to the degree of Bachelor of Science in Biochemistry connects the ever-growing important interface between biology and chemistry. Training emphasizing advanced experimental and theoretical principles is provided in both the biological and chemical sciences, as a foundation for a variety of career paths, including further training in biology, chemistry or biochemistry; molecular biology; and medical or dental school. Students successfully completing the biochemistry curriculum may have their degrees certified by the American Chemical Society. Biochemistry majors are urged to consult with advisers from both the Biology Department and the Chemistry and Biochemistry Department to formulate appropriate programs of study and to explore the numerous career paths available.
A major in Biochemistry is meant to prepare students for graduate studies in Chemistry or Biochemistry, for admission to a professional school such as medical school or pharmacy school, or employment in the biotechnology sector.
Biochemistry explores the chemistry that underpins all biological processes. Building on research advances, Biochemistry uses a variety of tools and approaches to open up new frontiers and address field-bending issues of biological significance with ever-increasing accuracy and detail. Biochemistry began here even before the founding of Vanderbilt University with lectures being given in the Medical Department of the University of Nashville in 1851, and with the Department of Biochemistry starting under that name in 1925. Through its history since then the Department has flourished under the direction of five chairmen and currently has 20 primary faculty and a Ph.D. program. The offices and laboratories are in Light Hall, the Robinson Research Building, the Preston Research Building, and Medical Research Building III (see maps), administratively part of the School of Medicine. Ph.D. degrees have been granted in the Department since 1926. Over the years, faculty in the Department of Biochemistry have received considerable recognition, including receipt of major University awards, election to the National Academy of Sciences, and a Nobel Prize in Physiology or Medicine (Stanley Cohen, 1986). Although formal ratings of biochemistry departments are not made, the Department of Biochemistry in 2014 received more funding from the National Institutes of Health than any other Biochemistry Department in the nation. We are proud of our history and current status, and we strive towards continued excellence in research, training, and service in the field of biochemistry.
Biochemistry is the study of the molecular basis of cellular and organismal function, making it a central discipline in the biological sciences. Biochemists ask the question, “How do life processes work at the molecular level?” The Department of Biochemistry offers undergraduate programs leading to the BA and BS degrees in biochemistry and graduate programs leading to the MS and PhD degrees. There are also dual-degree programs, leading to the MD/PhD, MD/MS in Biomedical Investigation, JD/MS, MS/MBA, and MS/MA in Patent Practice degrees. The department also participates in several interdisciplinary and interdepartmental programs in the School of Medicine and at Case Western Reserve University that provide additional avenues of study. Research by Biochemistry faculty members covers a range of topics aimed at understanding life processes at the molecular level. Our efforts are broadened by collaborations with faculty in other university departments and with scientists at other academic and biotech research institutions. Research in the department is aimed at understanding the structures of biological macromolecules, the functions of proteins and enzymes, and the growth and differentiation of cells. There is also a focus on antibiotics and drug development.
The Graduate Program in Biochemistry is part of a large, diverse, and highly interactive community of biological scientists that form the Graduate Program in Molecular Biosciences at Rutgers University. This consortium is currently made up of five graduate programs and functions to coordinate the recruitment, admissions, and first year core curriculum of Ph.D. students, as well as helping our students in selecting Ph.D. research advisers from among the more than 200 faculty members on campus. The Biochemistry Program currently has approximately 100 faculty members from a number of departments in the two universities. Faculty research spans a wide variety of topics, including: DNA replication and transcription, virus gene expression, tumor biology, structural biochemistry, signal transduction and molecular targeting, protein chemistry and enzymology. Additional or alternative studies are designed to meet individual needs. Thus graduate students have the opportunity to select additional study areas in their work. The Biochemistry Program offers advanced studies leading to the Ph.D. degree: The Ph.D. requirements include a set of core courses during their first year. In addition students are required to conduct laboratory research, pass parts I and II of the qualifying examination, and write and defend a research dissertation. All Ph.D. students are guaranteed a stipend of $28,455 in addition to health coverage and tuition remission for the duration of their graduate studies, provided that academic standards are met and progress towards a Ph.D. is maintained.
For students from all over the world who wish to receive a prestigious education in hospitality, hotel and restaurant business, the Glion Institute of Higher Education Bulle does not need a special introduction. This high-tech, modern institution is one of the leaders of education in the hospitality industry, one of the largest and most prestigious specialized world schools.
The first campus of the Glion Institute of Higher Education Bulle was opened in 1962 in the premises of a former five-star hotel: today Glion offers training on several campuses in Switzerland, has branches in London and China. This is the first private school of hotel and restaurant business in Switzerland, offering a variety of higher education programs, diploma courses and short-term training programs.
The Glion Institute of Higher Education Bulle is designed to teach 2-3 year students and graduate students. In a cozy, modern and well-equipped campus, senior students and undergraduates can successfully conduct a variety of studies, group and individual projects, devote maximum time to practical pursuits.