printer friendly pageBIOE 131: Ethics in Bioengineering (ETHICSOC 131X)
Bioengineering focuses on the development and application of new technologies in the biology and medicine. These technologies often have powerful effects on living systems at the microscopic and macroscopic level. They can provide great benefit to society, but they also can be used in dangerous or damaging ways. These effects may be positive or negative, and so it is critical that bioengineers understand the basic principles of ethics when thinking about how the technologies they develop can and should be applied. On a personal level, every bioengineer should understand the basic principles of ethical behavior in the professional setting. This course will involve substantial writing, and will use case-study methodology to introduce both societal and personal ethical principles, with a focus on practical applications
Terms: Spr
| Units: 3
| UG Reqs: GER:EC-EthicReas, WAY-ER
Instructors:
Altman, R. (PI)
;
Magnus, D. (PI)
;
Cooper, E. (TA)
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Instructors:
Altman, R. (PI)
;
Magnus, D. (PI)
;
Cooper, E. (TA)
;
Kim, Y. (TA)
;
McRae, K. (TA)
;
Soh, J. (TA)
;
Wang, X. (TA)
;
Wang, Y. (TA)
;
Wilson, S. (TA)
BIOE 193: Interdisciplinary Approaches to Human Health Research (BIO 193, CHEM 193, CHEMENG 193)
For undergraduate students participating in the Stanford ChEM-H Undergraduate Scholars Program. This course will expose students to interdisciplinary research questions and approaches that span chemistry, engineering, biology, and medicine. Focus is on the development and practice of scientific reading, writing, and presentation skills intended to complement hands-on laboratory research. Students will read scientific articles, write research proposals, make posters, and give presentations.
Last offered: Spring 2020
| Repeatable
11 times
(up to 11 units total)
BIOE 206: Mixed-Reality in Medicine (BMP 206, RAD 206)
Mixed reality uses transparent displays to place virtual objects in the user's field of vision such that they can be aligned to and interact with actual objects. This has tremendous potential for medical applications. The course aims to teach the basics of mixed-reality device technology, and to directly connect engineering students to physicians for real-world applications. Student teams will complete guided assignments on developing new mixed-reality technology and a final project applying mixed-reality to solve real medical challenges. Prerequisites: (1) Programming competency in a language such as C, C++. or Python. (2) A basic signal processing course such as
EE102B (Digital Signal Processing), while not required, will be helpful. (3) A medical imaging course, while not required, will be helpful. Please contact the instructors with any questions about prerequisites.
Terms: Aut
| Units: 3
BIOE 217: Translational Bioinformatics (BIOMEDIN 217, CS 275, GENE 217)
Analytic and interpretive methods to optimize the transformation of genetic, genomic, and biological data into diagnostics and therapeutics for medicine. Topics: access and utility of publicly available data sources; types of genome-scale measurements in molecular biology and genomic medicine; linking genome-scale data to clinical data and phenotypes; and new questions in biomedicine using bioinformatics. Case studies. Prerequisites: programming ability at the level of
CS 106A and familiarity with statistics and biology.
Terms: Spr
| Units: 3-4
BIOE 222: Physics and Engineering Principles of Multi-modality Molecular Imaging of Living Subjects (BMP 222, RAD 222)
Physics and Engineering Principles of Multi-modality Molecular Imaging of Living Subjects (
RAD 222A). Focuses on instruments, algorithms and other technologies for non-invasive imaging of molecular processes in living subjects. Introduces research and clinical molecular imaging modalities, including PET, SPECT, MRI, Ultrasound, Optics, and Photoacoustics. For each modality, lectures cover the basics of the origin and properties of imaging signal generation, instrumentation physics and engineering of signal detection, signal processing, image reconstruction, image data quantification, applications of machine learning, and applications of molecular imaging in medicine and biology research.
Terms: Aut
| Units: 3-4
Instructors:
Levin, C. (PI)
BIOE 279: Computational Biology: Structure and Organization of Biomolecules and Cells (BIOMEDIN 279, BIOPHYS 279, CME 279, CS 279)
Computational techniques for investigating and designing the three-dimensional structure and dynamics of biomolecules and cells. These computational methods play an increasingly important role in drug discovery, medicine, bioengineering, and molecular biology. Course topics include protein structure prediction, protein design, drug screening, molecular simulation, cellular-level simulation, image analysis for microscopy, and methods for solving structures from crystallography and electron microscopy data. Prerequisites: elementary programming background (
CS 106A or equivalent) and an introductory course in biology or biochemistry.
Terms: Aut
| Units: 3
Instructors:
Dror, R. (PI)
;
Bresette, L. (TA)
;
Li, D. (TA)
;
McAvity, J. (TA)
;
Sayana, R. (TA)
;
Suriana, P. (TA)
;
Xu, J. (TA)
BIOE 333: Systems Medicine
The human body is a wondrous system. It is able to maintain healthy function despite huge molecular and environmental variations. But the circuits that enable it to function so robustly have specific fragilities that lead to diseases. This course will provide basic principles for understanding human physiological circuits and show how these principles help to understand disease processes and their dynamics. The course will include guitar songs and other enjoyable methods to improve learning.
Last offered: Autumn 2021
BIOE 361: Biomaterials in Regenerative Medicine (MATSCI 381)
Materials design and engineering for regenerative medicine. How materials interact with cells through their micro- and nanostructure, mechanical properties, degradation characteristics, surface chemistry, and biochemistry. Examples include novel materials for drug and gene delivery, materials for stem cell proliferation and differentiation, and tissue engineering scaffolds. Prerequisites: undergraduate chemistry, and cell/molecular biology or biochemistry.
Terms: Spr
| Units: 3
BIOE 390: Introduction to Bioengineering Research (MED 289)
Preference to medical and bioengineering graduate students with first preference given to Bioengineering Scholarly Concentration medical students. Bioengineering is an interdisciplinary field that leverages the disciplines of biology, medicine, and engineering to understand living systems, and engineer biological systems and improve engineering designs and human and environmental health. Students and faculty make presentations during the course. Students expected to make presentations, complete a short paper, read selected articles, and take quizzes on the material.
Terms: Aut
| Units: 1-2
| Repeatable
5 times
(up to 10 units total)
BIOE 393: Bioengineering Departmental Research Colloquium
Bioengineering department labs at Stanford present recent research projects and results. Guest lecturers. Topics include applications of engineering to biology, medicine, biotechnology, and medical technology, including biodesign and devices, molecular and cellular engineering, regenerative medicine and tissue engineering, biomedical imaging, and biomedical computation.
Terms: Aut
| Units: 1
| Repeatable
for credit
Instructors:
Camarillo, D. (PI)
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