The course covers the fundamental electrical and electronic circuit theory concepts and their usages.
Equivalent circuit of a MEMS resonator
(D. Grogg et al., Journal of Microelectromechanical Systems 18: 466-79, 2009)
This course aims to introduce basic principles and phenomena in the area of biomedical instrumentation. At the end of this course, student can understand, evaluate, and design systems and devices that can measure, test and/or acquire biological information from the human body.
Microfluidic platform for automated biomarker detection
(H.C. Tekin et al., Lab on a Chip 13: 1053-1059; 2013)
This course integrates principle concepts of engineering, which is commonly used in bioengineering. Content includes engineering mathematics, solid mechanics, heat and mass transfer, fluidic dynamics, bioinstrumentation and bioimaging.
Portable lensless microscopy platform for bioimaging
(H.C. Tekin et al., BioX Interdisciplinary Initiatives Symposium-Clark Center at Stanford University; 2014)
This course introduces to students the fundamentals of BioMEMS technology, typical BioMEMS devices and their applications. Preparation of a literature review paper on the student’s interest or research area will be required at the end of this course.
Credit card sized microfluidic chip for automatic biomarker detection
(H.C. Tekin et al., Lab on a Chip 13: 1053-1059, 2013)
This course provides a theoretical background of microfluidics effects and concepts. Microfluidics flows will also be simulated using finite element modelling tools.
Streamlines profiles inside a microfluidic mixer
(H.C. Tekin et al., Microfluidics and Nanofluidics 10: 749-59, 2011)
This course covers basic information about biosensors and their applications with up-to-date examples. Preparation of a literature review paper on the student’s interest or research area will be required at the end of this course.
Graphene-based biosensors integrated in a microfluidic platform for blood analysis
(S. Viswanathan et al., Materials Today 18: 513-522, 2015)