Description

This course introduces the basic driving forces for electric current, fluid flow, and mass transport, plus their application to a variety of biological systems. Basic mathematical and engineering tools will be introduced, in the context of biology and physiology. Various electrokinetic phenomena are also considered as an example of coupled nature of chemical-electro-mechanical driving forces. Applications include transport in biological tissues and across membranes, manipulation of cells and biomolecules, and microfluidics. This course introduces the basic driving forces for electric current, fluid flow, and mass transport, plus their application to a variety of biological systems. Basic mathematical and engineering tools will be introduced, in the context of biology and physiology. Various electrokinetic phenomena are also considered as an example of coupled nature of chemical-electro-mechanical driving forces. Applications include transport in biological tissues and across membranes, manipulation of cells and biomolecules, and microfluidics.

Subjects

hydrodynamic flow | hydrodynamic flow | electroosmosis | electroosmosis | diffusion | diffusion | electrophoresis | electrophoresis | reaction | reaction | membrane | membrane | cell | cell | biomolecule | biomolecule | microfluidics | microfluidics | ion transport | ion transport | electrokinetics | electrokinetics | Debye layer | Debye layer | Zeta potential | Zeta potential | inviscid flow | inviscid flow | viscous flow | viscous flow | tissue | tissue | organ | organ | biology | biology | molecular biology | molecular biology | Maxwell's equations | Maxwell's equations | electro-quasistatics | electro-quasistatics | Van der Waals | Van der Waals | bioMEMS | bioMEMS

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Description

This course is a project-based introduction to manipulating and characterizing cells and biological molecules using microfabricated tools. It is designed for first year undergraduate students. In the first half of the term, students perform laboratory exercises designed to introduce (1) the design, manufacture, and use of microfluidic channels, (2) techniques for sorting and manipulating cells and biomolecules, and (3) making quantitative measurements using optical detection and fluorescent labeling. In the second half of the term, students work in small groups to design and test a microfluidic device to solve a real-world problem of their choosing. Includes exercises in written and oral communication and team building. This course is a project-based introduction to manipulating and characterizing cells and biological molecules using microfabricated tools. It is designed for first year undergraduate students. In the first half of the term, students perform laboratory exercises designed to introduce (1) the design, manufacture, and use of microfluidic channels, (2) techniques for sorting and manipulating cells and biomolecules, and (3) making quantitative measurements using optical detection and fluorescent labeling. In the second half of the term, students work in small groups to design and test a microfluidic device to solve a real-world problem of their choosing. Includes exercises in written and oral communication and team building.

Subjects

HST.410 | HST.410 | 6.07 | 6.07 | cell manipulation | cell manipulation | microchips | microchips | lithography | lithography | rapid prototyping | rapid prototyping | optical imaging of cells | optical imaging of cells | cell sorting | cell sorting | microfluidics | microfluidics | osmosis | osmosis | diffusion | diffusion | microfabrication | microfabrication | models of diffusion | models of diffusion | laminar flow | laminar flow | MATLAB data analysis | MATLAB data analysis | cell traps | cell traps | experimental design | experimental design | cytometry techniques | cytometry techniques | computer simulation of neural behavior | computer simulation of neural behavior | casting PDMS | casting PDMS | coulter counter | coulter counter | plasma bonding | plasma bonding

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Description

Includes audio/video content: AV special element video. This course links clean energy sources and storage technology to energy consumption case studies to give students a concept of the full circle of production and consumption. Specifically, photovoltaic, organic photovoltaic, piezoelectricity and thermoelectricity sources are applied to electrophoresis, lab on a chip, and paper microfluidic applications–relevant analytical techniques in biology and chemistry. Hands-on experimentation with everyday materials and equipment help connect the theory with the implementation. Complementary laboratories fabricating LEDs, organic LEDs and spectrometers introduce the diagnostic tools used to characterize energy efficiency.This course is one of many OCW Energy Courses, and it is an elective Includes audio/video content: AV special element video. This course links clean energy sources and storage technology to energy consumption case studies to give students a concept of the full circle of production and consumption. Specifically, photovoltaic, organic photovoltaic, piezoelectricity and thermoelectricity sources are applied to electrophoresis, lab on a chip, and paper microfluidic applications–relevant analytical techniques in biology and chemistry. Hands-on experimentation with everyday materials and equipment help connect the theory with the implementation. Complementary laboratories fabricating LEDs, organic LEDs and spectrometers introduce the diagnostic tools used to characterize energy efficiency.This course is one of many OCW Energy Courses, and it is an elective

Subjects

clean energy | clean energy | energy sources | energy sources | energy storage | energy storage | energy consumption | energy consumption | photovoltaic | photovoltaic | piezoelectric | piezoelectric | thermoelectric | thermoelectric | LED | LED | light emitting diode | light emitting diode | organic LED | organic LED | analytical biology | analytical biology | analytical chemistry | analytical chemistry | microfluidics | microfluidics | spectrometer | spectrometer | energy efficiency | energy efficiency

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Description

Includes audio/video content: AV lectures. This collection of videos teaches how to use a flatbed scanner to create photographs of science and engineering. It is part of the interdisciplinary course taught at MIT called “Visual Strategies for Scientists and Engineers” that provides instruction in best practices for creating more effective graphics and photographs to support and communicate research in science and engineering.About the InstructorFelice Frankel is an award-winning science photographer and research scientist in the Center for Materials Science and Engineering at the Massachusetts Institute of Technology. Felice's images have been internationally published in books, journals, and magazines, including the New York Times, Nature, Science, National Geographic, and Di Includes audio/video content: AV lectures. This collection of videos teaches how to use a flatbed scanner to create photographs of science and engineering. It is part of the interdisciplinary course taught at MIT called “Visual Strategies for Scientists and Engineers” that provides instruction in best practices for creating more effective graphics and photographs to support and communicate research in science and engineering.About the InstructorFelice Frankel is an award-winning science photographer and research scientist in the Center for Materials Science and Engineering at the Massachusetts Institute of Technology. Felice's images have been internationally published in books, journals, and magazines, including the New York Times, Nature, Science, National Geographic, and Di

Subjects

scientific photography | scientific photography | journal submissions | journal submissions | PDMS photography | PDMS photography | microfluidic devices | microfluidic devices | microarrays | microarrays | drug delivery device | drug delivery device | petri dishes | petri dishes | E. Coli growth | E. Coli growth | flatbed scanner images | flatbed scanner images | human physiome chip | human physiome chip | lung on a chip | lung on a chip | electronic camera | electronic camera | microscale solar cells | microscale solar cells | solar cell | solar cell | E-Ink | E-Ink | tomato images | tomato images | music box | music box | Venus’ flower basket | Venus’ flower basket | Soft microfluidic sensor | Soft microfluidic sensor | paper-based microfluidics | paper-based microfluidics | diagnostic device | diagnostic device | macro photography | macro photography

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

Site sourced from

http://ocw.mit.edu/rss/all/mit-allavcourses.xml

Attribution

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Description

This course introduces the basic driving forces for electric current, fluid flow, and mass transport, plus their application to a variety of biological systems. Basic mathematical and engineering tools will be introduced, in the context of biology and physiology. Various electrokinetic phenomena are also considered as an example of coupled nature of chemical-electro-mechanical driving forces. Applications include transport in biological tissues and across membranes, manipulation of cells and biomolecules, and microfluidics.

Subjects

hydrodynamic flow | electroosmosis | diffusion | electrophoresis | reaction | membrane | cell | biomolecule | microfluidics | ion transport | electrokinetics | Debye layer | Zeta potential | inviscid flow | viscous flow | tissue | organ | biology | molecular biology | Maxwell's equations | electro-quasistatics | Van der Waals | bioMEMS

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

Site sourced from

https://ocw.mit.edu/rss/all/mit-alllifesciencescourses.xml

Attribution

Click to get HTML | Click to get attribution | Click to get URL

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Description

This course links clean energy sources and storage technology to energy consumption case studies to give students a concept of the full circle of production and consumption. Specifically, photovoltaic, organic photovoltaic, piezoelectricity and thermoelectricity sources are applied to electrophoresis, lab on a chip, and paper microfluidic applications–relevant analytical techniques in biology and chemistry. Hands-on experimentation with everyday materials and equipment help connect the theory with the implementation. Complementary laboratories fabricating LEDs, organic LEDs and spectrometers introduce the diagnostic tools used to characterize energy efficiency.This course is one of many OCW Energy Courses, and it is an elective subject in MIT’s undergraduate Energy Studies Min

Subjects

clean energy | energy sources | energy storage | energy consumption | photovoltaic | piezoelectric | thermoelectric | LED | light emitting diode | organic LED | analytical biology | analytical chemistry | microfluidics | spectrometer | energy efficiency

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

Site sourced from

https://ocw.mit.edu/rss/all/mit-allcourses.xml

Attribution

Click to get HTML | Click to get attribution | Click to get URL

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Description

This course is a project-based introduction to manipulating and characterizing cells and biological molecules using microfabricated tools. It is designed for first year undergraduate students. In the first half of the term, students perform laboratory exercises designed to introduce (1) the design, manufacture, and use of microfluidic channels, (2) techniques for sorting and manipulating cells and biomolecules, and (3) making quantitative measurements using optical detection and fluorescent labeling. In the second half of the term, students work in small groups to design and test a microfluidic device to solve a real-world problem of their choosing. Includes exercises in written and oral communication and team building.

Subjects

HST.410 | 6.07 | cell manipulation | microchips | lithography | rapid prototyping | optical imaging of cells | cell sorting | microfluidics | osmosis | diffusion | microfabrication | models of diffusion | laminar flow | MATLAB data analysis | cell traps | experimental design | cytometry techniques | computer simulation of neural behavior | casting PDMS | coulter counter | plasma bonding

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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Description

This course encourages creative thinking through hands-on experience via building, observing and manipulating micro-and nano-scale structures. Students learn about underlying science and engineering principles and possible applications.

Subjects

microfluidics | surface science | self-assembly | MEMS | carbon nanotube and graphene | SEM | AFM | micro 3D printing

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

Site sourced from

https://ocw.mit.edu/rss/all/mit-allcourses.xml

Attribution

Click to get HTML | Click to get attribution | Click to get URL

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Description

This collection of videos teaches how to use a flatbed scanner to create photographs of science and engineering. It is part of the interdisciplinary course taught at MIT called “Visual Strategies for Scientists and Engineers” that provides instruction in best practices for creating more effective graphics and photographs to support and communicate research in science and engineering.About the InstructorFelice Frankel is an award-winning science photographer and research scientist in the Center for Materials Science and Engineering at the Massachusetts Institute of Technology. Felice's images have been internationally published in books, journals, and magazines, including the New York Times, Nature, Science, National Geographic, and Discover. She is a fellow of the American Ass

Subjects

scientific photography | journal submissions | PDMS photography | microfluidic devices | microarrays | drug delivery device | petri dishes | E. Coli growth | flatbed scanner images | human physiome chip | lung on a chip | electronic camera | microscale solar cells | solar cell | E-Ink | tomato images | music box | ? flower basket | Soft microfluidic sensor | paper-based microfluidics | diagnostic device | macro photography

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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