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BE.430J Fields, Forces, and Flows in Biological Systems (MIT) BE.430J Fields, Forces, and Flows in Biological Systems (MIT)

Description

This course covers the following topics: conduction, diffusion, convection in electrolytes; fields in heterogeneous media; electrical double layers; Maxwell stress tensor and electrical forces in physiological systems; and fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies considered include membrane transport; electrode interfaces; electrical, mechanical, and chemical transduction in tissues; electrophoretic and electroosmotic flows; diffusion/reaction; and ECG. The course also examines electromechanical and physicochemical interactions in biomaterials and cells; orthopaedic, cardiovascular, and other clinical examples. This course covers the following topics: conduction, diffusion, convection in electrolytes; fields in heterogeneous media; electrical double layers; Maxwell stress tensor and electrical forces in physiological systems; and fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies considered include membrane transport; electrode interfaces; electrical, mechanical, and chemical transduction in tissues; electrophoretic and electroosmotic flows; diffusion/reaction; and ECG. The course also examines electromechanical and physicochemical interactions in biomaterials and cells; orthopaedic, cardiovascular, and other clinical examples.

Subjects

biomaterials | biomaterials | conduction | conduction | diffusion | diffusion | convection in electrolytes | convection in electrolytes | fields in heterogeneous media | fields in heterogeneous media | electrical double layers | electrical double layers | Maxwell stress tensor | Maxwell stress tensor | fluid and solid continua | fluid and solid continua | biological tissues | biological tissues | membrane transport | membrane transport | electrode | electrode | transduction | transduction | electrophoretic flow | electrophoretic flow | electroosmotic flow | electroosmotic flow | diffusion reaction | diffusion reaction | ECG | ECG | orthopaedic | cardiovascular | orthopaedic | cardiovascular | 2.795J | 2.795J | 2.795 | 2.795 | 6.561J | 6.561J | 6.561 | 6.561 | 10.539J | 10.539J | 10.539 | 10.539 | HST.544J | HST.544J | HST.544 | HST.544

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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20.430J Fields, Forces, and Flows in Biological Systems (BE.430J) (MIT) 20.430J Fields, Forces, and Flows in Biological Systems (BE.430J) (MIT)

Description

This course covers the following topics: conduction, diffusion, convection in electrolytes; fields in heterogeneous media; electrical double layers; Maxwell stress tensor and electrical forces in physiological systems; and fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies considered include membrane transport; electrode interfaces; electrical, mechanical, and chemical transduction in tissues; electrophoretic and electroosmotic flows; diffusion/reaction; and ECG. The course also examines electromechanical and physicochemical interactions in biomaterials and cells; orthopaedic, cardiovascular, and other clinical examples. This course covers the following topics: conduction, diffusion, convection in electrolytes; fields in heterogeneous media; electrical double layers; Maxwell stress tensor and electrical forces in physiological systems; and fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies considered include membrane transport; electrode interfaces; electrical, mechanical, and chemical transduction in tissues; electrophoretic and electroosmotic flows; diffusion/reaction; and ECG. The course also examines electromechanical and physicochemical interactions in biomaterials and cells; orthopaedic, cardiovascular, and other clinical examples.

Subjects

biomaterials | biomaterials | conduction | conduction | diffusion | diffusion | convection in electrolytes | convection in electrolytes | fields in heterogeneous media | fields in heterogeneous media | electrical double layers | electrical double layers | Maxwell stress tensor | Maxwell stress tensor | fluid and solid continua | fluid and solid continua | biological tissues | biological tissues | membrane transport | membrane transport | electrode | electrode | transduction | transduction | electrophoretic flow | electrophoretic flow | electroosmotic flow | electroosmotic flow | diffusion reaction | diffusion reaction | ECG | ECG | orthopaedic | cardiovascular | orthopaedic | cardiovascular | 20.430 | 20.430 | 2.795 | 2.795 | 6.561 | 6.561 | 10.539 | 10.539 | HST.544 | HST.544

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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HST.582J Biomedical Signal and Image Processing (MIT) HST.582J Biomedical Signal and Image Processing (MIT)

Description

This course presents the fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. It covers principles and algorithms for processing both deterministic and random signals. Topics include data acquisition, imaging, filtering, coding, feature extraction, and modeling. The focus of the course is a series of labs that provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging. The labs are done in MATLAB® during weekly lab sessions that take place in an electronic classroom. Lectures cover signal processing topics relevant to the lab exercises, as well as background on the biological signals processed in the labs. This course presents the fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. It covers principles and algorithms for processing both deterministic and random signals. Topics include data acquisition, imaging, filtering, coding, feature extraction, and modeling. The focus of the course is a series of labs that provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging. The labs are done in MATLAB® during weekly lab sessions that take place in an electronic classroom. Lectures cover signal processing topics relevant to the lab exercises, as well as background on the biological signals processed in the labs.

Subjects

HST.582 | HST.582 | 6.555 | 6.555 | 16.456 | 16.456 | signal processing | signal processing | medicine | medicine | biological signal | biological signal | diagnosis | diagnosis | diagnostic tool | diagnostic tool | physiology | physiology | cardiology | cardiology | speech recognition | speech recognition | speech processing | speech processing | imaging | imaging | medical imaging | medical imaging | MRI | MRI | ultrasound | ultrasound | ECG | ECG | electrocardiogram | electrocardiogram | fourier | fourier | FFT | FFT | applications of probabilitym | applications of probabilitym | noise | noise | MATLAB | MATLAB | digital filter | digital filter | DSP | DSP

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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HST.542J Quantitative Physiology: Organ Transport Systems (MIT) HST.542J Quantitative Physiology: Organ Transport Systems (MIT)

Description

This course elaborates on the application of the principles of energy and mass flow to major human organ systems. It discusses mechanisms of regulation and homeostasis. It also discusses anatomical, physiological, and pathophysiological features of the cardiovascular, respiratory, and renal systems. There is emphasis on those systems, features, and devices that are most illuminated by the methods of physical sciences. This course elaborates on the application of the principles of energy and mass flow to major human organ systems. It discusses mechanisms of regulation and homeostasis. It also discusses anatomical, physiological, and pathophysiological features of the cardiovascular, respiratory, and renal systems. There is emphasis on those systems, features, and devices that are most illuminated by the methods of physical sciences.

Subjects

electrocardiogram | electrocardiogram | cardiovascular system | cardiovascular system | cardiovascular physiology | cardiovascular physiology | electrophysiology | electrophysiology | myocardial cells | myocardial cells | electrocardiography | electrocardiography | physiological fluid mechanics | physiological fluid mechanics | respiratory physiology | respiratory physiology | renal physiology | renal physiology | quantitative physiology | quantitative physiology | pulmonary mechanics | pulmonary mechanics | heart | heart | arrhythmia | arrhythmia | pulmonary modeling | pulmonary modeling | clinical electrocardiography | clinical electrocardiography | ECG | ECG | EKG | EKG | ischemia | ischemia | infarction | infarction | vector cardiogram | vector cardiogram | purkinje fibers | purkinje fibers | QRS waveform | QRS waveform | tachycardia | tachycardia | action potential | action potential | depolarization | depolarization | afterdepolarization | afterdepolarization | total lung capacity | total lung capacity | systolic | systolic | diastolic | diastolic | residual volume | residual volume | vital capacity | vital capacity | HST.542 | HST.542 | 2.792 | 2.792 | 20.371J20.371 | 20.371J20.371 | 6.022 | 6.022

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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BE.430J Fields, Forces, and Flows in Biological Systems (MIT)

Description

This course covers the following topics: conduction, diffusion, convection in electrolytes; fields in heterogeneous media; electrical double layers; Maxwell stress tensor and electrical forces in physiological systems; and fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies considered include membrane transport; electrode interfaces; electrical, mechanical, and chemical transduction in tissues; electrophoretic and electroosmotic flows; diffusion/reaction; and ECG. The course also examines electromechanical and physicochemical interactions in biomaterials and cells; orthopaedic, cardiovascular, and other clinical examples.

Subjects

biomaterials | conduction | diffusion | convection in electrolytes | fields in heterogeneous media | electrical double layers | Maxwell stress tensor | fluid and solid continua | biological tissues | membrane transport | electrode | transduction | electrophoretic flow | electroosmotic flow | diffusion reaction | ECG | orthopaedic | cardiovascular | 2.795J | 2.795 | 6.561J | 6.561 | 10.539J | 10.539 | HST.544J | HST.544

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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HST.582J Biomedical Signal and Image Processing (MIT)

Description

This course presents the fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. It covers principles and algorithms for processing both deterministic and random signals. Topics include data acquisition, imaging, filtering, coding, feature extraction, and modeling. The focus of the course is a series of labs that provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging. The labs are done in MATLAB® during weekly lab sessions that take place in an electronic classroom. Lectures cover signal processing topics relevant to the lab exercises, as well as background on the biological signals processed in the labs.

Subjects

HST.582 | 6.555 | 16.456 | signal processing | medicine | biological signal | diagnosis | diagnostic tool | physiology | cardiology | speech recognition | speech processing | imaging | medical imaging | MRI | ultrasound | ECG | electrocardiogram | fourier | FFT | applications of probabilitym | noise | MATLAB | digital filter | DSP

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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HST.542J Quantitative Physiology: Organ Transport Systems (MIT)

Description

This course elaborates on the application of the principles of energy and mass flow to major human organ systems. It discusses mechanisms of regulation and homeostasis. It also discusses anatomical, physiological, and pathophysiological features of the cardiovascular, respiratory, and renal systems. There is emphasis on those systems, features, and devices that are most illuminated by the methods of physical sciences.

Subjects

electrocardiogram | cardiovascular system | cardiovascular physiology | electrophysiology | myocardial cells | electrocardiography | physiological fluid mechanics | respiratory physiology | renal physiology | quantitative physiology | pulmonary mechanics | heart | arrhythmia | pulmonary modeling | clinical electrocardiography | ECG | EKG | ischemia | infarction | vector cardiogram | purkinje fibers | QRS waveform | tachycardia | action potential | depolarization | afterdepolarization | total lung capacity | systolic | diastolic | residual volume | vital capacity | HST.542 | 2.792 | 20.371J20.371 | 6.022

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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20.430J Fields, Forces, and Flows in Biological Systems (BE.430J) (MIT)

Description

This course covers the following topics: conduction, diffusion, convection in electrolytes; fields in heterogeneous media; electrical double layers; Maxwell stress tensor and electrical forces in physiological systems; and fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies considered include membrane transport; electrode interfaces; electrical, mechanical, and chemical transduction in tissues; electrophoretic and electroosmotic flows; diffusion/reaction; and ECG. The course also examines electromechanical and physicochemical interactions in biomaterials and cells; orthopaedic, cardiovascular, and other clinical examples.

Subjects

biomaterials | conduction | diffusion | convection in electrolytes | fields in heterogeneous media | electrical double layers | Maxwell stress tensor | fluid and solid continua | biological tissues | membrane transport | electrode | transduction | electrophoretic flow | electroosmotic flow | diffusion reaction | ECG | orthopaedic | cardiovascular | 20.430 | 2.795 | 6.561 | 10.539 | HST.544

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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