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3.051J Materials for Biomedical Applications (MIT) 3.051J Materials for Biomedical Applications (MIT)

Description

This course gives an introduction to the interactions between proteins, cells and surfaces of biomaterials. It includes surface chemistry and physics of selected metals, polymers and ceramics, modification of biomaterials surfaces, and surface characterization methodology; quantitative assays of cell behavior in culture and methods of statistical analysis; organ replacement therapies and acute and chronic response to implanted biomaterials. The course includes topics in biosensors, drug delivery and tissue engineering. This course gives an introduction to the interactions between proteins, cells and surfaces of biomaterials. It includes surface chemistry and physics of selected metals, polymers and ceramics, modification of biomaterials surfaces, and surface characterization methodology; quantitative assays of cell behavior in culture and methods of statistical analysis; organ replacement therapies and acute and chronic response to implanted biomaterials. The course includes topics in biosensors, drug delivery and tissue engineering.

Subjects

Interactions between proteins | Interactions between proteins | cells | cells | Surface chemistry and physics of metals | Surface chemistry and physics of metals | polymers and ceramics | polymers and ceramics | Surface characterization methodology | Surface characterization methodology | Quantitative assays of cell behavior | Quantitative assays of cell behavior | Organ replacement therapies | Organ replacement therapies | Acute and chronic response to implanted biomaterials | Acute and chronic response to implanted biomaterials | Biosensors | Biosensors | drug delivery and tissue engineering | drug delivery and tissue engineering | Interactions between proteins | cells | Interactions between proteins | cells | Surface chemistry and physics of metals | polymers and ceramics | Surface chemistry and physics of metals | polymers and ceramics | Biosensors | drug delivery and tissue engineering | Biosensors | drug delivery and tissue engineering | BE.340J | BE.340J | 3.051 | 3.051 | BE.340 | BE.340 | 20.340 | 20.340

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3.40J Physical Metallurgy (MIT) 3.40J Physical Metallurgy (MIT)

Description

This course examines how the presence of 1-, 2- and 3D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. It considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. In addition, it concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties. Examples include microelectronic circuitry, magnetic memory and drug delivery applications. This course examines how the presence of 1-, 2- and 3D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. It considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. In addition, it concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties. Examples include microelectronic circuitry, magnetic memory and drug delivery applications.

Subjects

1- | 2- and 3D defects | 1- | 2- and 3D defects | second phases | second phases | mechanical | electromagnetic and chemical behavior of metals and alloys | mechanical | electromagnetic and chemical behavior of metals and alloys | point | line and interfacial defects | point | line and interfacial defects | structural transformations | structural transformations | annealing | annealing | spinodal decomposition | spinodal decomposition | nucleation | nucleation | growth | growth | particle coarsening | particle coarsening | structure-function relationships | structure-function relationships | grain size | grain size | interstitial and substitutional solid solutions | interstitial and substitutional solid solutions | second-phase particles | second-phase particles | microelectronic circuitry | microelectronic circuitry | magnetic memory | magnetic memory | drug delivery applications | drug delivery applications | 3.40 | 3.40 | 22.71 | 22.71

License

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BE.462J Molecular Principles of Biomaterials (MIT) BE.462J Molecular Principles of Biomaterials (MIT)

Description

Analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, biosensors, and cell-guiding surfaces.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.Microsoft® is a registered trademark or trademark of Microsoft Corporation in the U.S Analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, biosensors, and cell-guiding surfaces.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.Microsoft® is a registered trademark or trademark of Microsoft Corporation in the U.S

Subjects

Analysis | Analysis | design | design | molecular scale | molecular scale | biological systems | biological systems | biotechnology | biotechnology | biomedical engineering | biomedical engineering | molecular interactions | molecular interactions | synthetic molecules | synthetic molecules | synthesis | synthesis | processing approaches | processing approaches | cell functions | cell functions | materials science | materials science | tissue engineering | tissue engineering | drug delivery | drug delivery | biosensors | biosensors | cell-guiding surfaces | cell-guiding surfaces | 3.962J | 3.962J | BE.462 | BE.462 | 3.962 | 3.962

License

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20.462J Molecular Principles of Biomaterials (BE.462J) (MIT) 20.462J Molecular Principles of Biomaterials (BE.462J) (MIT)

Description

Analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, biosensors, and cell-guiding surfaces.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.Microsoft® is a registered trademark or trademark of Microsoft Corporation in the U.S Analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, biosensors, and cell-guiding surfaces.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.Microsoft® is a registered trademark or trademark of Microsoft Corporation in the U.S

Subjects

Analysis | Analysis | design | design | molecular scale | molecular scale | biological systems | biological systems | biotechnology | biotechnology | biomedical engineering | biomedical engineering | molecular interactions | molecular interactions | synthetic molecules | synthetic molecules | synthesis | synthesis | processing approaches | processing approaches | cell functions | cell functions | materials science | materials science | tissue engineering | tissue engineering | drug delivery | drug delivery | biosensors | biosensors | cell-guiding surfaces | cell-guiding surfaces | BE.462J | BE.462J | BE.462 | BE.462 | 3.962 | 3.962

License

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3.051J Materials for Biomedical Applications (MIT) 3.051J Materials for Biomedical Applications (MIT)

Description

This class provides an introduction to the interactions between cells and the surfaces of biomaterials. The course covers: surface chemistry and physics of selected metals, polymers, and ceramics; surface characterization methodology; modification of biomaterials surfaces; quantitative assays of cell behavior in culture; biosensors and microarrays; bulk properties of implants; and acute and chronic response to implanted biomaterials. General topics include biosensors, drug delivery, and tissue engineering. This class provides an introduction to the interactions between cells and the surfaces of biomaterials. The course covers: surface chemistry and physics of selected metals, polymers, and ceramics; surface characterization methodology; modification of biomaterials surfaces; quantitative assays of cell behavior in culture; biosensors and microarrays; bulk properties of implants; and acute and chronic response to implanted biomaterials. General topics include biosensors, drug delivery, and tissue engineering.

Subjects

interactions between proteins | cells and surfaces of biomaterials | interactions between proteins | cells and surfaces of biomaterials | surface chemistry and physics of metals | polymers and ceramics | surface chemistry and physics of metals | polymers and ceramics | Surface characterization methodology | Surface characterization methodology | Quantitative assays of cell behavior in culture | Quantitative assays of cell behavior in culture | Organ replacement therapies | Organ replacement therapies | Acute and chronic response to implanted biomaterials | Acute and chronic response to implanted biomaterials | biosensors | drug delivery and tissue engineering | biosensors | drug delivery and tissue engineering

License

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20.462J Molecular Principles of Biomaterials (MIT) 20.462J Molecular Principles of Biomaterials (MIT)

Description

This course covers the analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. This course covers the analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces.

Subjects

biomaterials | biomaterials | biomaterial engineering | biomaterial engineering | biotechnology | biotechnology | cell-guiding surface | cell-guiding surface | molecular biomaterials | molecular biomaterials | drug release | drug release | polymers | polymers | pulsatile release | pulsatile release | polymerization | polymerization | polyer erosion | polyer erosion | tissue engineering | tissue engineering | hydrogels | hydrogels | adhesion | adhesion | migration | migration | drug diffusion | drug diffusion | molecular switches | molecular switches | molecular motors | molecular motors | nanoparticles | nanoparticles | microparticles | microparticles | vaccines | vaccines | drug targeting | drug targeting | micro carriers | micro carriers | nano carriers | nano carriers | intracellular drug delivery | intracellular drug delivery | 20.462 | 20.462 | 3.962 | 3.962

License

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HST.525J Tumor Pathophysiology and Transport Phenomena (MIT) HST.525J Tumor Pathophysiology and Transport Phenomena (MIT)

Description

Tumor pathophysiology plays a central role in the growth, invasion, metastasis and treatment of solid tumors. This class applies principles of transport phenomena to develop a systems-level, quantitative understanding of angiogenesis, blood flow and microcirculation, metabolism and microenvironment, transport and binding of small and large molecules, movement of cancer and immune cells, metastatic process, and treatment response. Additional Faculty Dr. Pat D'Amore Dr. Dan Duda Dr. Robert Langer Prof. Robert Weinberg Dr. Marsha Moses Dr. Raghu Kalluri Dr. Lance Munn Tumor pathophysiology plays a central role in the growth, invasion, metastasis and treatment of solid tumors. This class applies principles of transport phenomena to develop a systems-level, quantitative understanding of angiogenesis, blood flow and microcirculation, metabolism and microenvironment, transport and binding of small and large molecules, movement of cancer and immune cells, metastatic process, and treatment response. Additional Faculty Dr. Pat D'Amore Dr. Dan Duda Dr. Robert Langer Prof. Robert Weinberg Dr. Marsha Moses Dr. Raghu Kalluri Dr. Lance Munn

Subjects

HST.525 | HST.525 | 10.548 | 10.548 | tumor | tumor | cancer | cancer | tumor vasculature | tumor vasculature | antiangiogenesis | antiangiogenesis | bone marrow-derived stem cells | bone marrow-derived stem cells | BMDC | BMDC | stem cell research | stem cell research | experimental cancer therapy | experimental cancer therapy | cancer research | cancer research | tumor-host interactions | tumor-host interactions | vascular normalization | vascular normalization | vascular transport | vascular transport | interstitial transport | interstitial transport | lymphatic transport | lymphatic transport | microcirculation | microcirculation | molecular therapeutics | molecular therapeutics | blood vessels | blood vessels | angiogenesis | angiogenesis | drug delivery | drug delivery | intravital microscopy | intravital microscopy

License

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20.320 Analysis of Biomolecular and Cellular Systems (MIT) 20.320 Analysis of Biomolecular and Cellular Systems (MIT)

Description

This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling. This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling.

Subjects

biological engineering | biological engineering | kinase | kinase | PyMOL | PyMOL | PyRosetta | PyRosetta | MATLAB | MATLAB | Michaelis-Menten | Michaelis-Menten | bioreactor | bioreactor | bromodomain | bromodomain | protein-ligand interactions | protein-ligand interactions | titration analysis | titration analysis | fractional separation | fractional separation | isothermal titration calorimetry | isothermal titration calorimetry | ITC | ITC | mass spectrometry | mass spectrometry | MS | MS | co-immunoprecipitation | co-immunoprecipitation | Co-IP | Co-IP | Forster resonance energy transfer | Forster resonance energy transfer | FRET | FRET | primary ligation assay | primary ligation assay | PLA | PLA | surface plasmon resonance | surface plasmon resonance | SPR | SPR | enzyme kinetics | enzyme kinetics | kinase engineering | kinase engineering | competitive inhibition | competitive inhibition | epidermal growth factor receptor | epidermal growth factor receptor | mitogen-activated protein kinase | mitogen-activated protein kinase | MAPK | MAPK | genome editing | genome editing | Imatinib | Imatinib | Gleevec | Gleevec | Glivec | Glivec | drug delivery | drug delivery | kinetics of molecular processes | kinetics of molecular processes | dynamics of molecular processes | dynamics of molecular processes | kinetics of cellular processes | kinetics of cellular processes | dynamics of cellular processes | dynamics of cellular processes | intracellular scale | intracellular scale | extracellular scale | extracellular scale | and cell population scale | and cell population scale | biotechnology applications | biotechnology applications | gene regulation networks | gene regulation networks | nucleic acid hybridization | nucleic acid hybridization | signal transduction pathways | signal transduction pathways | cell populations in tissues | cell populations in tissues | cell populations in bioreactors | cell populations in bioreactors | experimental methods | experimental methods | quantitative analysis | quantitative analysis | computational modeling | computational modeling

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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RES.10-001 Making Science and Engineering Pictures (MIT) RES.10-001 Making Science and Engineering Pictures (MIT)

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

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3.051J Materials for Biomedical Applications (MIT)

Description

This course gives an introduction to the interactions between proteins, cells and surfaces of biomaterials. It includes surface chemistry and physics of selected metals, polymers and ceramics, modification of biomaterials surfaces, and surface characterization methodology; quantitative assays of cell behavior in culture and methods of statistical analysis; organ replacement therapies and acute and chronic response to implanted biomaterials. The course includes topics in biosensors, drug delivery and tissue engineering.

Subjects

Interactions between proteins | cells | Surface chemistry and physics of metals | polymers and ceramics | Surface characterization methodology | Quantitative assays of cell behavior | Organ replacement therapies | Acute and chronic response to implanted biomaterials | Biosensors | drug delivery and tissue engineering | Interactions between proteins | cells | Surface chemistry and physics of metals | polymers and ceramics | Biosensors | drug delivery and tissue engineering | BE.340J | 3.051 | BE.340 | 20.340

License

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3.051J Materials for Biomedical Applications (MIT)

Description

This class provides an introduction to the interactions between cells and the surfaces of biomaterials. The course covers: surface chemistry and physics of selected metals, polymers, and ceramics; surface characterization methodology; modification of biomaterials surfaces; quantitative assays of cell behavior in culture; biosensors and microarrays; bulk properties of implants; and acute and chronic response to implanted biomaterials. General topics include biosensors, drug delivery, and tissue engineering.

Subjects

interactions between proteins | cells and surfaces of biomaterials | surface chemistry and physics of metals | polymers and ceramics | Surface characterization methodology | Quantitative assays of cell behavior in culture | Organ replacement therapies | Acute and chronic response to implanted biomaterials | biosensors | drug delivery and tissue engineering

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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Targeting and controlling medication delivery

Description

3D video demonstrating what is inside a controlled release formulation

Subjects

3D | controlled release formulation | drug delivery | pills | medication | video | Subjects allied to medicine | B000

License

Attribution 4.0 International Attribution 4.0 International http://creativecommons.org/licenses/by/4.0/ http://creativecommons.org/licenses/by/4.0/

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3.40J Physical Metallurgy (MIT)

Description

This course examines how the presence of 1-, 2- and 3D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. It considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. In addition, it concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties. Examples include microelectronic circuitry, magnetic memory and drug delivery applications.

Subjects

1- | 2- and 3D defects | second phases | mechanical | electromagnetic and chemical behavior of metals and alloys | point | line and interfacial defects | structural transformations | annealing | spinodal decomposition | nucleation | growth | particle coarsening | structure-function relationships | grain size | interstitial and substitutional solid solutions | second-phase particles | microelectronic circuitry | magnetic memory | drug delivery applications | 3.40 | 22.71

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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BE.462J Molecular Principles of Biomaterials (MIT)

Description

Analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, biosensors, and cell-guiding surfaces.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.Microsoft® is a registered trademark or trademark of Microsoft Corporation in the U.S

Subjects

Analysis | design | molecular scale | biological systems | biotechnology | biomedical engineering | molecular interactions | synthetic molecules | synthesis | processing approaches | cell functions | materials science | tissue engineering | drug delivery | biosensors | cell-guiding surfaces | 3.962J | BE.462 | 3.962

License

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20.462J Molecular Principles of Biomaterials (BE.462J) (MIT)

Description

Analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, biosensors, and cell-guiding surfaces.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.Microsoft® is a registered trademark or trademark of Microsoft Corporation in the U.S

Subjects

Analysis | design | molecular scale | biological systems | biotechnology | biomedical engineering | molecular interactions | synthetic molecules | synthesis | processing approaches | cell functions | materials science | tissue engineering | drug delivery | biosensors | cell-guiding surfaces | BE.462J | BE.462 | 3.962

License

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20.320 Analysis of Biomolecular and Cellular Systems (MIT)

Description

This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling.

Subjects

biological engineering | kinase | PyMOL | PyRosetta | MATLAB | Michaelis-Menten | bioreactor | bromodomain | protein-ligand interactions | titration analysis | fractional separation | isothermal titration calorimetry | ITC | mass spectrometry | MS | co-immunoprecipitation | Co-IP | Forster resonance energy transfer | FRET | primary ligation assay | PLA | surface plasmon resonance | SPR | enzyme kinetics | kinase engineering | competitive inhibition | epidermal growth factor receptor | mitogen-activated protein kinase | MAPK | genome editing | Imatinib | Gleevec | Glivec | drug delivery | kinetics of molecular processes | dynamics of molecular processes | kinetics of cellular processes | dynamics of cellular processes | intracellular scale | extracellular scale | and cell population scale | biotechnology applications | gene regulation networks | nucleic acid hybridization | signal transduction pathways | cell populations in tissues | cell populations in bioreactors | experimental methods | quantitative analysis | computational modeling

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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20.462J Molecular Principles of Biomaterials (MIT)

Description

This course covers the analysis and design at a molecular scale of materials used in contact with biological systems, including biotechnology and biomedical engineering. Topics include molecular interactions between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of state-of-the-art materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces.

Subjects

biomaterials | biomaterial engineering | biotechnology | cell-guiding surface | molecular biomaterials | drug release | polymers | pulsatile release | polymerization | polyer erosion | tissue engineering | hydrogels | adhesion | migration | drug diffusion | molecular switches | molecular motors | nanoparticles | microparticles | vaccines | drug targeting | micro carriers | nano carriers | intracellular drug delivery | 20.462 | 3.962

License

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HST.525J Tumor Pathophysiology and Transport Phenomena (MIT)

Description

Tumor pathophysiology plays a central role in the growth, invasion, metastasis and treatment of solid tumors. This class applies principles of transport phenomena to develop a systems-level, quantitative understanding of angiogenesis, blood flow and microcirculation, metabolism and microenvironment, transport and binding of small and large molecules, movement of cancer and immune cells, metastatic process, and treatment response. Additional Faculty Dr. Pat D'Amore Dr. Dan Duda Dr. Robert Langer Prof. Robert Weinberg Dr. Marsha Moses Dr. Raghu Kalluri Dr. Lance Munn

Subjects

HST.525 | 10.548 | tumor | cancer | tumor vasculature | antiangiogenesis | bone marrow-derived stem cells | BMDC | stem cell research | experimental cancer therapy | cancer research | tumor-host interactions | vascular normalization | vascular transport | interstitial transport | lymphatic transport | microcirculation | molecular therapeutics | blood vessels | angiogenesis | drug delivery | intravital microscopy

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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3.051J Materials for Biomedical Applications (MIT)

Description

This class provides an introduction to the interactions between cells and the surfaces of biomaterials. The course covers: surface chemistry and physics of selected metals, polymers, and ceramics; surface characterization methodology; modification of biomaterials surfaces; quantitative assays of cell behavior in culture; biosensors and microarrays; bulk properties of implants; and acute and chronic response to implanted biomaterials. General topics include biosensors, drug delivery, and tissue engineering.

Subjects

interactions between proteins | cells and surfaces of biomaterials | surface chemistry and physics of metals | polymers and ceramics | Surface characterization methodology | Quantitative assays of cell behavior in culture | Organ replacement therapies | Acute and chronic response to implanted biomaterials | biosensors | drug delivery and tissue engineering

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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RES.10-001 Making Science and Engineering Pictures (MIT)

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

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