William Hoiles, Vikram Krishnamurthy, Bruce Cornell
Dynamics of Engineered Artificial Membranes and Biosensors
William Hoiles, Vikram Krishnamurthy, Bruce Cornell
Dynamics of Engineered Artificial Membranes and Biosensors
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A state-of-the-art guide to building synthetic membranes for biological devices, covering their construction, measurement, and modelling.
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A state-of-the-art guide to building synthetic membranes for biological devices, covering their construction, measurement, and modelling.
Produktdetails
- Produktdetails
- Verlag: Cambridge University Press
- Seitenzahl: 474
- Erscheinungstermin: 26. März 2019
- Englisch
- Abmessung: 286mm x 221mm x 30mm
- Gewicht: 1444g
- ISBN-13: 9781108423502
- ISBN-10: 1108423507
- Artikelnr.: 49228059
- Verlag: Cambridge University Press
- Seitenzahl: 474
- Erscheinungstermin: 26. März 2019
- Englisch
- Abmessung: 286mm x 221mm x 30mm
- Gewicht: 1444g
- ISBN-13: 9781108423502
- ISBN-10: 1108423507
- Artikelnr.: 49228059
William Hoiles is a Research Fellow in the Department of Electrical and Computer Engineering at the University of British Columbia, Vancouver.
Part I. Background: 1. Motivation and outline
2. Biochemistry for engineers: a short primer
3. Engineered artificial membranes
Part II. Building Engineered Membranes, Devices and Experimental Results: 4. Formation of engineered tethered membranes
5. Ion-channel switch biosensor
6. Physiochemical membrane platforms
7. Experimental measurement methods for engineered membranes
Part III. Dynamic Models for Artificial Membranes: Atoms-to-Device: 8. Reaction-rate constrained models for engineered membranes
9. Reaction-rate constrained models for the ICS biosensor
10. Diffusion constrained continuum models of engineered membranes
11. Electroporation models in engineered artificial membranes
12. Electroporation measurements in engineered membranes
13. Electrophysiological response of ion channels and cells
14. Coarse-grained molecular dynamics
15. All-atom molecular dynamics simulation models
16. Closing summary for part III: from atoms to device
Appendices: Appendix A. Elementary primer on partial differential equations (PDE)
Appendix B. Tutorial on coarse-grained molecular dynamics with peptides.
2. Biochemistry for engineers: a short primer
3. Engineered artificial membranes
Part II. Building Engineered Membranes, Devices and Experimental Results: 4. Formation of engineered tethered membranes
5. Ion-channel switch biosensor
6. Physiochemical membrane platforms
7. Experimental measurement methods for engineered membranes
Part III. Dynamic Models for Artificial Membranes: Atoms-to-Device: 8. Reaction-rate constrained models for engineered membranes
9. Reaction-rate constrained models for the ICS biosensor
10. Diffusion constrained continuum models of engineered membranes
11. Electroporation models in engineered artificial membranes
12. Electroporation measurements in engineered membranes
13. Electrophysiological response of ion channels and cells
14. Coarse-grained molecular dynamics
15. All-atom molecular dynamics simulation models
16. Closing summary for part III: from atoms to device
Appendices: Appendix A. Elementary primer on partial differential equations (PDE)
Appendix B. Tutorial on coarse-grained molecular dynamics with peptides.
Part I. Background: 1. Motivation and outline
2. Biochemistry for engineers: a short primer
3. Engineered artificial membranes
Part II. Building Engineered Membranes, Devices and Experimental Results: 4. Formation of engineered tethered membranes
5. Ion-channel switch biosensor
6. Physiochemical membrane platforms
7. Experimental measurement methods for engineered membranes
Part III. Dynamic Models for Artificial Membranes: Atoms-to-Device: 8. Reaction-rate constrained models for engineered membranes
9. Reaction-rate constrained models for the ICS biosensor
10. Diffusion constrained continuum models of engineered membranes
11. Electroporation models in engineered artificial membranes
12. Electroporation measurements in engineered membranes
13. Electrophysiological response of ion channels and cells
14. Coarse-grained molecular dynamics
15. All-atom molecular dynamics simulation models
16. Closing summary for part III: from atoms to device
Appendices: Appendix A. Elementary primer on partial differential equations (PDE)
Appendix B. Tutorial on coarse-grained molecular dynamics with peptides.
2. Biochemistry for engineers: a short primer
3. Engineered artificial membranes
Part II. Building Engineered Membranes, Devices and Experimental Results: 4. Formation of engineered tethered membranes
5. Ion-channel switch biosensor
6. Physiochemical membrane platforms
7. Experimental measurement methods for engineered membranes
Part III. Dynamic Models for Artificial Membranes: Atoms-to-Device: 8. Reaction-rate constrained models for engineered membranes
9. Reaction-rate constrained models for the ICS biosensor
10. Diffusion constrained continuum models of engineered membranes
11. Electroporation models in engineered artificial membranes
12. Electroporation measurements in engineered membranes
13. Electrophysiological response of ion channels and cells
14. Coarse-grained molecular dynamics
15. All-atom molecular dynamics simulation models
16. Closing summary for part III: from atoms to device
Appendices: Appendix A. Elementary primer on partial differential equations (PDE)
Appendix B. Tutorial on coarse-grained molecular dynamics with peptides.