Chemical and Biochemical Approaches for the Study of Anesthetic Function, Part A

<p>Computational approaches<br>1. Physical accuracy leads to biological relevance: Best practices for simulating ligand-gated ion channels interacting with general anesthetics<br>Grace Brannigan and Sruthi Murlidaran<br>2. Computational approaches for studying voltage-gated ion channels modulation by general anesthetics<br>Vincenzo Carnevale<br>3. Anesthetic parameterization<br>Jerome Henin<br>4. Pharmacophore QSAR, QM, ONIOM<br>Edward Bertaccini<br>5. Kinetic modeling of electrophysiology data<br>Robert Cantor</p> <p>Genetics and model organisms<br>6. General genetic strategies<br>Philip G. Morgan<br>7. Worms<br>Margaret Sedensky<br>8. Flies<br>Bruno van Swinderen<br>9. Tadpoles<br>Kellie Ann Woll<br>10. Zebrafish<br>Victoria Bedell and Julia Dallman<br>11. Mice<br>Max Kelz</p> <p>Photolabeling<br>12. Mass spect ID of adducts<br>Kellie Ann Woll<br>13. Photolabeling protection/competition<br>Jonathan Cohen</p> <p>Xenon<br>14. Xenon-protein interactions<br>Benjamin Roose and Ivan Dmochowski<br>15. Xenon gas delivery/recovery procedures<br>Mervyn Maze<br>16. Hyperpolarized Xe-129 MRI<br>Mitchell Albert<br>17. CT imaging<br>Andrew McKinstry-Wu</p> <p>Electrophysiology<br>18. Native system electrophysiology (slices, cells, in vivo)<br>Boris Heifets<br>19. Voltage-gated ion channels (Kv, Nav)<br>Manuel Covarrubias and Elaine Yang<br>20. Ligand-gated ion channels<br>Stuart A. Forman</p>