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Box A The Patch Clamp Method (Part 1)

Box A The Patch Clamp Method (Part 1). Box A The Patch Clamp Method (Part 2). 4.1 Measurements of ionic currents flowing through single Na + channels. (Part 1). 4.1 Measurements of ionic currents flowing through single Na + channels. (Part 2).

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Box A The Patch Clamp Method (Part 1)

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  1. Box A The Patch Clamp Method (Part 1)

  2. Box A The Patch Clamp Method (Part 2)

  3. 4.1 Measurements of ionic currents flowing through single Na+ channels. (Part 1)

  4. 4.1 Measurements of ionic currents flowing through single Na+ channels. (Part 2)

  5. 4.2 Measurements of ionic currents flowing through single K+ channels. (Part 1)

  6. 4.2 Measurements of ionic currents flowing through single K+ channels. (Part 2)

  7. 4.3 Functional states of voltage-gated Na+ and K+ channels. (Part 1)

  8. 4.3 Functional states of voltage-gated Na+ and K+ channels. (Part 2)

  9. Box B Expression of Ion Channels in Xenopus Oocytes (Part 1)

  10. Box B Expression of Ion Channels in Xenopus Oocytes (Part 2)

  11. 4.4 Types of voltage-gated ion channels. (Part 1)

  12. 4.4 Types of voltage-gated ion channels. (Part 2)

  13. 4.5 Diverse properties of K+ channels. (Part 1)

  14. 4.5 Diverse properties of K+ channels. (Part 2)

  15. 4.5 Diverse properties of K+ channels. (Part 3)

  16. 4.5 Diverse properties of K+ channels. (Part 4)

  17. 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels. (Part 1)

  18. 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels. (Part 2)

  19. 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels. (Part 3)

  20. K2p channel structure from Brohawn et al., 2012

  21. 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels. (Part 4)

  22. 4.7 A charged voltage sensor permits voltage-dependent gating of ion channels.

  23. 4.8 Structure of a simple bacterial K+ channel determined by crystallography. (Part 1)

  24. 4.8 Structure of a simple bacterial K+ channel determined by crystallography. (Part 2)

  25. Box C Toxins that Poison Ion Channels

  26. Figure 4.8 Structure of a mammalian voltage-gated K+

  27. 4.10 Examples of ion transporters found in cell membranes. (Part 1)

  28. 4.10 Examples of ion transporters found in cell membranes. (Part 2)

  29. 4.11 Ionic movements due to the Na+/K+ pump. (Part 1)

  30. 4.11 Ionic movements due to the Na+/K+ pump. (Part 2)

  31. 4.12 Electrogenic transport of ions by the Na+/K+ pump can influence membrane potential.

  32. 4.13 Molecular structure of the Na+/K+ pump. (Part 1)

  33. Figure 4.11 Molecular properties of the Na+/K+ pump

  34. Figure 4.12 Molecular structure of the Ca2+ pump

  35. 4.13 Molecular structure of the Na+/K+ pump. (Part 2)

  36. Box D Diseases Caused by Altered Ion Channels (Part 1)

  37. Box D Diseases Caused by Altered Ion Channels (Part 2)

  38. Box D Diseases Caused by Altered Ion Channels (Part 3)

  39. Box D Diseases Caused by Altered Ion Channels (Part 4)

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