Transcript Ch04 Figures

Figure 4.1 Patch clamp measurements of ionic currents through single Na+ channels
Figure 4.1 Patch clamp measurements of ionic currents through single Na+ channels (Part 1)
Figure 4.1 Patch clamp measurements of ionic currents through single Na+ channels (Part 2)
Box 4A The Patch Clamp Method
Box 4A The Patch Clamp Method (Part 1)
Box 4A The Patch Clamp Method (Part 2)
Box 4A The Patch Clamp Method (Part 3)
Figure 4.2 Patch clamp measurements of ionic currents through single K+ channels
Figure 4.2 Patch clamp measurements of ionic currents through single K+ channels (Part 1)
Figure 4.2 Patch clamp measurements of ionic currents through single K+ channels (Part 2)
Figure 4.3 Functional states of voltage-gated Na+ and K+ channels
Box 4B Expression of Ion Channels in Xenopus Oocytes
Figure 4.4 Types of voltage-gated ion channels
Figure 4.4 Types of voltage-gated ion channels (Part 1)
Figure 4.4 Types of voltage-gated ion channels (Part 2)
Figure 4.5 Diverse properties of K+ channels
Figure 4.5 Diverse properties of K+ channels (Part 1)
Figure 4.5 Diverse properties of K+ channels (Part 2)
Figure 4.5 Diverse properties of K+ channels (Part 3)
Figure 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels
Figure 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels (Part 1)
Figure 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels (Part 2)
Figure 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels (Part 3)
Figure 4.6 Topology of principal subunits of voltage-gated Na+, Ca2+, K+, and Cl– channels (Part 4)
Box 4C Toxins That Poison Ion Channels
Figure 4.7 A charged voltage sensor permits voltage-dependent gating of ion channels
Figure 4.7 A charged voltage sensor permits voltage-dependent gating of ion channels
Figure 4.8 Structure of a simple bacterial K+ channel
Figure 4.8 Structure of a simple bacterial K+ channel (Part 1)
Figure 4.8 Structure of a simple bacterial K+ channel (Part 2)
Figure 4.9 Structure of a mammalian voltage-gated K+ channel
Figure 4.9 Structure of a mammalian voltage-gated K+ channel (Part 1)
Figure 4.9 Structure of a mammalian voltage-gated K+ channel (Part 2)
Figure 4.9 Structure of a mammalian voltage-gated K+ channel (Part 3)
Figure 4.9 Structure of a mammalian voltage-gated K+ channel (Part 4)
Box 4D(1) Diseases Caused by Altered Ion Channels
Box 4D(1) Diseases Caused by Altered Ion Channels (Part 1)
Box 4D(1) Diseases Caused by Altered Ion Channels (Part 2)
Box 4D(1) Diseases Caused by Altered Ion Channels (Part 3)
Box 4D(2) Diseases Caused by Altered Ion Channels
Figure 4.10 Examples of ion transporters found in cell membranes
Figure 4.10 Examples of ion transporters found in cell membranes (Part 1)
Figure 4.10 Examples of ion transporters found in cell membranes (Part 2)
Figure 4.11 Ion movements due to the Na+/K+ pump
Figure 4.11 Ion movements due to the Na+/K+ pump (Part 1)
Figure 4.11 Ion movements due to the Na+/K+ pump (Part 2)
Figure 4.12 Electrogenic transport of ions by the Na+/K+ pump can influence membrane potential
Figure 4.12 Electrogenic transport of ions by the Na+/K+ pump can influence membrane potential
Figure 4.13 Molecular organization of the Na+/K+ pump
Figure 4.13 Molecular organization of the Na+/K+ pump (Part 1)
Figure 4.13 Molecular organization of the Na+/K+ pump (Part 2)
Figure 4.14 Molecular structure of the Ca2+ pump
Figure 4.14 Molecular structure of the Ca2+ pump (Part 1)
Figure 4.14 Molecular structure of the Ca2+ pump (Part 2)