FileTitleManuscript Id
Chapter Introductionlife11e_ch44_1.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_1_dlap.xml57e57e94757a2e8832000000
key concept 44.1 Neurons and Glia Are Unique Cells of Nervous Systems life11e_ch44_2.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_2_dlap.xml57e57e94757a2e8832000000
Vertebrate neurons and macroglia originate in the embryonic neural tube life11e_ch44_3.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_3_dlap.xml57e57e94757a2e8832000000
The structure of neurons reflects their functions life11e_ch44_4.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_4_dlap.xml57e57e94757a2e8832000000
Glia are the “silent partners” of neurons life11e_ch44_5.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_5_dlap.xml57e57e94757a2e8832000000
recaplife11e_ch44_6.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_6_dlap.xml57e57e94757a2e8832000000
key concept 44.2 Neurons Generate and Transmit Electric Signals life11e_ch44_7.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_7_dlap.xml57e57e94757a2e8832000000
Simple electrical concepts underlie neuronal function life11e_ch44_8.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_8_dlap.xml57e57e94757a2e8832000000
Activities of neurons are recorded as changes in membrane potential life11e_ch44_9.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_9_dlap.xml57e57e94757a2e8832000000
Ion transporters and channels generate membrane potentials life11e_ch44_10.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_10_dlap.xml57e57e94757a2e8832000000
Ion channels and their properties can be studied directly life11e_ch44_11.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_11_dlap.xml57e57e94757a2e8832000000
Gated ion channels alter membrane potential life11e_ch44_12.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_12_dlap.xml57e57e94757a2e8832000000
Graded changes in membrane potential can integrate information life11e_ch44_13.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_13_dlap.xml57e57e94757a2e8832000000
Sudden changes in Na+ and K+ channels generate action potentials life11e_ch44_14.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_14_dlap.xml57e57e94757a2e8832000000
Action potentials are conducted along axons without loss of signal life11e_ch44_15.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_15_dlap.xml57e57e94757a2e8832000000
Action potentials jump along myelinated axons life11e_ch44_16.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_16_dlap.xml57e57e94757a2e8832000000
recaplife11e_ch44_17.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_17_dlap.xml57e57e94757a2e8832000000
key concept 44.3 Neurons Communicate with Other Cells life11e_ch44_18.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_18_dlap.xml57e57e94757a2e8832000000
The neuromuscular junction is a model chemical synapse life11e_ch44_19.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_19_dlap.xml57e57e94757a2e8832000000
The arrival of an action potential causes the release of neurotransmitter life11e_ch44_20.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_20_dlap.xml57e57e94757a2e8832000000
Synaptic functions involve many proteins life11e_ch44_21.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_21_dlap.xml57e57e94757a2e8832000000
The postsynaptic membrane responds to neurotransmitter life11e_ch44_22.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_22_dlap.xml57e57e94757a2e8832000000
Synapses can be excitatory or inhibitory life11e_ch44_23.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_23_dlap.xml57e57e94757a2e8832000000
The postsynaptic neuron sums excitatory and inhibitory input life11e_ch44_24.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_24_dlap.xml57e57e94757a2e8832000000
Electrical synapses are fast but do not integrate information well life11e_ch44_25.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_25_dlap.xml57e57e94757a2e8832000000
The action of a neurotransmitter depends on the receptor to which it binds life11e_ch44_26.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_26_dlap.xml57e57e94757a2e8832000000
To turn off responses, synapses must be cleared of neurotransmitter life11e_ch44_27.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_27_dlap.xml57e57e94757a2e8832000000
The diversity of receptors makes drug specificity possible life11e_ch44_28.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_28_dlap.xml57e57e94757a2e8832000000
recaplife11e_ch44_29.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_29_dlap.xml57e57e94757a2e8832000000
key concept 44.4 Neurons and Glia Form Information-Processing Circuits life11e_ch44_30.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_30_dlap.xml57e57e94757a2e8832000000
Nervous systems range in complexity life11e_ch44_31.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_31_dlap.xml57e57e94757a2e8832000000
Reflexes are controlled by simple circuits involving sensory neurons, interneurons, and effectors life11e_ch44_32.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_32_dlap.xml57e57e94757a2e8832000000
The vertebrate brain is the seat of behavioral complexity life11e_ch44_33.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_33_dlap.xml57e57e94757a2e8832000000
recaplife11e_ch44_34.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_34_dlap.xml57e57e94757a2e8832000000
Investigating Lifelife11e_ch44_35.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_35_dlap.xml57e57e94757a2e8832000000
Chapter Summary life11e_ch44_36.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_36_dlap.xml57e57e94757a2e8832000000
Apply What You’ve Learned life11e_ch44_37.html57e57e94757a2e8832000000
DLAP questionslife11e_ch44_37_dlap.xml57e57e94757a2e8832000000