front 1 Astrocytes provide the defense for the | back 1 CNS |
front 2 The ANS motor fibers conduct nerve impulses from the CNS to | back 2 smooth muscle, cardiac muscle, and glands. |
front 3 Ependymal cells are | back 3 ciliated CNS neuroglia that plays an active role in moving the cerebrospinal fluid. |
front 4 The central nervous system uses frequency of action potentials to determine the strength of a | back 4 stimulus. |
front 5 Bipolar neurons are commonly found in the | back 5 retina of the eye |
front 6 Acetylcholine is an | back 6 excitatory neurotransmitter secreted by motor neurons innervating skeletal muscle. |
front 7 The nervous system integrative function | back 7 analyzes sensory information, stores information, makes decisions. |
front 8 The period after an initial stimulus when a neuron is not sensitive to another stimulus is the | back 8 absolute refractory period. |
front 9 The part of a neuron that conducts impulses away from its cell body is called an | back 9 axon |
front 10 A voltage-gated channel | back 10 opens in response to a change in membrane potential and participates in the generation and conduction of action potentials. |
front 11 An impulse from one nerve cell is communicated to another nerve cell via the | back 11 synapse |
front 12 The role of acetylcholinesterase is | back 12 to destroy ACh a brief period after its release by the axon endings. |
front 13 Innervation of skeletal muscle is not a function of | back 13 the autonomic nervous system |
front 14 Collections of nerve cell bodies outside the central nervous system are called | back 14 ganglia |
front 15 The term central nervous system refers to | back 15 the brain and spinal cord |
front 16 The substance released at axon terminals to propagate a nervous impulse is called a | back 16 neurotransmitter. |
front 17 A neuron that has as its primary function the job of connecting other neurons is called an | back 17 association neuron. |
front 18 Saltatory conduction is made possible by | back 18 the myelin sheath |
front 19 Nucleic acid is not a | back 19 chemical class of neurotransmitters |
front 20 The synaptic cleft prevents | back 20 an impulse from being transmitted directly from one neuron to another. |
front 21 Amplitude of various sizes describes | back 21 a graded potential |
front 22 Neuroglia that control the chemical environment around neurons by buffering potassium and recapturing neurotransmitters are | back 22 astrocytes. |
front 23 Schwann cells are functionally similar to | back 23 oligodendrocytes |
front 24 Immediately after an action potential has peaked | back 24 potassium cellular gates open |
front 25 Nerve cell adhesion molecules (N-CAMs) are crucial for the development of | back 25 neural connections. |
front 26 An inhibitory postsynaptic potential (IPSP) is associated with | back 26 hyperpolarization |
front 27 excitatory postsynaptic potential (EPSP) is being generated on the dendritic membrane a single type of channel will open | back 27 permitting simultaneous flow of sodium and potassium. |
front 28 When a sensory neuron is excited by some form of energy, the resulting graded potential is called a | back 28 generator potential |
front 29 Graded potentials decrease amplitude as they move away from | back 29 the stimulus point |
front 30 Sodium gates in the membrane can open in response to | back 30 electrical potential changes |
front 31 A second nerve impulse cannot be generated | back 31 until the membrane potential has been reestablished. |
front 32 How does the interior surface of a cell membrane of a resting (nonconducting) neuron differ from the external environment? | back 32 The interior is negatively charged and contains less sodium. |
front 33 If a motor neuron in the body were stimulated by an electrode placed about midpoint along the length of the axon the impulse would spread | back 33 bidirectionally |
front 34 Endorphin neurotransmitters inhibit pain and are mimicked by | back 34 morphine, heroin, and methadone. |
front 35 Short distance depolarization describes | back 35 the excitatory postsynaptic potential |