Neuronal potentials resting

Choline is supplied to the neuron either from plasma or by metabolism of choline-containing compounds 193 A slow release of acetylcholine from neurons at rest probably occurs at all cholinergic synapses 194 The relationship between acetylcholine content in a vesicle and the quanta of acetylcholine released can only be estimated 194 Depolarization of the nerve terminal by an action potential increases the number of quanta released per unit time 194 All the acetylcholine contained within the cholinergic neuron does not behave as if in a single compartment 194... 

There is one last, important point. The unequal distribution of ions across the plasma membrane of the neuron leads to a net negative charge on the inside of the neuron and a net positive charge on the outside. This separation of charge creates a potential difference, or voltage, across the neuronal plasma membrane. For a neuron at rest, this potential difference amounts to about 65 millivolts (mV), with the inside negative. By convention, we say that the resting potential of the neuron is -65 mV. 

An intrinsic ionic charge gradient across the membrane exists because of semipermeable nature of membrane, which maintains a difference in the concentration of the ions between the cytosol and the extracellular matrix. This difference results in a definite potential across membrane of the normal cells, which is called the resting potential. Normal plant cells, mammalian muscle cells, and neurons have resting potential values of about —120, —90, and —70 mV, respectively. Along with the resistance to the flow of ions, membrane also exhibits a capacitance. Cm, which is given by... 

The M-channels (M for muscarine) are expressed in the peripheral sympathetic neurons and CNS. In the absence of acetylcholine, the M-channel opens at resting membrane potential and dampens neuronal responsiveness to synaptic inputs. Acetylcholine inhibits M-channel activity by activation of Ml receptor. 

Figure 1.6 Presynaptic inhibition of the form seen in the dorsal horn of the spinal cord, (a) The axon terminal (i) of a local neuron is shown making an axo-axonal contact with a primary afferent excitatory input (ii). (b) A schematic enlargement of the synapse, (c) Depolarisation of the afferent terminal (ii) at its normal resting potential by an arriving action potential leads to the optimal release of neurotransmitter, (d) When the afferent terminal (ii) is already partially depolarised by the neurotransmitter released onto it by (i) the arriving acting potential releases less transmitter and so the input is less effective...

SKca and M channels are not the only K+ channels regulated by transmitters. As noted above, transmitters can also close, or open, other K+ channels that do not directly regulate excitability but instead determine the resting potential of the neuron, and hence depolarise or hyperpolarise the neuron. 

Figure 11.5 Chloride distribution and the GABAa response. The change in membrane voltage (Fm) that results from an increase in chloride conductance following activation of GABAa receptors is determined by the resting membrane potential and the chloride equilibrium potential (Fci)- (a) Immature neurons accumulate CF via NKCC, while mature neurons possess a Cl -extruding transporter (KCC2). (b) In immature neurons GABAa receptor activation leads to CF exit and membrane depolarisation while in mature neurons the principal response is CF entry and h5q)erpolarisation. This is the classic inhibitory postsynaptic potential (IPSP)...

Depolarization occurs when the membrane potential becomes less negative, moving toward zero. As will be discussed, depolarization makes the neuron more excitable. Hyperpolarization occurs when the membrane potential becomes more negative, moving away from zero. Hyperpolarization tends to make the neuron less excitable. Depolarization and hyperpolarization signals are transient or short-lived. Once the stimulus has been removed, the membrane potential returns to its resting state. Following... 

Figure 4.1 Types of changes in membrane potential. The resting membrane potential in a typical neuron is -70 mV. Movement of the membrane potential toward zero (less negative) is referred to as depolarization. The return of the membrane potential to its resting value is referred to as repolarization. Movement of the membrane potential further away from zero (more negative) is referred to as hyperpolarization.

The sinoatrial (SA) node is located in the wall of the right atrium near the entrance of the superior vena cava. The specialized cells of the SA node spontaneously depolarize to threshold and generate 70 to 75 heart beats/ min. The "resting" membrane potential, or pacemaker potential, is different from that of neurons, which were discussed in Chapter 3 (Membrane Potential). First of all, this potential is approximately -55 mV, which is less negative than that found in neurons (-70 mV see Figure 13.2, panel A). Second, pacemaker potential is unstable and slowly depolarizes toward threshold (phase 4). Two important ion currents contribute to this slow depolarization. These cells are inherently leaky to sodium. The resulting influx of Na+ ions occurs through channels that differ from the fast Na+ channels that cause rapid depolarization in other types of excitable cells. Toward the end of phase... 

However, in the SAnode, the action potential develops more slowly because the fast Na+ channels do not play a role. Whenever the membrane potential is less negative than -60 mV for more than a few milliseconds, these channels become inactivated. With a resting membrane potential of -55 mV, this is clearly the case in the SA node. Instead, when the membrane potential reaches threshold in this tissue, many slow Ca++ channels open, resulting in the depolarization phase of the action potential. The slope of this depolarization is less steep than that of neurons. 

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