All of the following are true characteristics of the neural axon and soma except “increased ribosomal activity in the axon hillock.” The axon hillock is a site of neurotransmitter transport. These molecules are produced and packaged in the soma of the neuron, before being translocated to the axon hillock via microtubule tracks. There is little to no ribosomal activity in the axon of a neuron, since most ribosomes are located near the nucleus of a cell, which is the site of mRNA release.

The enteric nervous system (ENS) is a component of the autonomic nervous system, which is a component of the peripheral nervous system. The ENS is responsible for innervating the digestive organs and, thus, regulating digestion.

The central nervous system is composed of the brain and spinal cord, while the peripheral nervous system prolifertates the body. The somatic nervous system is under voluntary control, while the autonomic is involuntary. The cranial nerves are a set of specialized nerves that branch directly off of the spinal cord.

Along with capillaries, the ependymal cells create the choroid plexus. The choroid plexus is responsible for synthesizing and secreting cerebrospinal fluid around the brain and the spinal cord. 

Calcium is a very common vehicle that drives membrane fusion, including the fusion of synaptic vesicles with the synaptic cell membrane. This allows the ejection of neurotransmitter into the synaptic cleft.

There are two types of synapses: the chemical synapse and the electrical synapse. Chemical synapses are more common than electrical synapses, and use neurotransmitters (chemicals) to propagate action potentials. Electrical synapses have tunnels between cells, called gap junctions, that quickly transmit signals from one cell to the other. Electrical synapses are found extensively in the heart, since it is essential to have quick signal transmission between cardiac cells.

In chemical synapses an action potential reaches the end of a presynaptic neuron, which causes neurotransmitters to be released from the presynaptic neuron. These neurotransmitters bind to receptors on the postsynaptic neuron and initiate a signal transduction pathway in the postsynaptic neuron. The space between the presynaptic and postsynaptic neuron is called the synaptic cleft. Synaptic clefts are important regions where neurotransmitters are released and regulated.

Calcium ions play an important role in chemical synapses. Once an action potential arrives at the presynaptic neuron terminal, calcium ion channels on the presynaptic neuron become permeable to calcium ions. This facilitates the movement of calcium ions into the presynaptic neuron. Influx of calcium ions signals the presynaptic neuron to release neurotransmitters into the synaptic cleft, which eventually bind to receptors on the postsynaptic neuron. The calcium ions do not enter the postsynaptic neuron at the synapse.

Electrical synapses have two main characteristics. First, they transmit signals through specialized tunnels between cells called gap junctions. Gap junctions facilitate movement of molecules and ions between cells. This movement enables transmission of signals between adjacent cells. Second, electrical synapses have a much higher speed of signal transmission than chemical synapses. This occurs because the signals in electrical synapses are transmitted directly from one cell to the next via gap junctions. In chemical synapses, however, signals are transmitted indirectly via neurotransmitters, which decreases the speed of signal transmission.

A chemical synapse is a type of synapse that uses neurotransmitters to transmit signals. A presynaptic neuron receives an action potential, which prompts neurotransmitters to be released into the synaptic cleft. These neurotransmitters traverse across the synaptic cleft and bind to receptors on the postsynaptic neuron. Binding of neurotransmitters initiates a signal pathway in the postsynaptic neuron.

One of the characteristics of a chemical synapse is that it is unidirectional. This means that the signal can only be propagated in one direction. The signal is always transmitted from the presynaptic to the postsynaptic neuron, never the other way around.

Chemical synapses are indeed more common than electrical synapses. Most nerves, neuromuscular junctions, and major organs in the body use chemical synapses to transmit action potentials. The only major exception is the heart; cardiac cells in the heart use electrical synapses to transmit signal from one cell to the other.

In a chemical synapse, the presynaptic neuron transmits a signal to the adjacent postsynaptic neuron. The postsynaptic neuron receives this signal via neurotransmitters. Recall that a neuron has directionality, with dendrites on one end and an axon on the other end. Dendrites receive an outside signal (signal enters neuron), whereas an axon transmits the signal to an adjacent neuron or muscle (signal exits neuron). This means that the axon end of the presynaptic neuron transmits the signal to the dendrite end of the postsynaptic neuron via a chemical synapse.

During the absolute refractory period, no action potential can occur. In the relative refractory period, an action potential can occur with more stimulation than is normally required.

Saltatory conduction is the property that allows an action potential to jump from one node to the next along a neural axon. This is accomplished by the presence of myelin, a non-conducting sheath around the axon. Myelin interrupts the flow of current down the membrane, forcing it to skip from one region of membrane to the next, rather than fluidly traveling down the entire axon length.

Depolarization is the stage of action potential transmission in which sodium channels are opened, and sodium rushes into the cell down its concentration gradient. The resting potential of the neural membrane is roughly . The rapid influx of positive sodium ions causes this potential in increase to at the action potential peak.

Repolarization is the stage of action potential transmission in which potassium channels of a cell are opened, and potassium moves out of the cell. This event re-establishes the negative resting membrane potential. 

The refractory period is the obligatory temporal gap between action potentials. After an action potential, the primary gating mechanism of the voltage-gated sodium channels causes the channels to close and deactivate. This constitutes the absolute refractory period, during which no stimulus is capable of producing an action potential. The relative refractory period follows, during the cell repolarization, when potassium efflux causes the membrane potential to drop below the resting potential. This state of hyperpolarization means that a greater stimulus is required to reach threshold, and constitutes the relative refractory period.