![This is blank.](https://digitalhistology.org/wp-content/themes/histology-unified/imgs/trans.png)
Bipolar neuron
In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x
![Neuronal cell bodies <p>In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x</p>](https://digitalhistology.org/wp-content/uploads/2017/05/T.N.Type-17-1-ping.png)
Neuronal cell bodies
In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x
![Neuronal processes <p>In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x</p>](https://digitalhistology.org/wp-content/uploads/2017/05/T.N.Type-17-2-ping.png)
Neuronal processes
In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x
![Schwann cell nuclei <p>In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x</p>](https://digitalhistology.org/wp-content/uploads/2017/05/T.N.Type-17-3-ping.png)
Schwann cell nuclei
In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x
![Capillaries <p>In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x</p>](https://digitalhistology.org/wp-content/uploads/2017/05/T.N.Type-17-4-ping.png)
Capillaries
In most cases, special sensory stimuli are transduced by receptor cells and the signal is carried by a dendrite toward the cell body. An axon leaves the cell body from its opposite pole to form a cranial nerve that enters the brain. Axonal and dendritic processes cannot be differentiated in this image. Vestibular ganglion of the ear 1200x