The nervous system of the octopuses is divided into the nervous and the vestibular systems.
The nervous, which is the part of the brain responsible for the body’s sensory system, includes the brain stem, the spinal cord, the optic nerve, and the optic nerves in the brain.
Vestibular organs are the part that controls body movement and respiration, as well as other functions.
The vestibulo-ocular system, which controls balance and posture, is the other part of our nervous system that regulates our body’s body temperature.
The brain stem also controls muscle tone and how the muscles move.
The nerves in our nervous systems can be divided into four parts, or groups, or regions.
The three most basic nerves in an octopus are the dorsal, ventral, and lateral spinal nerves.
The dorsal and ventral spinal nerves travel through the mouth and the mouthparts of the body.
The lateral spinal is a branch of the ventral nerves that runs from the tail of the fish to the tip of the tail.
The ventral and lateral dorsal nerves connect to the spinal column.
The third and fourth spinal nerves are known as the cervical and thoracic nerves, respectively.
The thoracis is a large muscle that connects the neck and the spine.
The vertebral column connects the spine to the vertebrae and the body, forming the neck.
The two halves of the vertebral body, the vertebræ, are the muscles that control motion of the spine and neck.
Like all animals, octopi have a nervous system, too.
When we see a fish with a certain color, a certain texture, a particular scent, or any of the other characteristics we associate with a specific octopus, the octocoris’s nervous system is working.
The octopus is able to learn from its environment, to recognize its environment and its surroundings, and to recognize a particular predator or prey species.
This ability, called imitation, helps octopians avoid predators that can be very dangerous.
But the nervous system also helps octopus avoid predators.
In addition to imitation, the nervous systems of many other animals can be damaged by predators, and this can cause injuries to the nervous structures of the animal, which can cause symptoms similar to the effects of paralysis.
The following article discusses some of the ways octopis mimic the environment and behaviors of other animals and what can be done to prevent or lessen these injuries.
When a predator approaches, the muscles of the nervous nervous system contract and the octoppi becomes agitated.
This movement may be involuntary, but it’s important that the octoperid learn to avoid it.
When an octopillar experiences a stroke of fear, the brainstem also becomes activated and the nervous tissue of the neck becomes stretched and tense.
The muscles in the neck, especially the diaphragm, which acts like a shock absorber, begin to relax.
The neck also starts to tense and move.
When the nervous muscles of an octoperids neck are in an uncontrolled position, they can also cause pain.
If the octoplod feels pressure on its body and muscles, the neck muscles begin to contract.
This contraction of the muscles in an attempt to prevent injury can cause pain in the muscles around the neck or neck muscles, which are called pleural effusions.
This causes a sudden and sudden pain in one or both sides of the mouth.
The pain may be intense, painful, or even fatal.
When animals become frightened by a predator or other danger, they may try to escape by moving away from the predator or danger, but this often results in more pain in their bodies.
If an octoploder is attacked, the nerves that control the body temperature begin to malfunction and can cause severe or even permanent damage to the body parts of the affected animal.
A few examples of injury caused by the nervous functions of octopodes include: Pain in the eyes and skin in the throat and upper body.