Strip Ganglion Plate

The ganglion plate strip (stria ganglionaris interna) is a narrow layer of tissue that is located on the inside of the eardrum. It plays an important role in the transmission of sound signals in the human auditory system.

The strip ganglion plate consists of many thin fibers called ganglion cells. These cells have long axons that run through the entire eardrum and end at the cochlea, the internal organ of hearing. When sound waves strike the eardrum, these fibers become excited and transmit signals to the cochlea.

In addition, the ganglion plate strip contains many nerve endings that provide communication between the auditory nerve and the brain. This allows a person to perceive sound signals and determine their source.

Damage to the ganglion plate strip can lead to hearing loss and impaired perception of sound signals. However, due to its important role in auditory function, the lamina ganglion stria is a subject of study for scientists and clinicians who study the causes and treatments of hearing loss.

strip (stripe) ganglion plate - (stria ganglionaria laminae, stria la.) - a secondary strip of the dentate plate, located between the conditional and facial lines and the two upper fan fibers. The g. ends in the sulcus interapicalis. It has a width of 0.3 mm in humans and contains inside the fibers of the internal sensory ganglion of the trigeminal nerve, ending in nerve terminal branches. Between the superior surface of the strip and the fibers of the levator pterygoid there is space for movement of the mandible.

Signs of damage: • complaints of pain, burning, tingling (see Trigeminal neuralgia), numbness, crawling, sensitivity disorders in the area of ​​innervation of one or more branches of the trigeminal nerve; mental disorders.

Principle of operation: the strength and time of irritation of receptors is regulated by the current following along the nerve fibers after exposure to physical force, as well as during adaptation (the counteraction of any artificial adaptation to the adaptation of the body is called stabilization). The principle of adaptation is also manifested in a wide range of psychophysiological mechanisms. At the very beginning of adaptation to the presented stimulus, the body reacts to it as strong. As training progresses (with hyperreactivity