End Plate Potential Miniature

Miniature end plate potential (MEPP) is a physical phenomenon that finds its application in various fields of science and technology. This phenomenon is that when an electric field is applied to an end plate whose dimensions are comparable to the electron mean free path, a miniature potential arises that can be used to control the electron current.

The history of the discovery of the MPCP is associated with the name of Hall, who in 1879 discovered the effect, which received the name Hall. In the 1960s, it was discovered that by applying an electric field to an end plate whose dimensions are comparable to the electron mean free path, a miniature potential arises that can be used to control electron current.

MECP has low voltage and high sensitivity, making it a useful tool for creating high-precision, low-power electronic devices. MPCP finds application in various fields, such as electronics, microelectronics, optics, photonics, nanotechnology and others.

The use of MECP allows the creation of devices with high resolution and accuracy, such as microelectromechanical systems (MEMS), microelectronic inertial sensors, optical micromachines, integrated circuits and others. The MPCP can also be used as a sensor for pressure, temperature, humidity and other environmental parameters.

In conclusion, miniature endplate potential is an important area of ​​physics that has wide potential for applications in various fields of science and technology. Its use allows the creation of high-precision and low-power devices, which makes it an indispensable tool for modern technologies.



Endplate (miniature) potential (EPP) is the electrical potential that is created across the muscle fiber membrane when it is excited and can be used to assess muscle functionality. Miniature potentials are of particular importance for studying the properties of nerve impulses that are transmitted through the axon to the neuromuscular junction. This work is devoted to studying the potential of the end plate, its formation and use.

The main object of study of endplate potential is the electrical potential at the axon membrane. The formation of a miniature potential occurs through the interaction of the membrane potential resulting from the action of excitation and the terminal cell potential. This makes it possible to study the properties of nerve transmission. The miniature potential may play an important role in understanding the role of axonal transport, since its formation occurs when the speed of current along the axon changes. In addition, the miniature curve can be used to assess the functional state of the muscle, which can influence the treatment of muscle pathology. In medicine, the terminal bone potential is used to diagnose disorders of neuromuscular functions, for example, in neurological diseases or injuries, when there is a disturbance in the conduction of potentials along the nerves.

Studying the potential of the terminal ossicle is important not only for science, but also for clinical practice, and therefore is of great importance for the timely diagnosis of diseases of the nervous system and muscle tissue. The results of studies related to the study of this phenomenon can help improve treatment methods for various diseases, such as myasthenia gravis, paralysis, disc herniation, etc.