The whole-body nerve conduction electric model is a high-tech teaching device integrating anatomy and physiology teaching, aiming to visually display the structure of the human nervous system and the conduction process of nerve impulses. The model is designed in proportion to the human body, clearly marking the distribution of the central and peripheral nerves. It simulates the transmission path of neural signals through electric light effects, allowing students to directly observe the process by which neural stimuli are transmitted from the brain through the spinal cord to the limbs.

In teaching applications, this model is widely used in medical, nursing, biological and anatomical courses to explain the composition of the nervous system, the mechanism of reflex arcs and the principles of neural signal transmission. Through the photoelectric dynamic demonstration, learners can better understand the physiological connection between sensory input and motor output, and enhance their learning interest and depth of understanding.

In addition, this model is often used in medical exhibitions and health science popularization activities to demonstrate the working principle of the nervous system and help the public understand the mechanisms of nerve conduction disorders in diseases such as nerve injury, stroke, and Parkinson's disease. The intuitiveness and interactivity of the whole-body neural conduction electric model make the abstract neural activities vivid, easy to understand and rich in teaching value.