1Direct Muscle Stimulation

.MDS multi-directional pulse directly acts on muscle fibers by emitting electrical pulse signals of specific frequencies and intensities. These pulses can cause changes in the membrane potential of muscle cells, just like sending a "contraction command" to the muscles. For example, when a pulse reaches a muscle cell, it will open the ion channels on the cell membrane, leading to the flow of ions and thus triggering a muscle contraction response. This stimulation method is similar to the principle of nerve signals emitted by the brain to stimulate muscle contraction, but MDS pulses can more precisely control the intensity and frequency of stimulation.

2. Enhancing the Sense of Muscle Contraction

Compared with traditional training methods, MDS multi-directional pulses can significantly enhance the sense of muscle contraction. Traditional training mainly relies on one's own neuromuscular system to initiate and control muscle contraction, while MDS pulses can directly trigger muscle contraction, and its contraction intensity can reach 30 times that of traditional training. This is because the stimulation frequency and intensity of the pulses can be adjusted to a relatively high level, enabling the muscles to produce a stronger contraction response. For example, when doing arm muscle training, using MDS pulse stimulation can make the arm muscles produce a stronger sense of tension than ordinary dumbbell training

3. Activating More Muscle Fibers

High-frequency and high-intensity MDS pulse contractions can activate more muscle fibers. Muscles are composed of many muscle fibers. In traditional training, often only a part of muscle fibers can be activated. The high-frequency stimulation of MDS pulses can enable more muscle fibers to participate in the contraction process. Just like a team working, traditional training may only mobilize some members to work, while MDS pulses can mobilize the entire team. These activated muscle fibers will cooperate with each other to enhance the overall contractility of muscles. Moreover, this kind of stimulation can also promote muscle filament sliding. Muscle filament sliding is the microscopic mechanism of muscle contraction. More muscle filament sliding means more effective muscle contraction and training effect

4. Efficient Contraction Frequency

MDS multidirectional pulses can make muscles contract more than 50,000 times in a single contraction. In traditional active exercise, the number of muscle contractions is relatively small. For example, in an ordinary push-up training session, muscle contractions may only be dozens to hundreds of times. The MDS pulse, through continuous stimulation, allows muscles to contract a large number of times in a short period. This efficient contraction method can stimulate muscle growth more effectively than active exercise. Because a large number of muscle contractions will trigger a series of physiological reactions, such as increasing muscle protein synthesis and promoting muscle cell metabolism, thereby promoting muscle growth and strength improvement.

5. MDS Multi - directional Electrical Muscle - building Technology

This is one of the core technologies of the entire system. It achieves efficient stimulation of muscles through a specific electrical pulse mode. Its multi-directional characteristic means that pulses can stimulate muscle fibers from multiple angles and dimensions, ensuring that all parts of the muscles can be fully exercised. It is like having an all-round "fitness coach" who can accurately find each bundle of muscle fibers and make them all active. Compared with traditional unidirectional electrical stimulation, this technology can stimulate muscles more evenly and reduce local overstimulation or unstimulated conditions of muscles, thereby improving the effect and efficiency of muscle building.

6.Intelligent Exercise Mode Recognition and Adaptation Technology

This technology can automatically recognize the user's exercise intention and physical state, and then adapt the most suitable exercise mode for the user. It collects the user's exercise data through built-in sensors, such as the degree of muscle exertion, exercise speed and amplitude. For example, when the user wants to perform exercise in the activation and fat burning mode, the technical system will automatically adjust the parameters of the equipment, such as pulse frequency and intensity, according to the user's physical data such as body fat percentage and heart rate to achieve the best fat burning effect. At the same time, in the body curve shaping mode and muscle carving mode, it can also intelligently adjust the stimulation method according to the user's muscle morphology and different target muscle groups to provide users with a personalized exercise experience

7.Biological Feedback and Regulation Technology

This technology can monitor users' physical physiological feedback in real time, including muscle fatigue level, heart rate changes, metabolic rate, etc. Based on this feedback information, the system can dynamically adjust exercise intensity and mode. For example, if the user's muscles show signs of excessive fatigue, such as decreased muscle strength and abnormal muscle electrical signals, the system will automatically reduce the pulse intensity or adjust the exercise mode to avoid user injury while ensuring exercise effectiveness. Moreover, by collecting these biological feedback data over a long period of time, the system can also generate personalized exercise plans and suggestions for users to help them manage their body shape and conduct fitness training more scientifically