Phosphatidylserine plays a key role in nerve regeneration. The following are its main mechanisms of action:
Cell membrane stability: Phosphatidylserine is one of the main components of cell membranes, which can enhance the stability of cell membranes. When the nerve is damaged, the cell membrane may be damaged, resulting in a disorder of the exchange of substances inside and outside the cell, and phosphatidylserine supplementation can repair the damaged cell membrane and restore its normal function, thereby providing a suitable environment for nerve regeneration.
Inflammation regulation: Phosphatidylserine has an anti-inflammatory effect and can regulate the inflammatory response, reducing the release of inflammatory factors and the degree of inflammatory response. After nerve damage, the activation of the inflammatory response may further lead to damage to neurons and glial cells, and the anti-inflammatory effect of phosphatidylserine can reduce the inflammatory response and reduce cell damage, thereby contributing to nerve regeneration.
Neuroprotection: Phosphatidylserine has a protective effect on neurons, it can promote the regeneration and repair of nerve cells, and increase the survival rate of neurons. Phosphatidylserine improves neurological recovery after nerve damage by inhibiting neuronal apoptosis, promoting neuronal signaling, and enhancing the function of nerve cells.
Neurotransmitter regulation: Phosphatidylserine can regulate the synthesis and release of neurotransmitters, it can increase the synthesis and release of acetylcholine, and increase the level of acetylcholine in the brain. Acetylcholine is an important neurotransmitter involved in cognitive and memory functions in the brain, and phosphatidylserine's modulating effects help promote the restoration and repair of nerve function.
Phosphatidylserine plays a key role in the process of nerve regeneration by enhancing the stability of cell membranes, regulating inflammation, protecting neurons and regulating neurotransmitters, which help to promote cell repair and regeneration in damaged areas, thereby improving nerve function.