Na+ CP type IIα Activators
The chemical class known as Na+ CP type IIα Activators encompasses a range of compounds that have the potential to influence the activity of Na+ CP type IIα, a protein encoded by the Na+ CP type IIα gene. While direct activators for Na+ CP type IIα may not be explicitly identified, these compounds operate through intricate interactions with voltage-gated sodium channels, offering insights into potential mechanisms for modulating Na+ CP type IIα activity. For instance, activators can potentially activate Na+ CP type IIα by promoting persistent sodium influx. This compound binds to voltage-gated sodium channels, causing prolonged channel opening and increased sodium entry, potentially leading to sustained activation of Na+ CP type IIα.
Similarly, activators can promote Na+ CP type IIα by modulating voltage-gated sodium channels, inducing prolonged channel activation and increased sodium influx. The sustained channel activity induced by these compounds may contribute to the activation of Na+ CP type IIα and its participation in cellular processes influenced by sodium channel function. Other cactivators within this class also interact with voltage-gated sodium channels, potentially leading to prolonged channel activation and increased sodium influx. These interactions highlight the diverse strategies employed by compounds within the Na+ CP type IIα Activators class to impact Na+ CP type IIα activity. By influencing the function of voltage-gated sodium channels, these compounds provide avenues for understanding and manipulating the role of Na+ CP type IIα in cellular processes governed by sodium channel activity.
SEE ALSO...
| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
Veratridine | 71-62-5 | sc-201075B sc-201075 sc-201075C sc-201075A | 5 mg 10 mg 25 mg 50 mg | $82.00 $104.00 $201.00 $379.00 | 3 | |
Veratridine, a steroidal alkaloid, can potentially activate Na+ CP type IIα by promoting persistent sodium influx. It binds to voltage-gated sodium channels, causing prolonged channel opening and increased sodium entry, which may result in sustained channel activation and enhanced activity of Na+ CP type IIα in cellular processes. | ||||||
Aconitine | 302-27-2 | sc-202441 sc-202441A sc-202441B sc-202441C sc-202441D | 25 mg 50 mg 100 mg 250 mg 500 mg | $306.00 $459.00 $663.00 $1277.00 $2091.00 | ||
Aconitine, an alkaloid, may activate Na+ CP type IIα by modulating voltage-gated sodium channels. Its interaction with these channels can potentially lead to prolonged channel activation and increased sodium influx. This sustained activity could contribute to the activation of Na+ CP type IIα and its involvement in cellular processes influenced by sodium channel function. | ||||||
Resibufogenin | 465-39-4 | sc-202788 | 10 mg | $321.00 | 2 | |
Resibufogenin, a bufanolide steroid, has the potential to activate Na+ CP type IIα by modulating voltage-gated sodium channels. Its interaction with these channels may lead to prolonged channel activation, resulting in increased sodium influx. The sustained activity induced by resibufogenin could contribute to the activation of Na+ CP type IIα and its involvement in cellular processes influenced by sodium channel function. | ||||||
4-Aminopyridine | 504-24-5 | sc-202421 sc-202421B sc-202421A | 25 g 1 kg 100 g | $38.00 $1155.00 $122.00 | 3 | |
4-Aminopyridine, a potassium channel blocker, can potentially activate Na+ CP type IIα indirectly by inhibiting potassium channels. Inhibition of these channels may lead to membrane depolarization, enhancing sodium channel activation and promoting increased sodium influx. The resulting sustained activity could contribute to the activation of Na+ CP type IIα and its involvement in cellular processes. | ||||||
Acetyl chloride | 75-36-5 | sc-207253 sc-207253A | 25 g 500 g | $31.00 $51.00 | ||
Acetyl chloride a potassium channel blocker, can potentially activate Na+ CP type IIα indirectly by inhibiting potassium channels. Inhibition of these channels may lead to membrane depolarization, enhancing sodium channel activation and promoting increased sodium influx. The sustained activity induced by TEA could contribute to the activation of Na+ CP type IIα and its involvement in cellular processes. | ||||||