NOOHEXA | 30ML

Active Ingredients

Per ml

• Noopept – 30 mg

• Dihexa – 5 mg

• 9-Me-BC (9-Methyl-β-carboline) – 2.5 mg

Per 30 ml bottle

• Noopept – 900 mg

• Dihexa – 150 mg

• 9-Me-BC – 75 mg

Full Research Description

This advanced research formulation is designed for investigation of neuroplasticity signaling pathways, synaptic structural development, and dopaminergic neuron-related mechanisms. The combination of Noopept, Dihexa, and 9-Me-BC provides a multi-pathway research platform focused on molecular processes associated with neuronal adaptation, synapse formation signaling, and cognitive pathway exploration.

Noopept has been studied in laboratory models for its relationship to neurotrophic signaling pathways, including mechanisms associated with neuronal growth factor expression and adaptive cellular response to oxidative stress. Research literature has explored its role in pathways connected to long-term potentiation (LTP), a cellular mechanism commonly examined in models of learning and memory formation.

Dihexa has been investigated for its interaction with the hepatocyte growth factor (HGF) / c-Met signaling pathway, which has been associated in experimental research with synaptogenesis and dendritic spine formation. These structural adaptations are of interest in laboratory models studying neuronal network development, connectivity, and synaptic efficiency.

9-Me-BC (9-Methyl-β-carboline) has been explored in research examining dopaminergic neuron signaling pathways, neuronal survival mechanisms, and neurogenesis-related processes. Experimental literature has evaluated its relationship to pathways associated with dopamine system function and neuronal structural integrity, making it a complementary component in multi-pathway neuroplasticity research models.

Together, these compounds provide a focused research combination for investigating:

• neuroplasticity-related signaling pathways

• synaptic density and structural adaptation mechanisms

• dopaminergic neuron pathway research

• neuronal communication efficiency models

• dendritic spine formation signaling pathways

• long-term potentiation (LTP) associated mechanisms

• neurotrophic factor expression pathways

This formulation supports investigation into the relationship between neuronal structural signaling pathways and dopaminergic regulatory mechanisms, which are commonly explored in research models related to learning processes, neural adaptation, and cognitive pathway signaling.

Specifications

Total volume: 30 ml

High-concentration research preparation

Research use only.

Not for human consumption.