SEMAX

Semax is a synthetic ACTH (4–10) analog developed for cognitive and neurological research. It has been studied in humans for effects on attention, memory, neural resilience, and neurotrophic signaling and has applications in stroke recovery and cognitive performance research.

⚗️ Product Features

• 🩺 Synthetic ACTH‑derived peptide (ACTH 4–10 analog)

• 🧪 Manufactured under strict peptide quality standards

• ✅ ≥98 % purity verified by HPLC

• 📄 Batch-specific Certificates of Analysis (COAs) included

• 💧 Sterile, lyophilized peptide for research applications

🔬 Human-Relevant Research Applications

🧠 Cognitive Function & Neuroplasticity

Semax has been shown in clinical observations to support attention, short-term memory, and cognitive performancein humans, particularly under stress or fatigue conditions. It also influences BDNF levels, which are important for neuronal growth and synaptic plasticity.
🔗 Clinical research overview and BDNF effects

🧩 Brain Network Activity & Rehabilitation

Evidence from human studies indicates that Semax may enhance functional brain network activity, supporting neural resilience and recovery, including post-stroke rehabilitation.
🔗 fMRI and clinical observations summary

🧾 Mechanism Summary

• 📈 Supports attention, memory, and working memory in human studies

• 🧩 Enhances functional brain network activity

• 🧬 Promotes BDNF-mediated neuronal growth and synaptic plasticity

• ⚙️ Modulates neural processes involved in learning and executive function

🔄 Reconstitution & Handling Guidance

1️⃣ Reconstitute using sterile bacteriostatic water
2️⃣ Add appropriate volume per research protocol
3️⃣ Gently swirl — do not shake
4️⃣ Store reconstituted peptide at 4–10 °C
5️⃣ Keep unopened vials refrigerated until use

❓ Frequently Asked Research Questions

What cognitive functions has Semax been studied for in humans?
Attention, short-term memory, EEG-linked cognitive activity, and brain network modulation.

Does Semax influence neurotrophic factors in humans?
Yes — increases in BDNF have been observed in human studies, supporting neuroplasticity and recovery.