Unlock the secrets of human movement with Delsys NeuroMap—a cutting-edge software suite designed to transform raw EMG signals into actionable insights on motor unit behavior. Developed for seamless integration with the Trigno Galileo sensors, NeuroMap empowers researchers, clinicians, and movement scientists to non-invasively decode the neural commands that drive muscle activity.‍

At the heart of NeuroMap is its advanced EMG decomposition engine, which automatically extracts and visualizes motor unit action potentials, firing rates, and recruitment patterns. This allows for a deeper understanding of neuromuscular control during complex movements such as gait, cycling, or rehabilitation exercises. With features like timestamped mean firing rate (MFR) exports, multi-file statistical analysis, and intuitive data visualization tools, NeuroMap streamlines the journey from data collection to discovery.

Whether you're exploring motor control, optimizing performance, or advancing neurophysiological research, NeuroMap offers the precision and clarity needed to reveal the neural code behind every movement.

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FAQ

What does Delsys NeuroMap do?

NeuroMap is a software suite that transforms raw EMG signals from Trigno Galileo sensors into detailed insights about motor unit behavior. It performs decomposition of surface EMG to identify individual motor unit action potentials, enabling researchers to study neuromuscular control at a level previously only possible with invasive techniques.

What hardware does NeuroMap require?

NeuroMap is designed for seamless integration with the Delsys Trigno Galileo sensors, which use a high-density electrode grid to capture fine spatial EMG detail required for motor unit decomposition. It is used in conjunction with the Trigno Research+ System and the EMGworks or Trigno Discover software platform.

What research and clinical applications does NeuroMap support?

NeuroMap is used by researchers and clinicians in motor neuroscience, rehabilitation science, sports science, and movement disorders. It is particularly valuable for studying motor unit recruitment, firing rate, and synchronization in conditions such as ALS, Parkinson's disease, stroke, and aging.

What outputs does NeuroMap provide?

NeuroMap outputs include identified motor unit action potential trains, firing rates, recruitment thresholds, and motor unit conduction velocity estimates. These metrics provide a comprehensive picture of how the nervous system controls muscle force production.

Is NeuroMap suitable for clinical use?

NeuroMap is primarily a research tool. For clinical applications, consult with NBT to understand which regulatory approvals and intended use specifications apply in your region and clinical context.