Mathematical models and computer simulations have the great potential to substantially
increase our understanding of the biophysical behavior of the neuromuscular system. This …

While electromyography (EMG) and magnetomyography (MMG) are both methods to
measure the electrical activity of skeletal muscles, no systematic comparison between both …

The lack of an efficient modelling-simulation-analysis workflow for creating and utilising
detailed subject-specific computational models is one of the key reasons why simulation …

Skeletal muscles can be voluntary controlled by the somatic nervous system yielding an
active contractile stress response. Thereby, the active muscle stresses are transmitted to the …

Purpose From the myofibrils to the whole muscle scale, muscle micro-constituents exhibit
passive and active mechanical properties, potentially coupled to electrical, chemical, and …

We present MegaMol, a low-overhead prototyping framework for interactive visualization of
large scientific data sets. We give a brief summary of related work for context and then focus …

Electromyography (EMG) can be used to study the behaviour of the motor neurons and thus
provides insights into the physiology of the central nervous system. However, due to the high …

The versatile neuromuscular system, consisting of skeletal muscles and the nervous system,
enables human to perform crucial everyday tasks. To investigate its functioning and …

Numerical simulations consist of many components that affect the simulation accuracy and
the required computational resources. However, finding an optimal combination of …

The multi-scale character of skeletal muscle models requires simulations with high spatial
resolution to capture all relevant effects. This naturally involves high computational load that …