BRAIN-COMPUTER INTERFACE & NEUROTECHNOLOGY
High-performance medical products for invasive and non-invasive use with the brain in research and clinical environments by g.tec medical engineering
WE ARE G.TEC MEDICAL ENGINEERING
g.tec medical engineering produces invasive and non-invasive brain-computer interfaces (BCIs) and neurotechnology that are used worldwide to measure and analyze brain waves with the highest possible resolution. A key factor is the real-time data analysis which enables many new applications and experiments in neuroscience.
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OUR NEWS
g.tec’s Dr. Christoph Guger to Discuss Future of Neurotechnology at World’s Largest BCI Event
g.tec medical engineering, a global leader in brain-computer interface (BCI) technology, is set to host the world’s largest BCI &…
Unlock Brain Connectivity: Recording CCEPs and Mapping Functional Cortical Networks
Cortico-cortical evoked potentials (CCEPs) are a neurophysiological technique used to assess functional connectivity between different regions of the brain. By delivering electrical stimulation to one cortical area and recording the resulting activity in another, CCEPs help map brain networks involved in movement, sensation, and cognition.
Brain Mapping in Children: Advancing Pediatric Epilepsy Surgery with cortiQ Cortical Mapping
Discover how advanced functional brain mapping is transforming pediatric epilepsy care. With cortiQ and real-time high-gamma frequency mapping, leading hospitals enhance seizure localization and optimize surgical planning for children with intractable epilepsy. Learn about groundbreaking research shaping the future of epilepsy treatment.
Using Brain Waves and Computer Interface Technology as a Communication System
Effective communication plays a crucial role in emergency situations, yet, according to the Oregon Health and Science University, conventional methods…
BEHAVIORAL, COGNITIVE BCI APPLICATIONS
BRAIN-COMPUTER INTERFACES
Brain-computer interfaces are increasingly being used to study and influence human cognition, behavior, and neural processes, using tools like g.tec’s biosignal amplifiers, EEG headsets, and its high-performance software environment, which provide the precision and reliability necessary to make these applications possible.
POWERFUL SOFTWARE SOLUTION
BCI PROTOTYPING ENVIRONMENT
g.tec’s rapid prototyping BCI environment allows you to realize many different applications with minimum effort. All major principles: slow waves, steady-state visual evoked potentials (SSVEP), motor imagery (MI) and evoked potentials (EP) are already implemented and can easily be used or modified.
FOR RESEARCH AND DEVELOPMENT
MATLAB-BASED BCI SOLUTIONS
g.tec’s BCI environment provides complete MATLAB-based research and development systems, including all hardware and software components needed for data acquisition, real-time and offline data analysis, data classification and neurofeedback, enabling to quickly setup closed-loop experiments including non-invasive or invasive stimulation of brain and body.
NEUROPSYCHOLOGY
INTEGRATED EEG AND FNIRS
g.tec’s hardware and software are ideal for recording physiological signals from various parts of the body across diverse experimental setups. When combined with transcranial Direct-Current Stimulation (tDCS), they enable researchers to explore and analyze the effects of targeted stimulation on the human body with precision and reliability.
INVASIVE NEUROTECHNOLOGY
BRAIN STIMULATION & CORTICAL MAPPING
Invasive and non-invasive stimulation and brain mapping techniques are used to determine brain functions in neuroscience, rehabilitation research and neurosurgery. g.tec’s electrical stimulators help you to understand cortical functions and perform brain-mapping experiments with a closed-loop system.
NON-INVASIVE NEUROTECHNOLOGY
HIGH-DENSITY EEG/EMG/ECG RECORDINGS
High-density EEG, EMG, and ECG recordings offer unparalleled precision and detail for capturing bioelectrical signals from the brain, muscles, and heart. By utilizing a dense array of electrodes, these systems provide high spatial resolution, enabling researchers and clinicians to map activity with exceptional accuracy.
MULTIMODAL RESEARCH SOLUTIONS
MULTI-CHANNEL EEG AND EYE TRACKING
Combining a high-precision, multi-channel EEG amplifier, such as the g.HIamp with active EEG electrode technology and Tobii’s advanced eye-tracking systems unlocks great potential in neuroscience research, cognitive studies, and brain-computer interface applications, enabling researchers to effectively analyze neural activity while accounting for eye movement artifacts.
ADVANCED SIGNAL PRECISION
EEG AND TMS RESEARCH
g.tec’s new g.LADYBIRD TMS-compatible EEG electrodes revolutionize combined EEG and TMS recordings by minimizing artifacts and ensuring high-quality signal acquisition during stimulation. These electrodes allow precise monitoring of brain activity, enabling researchers to better understand the neural effects of TMS with unparalleled accuracy.
SEAMLESS INTEGRATION
WEARABLE EEG AND EYE TRACKING
Integrating the g.Nautilus wearable EEG headset with Tobii’s advanced eye-tracking technology offers unparalleled opportunities for neuroscience and cognitive research. This combination ensures precise synchronization, enhancing artifact rejection and enabling detailed analysis of brain activity and eye movements in real-world scenarios.
THE NEW g.LADYBIRD TMS ELECTRODES
The g.LADYbird TMS electrodes, available in active and passive versions, are ultra-flat and specifically designed for combined EEG and TMS recordings. Their 3 mm thickness makes them the thinnest on the market, allowing the TMS coil to be placed closer to the brain while minimizing artifacts. The active electrodes feature built-in amplifiers for superior signal quality, reduced noise, and higher impedance tolerance, offering unparalleled performance and ease of use in TMS-EEG setups.
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