Cortivision’s fNIRS products provide safe, non-invasive and accurate brain oxygenation changes monitoring for studies with children and infants, supporting i.e. neurodevelopmental research in real-world and lab settings. With specialized designs for comfort and flexibility, our systems are ideal for monitoring young, active participants across developmental stages.

Cortivision fNIRS for Hyperscanning Studies

Hyperscanning technology, which allows for simultaneous monitoring of brain activity across multiple participants, is opening new possibilities in research on social interactions, group dynamics, and collaborative cognition. Cortivision’s fNIRS systems—Spectrum and Photon Cap – are suited for these studies, with features that facilitate precise, synchronized data collection across participants in a variety of settings. Whether in controlled laboratory conditions or real-world environments, our systems provide researchers with the tools needed to capture meaningful insights into how brains interact and respond during social activities.

Cortivision’s fNIRS technology provides researchers with a robust platform for Brain-Computer Interface (BCI) studies. By measuring brain oxygenation changes, it supports basic neural signal decoding, offering practical advantages like non-invasiveness, flexibility, and compatibility with EEG or other health trackers. This makes it an accessible tool for exploring neural control systems in experimental environments.

Cortivision’s fNIRS systems provide researchers with a reliable, portable solution for studying brain oxygenation changes during movement. With features like motion artifact control and lightweight design, they enable precise data collection in dynamic environments, supporting research in sports, rehabilitation, and real-world cognitive-motor interaction studies.

Cortivision’s fNIRS systems enable immersive research in Virtual Reality (VR) and multimodal studies. By integrating seamlessly with EEG, eye-tracking, and VR technologies, they provide researchers with comprehensive tools to study brain oxygenation changes in realistic, interactive settings, advancing cognitive, behavioral, and training-related research.