HiveOne.

The New Generation of Wearable

Brain Imaging

Modular Desgin. Superior Signal Quality. High-Density Neuroimaging. Built for Modern Neuroscience.

Request a Demo
Become an Early Research Partner

RESEARCH APPLICATIONS

Cognitive Neuroscience Hyperscanning Neurotechnology Research Neuroergonomics Longitudinal Monitoring Translational Neuroscience Real-World Neuroimaging Pediatric Neuroscience Clinical Research Motor and Movement Analysis Brain-Computer Interface BCI

High Signal Quality

Built Around a New
Sensor Generation

Hive One is the world’s first wearable fNIRS system to integrate high-sensitivity Silicon Photomultiplier (SiPM) sensors, developed in collaboration with ETH Zurich. Triple-wavelength acquisition at 735 nm, 810 nm, and 850 nm enables simultaneous measurement of oxygenated and deoxygenated hemoglobin with exceptional spectral precision.

Sampling rates of up to 250 Hz ensure temporal resolution suitable for cognitive neuroscience, BCI applications, and real-time neurofeedback research.

World-first SiPM sensor integration in wearable fNIRS for superior signal-to-noise ratio
Triple wavelengths at 735 nm, 810 nm, and 850 nm for precise hemodynamic separation
Sampling rates up to 250 Hz for high-temporal-resolution neuroimaging
Robust performance against motion artifacts in mobile and pediatric paradigms
350+ Maximum Channels (64-Optode Config)
250 Hz Maximum Sampling Rate
3 Wavelengths: 735 / 810 / 850 nm
5min set up

High-Density Neuroimaging

350+

Channels in the 64-Optode Advanced Configuration

Next-Gen Optodes

Proprietary Double-Tip optode design integrates a long-channel measurement (30 mm), a dedicated short channel (8 mm), and an onboard IMU – all in one compact wearable module.

Full Cortical Coverage

Large-scale cortical imaging with exceptional spatial resolution, covering frontal, parietal, temporal, and occipital regions simultaneously in a single wearable session.

Wearable Form Factor

Despite the high channel count, Hive One maintains a lightweight wearable design fully suited for mobile, longitudinal, pediatric, and hyperscanning research paradigms.

Short Channels

Dedicated Short Channels,
Built Into Every Optode

Every Hive One optode incorporates a multi-distance measurement architecture with a short-separation channel at 8 mm and a long-separation channel at 30 mm. The short channel captures superficial physiological activity, enabling its use as a local reference signal for noise correction at every measurement point.

This per-optode approach provides high-quality reference data simultaneously across the full montage – delivering more consistent results across adult and pediatric subjects alike.

Why It Matters
Improved physiological noise correction
Local 8 mm reference at each optode enables cleaner hemodynamic separation at the cortical level.
Enhanced signal fidelity
Stronger cortical signal separation from systemic interference at 30 mm depth.
Higher reproducibility
More consistent results across adult and pediatric subjects, sessions, and experimental conditions.
More reliable longitudinal measurements
Improved baseline correction supports repeated-measures and long-term research designs.

IMU Motion Tracking

Motion-Aware Neuroimaging

Each Hive One Double-Tip optode includes an integrated inertial measurement unit (IMU) for continuous 6-axis motion sensing at the individual sensor level. IMU data is recorded simultaneously with fNIRS signals, enabling motion-aware data processing, artifact detection, and robust neuroimaging in real-world and pediatric environments.

This is particularly critical for hyperscanning studies, neuroergonomics experiments, clinical monitoring with children, and any research paradigm involving naturalistic participant movement.

Sensor-Level IMU Integration per Optode
Real-Time Motion and Artifact Monitoring
6-Axis Per-Optode Motion Data

Superior Usability

Designed for Fast and
Scalable Workflows

The proprietary Hive One magnetic holder system makes high-density fNIRS setups practical for everyday research workflows, including studies with children. Reduced setup complexity translates directly into more productive research time and a better participant experience.

Rapid montage - significantly reduced setup time vs. traditional fNIRS systems
Simplified handling - intuitive magnetic attachment reduces operator training requirements
Reproducible placement - consistent optode positioning across sessions and subjects
Participant comfort - lightweight, low-pressure design suitable for adults and children
Scalable configurations - supports 8 to 64 optodes without added workflow complexity

System Configurations

Scale the System to
Your Research

Hive One is available in four modular configurations. Start with the setup that fits your current research and scale as your needs evolve.

Entry 8 Optodes

Compact entry configuration for focused experiments, pilot studies, and targeted cortical region analysis.

Starter 16 Optodes

Flexible setup for standard neuroscience experiments, mobile applications, and smaller-scale cortical mapping.

Core 32 Optodes

High-density configuration optimized for advanced cortical imaging, cognitive neuroscience, and hyperscanning studies.

Advanced 64 Optodes - 350+ Channels

Full-scale research platform with maximum cortical coverage. Ideal for large cohort studies, translational neuroscience, and precision brain monitoring.

Request Pricing Information

Technical Highlights

HiveOne combines fast and simple installation with a modular architecture, high-density measurements, and best-in-class signal quality.

Every specification in Hive One reflects a deliberate engineering decision. From sensor physics to system architecture, the platform was designed to set a new benchmark for wearable neuroimaging.

World-First SiPM sensor integration in wearable fNIRS - highest sensitivity available in any portable neuroimaging system
735 / 810 / 850 nm Triple-wavelength acquisition for precise oxygenated and deoxygenated hemoglobin separation
Up to 250 Hz Sampling rate - sufficient for BCI, neurofeedback, and high-speed cognitive paradigms
Double-Tip Design Proprietary optode architecture combining long-channel, short-channel, and IMU in a single unit
8 mm / 30 mm Short-separation and long-separation channels per optode for physiological noise correction
350+ Channels Maximum optical channels in the 64-source / 64-detector Advanced configuration
Per-Optode IMU 6-axis inertial motion unit integrated into each optode for real-time artifact monitoring
Hyperscanning Ready Supports dual-subject and multi-participant paradigms for social and interactive neuroscience
TTL Trigger I/O Integrated TTL trigger input and output for precise event synchronization with external devices
EEG / tES / Eye Tracking Multimodal compatibility for combined neuroimaging, neurostimulation, and oculomotor research
Real-Time Ready Supports neurofeedback, brain-computer interface experiments, and closed-loop applications
Magnetic Holder Rapid, reproducible montage system for adults and children - reduced setup time and improved comfort
Multimodal Integration

Multimodal
Neuroimaging Ready

Hive One is engineered for seamless integration with EEG, transcranial electrical stimulation (tES), and eye tracking systems, supporting simultaneous multimodal research workflows without the hardware complexity typically associated with combined neuroimaging setups.

Integrated TTL trigger input and output ensure precise event synchronization across all connected modalities. Hive One also supports real-time data streaming for neurofeedback and brain-computer interface applications.

EEG-fNIRS integration
Time-locked acquisition of hemodynamic and electrophysiological signals for richer brain characterization.
tES and neurostimulation compatibility
Simultaneous fNIRS monitoring during transcranial electrical or magnetic stimulation protocols.
Eye tracking integration
Combined oculomotor and neuroimaging paradigms for attention, cognitive load, and clinical research.
Real-time BCI and neurofeedback
TTL trigger I/O and low-latency streaming support closed-loop applications and online paradigms.
Longitudinal Research

Beyond Isolated
Brain Measurements

Most neuroimaging systems are optimized for single laboratory sessions. Hive One was designed for the full scope of modern neuroscience: repeated measurements, real-world monitoring, longitudinal brain assessment, scalable cohort studies, and precision neurotechnology applications. The lightweight, comfortable design also makes HiveOne well-suited for pediatric neuroimaging, developmental neuroscience, and research with children of all ages.

The future of precision neuroscience will be driven by large-scale, longitudinal brain data across populations - from children to older adults. Hive One was built to help researchers collect it.

Repeated Sessions Longitudinal Session Consistency
All Ages Adults and Pediatric Research
Large Cohorts Scalable Study Design
Origin and Expertise

Developed at ETH Zurich

Hive One was developed by optohive, an ETH Zurich spin-off emerging from years of dedicated research in neuroscience, neuroengineering, and wearable technology at one of the world’s leading technical universities.

In close collaboration with the University Hospital Zurich, optohive has integrated clinical insights and translational neuroscience expertise directly into the design, testing, and validation of Hive One.

Core Expertise
  • Wearable neurotechnology and optical brain imaging
  • Neuroscience and cognitive brain research
  • Medical engineering and biomedical hardware design
  • AI, signal processing, and neuroscience software
  • Optical imaging systems and photonics
  • Translational medicine and clinical validation
*
Recognition Swiss Technology Award Winner
Swiss Technology Award Winner

See the Brain.
Change Brain Health.

Hive One combines superior signal quality, high-density neuroimaging, wearable usability, longitudinal monitoring, and multimodal integration into a next-generation platform designed for the future of neuroscience research and precision brain medicine. Recognized with the Swiss Technology Award for innovation that matters.

Talk to Our Team
Become an Early Research Partner