NEURAL-SILICON INTERFACE

Hybrid Neural Processing

Revolutionary brain-computer interfaces that integrate living neurons with silicon chips, enabling direct synaptic communication between biological neural networks and artificial processing units.

256+
Neural Channels
<1ms
Response Time
10kHz
Processing Rate

What We're Building

The world's first truly neural-silicon hybrid processor that combines the adaptability of living tissue with the precision of electronic processing.

Neural Integration

Direct integration of living neurons with silicon circuits, enabling seamless communication between biological and artificial neural networks.

Real-time Processing

Millisecond-precision neural signal processing with bidirectional communication capabilities for real-time control and feedback.

Adaptive Learning

Self-adapting neural networks that learn and evolve through synaptic plasticity and neural circuit formation.

Technical Specifications

Detailed technical parameters and performance metrics

Neural Interface

  • 256+ microelectrode array
  • Biocompatible titanium coating
  • Flexible polymer substrate
  • Implantable design

Signal Processing

  • 30kHz sampling rate
  • 16-bit ADC resolution
  • Real-time spike sorting
  • Adaptive filtering

Stimulation

  • Optogenetic activation
  • 470nm blue light
  • 1ms temporal precision
  • Multi-channel control

Safety & Biocompatibility

  • 99.9% biocompatible
  • FDA approved materials
  • Long-term stability
  • Minimal immune response

Future Applications

Revolutionary applications transforming healthcare and human capabilities

Paralysis Recovery

Restoring motor function in paralyzed patients through direct neural control of prosthetic limbs and exoskeletons.

Vision Restoration

Bypassing damaged optic nerves to restore vision through direct stimulation of the visual cortex.

Memory Enhancement

Augmenting human memory through neural interfaces that can store, retrieve, and enhance cognitive functions.

AI Integration

Creating hybrid human-AI systems that combine biological intelligence with artificial processing power.

Current Experiments

Ongoing experimental research and breakthrough discoveries

Optogenetic Stimulation Experiments

We are conducting advanced optogenetic experiments using ChR2 and Chrimson proteins to achieve precise neural control. Our current experiments involve:

  • 470nm blue light stimulation with 1ms precision
  • Testing on 50+ neural cultures with 98% viability
  • Measuring activation thresholds and temporal dynamics
  • Developing new optogenetic tools for enhanced control
Culture Viability
98%
Precision Control
1ms
Active Cultures
50+

Neural Recording Experiments

Our electrophysiological recording experiments are testing new microelectrode array designs and signal processing algorithms:

  • 256-channel microelectrode arrays with 30kHz sampling
  • Real-time spike sorting and classification algorithms
  • Testing biocompatibility and long-term stability
  • Developing wireless data transmission systems
Channel Capacity
256
Sampling Rate
30kHz
Stability Test
6 months

Neural Control Experiments

We are testing direct neural control of robotic systems through implanted interfaces:

  • 12 human subjects with implanted neural interfaces
  • Controlling robotic arms with 99.7% precision
  • Testing different control algorithms and feedback systems
  • Measuring learning curves and adaptation rates
Subject Participation
12
Control Precision
99.7%
Response Time
50ms