Currently, the @arduino platform serves as the primary interface for converting fungal bioelectric signals into robotic movements. Research is ongoing, and Arduino’s expanding ecosystem continues to make scientific experiments more accessible.

4/ Predictive Behaviors AI predicts fungal responses and optimizes robot actions. 5/ Multi-Sensory Integration AI combines fungal signals with other sensory data. 6/ Long-Term Stability AI monitors fungal health and adjusts robot functions.

We agree that funding scientific research has challenges. We're exploring different paths to achieve our goals and see crypto as a potential part of the solution.

The B.O.R.G.’s research focuses on the use of organic materials as structures, actuators, sensors, and controllers toward the development of bioinspired, biodegradable, and biohybrid robotics. Watch the recent video with Victoria Webster-Wood:

Fungi can be grown in space and used for robotic assembly. Their integration into extraterrestrial missions is inevitable. We are sure that sooner or later, @elonmusk will mention fungi biohybrid robots in a SpaceX report.

Excited to partner with @RobotNext to make biohybrid robots * the next thing * 🚀 It's time to blur the lines between biology and machines. We’re here to push innovation in space exploration, robotics, and science. The future is adaptive, and it’s just beginning.

Fungi are highly sensitive to UV light. When exposed, their electrical activity spikes, making the robot move faster. What if light could be used as a command? By triggering fungal signals, UV dynamically changes the robot’s direction in real time.

Most robots leave waste behind. Biohybrid designs don’t. Unlike traditional machines, they are fully biodegradable and minimize environmental impact. When their lifecycle ends, fungal structures can simply be composted. They return to nature instead of polluting it.

Fungal Biohybrids for Space Exploration Mycelium thrives in radiation-heavy, nutrient-poor environments, making it ideal for extraterrestrial missions. Cultivating fungi in space enables on-site biohybrid robot production for exploration and monitoring.

Unlocking organic-inorganic interactions is essential for stable Fungal Computer Interfaces.

Watch a real-time demo of the mycelium-controlled wheeled robot 📽️ UV light triggers fungal signals, which are converted into movement commands, making the robot react dynamically to its environment.

Biohybrid robots fuse biological systems with synthetic materials, leveraging natural intelligence for new forms of adaptation and control. This approach redefines robotics by exploring self-repair, decentralized processing, and sustainable design inspired by living organisms.

Neurofungi research keeps making waves, featured in over 1,000 news portals and scientific blogs. Read the new article here:

We’re excited to announce that @aihanso has joined our team as an adviser to help expand the influence of the Neurofungi project’s ideas 🤝 More updates coming soon.

9/ By merging biological and synthetic intelligence, fungal biohybrids could shape the next generation of robotics, evolving alongside the changing world. The future is adaptive, decentralized, and alive.