Quantum Bio-Computing to Achieve AGI and Cure Disease
Pioneering the convergence of computing and biological systems to unlock artificial general intelligence
and revolutionize medical treatment. Our groundbreaking research combines advanced brain modeling, quantum mechanics,
and space-based research to push the boundaries of what’s possible
Quantum Bio-Computing to Achieve AGI and Cure Disease
Our Mission
We believe the path to artificial general intelligence lies at the intersection of quantum physics and biological computation. By understanding how the brain processes information at the quantum level, we can develop revolutionary treatments for neurological diseases while advancing toward true artificial intelligence.
Biocomputer Applications
Our multidisciplinary approach spans multiple domains
Modeling the Brain
Learning Optimization
Cognitive Enhancement
Drug Interaction Modeling
Bio-sensing
Battlefield Information Processing
Human Behavior
Financial Markets
Social Networks
Viral Behaviors
Wisdom of Crowds
Human Skills
Single Shot Learning
Friend/Foe Detection
Deception and phishing detection
Robotics – real world navigation
Aesthetic Judgement
Quantum Modeling
Modeling Chemistry
Modeling Biology
Cryptography
Modeling the Brain
Learning Optimization
Cognitive Enhancement
Drug Interaction Modeling
Bio-sensing
Battlefield Information Processing
Human Behavior
Financial Markets
Social Networks
Viral Behaviors
Wisdom of Crowds
Human Skills
Single Shot Learning
Friend/Foe Detection
Deception and phishing detection
Robotics – real world navigation
Aesthetic Judgement
Quantum Modeling
Modeling Chemistry
Modeling Biology
Cryptography
Large Brain Model: BaaS
Remote access to next gen computing
Large Brain Mobel: BaaS
Remote access to next gen computing
Innovation Stories
Reconstructing the Human
Brain in the Lab
Manned Space Mission
Manned Space Mission to
Study Brain Disease and Treatments
Why is Space Important?
Accelerated Aging
Condense decades of cellular changes into weeks, making it possible to study late-onset conditions like Alzheimer’s and Parkinson’s in dramatically shorter timeframes.
Enhanced Disease Modeling
Organoids mature faster in microgravity and show disease symptoms more clearly, improving drug testing accuracy and revealing new insights into disease origins.
Unique Brain Development Insights
Discover how gravity affects cell movement, synapse formation, and neural connections, providing new understanding of developmental disorders like autism.
Personalized Medicine
Screen thousands of drugs and doses using patient-specific cells to predict individual responses before lengthy clinical trials.
Why is Space Important?
Accelerated Aging
Condense decades of cellular changes into weeks, making it possible to study late-onset conditions like Alzheimer’s and Parkinson’s in dramatically shorter timeframes.
Enhanced Disease Modeling
Organoids mature faster in microgravity and show disease symptoms more clearly, improving drug testing accuracy and revealing new insights into disease origins.
Unique Brain Development Insights
Discover how gravity affects cell movement, synapse formation, and neural connections, providing new understanding of developmental disorders like autism.
Personalized Medicine
Screen thousands of drugs and doses using patient-specific cells to predict individual responses before lengthy clinical trials.
Latest Research
Orchestrated Objective Reduction (Orch OR)
Objective Reduction of the Wave Function Demonstrated on Superconducting Quantum Computer
James Tagg, William Reid
We describe an experiment using superconducting transmon qubits that demonstrates wavefunction collapse consistent with Orchestrated Objective Reduction (Orch-OR)
Schrödinger’s Cheshire Cat: A tabletop experiment to measure the Diósi-Penrose collapse time and demonstrate Objective Reduction (OR)
James Tagg, William Reid, Daniel Carlin
We propose a table-top experiment to put two small mirrors into superposition and observe them collapse in a time consistent with the Diósi-Penrose model.
Quantum Biology
Entangled biphoton generation in the myelin sheath
Zefei Liu, Yong-Cong Chen, and Ping Ao
In this study we employ cavity quantum electrodynamics to explore entangled biphoton generation through cascade emission in the vibration spectrum of C-H bonds within the lipid molecules’ tails.
Ultraviolet Superradiance from Mega-Networks of Tryptophan in Biological Architectures
N. S. Babcock, G. Montes-Cabrera, K. E. Oberhofer, M. Chergui, G. L. Celardo, P. Kurian
We analyze the cooperative effects induced by ultraviolet (UV) excitation of several biologically relevant Trp mega-networks, thus giving insights into novel mechanisms for cellular signaling and control.
The FitzHugh-Nagumo equations and quantum noise
Partha Ghose, Dimitris A. Pinotsis
It is unclear whether quantum phenomena can be observed in brain recordings because of thermal noise causing decoherence, that is, quantum superpositions and entanglement quickly collapsing into classical, i.e. non-quantum states.
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