Nine active research programs across neuroscience, cognitive computing, and digital ethics — pushing the boundaries of what is scientifically and ethically possible.
Multi-photon scanning protocols enabling lossless neural architecture reconstruction at 4nm resolution. Currently the world's highest-fidelity in-vivo mapping methodology.
Theoretical and experimental framework for migrating experiential continuity from biological to synthetic substrates. Involves quantum-coherent memory encoding architectures.
Legal and philosophical analysis of identity, continuity, and rights for digitally preserved consciousness. Published in collaboration with Geneva Law Faculty.
Encoding, indexing, and retrieval of episodic and semantic memory structures within synthetic neural matrices. Aims to achieve 99.8% fidelity on recall benchmarks.
Bidirectional communication channels between biological and computational cognitive systems. Focus on bandwidth, latency, and semantic fidelity.
Investigating subjective experience during and after substrate migration. Longitudinal monitoring of identity coherence metrics across transfer events.
Developing redundancy and parity mechanisms for biological data integrity. Addresses signal degradation and noise accumulation during extended storage cycles.
Containment and security architecture for digitized cognitive systems. Defines access boundaries, interaction constraints, and emergence detection procedures.
Access to this research program requires Level 4 clearance and a signed NDA. Contact the administration for eligibility criteria.
Across Nature, Cell, PNAS, Journal of Neuroscience and 40+ other journals.