Biology uses a multi-scale competency architecture of hierarchical problem solvers in various problem spaces that evolution and parasites can exploit.
Bioelectrical networks are a major medium through which cells collectively process information, and are ancestors of the nervous system.
Cells have the ability to solve local goals and navigate morphological spaces without a brain or nervous system.
Cells have the ability to adapt and solve problems they’ve never encountered before through navigating the large space of gene expression.
There is a physiological software layer between the genome and anatomy that determines anatomical structures and regeneration.
Cells can reach the same anatomical goal through different developmental paths, using different molecular mechanisms.
Cells can store and rewrite anatomical memories that determine regeneration and morphology.
Bioelectrical patterns can specify organ formation and regeneration at a high level, leveraging the intelligence of the tissue.
Simple bioelectrical interventions can rescue drastic hardware defects by overriding them with high-level signals.
Even simple skin cells have the latent capacity for novel morphogenetic and behavioral capabilities when freed from external constraints.
https://www.youtube.com/watch?v=7SwIQEEmIp4
Biology uses a multi-scale competency architecture of hierarchical problem solvers in various problem spaces that evolution and parasites can exploit.
Bioelectrical networks are a major medium through which cells collectively process information, and are ancestors of the nervous system.
Cells have the ability to solve local goals and navigate morphological spaces without a brain or nervous system.
Cells have the ability to adapt and solve problems they’ve never encountered before through navigating the large space of gene expression.
There is a physiological software layer between the genome and anatomy that determines anatomical structures and regeneration.
Cells can reach the same anatomical goal through different developmental paths, using different molecular mechanisms.
Cells can store and rewrite anatomical memories that determine regeneration and morphology.
Bioelectrical patterns can specify organ formation and regeneration at a high level, leveraging the intelligence of the tissue.
Simple bioelectrical interventions can rescue drastic hardware defects by overriding them with high-level signals.
Even simple skin cells have the latent capacity for novel morphogenetic and behavioral capabilities when freed from external constraints.
https://www.youtube.com/watch?v=7SwIQEEmIp4