Plasticity Without Genetic Change - Bioelectric Embryos & Synthetic Proto-Organisms

Plasticity Without Genetic Change - Bioelectric Embryos & Synthetic Proto-Organisms

Institute for Pure & Applied Mathematics (IPAM) via YouTube Direct link

Cell Collectives can pursue Target Morphologies other than their Genomic Default

14 of 17

14 of 17

Cell Collectives can pursue Target Morphologies other than their Genomic Default

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Plasticity Without Genetic Change - Bioelectric Embryos & Synthetic Proto-Organisms

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  1. 1 Intro
  2. 2 Knowledge Gaps: prediction
  3. 3 The State of the Art
  4. 4 Where is Anatomical Pattern Specified?
  5. 5 Same anatomy, despite perturbations
  6. 6 Somatic electrical activity is the cognitive medium of morphogenetic decision-making
  7. 7 Writing High-level Setpoints into Cellular CI
  8. 8 Endogenous membrane voltage pattern is crucial for Xenopus embryonic brain patterning
  9. 9 Re-writing Target Morphology
  10. 10 Bioelectrically-Encoded Pattern Memory
  11. 11 An organism's genome sets its Target Morphology, doesn't it?
  12. 12 Developing Quantitative, Predictive Multiscale
  13. 13 Machine Learning for Model Discovery
  14. 14 Cell Collectives can pursue Target Morphologies other than their Genomic Default
  15. 15 Biomedical Applications
  16. 16 Synthetic Morphology: probing the creativity of cellular collective intelligence
  17. 17 Xenobots - a novel proto-organism

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