Cell signaling as a cognitive process

Related work— refs + corpus + external arXiv

Cited / in-corpus / arXiv badges show which signals surfaced each row. Multi-source rows weighted higher.

• Frequency-dependent Chemolocation and Chemotactic Target Selection

  Buddhapriya Chakrabarti, Tom Chou, Ajay Gopinathan Sarah A. Nowak

  2026
  ≈ 71%
• AI-driven control of bioelectric signalling for real-time topological reorganization of cells

  Gon\c{c}alo Hora de Carvalho

  2025
  ≈ 70%
• Neural Cellular Automata Can Respond to Signals

  James Stovold

  2024
  ≈ 69%
• Neural mechanisms of predictive processing: a collaborative community experiment through the OpenScope program

  Nicholas Audette, Ryszard Auksztulewicz, Krzysztof Basi\'nski, Andr\'e M. Bastos, Michael Berry, Andres Canales-Johnson, Hannah Choi, Claudia Clopath, Uri Cohen, Rui Ponte Costa, Roberto De Filippo, Roman Doronin, S\'everine Durand, Steven P. Errington, Jeffrey P. Gavornik, Colleen J. Gillon, Arno Granier, Jordan P. Hamm, Loreen Hert\"ag, Henry Kennedy, Sandeep Kumar, Alexander Ladd, Hugo Ladret, J\'er\^ome A. Lecoq, Alexander Maier, Patrick McCarthy, Jie Mei, Jorge Mejias, John Hongyu Meng, Fabian Mikulasch, Noga Mudrik, Farzaneh Najafi, Kevin Nejad, Hamed Nejat, Karim Oweiss, Mihai A. Petrovici, Viola Priesemann, Lucas Rudelt, Sarah Ruediger, Simone Russo, Alessandro Salatiello, Walter Senn, Eli Sennesh, Sepehr Sima, Cem Uran, Anna Vasilevskaya, Julien Vezoli, Martin Vinck, Xiao-Jing Wang, Jacob A. Westerberg, Katharina Wilmes, Yihan Sophy Xiong Ido Aizenbud

  2026
  ≈ 69%
• A minimal model of cognition based on oscillatory and current-based reinforcement processes

  Yu Tian, and David J.T. Sumpter Linn\'ea Gyllingberg

  2024
  ≈ 69%
• The biogenic approach to cognition

  in corpus

  2005
  ≈ 69%
• Simulating Tissue Morphogenesis and Signaling

  Simon Tanaka, Patrick Fried, Philipp Germann and Denis Menshykau Dagmar Iber

  2013
  ≈ 69%
• A predictive processing model of perception and action for self-other distinction

  Stefan Kopp Sebastian Kahl

  2018
  ≈ 69%
• The computational boundary of a 'self': developmental bioelectricity drives multicellularity and scale-free cognition

  in corpus

  2019
  ≈ 69%
• Exploring Cognition through Morphological Info-Computational Framework

  Gordana Dodig-Crnkovic

  2024
  ≈ 68%
• State-dependent brain responsiveness, from local circuits to the whole brain

  J Goldman, N. Tort-Colet, A. Roques, J. Fousek, S. Petkoski, V. Jirsa, O. David, M. Jedynak, C. Capone, C. De Luca, G. De Bonis, P.S. Paolucci, E. Mikulan, Pigorini, M Massimini, A. Galluzzi, A. Pazienti, M. Mattia, A. Arena, B. E. Juel, E. Hagen, J.F. Storm, E. Montagni, F. Resta, F. S. Pavone, A. L. Allegra Mascaro, A. Dwarakanath, T. I. Panagiotaropoulos, J. Senk, M. Diesmann, A. Camassa, L. Dalla Porta, A. Manasanch, M.V. Sanchez-Vives A. Destexhe

  2025
  ≈ 68%
• Cognition coming about: self-organisation and free-energy

  Maxwell Ramstead, Axel Constant, Karl Friston Ines Hipolito

  2020
  ≈ 68%
• The scaling of goals via homeostasis: an evolutionary simulation, experiment and analysis

  Johanna Bischof, Jennifer V. LaPalme, and Michael Levin Leo Pio-Lopez

  2022
  ≈ 68%
• Cognition spaces: natural, artificial, and hybrid

  Ricard Sol\'e and Luis F Seoane and Jordi Pla-Mauri and Michael Timothy Bennett and Michael E. Hochberg and Michael Levin

  2026
  ≈ 68%
• Proposal of Pattern Recognition as a necessary and sufficient Principle to Cognitive Science

  Gilberto de Paiva

  2011
  ≈ 68%
• Multiple ways to implement and infer sentience

  in corpus
  ≈ 68%
• Remapping and navigation of an embedding space via error minimization: a fundamental organizational principle of cognition in natural and artificial systems

  L\'eo Pio-Lopez, Chris Fields, Michael Levin Benedikt Hartl

  2026
  ≈ 68%
• Failures of Contingent Thinking

  Evan Piermont and Peio Zuazo-Garin

  2026
  ≈ 67%
• Collective intelligence: A unifying concept for integrating biology across scales and substrates

  in corpus

  2024
  ≈ 67%
• Stress Sharing as cognitive glue for collective intelligences: A computational model of Dukkha as a coordinator for Morphogenesis

  in corpus

  2024
  ≈ 67%
• Toward an ethics of autopoietic technology: Dukkha, care, and Intelligence

  in corpus

  2023
  ≈ 66%
• Developmental Bioelectricity: the cognitive glue enabling evolutionary scaling from physiology to mind

  in corpus

  2023
  ≈ 65%
• Stress sharing as cognitive glue for collective intelligences: A computational model of stress as a coordinator for morphogenesis

  in corpus

  2024
  ≈ 65%
• Technological Approach to Mind Everywhere: An Experimentally-Grounded Framework for Understanding Diverse Bodies and Minds

  in corpus

  2022
  ≈ 65%
• Cognitive glues are shared models of relative scarcities: the economics of collective intelligence

  in corpus

  2026
  ≈ 64%
• cimcWhitepaper

  in corpus
  ≈ 64%
• Endless forms most beautiful 2.0: teleonomy and the bioengineering of chimaeric and synthetic organisms

  in corpus

  2023
  ≈ 64%
• Brains and where else? Mapping theories of consciousness to unconventional embodiments

  in corpus

  2026
  ≈ 64%
• Darwin's agential materials: evolutionary implications of multiscale competency in developmental biology

  in corpus

  2023
  ≈ 63%
• Why Learning Requires Feeling

  in corpus

  2026
  ≈ 63%

Similar preprints — Semantic Scholar

Cited by (1)

• Collective intelligence: A unifying concept for integrating biology across scales and substrates

  Collective intelligence, understood as William James' capacity to reach the same goal by different means, operates not only in beehives and ant colonies but as a scale-free organizing principle across