The Biophysics of Regenerative Repair Suggests New Perspectives on Biological Causation

Supplement 1: Relationship between bioelectricity, biomechanics, and biochemical signaling in the control of anatomy

Dynamic control of complex anatomical pattern is a multi‐scale process that occurs during embryogenesis, regeneration, metamorphosis, remodeling, and cancer suppression. Individual cells and cell networks must coordinate their activity toward specific tissue‐ and organ‐level morphological outcomes. These processes take place through three integrated layers: 1) gene‐regulatory networks consisting of transcriptional circuits and diffusible biochemical signals, 2) physical forces – biomechanical processes by which tensions and stresses implement morphological computation, and 3) bioelectric networks – neural‐like dynamics in gap junction‐coupled tissues expressing ion channels and pumps. Each of these layers processes information and implements emergent complexity at cell, tissue, organ, and whole‐body axis levels. They are coupled via bi‐directional functional links, and all play unique, important roles in decision‐making and implementation of pattern control. In this way, physics, chemistry, and computer science interplay to enable biological systems to regulate their own structure and function with a high degree of adaptive robustness. Created by Ben Oldroyd (with support of the Templeton World Charity Foundation).