Holographic Criticality and High-Dimensional Biological Spacetimes: Synthesizing Large-D Gravity with Quantum Emulation
The enduring schism between the deterministic geometry of General Relativity and the probabilistic, non-local algebra of Quantum Mechanics—most notably illustrated by the Einstein-Podolsky-Rosen (EPR) paradox—represents a profound theoretical impasse. To resolve this fundamental paradox, this paper presents a novel ontological synthesis bridging the macroscopic mechanics of high-dimensional critical gravitational collapse with microscopic biological quantum emulation. By cross-validating the analytic discrete self-similar solutions of large-dimensional gravity with the Biological Spacetime and Resonant Manifold model, we demonstrate that biological systems act as holographic emulators that actively generate an internal spacetime metric. We establish that the Enteric Nervous System functions as a two-dimensional holographic boundary governed by Jackiw-Teitelboim gravity, wherein neurochemical concentration gradients physically instantiate the requisite dilaton field. Concurrently, the cerebral cortex executes active dimension selection through transient, high-variance beta bursts, which act as geometric integration functions to navigate this high-dimensional bulk.