Biological Quantum Gravitational State Transfer (BQGST): A Unified Theoretical Framework for Macroscopic Quantum Teleportation via Gravitational Field Entanglement and Biological Quantum Substrates

We present Biological Quantum Gravitational State Transfer (BQGST), a unified theoretical framework proposing a mechanism for macroscopic quantum teleportation exploiting the intersection of quantum gravity, quantum biology, and quantum information theory. The framework identifies biological systems — specifically microtubules, DNA, cryptochrome proteins, and biophoton emission networks — as naturally evolved quantum gravitational interfaces capable of encoding, transmitting, and reconstructing the complete quantum information pattern of an organism via superposed gravitational fields and entangled spacetime topology. Drawing on Penrose-Hameroff Orchestrated Objective Reduction (Orch-OR), the ER=EPR conjecture (Maldacena & Susskind 2013), the Bekenstein-Hawking holographic entropy bound, and the Bose-Marletto-Vedral (BMV) gravitational entanglement mechanism, BQGST proposes a five-stage transfer protocol. The central contribution is a reframing of the scaling problem: rather than maintaining 10²7 individual atomic quantum states, BQGST encodes and transmits a gravitational information geometry derived from the holographic boundary data of the biological system — reducing the information-theoretic complexity from volumetric to surface-area scaling. Four experimentally testable predictions are presented alongside a formal mathematical treatment of each framework stage.