We propose a new theoretical framework—Quantum Mechanomorphics—describing systems in which quantum coherent states in biological protein complexes drive cascaded conformational signaling across an engineered lattice scaffold. Drawing from three converging fields—quantum biology (radical-pair mechanisms in cryptochromes), DNA-origami structural nanotechnology, and mechanoprotein dynamics—we theorize a BioQuantum Neural Lattice (BQNL): a three-dimensional face-centered cubic array of cryptochrome-derived protein nodes embedded in a DNA-origami scaffold, in which spin-selective electron transfer events propagate conformational change across coupled nodes. We present the theoretical basis for Q-wave propagation, analyze decoherence constraints, identify five critical experimental tests of the framework, and propose a research roadmap. This work establishes a new interdisciplinary field at the intersection of quantum biology, structural nanotechnology, and neuromorphic materials science.
Sajjan Kumar (Sun,) studied this question.