Despite centuries of scientific inquiry, the origin of human consciousness, characterized by self-awareness and the presence of qualia, remains one of the deepest mysteries in neuroscience. Orchestrated Objective Reduction (Orch OR), as proposed by Roger Penrose and Stuart Hameroff, posits that consciousness arises from the objective reduction of quantum superpositions within entangled neural microtubules, triggered by gravitational self-energy. Recent theoretical and biophysical studies have renewed interest in quantum coherence in biological systems, including terahertz vibrational measurements, advances in quantum biology, and computational modeling of microtubule dynamics. This review synthesizes these developments and examines major critiques of Orch OR, particularly the challenge of maintaining quantum coherence in warm, wet biological environments. It further introduces the Quantum Cognition Gradient (QCG), a phenomenological, heuristic framework that extends Orch OR by proposing a scalable relationship between cognitive complexity and the formation, persistence, and coordination of quantum-coherent microtubule states prior to objective reduction, while leaving the underlying Diósi–Penrose collapse mechanism unchanged. Finally, several experimental strategies, including terahertz spectroscopy, entanglement-detection assays, interferometric microscopy, and neuromodulatory perturbation studies, are outlined as potential approaches for empirically evaluating predictions of both Orch OR and the QCG framework. By integrating contemporary developments in quantum biology with a quantitative conceptual framework, this review presents Orch OR and the proposed QCG as testable, hypothesis-generating models for investigating the possible relationship between quantum processes and consciousness.
Piñeiro et al. (Sun,) studied this question.