Quantum Biology: Expanding the Life Science Paradigm – Summary
Steen Hvass Ingwersen1 & Peter Alsted Pedersen2
Institute for Frontier Science, 6114 LaSalle Ave PMB 605, Oakland, CA 94611 USA
1Corresponding author: Steen H. Ingwersen, MSci, Quantum Healing Center, Ryesgade 27, 1. DK-2200 Copenhagen N, Denmark. steen.ingwersen@live.dk
2Retired: Peter Alsted Pedersen, PhD, Bagsværdvej 248, Blok 2, Lejl. 214, DK-2880 Bagsværd, Denmark. peteralsted.pedersen@gmail.com
Keywords: wireless; Wi-FiTM; radiofrequency; microwave; seed; sprout; pea; red clover; water structurizer; structured water
Submitted: July 11, 2025
Revised:November 21, 2025
Accepted: December 5, 2025
Published: April 24, 2026
Abstract
For many years, the life sciences remained unaffected by the quantum mechanical revolution of physics, partly due to the assumption that quantum effects cancel out in the environment within living cells. However, it has become clear that quantum phenomena are at play in biological processes such as photosynthesis and enzymatic catalysis, and quantum biology is now a well-established scientific discipline.
Here, we review selected experimental findings to suggest a broader scope for quantum biology than currently believed. This includes repeated demonstrations of biological effects of highly diluted substances as well as of electro-activation, a more recent method for the transfer of biological effects from a substance to a carrier. A separate discipline, biological transmutation, has demonstrated conversion of stable elements using highly selective analytical techniques. These findings further increase the necessity for abandoning the classical model of atoms and molecules as stable and solid entities, a model still used in chemistry and biology.
The accumulation of such phenomena poses a challenge to the current paradigm in life-science. This calls for adopting the quantum mechanical concepts on a broader scale in biology than done so far. Here, we propose key features of such a revised paradigm. We envisage that this will pave the way for the life sciences to break through some of their current conceptual barriers and to study unexpected phenomena such as those mentioned above. Moreover, new possibilities for prevention and treatment of disease are likely to emerge in the wake of such a paradigm change.