Abstract

DNA is formed by the joining of quantum particles like electrons and charged atoms. DNA has different motions during transcription, translation, and replication, in which the charged particles move, accelerate, and emit waves. Thus, DNA could emit quantum waves which have many applications in biology.

The capacity of some bacterial DNA sequences to induce electromagnetic waves at high aqueous dilutions was detected. It appears to be a resonance phenomenon triggered by the ambient electromagnetic background of very low frequency waves. The genomic DNA of most pathogenic bacteria contains specific sequences which are able to generate such signals. According to the laws of physics, the motion of electrical charges produces a magnetic field and results in the emission of electromagnetic waves. Thus, each DNA can radiate various types of waves depending on the nature of its interaction with biological material like DNA and RNA.

The dark DNA” or “dark genome” is informally used to describe parts of an organism’s DNA and these regions turn out to be unique to a pathogen, they could be used as novel diagnostic markers in the future. This opens the way to the development of highly sensitive detection system for chronic bacterial infections in human and animal diseases. Our research is focused in the “black” or unknown sequences to discover new virulence factors, find new drug targets understand resistance mechanisms and these could eventually lead to new antibiotics or vaccine targets, though this is more research-focused than clinical right now. In this research, we have shown that DNA waves play major roles in the biological systems. We propose models for imaging by using concepts of quantum biology and DNA waves for detection. The models are useful in charting bacterial growth and treatment.