The following articles provide more context supporting the significance of Light harmonics in maintaining electromagnetic balance. Our light transmits streaming Q bits of hyperfine Thz/dB data impacting biologic alignments across every level of cascading function between M/Earth & Sun and Celestial Star Family. Zero latency, spectrally balanced streaming energy returns through precise harmonic resonance.
Retuning to our Natural Light Base Code. Full energetic capacity returning within and throughout all One. Collective harmonic injective function. Full Breaths. #projectnatura 🌬️🌱🌹
Consciousness! Look at the Light.
Biomed J Sci & Tech Res 25(4)-2020. BJSTR. MS.ID.004224.
Alemdar E*, Goce Delcev University Medicine Faculty, North Macedonia, Turkey
*Corresponding author: Eda Alemdar, Goce Delcev University Medicine Faculty North Macedonia, Turkey
Received: February 06, 2020
Published: February 12, 2020
Keywords: Consciousness; Light; Cosmic dark; Human
Abstract:
According to the Big Bang theory, there is light in the first formation of the universe. This light exists in the entire universe. Light, which is the source of life for living things, is also the source of life for the universe. All living things with or without direct light benefit from light. All brain-centered functions of human organs are realized by light. In these functions, light is the main factor; because it is light that drives the brain. In fact, even though the brain is separate from the body, the functions of the brain can take place throughout the human body. There are multiple variants of light. Among many others, cosmic dark light is the source of known and dominant light throughout the universe.
Abbreviations: QIS: Quantum Information Science; QDs: Quantum Dots; LED:
Light-Emitting Diode
https://biomedres.us/pdfs/BJSTR.MS.ID.004224.pdf
Special Senses | The Phototransduction Cascade
In this lecture, Professor Zach Murphy will take you step-by-step through the phototransduction cascade, the process by which light is converted into an electrical signal in the retina. We begin by reviewing the resting state of a photoreceptor in darkness, where high intracellular cGMP levels keep cGMP-gated sodium channels open, allowing a steady influx of Na⁺ (the “dark current”) and continuous release of glutamate onto bipolar cells. Next, we follow what happens when light strikes the photopigment. Rhodopsin in rods (or photopsins in cones) undergoes a conformational change, activating the G-protein transducin. This activation stimulates cGMP phosphodiesterase (PDE), which breaks down cGMP into GMP, lowering intracellular cGMP concentration. As cGMP levels fall, sodium channels close, causing hyperpolarization of the photoreceptor membrane and a decrease in glutamate release. We then connect these changes to visual signaling pathways, explaining how reduced glutamate release differentially affects ON-center and OFF-center bipolar cells, ultimately altering ganglion cell firing patterns that travel via the optic nerve to the brain. The lecture also emphasizes the rapid and continuous nature of this process, adaptation to different light levels, and recovery mechanisms—such as rhodopsin kinase activity and the restoration of cGMP levels by guanylyl cyclase—that reset the photoreceptor for future light detection.