Epistemology / Research - By: (Me) Nicholas Ellis @ www.youtube.com/sn1pe352
• Nikola Tesla -- discovered in 1895, alternating current, and invented the AC generator, has published many papers and invented manyelectrical equipment, including Tesla coil therapeutic tools.
• Alexander Gurwitsch discovered -- in 1922 "biophotons" and "mitogenic" mitosis "waves. His work is the first documented evidence of" bio-photons, and became the basis for the design of future bioelectromagnetic therapy devices.
• Georges Lakhovsky -- in 1925 invented the multi-wave oscillator, a broad range of electrical frequencies that balance back in the cell producesBody, and a paper published heal "News Radio" magazine, entitled "Cancer of ultra radio frequencies."
• Royal Raymond Rife -- in the 1930s showed how can its frequency research and mitogenic impulse-wave technology (in the public domain) to cure cancer.
• Ed Skilling -- 1950's breakthrough discoveries with space-age electronics, transmission and communication with the cells and the immune system of the body; results supercedesall previous electro-medicine technologies.
While examining bacteria and viruses, Dr.Royal Raymond Rife - Nikola Tesla , Walter Russell noticed that (Atoms - DNA RNA - CELLS - Biochemicals - Water Molecules) gave off a distinct light (or color) pattern. (In the late sixties it was discovered that every living cell actually gives off light and the healthier the cell the healthier the light; conversely the sicker the cell the weaker the light. But this research by Rife was done in the twenties using technology Rife himself invented.) So Rife began to experiment with instruments he invented that oscillated at the frequencies he'd determined from the organisms (bacteria and viruses) and he discovered that by playing back their own pattern of oscillation, slightly modified, he could destroy them without affecting the tissues around them. In other words, Rife could kill a particular virus or bacterium using light rays alone, light rays that were absolutely harmless to the host animal, but deadly to the microbe.
The power of light microscopes to resolve fine details has just doubled. A new technique can distinguish tiny structures inside cells, in colour and 3D, even if they are only 100 nanometres apart.
"We have opened a door to a whole new world of structures that you could not see and study before," says Heinrich Leonhardt of the Center for Integrated Protein Science at the Ludwig Maximilians University in Munich, Germany.
The resolution achievable with light microscopy - the diffraction limit - is normally restricted to about half the wavelength of visible light, around 200 nanometres. If two objects are closer together than this, they cannot be distinguished from each other and appear as one structure.
Electron microscopy, which uses much shorter wavelengths, can visualise smaller details, but is limited to black and white images and thin or very small specimens.
Now Leonhardt's team, along with John Sedat and colleagues at the University of California in San Francisco, US, have found a new trick to push past the diffraction limit.
Structured light
Shining structured patterns of light on specimens creates an interference pattern cast by the tiniest fine structures of the sample. This can be used to extract information about their shapes even if they cannot be visualised directly.
"It's similar to what happens when you try to scan in a printed photo," explains Leonhardt. "Your eye does not resolve the very fine colour dots on the paper, but the scanner does, and to your disappointment you see waves or shadows across the scanned image."
But these interference patterns actually contain valuable information, Leonhardt realised. "With some maths and good computers we can use this to reconstruct the image," he says.
Glowing DNA
The researchers created high-resolution views of fixed mouse cells, which had been stained with three different fluorescent colours. These labelled the DNA, the nuclear envelope and the pores through which molecules are transported into and out of the nucleus.
The new approach might make it possible to study in much greater detail how chromosomes and other subcellular components are structured in space. It could also distinguish DNA regions with active genes from those with inactive genes - an important step for understand ageing and many diseases.
Volker Westphal at the Max Planck Institute for Biophysical Chemistry in Göttingen, Germany, says the new technique is promising: "Others, including our group, have broken the diffraction limit before and we can now image structures as small as 40 nanometers in 3D and even in live cells, but this work is exciting because it creates excellent images of complex subcellular structures and permits biologists to make use of the full range of fluorescent colours they like to use".
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"In looking at the various environmental issues we are faced with, and the tasks that we need to fulfill for the planet, if we could get more than 10 percent of the people consciously aware, than I believe we could pull the 80 percent in that direction, too."-Dr.Masaru Emoto
sn1pe352 8 months ago