A computer controlled device has developed to produce precise quantum electromagnetic beams that alter membrane potential of diseased cells and tissues, offering effective relief to patients suffering from various conditions.
QMR technology effectively blocks LPS/HA-activation of the NLRP3 inflammasome and decreases COX-2, iNOS, and IL-1b protein expression and secretion in macrophage THP-1 cells.
Inflammation
MR technology’s fundamental principles rely on magnetic resonance, a quantum mechanical effect caused when an exposed quantum system interacts with an electromagnetic field. Magnetic interactions among particles within this quantum system cause electromagnetic waves within it to vibrate in response, creating a vibration within an electromagnetic wave which has no classical equivalent but instead can be measured with electronic equipment.
Vibrations of electromagnetic waves can also be used to detect changes in physical quantities such as temperature or pressure in a system, using electronic methods like EPR (electron paramagnetic resonance) or nuclear magnetic resonance (NMR). This principle resembles Larmor precession of electrons within an atom without energy exchange between particles; instead it relies on magnetic interactions induced by unpaired electron spin angular momentum that exists across matter – something Larmor precession cannot.
QMR therapy may reduce inflammation by stimulating cell production of ATP – an essential energy molecule involved in many cell processes such as stress responses and inflammation reactions. QMR therapies may increase production by improving mitochondrial function or increasing oxidative phosphorylation.
Recent research has demonstrated how QMR treatment effectively restrains LPS/HA-induced activation of the NLRP3 inflammasome in THP-1 differentiated macrophage cells by blocking COX-2 and iNOS protein expression, as well as decreasing NF-kB activity and peroxynitrite levels. Furthermore, QMR treatment significantly decreased secretion of proinflammatory cytokines such as IL-18 and IL-1b by LPS/HA treated macrophages.
Though the results of this study were encouraging, researchers only focused on a limited set of inflammatory markers and pathways. Future research should explore more anti-inflammatory stimuli and cell types to further comprehend QMR therapy’s anti-inflammatory benefits; but it remains clear that this innovative treatment could prove helpful in both the prevention and treatment of osteoarthritis (OA).
Pain
Quantum magnetic resonance therapy (QMRT) is an effective anti-inflammatory that can significantly ease pain associated with osteoarthritis (OA). QMRT works through interactions between electromagnetic fields and water molecules in cells; the latter serve to transmit electromagnetic signals while at the same time acting as carriers for other substances, including drugs or hormones.
RFQMR beams can generate voltage potentials that force hydrogen protons into tissue’s extracellular matrix, stimulating chondrocytes to secrete lubricating fluid that enhances joint elasticity and hydration – helping relieve pain considerably. Furthermore, electromagnets in these devices emit low-frequency electromagnetic fields which stimulate nerves into producing natural painkillers such as endorphins.
One study reported on a patient suffering from an anaplastic astrocytoma who saw considerable improvements after receiving four weeks of quantum magnetic resonance therapy for this condition. His tumor shrunk, no longer appearing on MRI scans and allowed him to move his head and neck without discomfort while speaking clearly without discomfort despite previous surgery and chemotherapy treatments. The treatment proved successful despite prior attempts.
This research marks the first demonstration that quantum magnetic resonance technology (QMR) can directly modify macrophage polarization toward anti-inflammatory M2 phenotype in living tissue in real time, supporting the theory that QMR can act as an adjunctive therapy against inflammation-related diseases by targeting cell polarization.
A patented device known as the Cytotron delivers rotating, target-specific radio frequencies at safe frequencies that penetrate deep into tissues and cells of the body. These frequencies are much lower than those found in cell phones or microwave ovens and therefore allow deeper penetration.
This device uses advanced electronic equipment to collect the weak magnetic field generated by an individual’s body, then analyzes this data. Using this information, doctors can assess their health status and any main problems they are having while also offering standard preventative advice. Based on quantum medicine principles – an emerging high-tech field combining medical science, bioinformatics, and electronic engineering.
Bone Remodeling
Electromagnetic fields have the power to change the structures and functions of cells and tissues in ways that have far-reaching implications for health. Pulsed magnetic fields, for instance, can quickly restart bone fracture healing that had become resistant. PEMF therapy, in turn, has been found to relieve osteoarthritis pain effectively while those same frequencies can also be found used by Reiki therapists for producing electromagnetic fields with optimal frequency ranges for stimulating tissue and bone healing.
RFQMR is an advanced technology that uses complex electromagnetic beam patterns in the sub-radio and near radio frequency spectrum, to precisely target tissues such as bones and cartilage with complex quantum electromagnetic beam patterns. By altering QMR spin in hydrogen atoms, this creates a streaming voltage potential flow through joints by forcing protons through extracellular matrix due to altered quantum magnetic resonance spin properties in them; stimulating chondrocytes located there.
This process, similar to how gravity and acceleration stress bones in knees to promote bone growth, can reduce arthritic inflammation by modulating its response and also slow the progression of osteoarthritis by encouraging cartilage production while slowing its degradation.
Arthritic symptoms arise due to energy being depleted from bones and cartilage structures, typically as the result of disrupted water-electromagnetism resonance systems; specifically these resonance systems are blocked by electromagnetic fields generated by Earth, its satellites and Schumann resonance; when someone ventures beyond earth orbit and loses this natural resonance it depletes massive amounts of energy across bones, organs and other tissues at an alarmingly rapid rate.
Robert Becker demonstrated through extensive experiments conducted during the 1950’s that bones contain an intrinsic electron current which allows their regeneration. He discovered this current made proteins which make up bone align properly while simultaneously stimulating calcium deposits into it to strengthen it further. Furthermore, this piezoelectric current was powered by semiconduction which then allowed bones to regenerate themselves.
Anti-Inflammatory Effects
Inflammation plays an essential role in osteoarthritis, the leading cause of pain and disability among older adults. While traditional treatments have shown little efficacy for this condition, often leaving many patients only one option available: joint replacement surgery. QMR therapy has the potential to dramatically enhance quality of life for such patients by targeting sources of inflammation directly as well as initiating healing processes that could alleviate symptoms.
Rotational Field Quantum Magnetic Resonance (RFQMR) is a non-ionising and non-thermal quantum electromagnetic beam pattern which has been shown to modulate cell membrane potential and downstream signaling in an accurate manner, and induce regenerative processes in knee cartilage articular cartilage.
Cytotron, a patented computer-controlled device capable of emitting RFQMR beams at any desired site in the body, enables doctors to target RFQMR beams at specific areas in need. Generated using 96 specially designed Mn-Pb-Cu guns, they have been shown to alter ionic and electronic properties within cells which ultimately change selective permeability.
Published recently are the findings from an in vitro study evaluating the effect of RFQMR on human macrophage THP-1 cells. According to this in vitro research study, QMR exposure decreased expression and secretion of proinflammatory mediators such as IL-1, IL-18 and TNF-, as well as inhibited activation of the NLRP3 inflammasome in these cells. Additionally, exposure increased ATP production while decreasing levels of oxidative stress within these cells.
This work represents a vital step towards understanding how biophysical vulnerabilities of solid tumors can be exploited to effectively treat and palliate cancer. Targeting biological signals without altering normal tissue function is key to moving beyond chemotherapy-based cancer treatments and increasing overall survival for terminally ill cancer patients. This approach to cancer care is founded on the idea that cancer cells rely heavily on biophysical signals produced by gravitational, thermal, chemical and mechanical stresses; by exploiting these vulnerabilities with innovative therapies such as QMRT it should become possible to create more effective cancer therapies.