Radionics, an non-invasive complementary alternative approach, focuses on energy healing and balance through specific rates to analyze your energy field, while exploring energy balance or imbalance with quantum rates and vibrations.
TimeWaver facilitates physical communication with this information field to allow analysis and optimization according to Burkhard Heim’s mediating point theory of radionics. TimeWaver serves as the perfect solution to enable radionics principles.
Optical Biosensors
Optic biosensors offer new analytical tools that are smaller and faster than traditional electrochemical or mechanical methods, providing opportunities for the detection of viruses, toxins, drugs, antibodies, tumour biomarkers as well as surface enhanced Raman scattering biosensors. With optical biosensors’ development comes new analytical tools with greater sensitivity in sensing a range of analytes such as viruses, toxins, drugs, antibodies or tumour biomarkers using techniques such as surface plasmon resonance (SPR), evanescent wave fluorescence bioluminescent optical fiber as well as interferometric, ellipsometric interference spectroscopy and surface enhanced Raman scattering biosensors.
Optic biosensors are sensitive tools capable of measuring interactions between molecules with great precision, unlike labeling techniques which require adding labels that alter physicochemical properties or introduce systematic error. An example of an optical biosensor would be the handheld glucose meter which detects changes in electrical current when immersed in blood, providing an instant readout of glucose levels.
Optic biosensors offer another significant application in environmental monitoring – the detection of environmental pollutants. To do this, enzymes which recognize specific molecules such as pesticides in water are detected using enzymes called acetylcholinesterase, while dehalogenases detect halogenated pollutants while acid phosphatase detects heavy metals – all simultaneously with much higher sensitivity than traditional chromatographic techniques.
Recently, optical biosensors incorporating various technologies have been created to detect endocrine disrupting substances in water samples. SERS biosensors utilize molecular interactions between molecules and SERS-active surfaces such as nanoroughened metallic surfaces or gold-coated optical fibre tips, in order to increase vibrational frequencies by several orders of magnitude and enable detection down to the nanogram L-1 range. Long-period fiber grating immunosensors were also created to detect E. coli bacteria in tap water at an LOD of 5×102 CFU/mL; such biosensors can be easily integrated into portable biosensor systems for use in remote areas and developing countries, potentially saving lives with this device.
Quantum Resonators
Researchers have developed an experimental platform that allows them to precisely control how two quantum resonators interact without incurring increased signal loss. Their unique design compresses millimeter-wave signals into a two-dimensional waveguide and directs where energy from each resonator travels, giving researchers control over when and how energy travels between resonators – creating entangled resonators that communicate across distances, showing “spooky action at a distance.”
This discovery could have profound ramifications for quantum computing, enabling mechanical resonators to be read out in longer-lived states than their current short-lived counterparts. This could reduce redundancies needed in quantum algorithms and increase security while decreasing error rates.
One of the primary obstacles in creating these devices has been addressing the low Duffing constant value, which allows thermal fluctuations to dominate resonator nonlinearity at temperatures far from quantum regime. Previous efforts attempted to increase nonlinearity by applying force fields or coupling two-level systems. Our new architecture addresses these barriers using a superconducting fluxonium qubit to selectively couple and decouple mechanical resonators.
Resonators can be chilled to their quantum ground state, where vibrations are tightly contained, to enable novel applications such as quantum squeezing of mechanical motion1,2,3, backaction-evading measurements4,5, and entanglement between mechanical resonators6. In some instances, nonclassical superpositions of coherent mechanical states – known as Schrodinger cat states – may also offer enhanced quantum sensing capabilities.
Scientists at the University of Innsbruck and ETH Zurich recently conducted a joint research effort, wherein superconducting fluxonium quantum bits were used to entangle two mechanical resonators using superconducting fluxonium quantum bits instead of traditional transmon qubits for reading out microwave resonators. Instead of employing transmon qubits for reading microwave resonators, this experiment used more sensitive quantum sensors known as fluxonium qubits instead.
Quantum radionics is an alternative form of energy medicine that employs specific frequencies and vibrations to identify an individual’s energy balance and imbalance, rather than offering conventional diagnosis. Instead of offering treatment plans through conventional means, quantum radionics explores individual energy imbalances while offering guidance to improve them with special radionic equipment.
Multiplexed Detection
Multiplexing enhances the amount of information gained from samples by simultaneously analysing multiple targets, providing more accurate diagnostics, reduced sample and reagent requirements, and lower processing costs. Multiplexing is particularly relevant to infectious disease diagnostics where new pathogens present significant challenges; current available methods only detect one target at a time which limits effectiveness against diseases like SARS-CoV-2 and influenza. Symptom-sharing infections could also be misdiagnosed or misclassified leading to unnecessary treatments or an increase risk.
Current technologies for detecting multiple targets using one sample include optical24 and electrochemical22 detection systems, although their multiplexing capacity is restricted due to fluorophore spectral properties or channel counts; in addition, these require expensive analytical instrumentation with long turnaround times.
Recently, researchers at Kyung Hee University in Yongin, South Korea have developed an advanced system for multiplexed detection that uses microchips and a laser-driven translation stage to enable simultaneous separations and detections on parallel aligned channels. Dubbed the flow genetic analysis system (FGAS), this technology offers significantly greater multiplexing capability than existing capillary array electrophoresis (CAE) techniques used for viral and bacterial nucleic acid testing.
Biosensors and Bioelectronics recently published a paper where researchers demonstrated multiplexed LIF detection using a microchip consisting of a channel network with two separate laser spots designed to be scanned by an infrared scanning laser; separation monitoring was managed through separate detection beams; multiplexing was achieved by positioning a translation stage to move detection spots in tandem with scanning laser scannings across the chip, thus multiplexing detection spots for LIF.
Although its exact details remain hazy, this process appears to involve scanning a microchip for target molecules and measuring their current as they pass through a nanopore. Specificity can be altered using molecular carriers containing DNA/peptide-based molecular carriers that bind with recognition units on its surface36,37,38; thus creating a system capable of multiplexed detection of both RNA and protein molecules present in liquid samples.
Tunability
Tunability refers to the ability of lasers or optical systems to change their wavelength of light production, making tunable lasers ideal for biosensing applications. By changing wavelength, researchers can detect different analytes. Furthermore, this technology enables fine-tuning quantum materials so as to maximize their response against specific biological molecules.
Tunable technologies have become more prevalent in daily consumer products. From adaptive eyeglasses to sound systems with adjustable settings, these advancements are designed to adapt to various environments and settings; providing greater personalization at lower costs.
Quantum Radionics, an energy medicine method using radionic equipment to analyze an individual’s energy field and examine potential energy imbalances through different quantum rates and vibrations, offers some of the most powerful uses of tunable technology in holistic healing.
An individual’s DNA sample can be used to identify their health concerns, before being processed through the radionic device for analysis to assess energy balance and wellbeing assessment. The final health report doesn’t offer traditional diagnoses but instead serves as a functional energy analysis of themselves which guides users towards improving their wellbeing.
As newer, advanced tunable technology enters the market, we will see exciting applications in biodynamic farming, robotics, quantum computing and more powerful tunable lasers become available – leading to an entirely new perspective of understanding of our world around us.
