Gariaev‘s research differs significantly from traditional genetics by taking an expansive view of genome. He and his team of biophysicists, molecular biologists, embryologists and linguists have discovered that our genome exhibits wave and holographic properties.
They have demonstrated how DNA can transmit information over distance, prompting damaged organs to regenerate.
Understanding the Wave Structure of DNA
DNA is a double helix that contains genetic information encoded within its two strands. When cells divide, their two DNA strands become detached and begin producing their complementary sequence under the influence of DNA polymerase enzyme. As these charged pairs move with one another during cell division, electromagnetic waves are created (Figure 1).
Hexagonal and pentagonal parts of molecules store waves and energy. This energy is then transmitted via coiling regions that create solenoid-like circuits; when excited they emit electromagnetic waves which interact with other DNA strands. These interactions form the basis of wave theory genetics.
Montagnier and others have discovered that certain bacterial DNA sequences produce electromagnetic signals of very low frequency when suspended in dilute aqueous solutions, known as DNA “waves.” A graphene or metal tube, generator, inductor, and scope can be used to measure these DNA waves; their frequency even allows us to tell whether chick embryos are male or female due to differences between male and female cells when it comes to DNA topology.
Wave Genetics
Wave genetics is an intriguing theory which proposes that our genome works not just on a biochemical level but also through electromagnetic waves. This concept suggests we could use electromagnetic waves to instantly transmit genetic information across distances–an exciting thought with far reaching implications.
This new theory proposes that DNA serves not only as the blueprint for our physical bodies, but also functions like a hologram with each cell acting as its own independent “wave copy.” These copies can then be combined to produce three-dimensional images of an organism as whole or produce multiple views of one cell (differing perspectives).
Russian researchers have also discovered that our genetic material can be altered and reprogrammed via acoustic, electromagnetic, and scalar waves without having to cut out and replace individual genes –as is traditionally done in genetic engineering. This research can explain phenomena like clairvoyance, intuition, spontaneous healing acts from remote places (remote healing acts are similar), affirmation techniques used for healing purposes like affirmations techniques or unusual light-auras around certain people such as spiritual masters as well as mind’s influence over weather patterns among others.
Dr. Gariaev‘s studies reveal that sequences of nucleotides found in DNA share similarities to human language, providing the basis for genetic linguistics – an emerging field which suggests our genes could actually communicate with us directly. His experiments also demonstrate how vibrational frequencies in our genes can alter physical reality by producing magnetized micro wormholes.
He demonstrated how our DNA can be affected by our thoughts and emotions, including thoughts that affect reprogramming. His work also demonstrated that sound and light frequencies could help heal our bodies naturally without cutting out and replacing individual genes – something known to esoteric and spiritual teachers for centuries; now it has been scientifically demonstrated and explained. However, correct frequencies must be utilized in order for this method to work successfully; that’s why it’s crucial that you find your personal resonant frequencies and use them regularly so your DNA stays healthy and strong!
Transmitting Genetic Information
Electronic communication of genetic information is by far the most prevalent way in which genetic data can be spread; this may include websites, social networking, email, text messages and mobile apps being used to share genetic data. While there may be numerous reasons for sharing genetic data this way, it’s essential that all those sharing genetic data understand its risks; including privacy risks as well as ethical and legal repercussions associated with its dissemination.
One major concern related to genetic information transmission is its potential use by insurers or employers for discriminatory purposes in employment and health coverage decisions, which would violate individuals’ rights against discrimination due to medical or genetic considerations and privacy protection laws, while also running counter to fundamental principles of medical ethics which place human dignity and rights as priority over scientific or socioeconomic goals.
At present, insurance companies and employers can legally request genetic information from applicants for life, disability, long-term care, critical illness and income replacement insurance policies. This presents numerous ethical and practical issues, such as concerns that genetic testing will be misused beyond its intended purpose of identifying hereditary disease risks, as well as applicants being dissuaded from seeking tests due to fears of discrimination or fear of stigmatisation.
One way to reduce these risks is requiring that genetic information is stored separately from patient medical records, to reduce its chances of transmission to insurers or employers and protect it through existing privacy and antidiscrimination legislation. Unfortunately, this would increase health-care costs as well as make getting necessary treatments more difficult for patients.
As another way of mitigating genetic information misuse, laboratories must also be properly configured and secured. This requires conducting a comprehensive security evaluation of their entire laboratory environment – from DNA sequencing instruments that generate data directly to all laboratory equipment connected via networked communications – including vulnerability scanning, packet monitoring, digital forensics full stack assessments hardware teardowns. Policies and procedures in place to safeguard information leakage such as management oversight will need to be considered in addition to how information flows are monitored by IT staff should also be carefully considered.
Regenerating Pancreas
Regenerating the pancreas is an integral goal in the fight against diabetes, with researchers working toward re-establishing its ability to generate its own endocrine islets – responsible for producing insulin and other hormones – by producing new pancreatic cells and creating the right environment in which they thrive. They’re also developing methods of transferring these new cells back into the body while testing them against its effectiveness against treating this form of disease.
The pancreas consists of two distinct components, with exocrine pancreas responsible for digestive enzyme production and exocrine pancreas responsible for producing digestive enzymes; and exocrine pancreas responsible for producing digestive enzymes; endocrine islets produce metabolic hormone insulin; however their regeneration capacity is extremely limited and any damage to them almost invariably leads to type 1 diabetes. Researchers are exploring several strategies to halt this progression including stimulating endogenous B-cell proliferation, reprogram non-islet cell types to produce insulin as well as transplanting new islets from genetically engineered animals.
Researchers in the Center for Regenerative Biotherapeutics are taking multiple approaches to regenerate and protect pancreatic islets. Additionally, they’re exploring which genes regulate how islets function as well as whether their function has been impaired due to diabetes.
They are also researching ways to re-create the normal cellular environment necessary for islets to function, which will require an in-depth knowledge of pancreatic beta cell biology. Beta cells produce insulin – a hormone which regulates your blood glucose levels – from groups known as islets of Langerhans in your pancreas, producing this hormone that allows certain cells to absorb glucose from your blood and convert it to glycogen which is stored in liver and muscle tissues until released when food is eaten reducing sharp spikes in blood glucose after meals.
Dr Gariaev‘s groundbreaking research proves that DNA, once thought to be static and static in its expression of life, is in fact dynamic and living system that can adapt and change itself through codon rearrangement in DNA strings. His discoveries have opened the way to cutting edge technologies like distant healing and noninvasive organ regeneration processes; significant longevity extensions; quantum computing.
