How Biophotons positively affect the body and alleviate ailments!
How Biophotons positively affect the body and alleviate ailments! A completely new and very easy-to-use form of biophoton therapy now makes it possible to relieve PAIN within a short time and improve sleep quality. The non-transdermal patches can also be used for other complaints. Since the late 1990s, biophoton therapy has played an increasing role in naturopathy. This is mainly due to the development of technical devices that allow for the easy application of biophoton therapy in practice. Now, an (almost) new form of therapy is making waves. Patches that are applied directly to the skin stimulate the biophotons in the body and show immediate effects. What is Biophoton Therapy? In 1975, German physicist Prof. Dr. Fritz-Albert Popp scientifically proved that our cells contain light and that they use this light to communicate with one another. This light, found in all living organisms, was called biophotons by Popp. He described biophotons as a very weak but highly structured or coherent light, similar to focused laser light. Popp found in his studies that weak or diseased cells emit less light than healthy, intact cells, but that cells can regenerate quickly when exposed to light. This principle forms the foundation of all current forms of biophoton therapy. The biophoton therapies known so far use coherent light to irradiate the entire body or specific areas of the body, thereby improving cell function systemically or locally. Numerous user studies confirm the success of biophoton therapy, e.g., in cases of migraine, osteoarthritis, skin diseases, depression, rheumatism, sleep disorders, or states of anxiety and exhaustion. The Revolution in Biophoton Therapy! More than ten years ago, an American scientist achieved another breakthrough in biophoton therapy. For the first time, biophotons could be specifically stimulated using patches applied to the skin. This technology has been available in Germany for about three years. These patches, which contain non-toxic bio-organic substances such as polysaccharides and amino acids, are capable of reflecting light of specific wavelengths and thereby stimulating biophotons in a very targeted way. While traditional biophoton therapy systems generally stimulate biophotons throughout the body or in specific areas, biophoton patches can be used with much more precision, as different types of patches reflect specific light frequencies that trigger different responses. For example, a certain pain relief patch can significantly reduce pain within minutes—without any active ingredient—when applied correctly. Another patch has been proven to greatly improve sleep quality, which has led to its approval in the EU as a health product for treating sleep disorders. Other effects of the various patches or combinations of patches include: So far, 72 clinical studies have been published proving the effectiveness of the different patches. The most recent study was published in early April 2014. It is a placebo-controlled double-blind study from France, conducted by French pain specialist Dr. Pierre Volckmann in several hospitals. The study results show a significant pain reduction in 94 percent of participants within a short time. Interested!? Feel free to get in touch with me …Warm regards,Mario
CANNABINOIDE
CBN – CBG – CBDA – CBGA – Everything You Need to Know About These Cannabinoids! The Endocannabinoid SystemThe endocannabinoid system is part of the human nervous system. It is also referred to as the endogenous cannabinoid system. The term “endogenous” describes processes that occur within the body and are not caused by external influences. The central components are the cannabinoid receptors CB1 and CB2, as well as endogenous cannabinoids (endocannabinoids) that bind to these receptors and activate them. When cannabis is consumed, the active ingredient THC also binds to cannabinoid receptors and thus unfolds its effect. HistoryIsraeli researchers Raphael Mechoulam and Yehiel Gaoni identified THC as the most important psychoactive ingredient in cannabis in the mid-1960s. About twenty years later, scientists discovered specific receptors in the human nervous system to which THC binds. Subsequently, Mechoulam and his research team found an endogenous cannabinoid. They named it Anandamide, inspired by the Sanskrit term “ananda,” which stands for bliss. This discovery marked the beginning of ongoing research into the endocannabinoid system. Structure of the Endocannabinoid SystemCannabinoid receptors are found in various regions of the human body and influence different processes. CB1 receptors are mainly distributed in the brain but are also found in organs such as the kidneys or intestines. A particularly high concentration of CB1 receptors is located in brain regions responsible for motor control (basal ganglia, cerebellum) and information processing (hippocampus). CB1 receptors play an important role in motivation and cognitive functions such as memory formation. CB2 receptors are mainly associated with the central nervous system’s immune defense. Activation of cannabinoid receptors occurs via endocannabinoids. Unlike most other neurotransmitters, endocannabinoids are not stored in nerve cells but are produced as needed. Along with anandamide, one of the best-known endocannabinoids is 2-arachidonoylglycerol, abbreviated as 2-AG. Function of the Endocannabinoid SystemThe endocannabinoid system plays a role in many bodily functions and also influences the activation of other neurotransmitters such as GABA, glutamate, and dopamine. Research into the endocannabinoid system is still relatively young, and new insights into its significance continue to emerge. Interference with the endocannabinoid system can have significant consequences. In humans, for example, artificial blocking of CB1 receptors by the drug Rimonabant can trigger severe anxiety disorders. As a result, a medication containing the active substance was withdrawn from the market. It was originally intended to suppress appetite and thus help with weight loss in obesity. CB1 receptors also regulate appetite. In cannabis users, this effect can result in the so-called “munchies.” Genetic variations of CB1 receptors are suspected to increase susceptibility to addiction or mental disorders. Furthermore, CB1 receptors are important in embryonic development for neurogenesis, the formation of neural networks. The endocannabinoid system also plays a vital role in the processing of current information, such as access to working and short-term memory. For many people, cannabinoids are completely new compounds. Yet, we see them almost everywhere and know some of them, such as CBD (cannabidiol) and THC (tetrahydrocannabinol).CBD products are mainstream and have been on the market for several years. But when it comes to molecules like CBN, CBG, CBDA, or even CBGA, that’s a different story. Some of these cannabinoids result from the transformation of existing cannabinoids. And what about the others? Let’s find out now! Cannabinoid: What Is It?There are more than a hundred different cannabinoids in the hemp plant (cannabis). They are all different and have unique properties. These compounds can interact with our endocannabinoid system, which is why they are of great interest to scientists around the world. Due to this interaction, cannabinoids are capable of influencing our essential biological functions. The benefits of cannabinoids for health and well-being are countless. Examples include the anxiolytic and anti-inflammatory properties of common cannabinoids like cannabidiol. Regular intake of CBD oil helps combat sleep disorders such as insomnia, night terrors, sleepwalking, sleep apnea, daytime sleepiness… In short, classic cannabinoids are a gift from above. Recently, new cannabinoids have entered the market. They are even on the verge of overshadowing CBD (cannabidiol) and THC (tetrahydrocannabinol). Lesser-known compounds like CBN (cannabinol), CBG (cannabigerol), CBDA (cannabidiolic acid), and CBGA (cannabigerolic acid) are now competing with the long-dominant cannabinoids. CBN (Cannabinol)This compound is in full development and enjoying great success. However, it is important to note that research on CBN is still limited. CBN (cannabinol) is obtained by decarboxylating tetrahydrocannabinol. The combined effect of high temperature and oxidation leads to a significant chemical transformation. From THC, a new cannabinoid emerges. Scientists continue to experiment with the effectiveness of cannabinol in relieving various everyday ailments. CBN interacts with the endocannabinoid system differently than other cannabinoids. The interaction is not less effective, but CBN binds to entirely different neurotransmitters. This “decarboxylated” version of THC (tetrahydrocannabinol) does not cause as many psychotropic effects as its predecessor. In terms of benefits, CBN is just as effective as classic cannabinoids. For example, it could help anorexic individuals in their daily struggle. Cannabinol has positive effects on appetite. For people with chronic pain, CBN may help soothe sore spots. It is said to have strong analgesic properties. Moreover, CBN is especially known for its exceptional effects on sleep. Its perfect synergy with THC provides an effective solution against insomnia. Confirming these effects is still difficult due to the complex synthesis of CBN. CBG (Cannabigerol)Cannabigerol is gaining increasing acceptance among consumers of hemp-derived products. Research into CBG is encouraging and opening new perspectives. Cannabigerol is naturally derived from hemp (cannabis). In fact, it is the precursor compound of other cannabinoids. The presence of specific enzymes leads to a cascade of chemical reactions resulting in the cannabinoids you already know. Because of this, hemp plants generally contain only small amounts of CBG, as most cannabigerol molecules have already been converted. However, breeders have succeeded in producing more by crossbreeding different cannabis strains. Unlike other cannabinoids, which primarily exert their effects through binding to CB1-CB2 neuroreceptors, CBG acts differently. In the cerebral cortex, a neurotransmitter called GABA is closely associated with regulating mood and emotions. CBG binds to
The redox signaling system and its importance
The body’s own REDOX SIGNALING SYSTEM How long can a human survive without redox molecules? A human cannot survive without redox molecules, as they are essential for fundamental biological processes. Redox molecules are involved in all cellular processes that make life possible. They regulate energy production, cell communication, cell repair, and protection against oxidative stress. Without these molecules, cells could not maintain their functions, which would lead to severe disruptions and eventually to organ failure. Why are redox molecules essential for life? Cellular respiration: Redox reactions are crucial for the production of ATP (adenosine triphosphate), the cell’s primary energy carrier. Without the ability to transfer electrons, cellular respiration would come to a halt and the cells could no longer maintain energy balance. Protection against oxidative stress: Redox molecules help maintain a balance between the production of reactive oxygen species (ROS) and antioxidants. An imbalance would lead to cell damage and death. Cell communication and repair: Redox molecules are also involved in signaling processes necessary for responding to damage and initiating repair mechanisms. What happens without redox molecules? Without redox molecules, cellular respiration would fail, leading to an energy deficit and cell death within minutes. The body would no longer be able to respond to oxidative stress, resulting in rapid accumulation of cellular damage and systemic dysfunction. Survival time without redox molecules: Practically speaking, a human cannot survive even a short time without redox molecules, as they are essential for basic cellular metabolism and homeostasis. The absence of these molecules would result in immediate cell death, quickly leading to organ failure in the affected tissues. More interest!?