BRAIN-770
A natural supplement to encourage the health of the pineal gland
In short, what we know as a physical body is made up of different organs. These organs are made up of tissues. And each tissue is made up of joining millions of cells that are put together according to their structure and function.
Well, in fact, our cells play the most fundamental role in shaping human physics. In other words, cells are the basic building blocks of our human body, which are made up of about 200 different types. Examples are red blood cells, skin cells, neurons, or fat cells. Although the cell itself is made up of molecules, atoms and subatomic particles.
Each package contains: 120 herbal capsules.
Recommended use: 2 capsules, twice a day.
BRAIN-770 Benefits
-
Decalcification of the pineal gland.
-
Disposes fluoride in the body.
-
Lowering blood fat, blood sugar and preventing diabetes.
-
Reduces oxidation speed and delays aging.
-
Relieves muscle fatigue and enhances body endurance.
-
Moistening and relaxing the bowels.
-
Hepatoprotective and anti-cancer effects.
-
Prevention of prostatic hypoplasia.
-
Improves immunity, anti-fatigue, anti-oxidation.
-
As a source of Iodine effectively improves the removal of sodium fluoride via urine.
-
It may reduce inflammation by thinning the fluids formed from injury, and facilitating the fluid’s drainage. This in turn, also speeds tissue repair.
-
It may help alleviate pain by inhibiting the release of pain-inducing amines called brady kinin.
-
It may enhance cardiovascular health by breaking down the protein by-products of blood coagulation called fibrin.
-
prevention of age-related diseases Such as Alzheimer & Parkinson's disease.
Description
In short, what we know as a physical body is made up of different organs. These organs are made up of tissues. And each tissue is made up of joining millions of cells that are put together according to their structure and function. Well, in fact, our cells play the most fundamental role in shaping human physics. In other words, cells are the basic building blocks of our human body, which are made up of about 200 different types. Examples are red blood cells, skin cells, neurons, or fat cells. Although the cell itself is made up of molecules, atoms and subatomic particles.
Now, to be more precise, a human being is made up of about 30 trillion human cells, each with its own structure and function, and that number is almost constant. But for a variety of reasons, the cell may die, so with the death of each cell, a cell division takes place to replace the dead cell with a new cell. Now these cells die in two different ways. In the first method, the life of the cell ends and it dies. In fact, cells have a specific life cycle. We mentioned earlier that there are about 200 different cell groups in the human body, and that the lifespan of each of the 200 cell groups is different. For example, white blood cells live only about 13 days, while red blood cells have a lifespan of about 120 days. Hepatocytes can live up to 18 months. While brain cells and eye cells survive almost all human life. In general, the average lifespan of a healthy human is 8 to 10 years.
And in the second method. In this method, the cell may die before the end of its life due to damage, which itself depends on two different factors. Internal factor and external factor.
Internal factors are when a cell is damaged from within the body for certain reasons, for example when a cell is infected by bacteria or viruses, and external factors are when a cell dies due to the wrong environment and lifestyle. For example, exposure to electromagnetic radiation or exposure to dust particles. In both cases, when the cell is damaged, the human body initiates a process called programmed cell death (PCD), which is essential to prevent disease. In this case, the infected cell, produces a signal. This signal causes phagocytes to find and eat it. Phagocytes are cells that are able to eat and digest dying cells. Cell division is now performed and the new cell replaces the dead cell. (information source)
Aging is an irreversible and inevitable process that affects all parts of the human body. On the cellular level, aging is associated with senescence, the cessation of cell division driven by mechanisms such as telomere shortening and other forms of genotoxic stress. Senescent cells are characterized by compromised nuclear structure, as well as enlarged and irregular shape. These changes are responsible for the progressive loss of physiological integrity observed on the organismal level. Although complete prevention of aging seems unlikely, anti-aging remedies that focus on delaying this process hold considerable pharmaceutical potential. (information source)
Just imagine making it to age 80, but you have not taken care of yourself. You thus suffer from severe degenerative disorders and have only a short time left to live. As our cells divide normally, or in response to poor lifestyle choices, telomeres progressively shorten until cells become dysfunctional or die. When this happens, we grow older, become afflicted with the diseases of aging, and eventually die. Telomeres are small units of DNA at the ends of our chromosomes. They are often compared to the plastic tips at the ends of shoelaces.
As long as these tips (telomeres) remain intact, they keep the chromosomes from fraying and the genes inside from unraveling. This same degenerative effect occurs in our stem cells with aging, which makes them progressively unable to create healthy new cells. There is evidence that fish oil, vitamin D, carnosine, multivitamins, and healthy lifestyle choices may slow the rate of telomere shortening. This helps explain why people who take care of themselves and use the proper supplements enjoy such profound health benefits. We live in a fascinating era. Throughout history there were no validated methods to slow human aging, let alone reverse it. Today, scientists are meticulously investigating methods to enable our aging bodies to grow younger. If they succeed, then we might be the last generation to succumb to aging and the horrific diseases that accompany it.
The pineal gland, also known as the pineal body, is a neuroendocrine gland found towards the center of the brain. It is located medially between the two cerebral hemispheres and is attached to the rear of the third ventricle by a small pineal stalk. The term ‘pineal’ refers to the structure of the gland, which often resembles a pinecone. However, there is much variation in shape, with many human pineal glands being pea-shaped or fusiform (tapering at both ends). The gland increases in size throughout early childhood and becomes fully developed at around age 5 to 7 years.
In humans, the pineal gland is a neuroendocrine gland weighing about 150 mg. The organ, part of the epithalamus, is located between the colliculi superiors of the lamina tecti, at the back of the posterior wall of the third brain ventricle. The pineal gland is characterized by a very rich network of blood vessels, which ensures blood flow of 4 mL/min/g, second only to the blood supply to the kidneys. Another unique anatomical feature of the gland is its location outside the blood–brain barrier. Therefore, unlike most other brain structures, the pineal gland has open access to blood and all of its components. Extremely rich vascularization and no significant restrictions in transport from the bloodstream make it possible for the pineal gland to accumulate significant amounts of various substances, mainly, calcium; microelements such as cobalt, zinc, and selenium; and fluoride.
The pineal gland is an endocrine gland whose main function is the biosynthesis and secretion of melatonin, a hormone responsible for regulating circadian rhythms, e.g., the sleep/wake cycle. Due to its exceptionally high vascularization and its location outside the blood–brain barrier, the pineal gland may accumulate significant amounts of calcium and fluoride, making it the most fluoride-saturated organ of the human body. Both the calcification and accumulation of fluoride may result in melatonin deficiency. (From the review Fluoride and the pineal gland in applied science journal) Initially, melatonin is released into the densely arranged local blood vessels of the pineal gland and the cerebrospinal fluid of the third ventricle; it then enters the general circulation and is distributed systemically around the body. (information source)
Calcification of the pineal gland often occurs as a result of excess fluoride and other mineral deposits. This may, in turn, affect the body’s ability to regulate melatonin and its circadian rhythm. The pineal gland is photosensitive and secretes less melatonin during the day and more at night; hence, why most people are awake during the day and feel tired for sleep at nighttime. (information source)
Pineal gland calcification decreases the capacity of the pineal gland to produce melatonin. Disruption of melatonin production has been linked with aging and Alzheimer’s disease. Alzheimer’s patients have highly calcified pineal glands, as do two-thirds of the adult population. Many of us have a pineal gland that is already completely calcified. The degree of pineal gland calcification is linked to a decreased capacity of the pineal gland to produce melatonin.
The effect of fluoride on the human body is characterized by a very narrow margin of safety, which means that even relatively low concentrations may cause various adverse or even toxic effects. The risk naturally increases with the intensity and duration of the exposure, with longterm exposure resulting in chronic poisoning. One of the defense mechanisms protecting the body against the effects of fluoride toxicity seems to be its deposition in calcified tissues.
Acute heavy metal intoxications may damage central nervous function, the cardiovascular and gastrointestinal (GI) systems, lungs, kidneys, liver, endocrine glands and bones. Chronic heavy metal exposure has been implicated in several degenerative diseases of these same systems and may increase the risk of some cancers. Heavy metals (including lead, cadmium, mercury, and the metalloid arsenic) are persistent in the environment and have documented potential for serious health consequences.
Heavy metal toxicity may damage:
-
central nervous system
-
cardiovascular system
-
gastrointestinal system
-
lungs
-
kidneys
-
liver
-
endocrine glands
-
bones
(Taken from the review "Heavy Metal Detox: Heavy Metals & Health Risks - Life Extension")
BRAIN-770 Ingredients
Pine pollen
As a kind of Chinese traditional medicine, pine pollen, which is the male spore of pine tree, has been used as a drug and food for thousands of years. Pine pollen has an effect in the treatment of different kinds of diseases such as colds, disease of the prostate, anemia, diabetes, hypertension, asthma, and rhinitis. Pine pollen is collected from Pinus massoniana Lamb., Pinus tabulaeformis Carr., and it has the characteristics of a single pollen source, pure quality, and is a stable component. Pine pollen powder, called “natural micronutrient storeroom,” is rich in many kinds of body-demanding amino acid, minerals, vitamin, enzyme, and flavonoids. Taken together, pine pollen is proved to delay the replicative senescence of human diploid fibroblasts and block D-galactose-induced increase of serum and cerebral AGEs level in model mouse, which may result in the reversal of D-galactose-induced aging effects in both neural and inflammation system. It is possible that pine pollen exerts its antiaging effects at least partially by its NEG-inhibiting effect in vivo. (information source)
The pine pollen powder is known for several uses in Chinese medicine:
-
Lowering blood fat, blood sugar and preventing diabetes
-
Reduce oxidation speed and delay aging
-
Relieve muscle fatigue and enhance body endurance
-
Moistening and relaxing the bowels
-
Hepatoprotective and anticancer effects
-
Prevention of prostatic Hypoplasia
-
Improving immunity, anti-fatigue, anti-oxidation.
cd
Black walnut hull
The walnut (Juglans spp.) is an appreciated nut that belongs to the Juglandaceae family. The fruit includes four main parts: the kernel, the skin, the shell, and the green husk. It is widely cultivated due to its edible kernel. In walnut production centers, high amounts of the husk as an agro-forest waste product are produced and discarded away. Recently, it has been demonstrated that the walnut green husk could be valued as a source of different natural bioactive compounds with excellent antioxidant and antimicrobial properties, and is a rich source of natural iodin. Iodine effectively improves the removal of sodium fluoride via urine. Iodine also helps remove the other halogens chlorine, bromine, and astatine, along with radioactive iodine. (information source)
cd
Papaya (Serrspeptase)
Serrapeptase, technically called Serratio Peptidase, is a proteolytic enzyme, which means that it chops up or digests protein. It is produced from the Papaya fruit. When this enzyme is isolated and coated in the form of a tablet, it has been shown to act as an anti-inflammatory and a pain-blocker, much like aspirin, ibuprofen and other nonsteroidal antiinflammatory drugs (NSAIDs). What’s more, preliminary research indicates that Serrapeptase may even help inhibit plaque build-up in arteries, thereby preventing atherosclerosis (hardening of the arteries) and a resulting heart attack or stroke. Therefore, much like aspirin, this naturally derived enzyme may work to prevent inflammation, pain, heart attack and stroke. Unlike aspirin and other over-the-counter (OTC) NSAIDs, Serrapeptase has not been shown to cause ulcers and stomach bleeding.
Serrapeptase is thought to work in three ways:
● It may reduce inflammation by thinning the fluids formed from injury, and facilitating the fluid’s drainage. This in turn, also speeds tissue repair.
● It may help alleviate pain by inhibiting the release of pain-inducing amines called bradykinin.
● It may enhance cardiovascular health by breaking down the protein by-products of blood coagulation called fibrin. Conveniently, Serrapeptase is able to dissolve the fibrin and other dead or damaged tissue without harming living tissue. This could enable the dissolution of atherosclerotic plaques without causing any harm to the inside of the arteries.
Serrapeptase has been used in Europe and Asia for over 25 years. Because the enzyme digests or dissolves all nonliving tissue, including blood clots, cysts and arterial plaque, it is used to treat a variety of conditions, including sprains and torn ligaments, postoperative swelling, venous thrombosis (clots in the legs), ear, nose and throat infections and atherosclerosis. (information source)
Fibrinolytic effect of serrapeptase: Serratiopeptidase is known to dissolve blood clots and artherosclerotic plaques by breaking down fibrin and other dead or damaged tissue [2]. It can also remove deposits of fatty substances, cholesterol, and cellular waste inside the arteries. The fibrinolytic property of serratiopeptidase may also help with the problems of thick blood, risk of stroke, thrombophlebitis and ossification of pine gland.
Another innovative and interesting application is in the treatment of Alzheimer’s disease via reduction of amyloidosis. Serratiopeptidase was found to be as effective as nattokinase (an enzyme shown to degrade amyloid fibroid) in relieving Alzheimer’s disease pathophysiology in a rat model . Oral administration of an enzyme decreased brain acetylcholinesterase activity, as well as levels of transforming growth factor ß, Fas, and interleukin-6, all of which were significantly increased in patients with Alzheimer’s disease. These results were confirmed by histological examination of brain tissue. This study demonstrates that serratiopeptidase can down-regulate the amyloidogenic pathway due to its proteolytic, anti-oxidant, and antiamyloidogenic effects. The study was further supported by a recent reports showing dissociation of insulin amyloids by serratiopeptidase both in vitro and in vivo. Amyloidosis is a result of misfolding of normal cellular protein to protease resistant β-sheets making insoluble aggregates. These aggregates build up in the body and their clearance is highly difficult. The amyloid dissociation ability of serratiopeptidase was better than that of the standard amyloid dissociating agent, nattokinase. This novel approach paves the way to explore the therapeutic potential of serratiopeptidase in different amyloid related disorders. (information source)
cd
Rhodiola Rosea
Known colloquially as the “golden root,” Rhodiola rosea L. is a Chinese herb that has been widely incorporated into various food additives, drinks, and cosmetic products. R. rosea plants are botanical adaptogens that grow mainly in the Himalayan belt and Tibet, and according to the basic tenets of traditional Chinese medicine, boost qi and reduce fatigue. R. rosea’s pharmacological anti-aging effects have been well documented. Studies have verified R. rosea’s therapeutic value for the treatment of aging-related diseases, including Alzheimer’s disease, Parkinson’s disease, cerebrovascular disease, diabetes, and cardiovascular disease (Zhuang et al., 2019). In addition, in vitro studies performed in human lung fibroblast cell lines have demonstrated R. rosea’s ability to reverse senescence-like phenotypes (Chiang, Chen, Wu, Wu, & Wen, 2015). (information source)
In addition to its multiplex stress-protective activity, Rhodiola rosea extracts have recently demonstrated its anti-aging, anti-inflammation, immune stimulating, DNA repair and anti-cancer effects in different model systems. Rhodiola rosea extracts and salidroside can impose cellular and systemic benefits similar to the effect of positive lifestyle interventions to normal physiological functions and for anti-cancer. (information source)
cd
Saffron (Crocus Sativa)
Saffron (Crocus sativus L.) is a medicinal plant, originally cultivated in the East and Middle East, and later in some Mediterranean countries. Saffron is obtained from the stigmas of the plant. Currently, the use of saffron is undergoing a revival. The medicinal virtues of saffron, its culinary use and its high added value have led to the clarification of its phytochemical profile and its biological and therapeutic characteristics. Saffron is rich in carotenoids and terpenes. Saffron and its major compounds have powerful antioxidant and antiinflammatory properties in vitro and in vivo.
Anti-tumor properties have also been described. Overall, the phytochemical profile of saffron confers many beneficial virtues on human health and, in particular, on the prevention of age-related diseases, which is a major asset reinforcing the interest for this medicinal plant. Saffron and crocins (Saffron's main constituent molecules) were found to inhibit beta-amyloid aggregation, a key step in the pathogenesis of Alzheimer’s disease. In addition, a recent systematic review of clinical trials demonstrated that saffron was equally effective as commonly used drugs for Alzheimer’s disease and resulted in no difference in the incidence of side effects.
(Taken from https://www.mdpi.com/journal/nutrients review on Saffron (Crocus sativus L.): A Source of Nutrients for Health and for the Treatment of Neuropsychiatric and Age-Related Diseases)
In a Parkinson’s disease model, it was shown that exercise and crocin supplementation, due to their anti-inflammatory and antioxidant properties, could ameliorate motor and memory deficits. In addition, C. sativus hydroethanolic extract has a neuroprotective effect on the nervous system of the meriones shawi rodent, suggesting that saffron could be a possible therapeutic agent in neurodegenerative disorders, including dopaminergic and noradrenergic injuries trigged by heavy metals like in Parkinson’s disease. (information source)