Working Methods for EPITALON.
The telomerase-activating peptide To help maintain and extend telomeres on chromosomes, Epitalon directly enhances the synthesis of telomerase enzyme by cells inside the body. In general, the pace at which an organism age is related to the rate at which cell populations age, which in turn influences the rate at which an organism matures physically. When Epitalon is injected into animals, it has not only reversed the indications of aging but also reversibly treated many other age-related disorders and illnesses. Aside from restoring and normalizing the pineal gland’s natural circadian cycle of cortisol production, epitalon has been proven to help restore and normalize melatonin synthesis by the pineal gland, resulting in better nighttime sleep.
Chromosomes and DNA
There are two polynucleotide chains in DNA (deoxyribonucleic acid) that form a double helix and serve as genetic instructions for the development, growth, and reproduction of all known species of animals and viruses. DNA and RNA are two examples of nucleic acids (ribonucleic acid). We can’t live without DNA and RNA. As one of the four major types of macromolecules required by all currently known living forms, nucleic acids join proteins, lipids, and complex carbohydrates. Among macromolecules, they are one of the four kinds that are necessary to all known life.
Chromosomes are DNA molecules that contain a piece of an organism’s genetic code (genome). DNA is organized into long, gene-containing structures called chromosomes in eukaryotic cells (including those of mammals, plants, fungi, and protists). Before a typical cell division occurs, these chromosomes are replicated by the process of DNA replication, resulting in each daughter cell has a complete set of chromosomes. DNA is kept in the nucleus of eukaryotic creatures rather than the mitochondria or chloroplasts of prokaryotic organisms, which have a smaller quantity of DNA stored in their cells.
DNA’s telomeres, the sequences of nucleotides at the ends of chromosomes, are a key structural component in the genome and are necessary for the proper functioning of the cell. When cells divide, they lose some of their DNA, and this is seen in the figure below: After each duplication, it is required to shorten the end of a chromosome because the enzymes that duplicate DNA are unable to continue their work all the way to the end. Thus, the chromosome’s terminus gets shortened after each duplication (this is because the synthesis of Okazaki fragments requires RNA primers attaching ahead on the lagging strand). This means that each time a cell divides, the telomeres on the ends of each chromosome shorten one more time, resulting in a reduced chromosomal length for each generation. Eventually, after many divisions, the telomeres reach a particular length, and the cell is unable to divide any more in order to replace worn out, damaged, or diseased cells, culminating in the cell’s death. Eventually, the cell is unable to divide anymore, and it is senescent. At this point, the cell had reached the Hayflick limit.
THE PINEAL GLAND.
Located in the brains of most vertebrates, the pineal gland is a small endocrine gland that controls the generation of hormones. Located in the epithalamus, where the two halves of the Thalamus come together, it is nestled in a nook between the two hemispheres. The body’s temperature is controlled by this organ. Among neuroendocrine secretory circumventricular organs, the pineal gland is one of those that does not have a blood-brain barrier at the capillary level. Epitalon is readily available and ideal for use in research activities. We recommend getting it from this website.