10 Different Structures Found In Plant And Animal Cells What Is D-Regen-10? How It Works and What It Does

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What Is D-Regen-10? How It Works and What It Does

The complex chemical composition of D-Regen-10 exhibits many positive attributes on the physiologic and metabolic functions of the living tissue cell and living plant cell that enhances the vitality of the cell through the ability of the science to influence vital biochemical functions of the cells. The ability to enhance these biochemical functions in a positive manner becomes more impressive when you study the negative aspects the science has on the bacterium, fungi and viruses that initiate chemical imbalances, metabolic disruptions and physiologic altering of the normal cells – the cell selectivity of the science is unparalleled and unique in its own way to other science and chemicals used for the same applications Douglas Bio Research Science. Two other characteristics of the compelling science is its safety for use by humans, agriculture, animal science and healthcare, has been proven to be safe in all aspects of life. The second distinguishing characteristic is the ecological attributes of the science. This gives the science the three characteristics that make it very unique in the areas of application where D-Regen-10 is appli9ed. It works (does what it was designed to do), it is safe for humans, animals and plants, and it is ecologically friendly (no adverse effects on the aquifer, or atmosphere).

One of the major characteristics of the ability of the science to affect the bacterium is its ability to penetrate the cell wall in a timely manner. Its ability to penetrate the cell’s plasma membrane allows the complex chemical structure to initiate many biochemical, physiologic and metabolic functions. The plant and tissue cell’s plasma membrane and cytoskeletal system has a distinct anatomical difference than the bacterium anatomy. These distinct differences are one of the contributing factors in giving the science its cell selectivity. In reviewing the anatomy of the cells, bacterium, fungi and viruses helps explain the selectivity ability of the science.

Plant Tissue The tissue cell and plant cell even though each has some distinct characteristics; they parallel each other in many ways in the anatomy, physiology, molecular structure and biochemical process. These remarkable and incredible tiny organisms have the ability to create, and sustain life in an amazing scientific manner. The drawing on the next page illustrates their similarity and complexity. To help these organisms in their biological and biochemical functions during their evolving the times of stress we must fully understand their cell machinery and the intricate balance of their components of biochemical functions. Plant cells have two structures not found in tissue cells-a cellulose cell wall exterior to the cell membrane and chloroplasts. This characteristic must be fully understood to help a plant cell repair itself. The plant cell’s fundamental biochemistry, photosynthesis, nutrition, mastic movements, environmental stress, germination, dormancy and stomata function and transpiration (plant H2) functions) must be studied to understand the process which the cell undergoes when it is traumatized by mechanical, chemical, insect, disease or water depletion. A full understanding of the biochemistry of the remarkable organism is necessary to develop solutions to help the plant cell maintain its natural defense, maintain metabolic and physiologic balance and repair itself.

Tissue Cell The tissue cello, the smallest living unit in the body is made up of microscopic membrane-bound compartments that contains chemicals that supply the following major components; water, organic polymers, nucleic acids, proteins, carbohydrates and lipids. This macro-tiny unit has the ability to perform many biochemical, physiological and metabolic functions. Maintaining balance of its complex specialized functions is the foundation of living organs and tissue. The human body is comprised of 200 different types of tissue cells. Tissue cells grow, divide and die while performing enormously complex biochemical, physiologic and metabolic functions. It is important to understand the functions of the components of the tissue cell to be able to develop substances that enable the tissue cell to maintain its functional balance when it is traumatized by physical, chemical, bacterial or severe etiological agents. The tissue cell’s structure can be divided into three major components that are complex in their own unique way, the outer plasma membrane, the DNA-containing nucleus and the organelles (cytoskeleton, mitochondrion, ribosomes, endoplasmic reticulum, vacuole, vesicles and Golgi). All of these components play a district role in the biochemical process of the cell that in turn drives the physiologic and metabolic process of this tiny living marvel. D-Regen-10, with its unique blend of chemicals, provides the tissue cell with substances to help maintain its balance when under attack from various etiological agents. The following diagrams will help give you a foundation of the anatomical structure of the tissue cell.

Bacterium Bacterium, like plant cells, has an exterior cell wall but it differs greatly in chemical deposits and structures form the cell wall of plants, Like all other cells, bacterium has a plasma membrane that functionally separates it from their environment. Some bacteria have a separate membrane (the outer membrane), exterior to the cell wall. This is an important anatomical aspect in designing agents to control or kill bacteria. This characteristic is the first point of attack by D-Regen-10, the positive charged electrons of the science is very conductive to the attraction of the science to the plasma membranes. Changing the electrical field of electrical field of electrical charges affects the living functions of the bacterium. This disruption will contribute to cell necrosis.

Viruses The smallest of all self-replicating living organisms, they are very small and unique in their nature. Viruses consist solely of a small segment of nucleic acid encased in a simple protein shell with no metabolic functions. They parasitize sub cellular machinery, subverting the sub cellular substances to their own purposes. The perception that viruses are simplistic can be deceptive. Viruses infect virtually every living organism, plate cells and tissue cells. They have the ability to exhibit a vast diversity of structures that embody a protein’s complexity of functions. In understanding the uniqueness and complexity of viruses, we are able to develop substances to help the plant cell and tissue cell repel the parasitizing attributes of the viruses. The virus cannot live without the sub cellular components of the living cells it attacks. The ability of D-Regen-10 to change the electrical charged field in the living organism enables the science to control the replication of the virus. It is important to recognize the differences in the virus verses bacterium, and plant and tissue cells to compose substances to control their replication.

Fungi Fungi, living organisms that are prevalent and not self-sustaining have different biochemical and physiological characteristics that distinguish this organism from the plant and tissue cell. Fungi can have multiple nuclei and with their thick ergosterol containing walls, will grow as perfect sexually reproducing forms in vitro but as imperfect forms to vilo. Fungi can grow sexually of asexually by budding (yeast), by filamentous extensions (molds) or spores. This organism can also exist as a dimorphic living organism, yeast at human body temperature and a mold at climate or room temperature Some species of this organism can produce spores that are resistant to extreme environmental conditions. Fungi lack the ability to initi9ate photosynthesis due to the absence of chlorophyll in the anatomical structure and must live as a parasite or a saprobe. This non-mobile organism lacks the vascular tissue to grow parts like the tissue or plant cell. The cell wall of the fungi is rigid and contains chitin, a long carbohydrate polymer, a variety of chemicals and non-cellulose compounds. Their walls contain different building blocks that the tissue or plant cells. Nucleic acid analysis shows their biochemical and physiological distinction from the plant and tissue organisms. A full understanding of fungi anatomy, biochemical and physiologic functions enable science to combat their pathogenic and ecological attributes that disrupts living. For More visit http://www.douglasbioresearch.com

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