STEM CELLS DISCOVER GOD PARTICLE

Stem Cell Physicists Discover "God Particle"

Stem Cell scientists may have discovered  a new subatomic particle Wednesday, calling it " the God particle" - that helps explain what gives all matter in the universe size and shape.

This new sub atomic particle is the missing cornerstone of particle physics,"newly discovered subatomic particle is a boson, but he stopped just shy of claiming outright that it is the Higgs boson itself - an extremely fine distinction.  "We have a discovery. We have observed a new particle that is is a major breakthrough in Stem Cell Research" The new stem cell particle is seen as the key to understanding why matter has mass, which combines with gravity to give an object weight. The idea is much like gravity and Isaac Newton's discovery of it: Gravity was there all the time before Newton explained it. But now scientists have seen something very much like the Higgs boson and can put that knowledge to further use.

CERN's atom smasher cost $10 billion has been creating high-energy collisions of atoms to investigate dark matter, antimatter and the creation of the universe, which many theorize occurred in a massive explosion known as the Big Bang.  Scientist teams presented evidence in complicated scientific terms what was essentially extremely strong evidence of a new particle that can beused for stem cell treatments for humans some day.

Stem Cell "God particle" was coined by Nobel Prize-winning physicist physicists, as an easier way of explaining how the subatomic universe works and got started.  Stem cell sienteist have been playing God by reaching into the fabric of the universe in a way we never have done before. Some day soon we will be able to reproduce and repair every part of the human body thus eliminating Cancer, heart disease and other illnesses for ever.

STEM CELL CORD BLOOD

Umbilical Stem Cell Cord Blood Research

What Is Stem Cell Cord Blood?

"Stem Cell Cord Blood" refers to the umbilical cord blood found after child birth in the placenta yet still attached to the umbilical cord. Stem cell cord blood is stored by stem cell storage banks primarily for umbilical cord blood stem cell research which can be used to treat many forms of cancer causing genetic diseases that kill millions of humans every year.

Stem cell cord blood is extracted by syringing out the placenta umbilical cord during birth just before the cord blood stem cell has been cut from the baby. These baby umbilical cord stem cells are perfect for advanced umbilical cord blood stem cell storage companies and especially for American President Obama Stem Cell Research policy guidelines of the stem cell industry.

Cord cells are collected and stored because they contain high concentration of natures most potent types of Baby stem cells that are necessary to stem cell rejuvenating cells. The problem with this process of Stem cell extractions that the Placenta cord blood does not produce enough stem cells for treatments or research in Adults.

 so the placenta is more valuable method of stem cell extraction mainly because it has 100 times more high quality baby stem cell storage than adult cord blood.

Obama Umbilical Cord Stem Cell Research

U.S. President Obama formed the stem cell research council under the the Food and Drug Agency to supervise all aspects of stem cell cord blood research under the title of Human Cells, Tissues cells, and Cellular and Tissue Based Human Research Products or "FDA"

The U.S. Stem Cell Research Agency has developed a standard Code of Stem Cell conduct under Federal Regulations to provide guidelines for public and private stem cell cord blood banking companies banks.

Public and private cord blood storage banks are eligible for funding  with either the American Association of Blood Banks AABB or the Foundation for the Accreditation of Cellular Therapy.

Stem Cell Storage Companies and  baby stem cell banks can review the updated status of Stem Cell banks from U.S. government list of accredited cord blood banks or the FACT search engine of accredited cord blood banks.

 Europe, Asia and Canada are also working together to develop new stem cell laws pertaining to umbilical cord blood stem cell research and stem cell storage companies.

EMBRIONC STEM CELLS

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Embryonic Stem Cells

1. Stages of development generating embryonic stem cells.
Stem cells, are derived from embryos. Most embryonic stem cells are derived from embryos that develop from eggs that have been fertilized in vitro fertilization clinic and then donated for research purposes with informed consent of the donors. They are not derived from eggs fertilized in a woman's body.

2.Growing Embryonic Stem Cells

Growing cells in the laboratory is known as cell culture. Human embryonic stem cells  are generated by transferring cells from a embryo into a plastic laboratory culture dish that contains a nutrient broth known as culture medium. The cells divide and spread over the surface of the dish. The inner surface of the culture dish is typically coated with mouse embryonic skin cells that have been treated so they will not divide. This coating layer of cells is called a feeder layer. The mouse cells in the bottom of the culture dish provide the cells a sticky surface to which they can attach. Feeder cells release nutrients into the culture medium. Researchers have devised ways to grow embryonic stem cells without mouse feeder cells. This is a significant scientific advance because of the risk that viruses or other macromolecules in the mouse cells may be transmitted to the human cells.

The process of generating an embryonic stem cell line is somewhat inefficient, so lines are not produced each time cells from the  embryo are placed into a culture dish. However, if the plated cells survive, divide and multiply enough to crowd the dish, they are removed gently and plated into several fresh culture dishes. The process of re-plating  the cells is repeated many times and for many months. Each cycle of  the cells is referred to as a passage. Once the cell line is established, the original cells yield millions of embryonic stem cells. Embryonic stem cells that have proliferated in cell culture for for a prolonged period of time without differentiating,  have not developed genetic abnormalities are referred to as an embryonic stem cell line. At any stage in the process, batches of cells can be frozen and shipped to other laboratories for further culture and experimentation.

3. Embryonic Stem Cells Tests
At various points during the process of generating embryonic stem cell lines, scientists test the cells to see whether they exhibit the fundamental properties that make them embryonic stem cells. This process is called characterization.

Scientists who study human embryonic stem cells have not yet agreed on a standard battery of tests that measure the cells' fundamental properties. However, laboratories that grow human embryonic stem cell lines use several kinds of tests, including:

    Growing and sub culturing the stem cells for many months. This ensures that the cells are capable of long-term growth and self-renewal. Scientists inspect the cultures through a microscope to see that the cells look healthy and remain undifferentiated.
    Using specific techniques to determine the presence of transcription factors that are typically produced by undifferentiated cells. Two of the most important transcription factors are Nanog and Oct4. Transcription factors help turn genes on and off at the right time, which is an important part of the processes of cell differentiation and embryonic development. In this case, both Oct 4 and Nanog are associated with maintaining the stem cells in an undifferentiated state, capable of self-renewal.
    Using specific techniques to determine the presence of paricular cell surface markers that are typically produced by undifferentiated cells.
    Examining the chromosomes under a microscope. This is a method to assess whether the chromosomes are damaged or if the number of chromosomes has changed. It does not detect genetic mutations in the cells.
    Determining whether the cells can be re-grown, or subcultures, after freezing, thawing, and re-plating.

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 4. Human Embryonic Stem Cells
1) allowing the cells to differentiate spontaneously in cell culture
2) manipulating the cells so they will differentiate to form cells characteristic of the three germ layers; or
 3) injecting the cells into a mouse with a suppressed immune system to test for the formation of a benign tumor called a teratoma. Since the mouse’s immune system is suppressed, the injected human stem cells are not rejected by the mouse immune system and scientists can observe growth and differentiation of the human stem cells. Teratomas typically contain a mixture of many differentiated or partly differentiated cell types—an indication that the embryonic stem cells are capable of differentiating into multiple cell types.

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STEM CELLS THE MAGIC POWER OF YOU

 DEEPAK CHOPRA EXPLAINS STEM CELLS
World Famous Doctor Deepak Chopra explanation about the magic power of you, how you are integrated into the cosmic universe and your stem cells. Incredibly simple concept of how to unlock the information and intelligent that is deep within your every stem cell at the molecular level. Stem cells will change your life some day and that day is today!

Image by tobin.t via Flickr

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STEM CELLS. WHY ARE THEY IMPORTANT

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Image via WikipediaWHY ARE STEM CELLS IMPORTANT



STEM CELLS have the remarkable potential to develop into many different cell types in the body during early life and growth. In addition, in many tissues they serve as a sort of internal repair system, dividing essentially without limit to replenish other cells as long as the person or animal is still alive. When a stem cell divides, each new cell has the potential either to remain a stem cell or become another type of cell with a more specialized function, such as a muscle cell, a red blood cell, or a brain cell.

Stem cells are distinguished from other cell types by two important characteristics. First, they are specialized cells capable of renewing themselves through cell division, sometimes after long periods of inactivity. Second, under certain physiologic or experimental conditions, they can be induced to become tissue- or organ-specific cells with special functions. In some organs, such as the gut and bone marrow, stem cells regularly divide to repair and replace worn out or damaged tissues. In other organs, however, such as the pancreas and the heart, stem cells only divide under special conditions.

Until recently, scientists primarily worked with two kinds of stem cells from animals and humans: embryonic stem cells and non-embryonic "somatic" or "adult" stem cells. The functions and characteristics of these cells will be explained in this document. Scientists discovered ways to derive embryonic stem cells from early mouse embryos nearly 30 years ago, in 1981. The detailed study of the biology of mouse stem cells led to the discovery, in 1998, of a method to derive stem cells from human embryos and grow the cells in the laboratory. These cells are called human embryonic stem cells. The embryos used in these studies were created for reproductive purposes through in vitro fertilization procedures. When they were no longer needed for that purpose, they were donated for research with the informed consent of the donor. In 2006, researchers made another breakthrough by identifying conditions that would allow some specialized adult cells to be "reprogrammed" genetically to assume a stem cell-like state. This new type of stem cell, called induced plenipotentiary stem cells  , will be discussed in a later section of this document.

Stem cells are important for living organisms for many reasons. In the 3- to 5-day-old embryo, called a blastocyst, the inner cells give rise to the entire body of the organism, including all of the many specialized cell types and organs such as the heart, lung, skin, sperm, eggs and other tissues. In some adult tissues, such as bone marrow, muscle, and brain, discrete populations of adult stem cells generate replacements for cells that are lost through normal wear and tear, injury, or disease.

Given their unique regenerative abilities, stem cells offer new potentials for treating diseases such as diabetes, and heart disease. However, much work remains to be done in the laboratory and the clinic to understand how to use these cells for cell-based therapies to treat disease, which is also referred to as regenerative or reparation medicine.

Laboratory studies of stem cells enable scientists to learn about the cells’ essential properties and what makes them different from specialized cell types. Scientists are already using stem cells in the laboratory to screen new drugs and to develop model systems to study normal growth and identify the causes of birth defects.

Research on stem cells continues to advance knowledge about how an organism develops from a single cell and how healthy cells replace damaged cells in adult organisms. Stem cell research is one of the most fascinating areas of contemporary biology, but, as with many expanding fields of scientific inquiry, research on stem cells raises scientific questions as rapidly as it generates new discoveries.

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