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| There is also ongoing research to reduce the potential for rejection of the differentiated cells derived from ESCs once researchers are capable of creating an approved therapy from ESC research. One of the possibilities to prevent rejection is by creating embryonic stem cells that are genetically identical to the patient. This can be achieved by fusing an ] (]), the nucleus (containing the genetic material: ]) of which is removed, with the nucleus from another of the patient's cells. The fused cell produced, similar to a ], is allowed to begin dividing based on the instructions available within the materials originating in the oocyte ]. At an early blastocyte stage, embryonic stem cells can be extracted. Because they are genetically identical to the patient, the patient's immune system will not reject differentiated cells derived from these embryonic stem cells. An alternative solution for rejection by the patient to therapies derived from non-cloned ESCs is to derive many well-characterized ES cell lines from different genetic backgrounds and use the cell line that is most similar to the patient; treatment can then be tailored to the patient, minimizing the risk of rejection. | There is also ongoing research to reduce the potential for rejection of the differentiated cells derived from ESCs once researchers are capable of creating an approved therapy from ESC research. One of the possibilities to prevent rejection is by creating embryonic stem cells that are genetically identical to the patient. This can be achieved by fusing an ] (]), the nucleus (containing the genetic material: ]) of which is removed, with the nucleus from another of the patient's cells. The fused cell produced, similar to a ], is allowed to begin dividing based on the instructions available within the materials originating in the oocyte ]. At an early blastocyte stage, embryonic stem cells can be extracted. Because they are genetically identical to the patient, the patient's immune system will not reject differentiated cells derived from these embryonic stem cells. An alternative solution for rejection by the patient to therapies derived from non-cloned ESCs is to derive many well-characterized ES cell lines from different genetic backgrounds and use the cell line that is most similar to the patient; treatment can then be tailored to the patient, minimizing the risk of rejection. | ||
| == Breakthrough In Extraction of Cells == | |||
| In a Wednesday, August 24th, 2006 article in Nature magazine. It was reported by Dr. Robert Lanza (medical director of Advanced Cell Technology in Worcester, Mass) that scientists had found a way to extract stem cells without destroying the actual embryo. In what could prove to be a medical milestone, researchers have succeeded in generating new lines of human embryonic stem cells without destroying the embryo. | |||
| The breakthrough may enable scientists to circumvent the ban on federal funding of stem cell research, paving the way for gains in treating or curing diseases such as diabetes, spinal injury and Alzheimer's disease. Many Scientists in the field and other Pro Stem Cell research people hope that this finding can finally convince congress and President George W. Bush to start federally funding Stem Cell Research, due to the significant restrictions on federal funding of stem cell research George W Bush has has approved on the bases of morals associated with a strong religious belief that destroying the embryo is murder and is associated with abortion. | |||
| This finding is essentially very new and has yet to make its way to congressional debate or bills to approve the federal funding of stem cell research. | |||
| ==External links== | ==External links== | ||
Revision as of 07:48, 24 August 2006
Embryonic stem cells (ESCs) are stem cells derived from the inner cell mass of a blastocyst, which is an early stage embryo - approximately 4 to 5 days old in humans - consisting of 50-150 cells. Embryonic stem cells are pluripotent, meaning they are able to differentiate into all derivatives of the three primary germ layers: ectoderm, endoderm and mesoderm. In other words, they can develop into each of the more than 200 cell types of the adult body when given sufficient and necessary stimulation for a specific cell type. When given no stimuli for differentiation, ESCs will continue to divide in vitro and each daughter cell will remain pluripotent. The pluripotency of ESCs distinguishes them from adult stem cells or progenitor cells, the latter two only having the capacity to form a more limited number of different cell types.
Because of their unique combined abilities of unlimited expansion and pluripotency, embryonic stem cells are a potential source for regenerative medicine and tissue replacement after injury or disease. To date, no approved medical treatments have been derived from embryonic stem cell research. This is not unusual for a new medical research field; in this case, the first human embryonic stem cell line was only reported in 1998.
Research history and developments
Embryonic stem cells were first derived from mouse embryos in 1981 by two independent research groups (Evans & Kaufman and Martin). A breakthrough in human embryonic stem cell research came in November 1998 when a group led by James Thomson at the University of Wisconsin-Madison first developed a technique to isolate and grow the cells when derived from human blastocysts.
Researchers at the Whitehead Institute announced in 2003 that they had successfully used embryonic stem cells to produce haploid, male gametes. They found embryonic stem cells that had begun to differentiate into embryonic germ cells and then further differentiated into the male haploid cells. When injected into oocytes, these haploid cells restored the somatic diploid complement of chromosomes and formed blastocysts in vitro.
The online edition of Nature Medicine published a study on January 23, 2005 which stated that the human embryonic stem cells available for federally funded research are contaminated with non-human molecules from the culture medium used to grow the cells. It is a common technique to use mouse cells and other animal cells to maintain the pluripotency of actively dividing stem cells. The problem was discovered when non-human sialic acid in the growth media was found to compromise the potential uses of the embryonic stem cells in humans, according to scientists at the University of California, San Diego.
A study was published in the online edition of Lancet Medical Journal on March 8, 2005 that detailed information about a new stem cell line which was derived from human embryos under completely cell- and serum-free conditions. After more than 6 months of undifferentiated proliferation, these cells demonstrated the potential to form derivatives of all three embryonic germ layers both in vitro and in teratomas. These properties were also successfully maintained (for more than 30 passages) with the established stem-cell lines. (Lancet Medical Journal)
Recently, in California, researchers have injected embryonic stem cells into mice as they developed in the womb. Upon maturing, it was found that some of the human ESCs had survived and two months after injection, the researchers found that the HESCs had undertaken "the characteristics of mouse cells" .
Scientists in Australia have grown human prostate tissue in mice through the use of ESCs. The research involved combining human ESCs with mouse prostate cells, and then using a mouse as the host to grow the human prostate. The researchers were able to show the resulting tissue was also functional as a human prostate. This work may enable medical researchers to use a prostate derived in this manner as a model for studying prostate cancer and disease and analysis of future prostate-related drugs.
There is also ongoing research to reduce the potential for rejection of the differentiated cells derived from ESCs once researchers are capable of creating an approved therapy from ESC research. One of the possibilities to prevent rejection is by creating embryonic stem cells that are genetically identical to the patient. This can be achieved by fusing an egg (oocyte), the nucleus (containing the genetic material: DNA) of which is removed, with the nucleus from another of the patient's cells. The fused cell produced, similar to a zygote, is allowed to begin dividing based on the instructions available within the materials originating in the oocyte cytoplasm. At an early blastocyte stage, embryonic stem cells can be extracted. Because they are genetically identical to the patient, the patient's immune system will not reject differentiated cells derived from these embryonic stem cells. An alternative solution for rejection by the patient to therapies derived from non-cloned ESCs is to derive many well-characterized ES cell lines from different genetic backgrounds and use the cell line that is most similar to the patient; treatment can then be tailored to the patient, minimizing the risk of rejection.
Breakthrough In Extraction of Cells
In a Wednesday, August 24th, 2006 article in Nature magazine. It was reported by Dr. Robert Lanza (medical director of Advanced Cell Technology in Worcester, Mass) that scientists had found a way to extract stem cells without destroying the actual embryo. In what could prove to be a medical milestone, researchers have succeeded in generating new lines of human embryonic stem cells without destroying the embryo.
The breakthrough may enable scientists to circumvent the ban on federal funding of stem cell research, paving the way for gains in treating or curing diseases such as diabetes, spinal injury and Alzheimer's disease. Many Scientists in the field and other Pro Stem Cell research people hope that this finding can finally convince congress and President George W. Bush to start federally funding Stem Cell Research, due to the significant restrictions on federal funding of stem cell research George W Bush has has approved on the bases of morals associated with a strong religious belief that destroying the embryo is murder and is associated with abortion.
This finding is essentially very new and has yet to make its way to congressional debate or bills to approve the federal funding of stem cell research.Article Here
External links
- Scientists Make Stem Cells Without Harming Embryos - LiveScience.com
- Scientists Harvest Stem Cells Without Harming Embryo - MSN Health and Fitness
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