 |
|
Discarded placentas deliver researchers promising cells similar to embryonic stem cells
August 08, 2005Routinely discarded as medical waste, placental tissue could feasibly provide an abundant source of cells with the same potential to treat diseases and regenerate tissues as their more controversial counterparts, embryonic stem cells, suggests a University of Pittsburgh study to be published in the journal Stem Cells and available now as an early online publication in Stem Cells Express.
A part of the placenta called the amnion, or the outer membrane of the amniotic sac, is comprised of cells that have strikingly similar characteristics to embryonic stem cells, including the ability to express two key genes that give embryonic stem cells their unique capability for developing into any kind of specialized cell, the researchers report. And according to the results of their studies, these so-called amniotic epithelial cells could in fact be directed to form liver, pancreas, heart and nerve cells under the right laboratory conditions.
"If we could develop efficient methods that would allow amnion-derived cells to differentiate into specific cell types, then placentas would no longer be relegated to the trashcan. Instead, we'd have a useful source of cells for transplantation and regenerative medicine," said senior author Stephen C. Strom, Ph.D., associate professor of pathology at the University of Pittsburgh School of Medicine and a researcher at the university's McGowan Institute for Regenerative Medicine.
According to U.S. census figures, there are more than 4 million live births each year. For each discarded placenta, the researchers calculate there are about 300 million amniotic epithelial cells that potentially could be expanded to between 10 and 60 billion cells relatively easily.
"Provided that research advances to the point that we can demonstrate these cells' true therapeutic benefit, parents could conceivably choose to bank their child's amniotic epithelial cells in the event they may someday be needed, as is sometimes done now with umbilical cord blood," commented Dr. Strom.
The amnion is derived from the embryo and forms as early as eight days after fertilization, when the fate of cells has yet to be determined, and serves to protect the developing fetus. According to the researchers' studies using placentas from full-term pregnancies, amniotic epithelial cells have many of the telltale surface markers that define embryonic stem cells, and also express the Oct-4 and nanog genes that are known to be required for self-renewal and pluripotency - the ability to develop into any type of cell.
Yet the authors are careful to point out that despite their remarkable similarities to embryonic stem cells, amniotic epithelial cells are not stem cells per se, because they can't grow indefinitely. This may be due to the fact that these amnion-derived cells do not express a certain enzyme, called telomerase, that is important for normal DNA and chromosome replication, and by extension, ultimately, cell division.
"Perhaps it's to their advantage that the amnion epithelial cells lack telomerase expression, because telomerase is associated with many cancers and one of the main concerns about stem cell therapies is that transplanted stem cells would replicate in the recipient to form tumors," noted Toshio Miki, M.D., Ph.D., first author of the paper and an instructor in the department of pathology at the School of Medicine.
To help determine if amnion-derived cells that are delivered directly to tissues would cause tumors, the researchers conducted studies in immune system-deficient mice and found no evidence that tumors had developed seven months after the cells were injected into multiple sites.
While amniotic epithelial cells do not share the same capacity for unlimited replication as do embryonic stem cells, they still can double in population size about 20 times over without needing another cell type serving as a feeder cell layer. This is significant, because to replicate, the currently available embryonic stem cell lines require a bed of mouse cells, traces of which can end up in each new generation of stem cells. Amniotic epithelial cells, on the other hand, create their own feeder layer, with some cells choosing to spread out at the bottom of the culture dish thereby giving those cells just above them the best environment for replicating and for retaining their stem cell characteristics.
With the addition of various growth factors, the authors report the amnion-derived cells could differentiate to become liver cells, heart cells, the glial and neuronal cells that make up the nervous system, and pancreatic cells with genetic markers for insulin and glycogen production.
"In this first paper we sought to determine if amniotic epithelial cells have the potential to differentiate into many different cell types rather than focusing on ways for optimizing this potential for a specific cell type. Further studies will be required to better understand if and how they may be useful in a clinical setting," Dr. Strom added.
The researchers say their original motivation was, and still is, to identify cells with the same therapeutic promise as embryonic stem cells. To this end, they began looking at the viability of amnion as a cell source in late 2001, obtaining discarded placentas from full-term births under an Institutional Review Board-approved protocol. In 2002, the University of Pittsburgh licensed the technology to a company now called Stemnion, LLC, and as part of the agreement, and in keeping with university patent policy, Drs. Strom and Miki will receive license proceeds. Both have served as paid consultants and hold equity in Stemnion.
The research was supported by the Alpha-1 Foundation and the National Institute of Diabetes and Digestive and Kidney Diseases, a part of the National Institutes of Health. In addition to Drs. Miki and Strom, other authors are Thomas Lehmann, Ph.D., and Hongbo Cai, M.D., Ph.D., both from the department of pathology, and Donna Stolz, Ph.D., of the department of cell biology and physiology.
University of Pittsburgh Medical Center
According to U.S. census figures, there are more than 4 million live births each year. For each discarded placenta, the researchers calculate there are about 300 million amniotic epithelial cells that potentially could be expanded to between 10 and 60 billion cells relatively easily.
"Provided that research advances to the point that we can demonstrate these cells' true therapeutic benefit, parents could conceivably choose to bank their child's amniotic epithelial cells in the event they may someday be needed, as is sometimes done now with umbilical cord blood," commented Dr. Strom.
The amnion is derived from the embryo and forms as early as eight days after fertilization, when the fate of cells has yet to be determined, and serves to protect the developing fetus. According to the researchers' studies using placentas from full-term pregnancies, amniotic epithelial cells have many of the telltale surface markers that define embryonic stem cells, and also express the Oct-4 and nanog genes that are known to be required for self-renewal and pluripotency - the ability to develop into any type of cell.
Yet the authors are careful to point out that despite their remarkable similarities to embryonic stem cells, amniotic epithelial cells are not stem cells per se, because they can't grow indefinitely. This may be due to the fact that these amnion-derived cells do not express a certain enzyme, called telomerase, that is important for normal DNA and chromosome replication, and by extension, ultimately, cell division.
"Perhaps it's to their advantage that the amnion epithelial cells lack telomerase expression, because telomerase is associated with many cancers and one of the main concerns about stem cell therapies is that transplanted stem cells would replicate in the recipient to form tumors," noted Toshio Miki, M.D., Ph.D., first author of the paper and an instructor in the department of pathology at the School of Medicine.
To help determine if amnion-derived cells that are delivered directly to tissues would cause tumors, the researchers conducted studies in immune system-deficient mice and found no evidence that tumors had developed seven months after the cells were injected into multiple sites.
While amniotic epithelial cells do not share the same capacity for unlimited replication as do embryonic stem cells, they still can double in population size about 20 times over without needing another cell type serving as a feeder cell layer. This is significant, because to replicate, the currently available embryonic stem cell lines require a bed of mouse cells, traces of which can end up in each new generation of stem cells. Amniotic epithelial cells, on the other hand, create their own feeder layer, with some cells choosing to spread out at the bottom of the culture dish thereby giving those cells just above them the best environment for replicating and for retaining their stem cell characteristics.
With the addition of various growth factors, the authors report the amnion-derived cells could differentiate to become liver cells, heart cells, the glial and neuronal cells that make up the nervous system, and pancreatic cells with genetic markers for insulin and glycogen production.
"In this first paper we sought to determine if amniotic epithelial cells have the potential to differentiate into many different cell types rather than focusing on ways for optimizing this potential for a specific cell type. Further studies will be required to better understand if and how they may be useful in a clinical setting," Dr. Strom added.
The researchers say their original motivation was, and still is, to identify cells with the same therapeutic promise as embryonic stem cells. To this end, they began looking at the viability of amnion as a cell source in late 2001, obtaining discarded placentas from full-term births under an Institutional Review Board-approved protocol. In 2002, the University of Pittsburgh licensed the technology to a company now called Stemnion, LLC, and as part of the agreement, and in keeping with university patent policy, Drs. Strom and Miki will receive license proceeds. Both have served as paid consultants and hold equity in Stemnion.
The research was supported by the Alpha-1 Foundation and the National Institute of Diabetes and Digestive and Kidney Diseases, a part of the National Institutes of Health. In addition to Drs. Miki and Strom, other authors are Thomas Lehmann, Ph.D., and Hongbo Cai, M.D., Ph.D., both from the department of pathology, and Donna Stolz, Ph.D., of the department of cell biology and physiology.
University of Pittsburgh Medical Center
Embryonic Stem Cells Current Events and Embryonic Stem Cells News RSSEmbryonic stem cells might help reduce transplantation rejection
Researchers have shown that immune-defense cells influenced by embryonic stem cell-derived cells can help prevent the rejection of hearts transplanted into mice, all without the use of immunosuppressive drugs.
Stem cell regeneration repairs congenital heart defect
Mayo Clinic investigators have demonstrated that stem cells can be used to regenerate heart tissue to treat dilated cardiomyopathy, a congenital defect.
OU Cancer Institute Scientists Identify New Cancer Stem Cell Marker; Developing Drug to Stop Cancer Recurrence
After years of working toward this goal, scientists at the OU Cancer Institute have found a way to isolate cancer stem cells in tumors so they can target the cells and kill them, keeping cancer from returning.
Human embryonic stem cell secretions minimized tissue injury after heart attack
A novel way to improve survival and recovery rate after a heart attack was reported in the journal Stem Cell Research by scientists at Singapore's Institute of Medical Biology (IMB) and Bioprocessing Technology Institute (BTI) and The Netherlands' University Medical Center Utrecht.
Updated guidelines for stem cell research released
The National Academies today released amended guidelines for research involving human embryonic stem cells, revising those that were issued in 2005 and updated in 2007.
TAU Researchers Create New Stem Cell Screening Tool
Stem cell research is the next great leap in medicine. In the future, new tissue grown in a laboratory could replace a failing heart, or new cells take the place of damaged cells in the brain.
Stem cell research puts interstate rivalry on hold
Victoria and New South Wales have put aside their competitive interstate rivalry to collaborate on a stem cell research project, as announced by Innovation Minister Gavin Jennings and NSW Minister for Science and Medical Research, Verity Firth, today.
UC Riverside researcher develops novel method to grow human embryonic stem cells
The majority of researchers working with human embryonic stem cells (hESCs) - cells which produce any type of specialized adult cells in the human body - use animal-based materials for culturing the cells. But because these materials are animal-based, they could transmit viruses and other pathogens to the hESCs, making the cells unsuitable for medical use.
Protein key to control, growth of blood cells
New research sheds light on the biological events by which stem cells in the bone marrow develop into the broad variety of cells that circulate in the blood. The findings may help improve the success of bone marrow transplants and may lead to better treatments for life-threatening blood diseases.
Sugar study is sweetener for stem cell science
Scientists at The University of Manchester are striving to discover how the body's natural sugars can be used to create stem cell treatments for heart disease and nerve damage - thanks to a £370,000 funding boost.
More Embryonic Stem Cells Current Events and Embryonic Stem Cells News Articles
 | The Human Embryonic Stem Cell Debate: Science, Ethics, and Public Policy (Basic Bioethics) CHOICE Outstanding Academic Book for 2002 Human embryonic stem cells can divide indefinitely and have the potential to develop into many types of tissue. Research on these cells is essential to one of the most intriguing medical frontiers, regenerative medicine. It also raises a host of difficult ethical issues and has sparked great public interest and controversy. This book offers a... |
 | Human Embryonic Stem Cells: The Practical Handbook With this valuable practical guide, three members of the Harvard Stem Cell Institute have compiled and edited the definite handbook for the exciting new field of human embryonic stem cell research. The editors have gathered protocols from scientists with extensive reputation and expertise, describing and comparing currently used techniques for the culture of human stem cells and discussing the... |
 | Human Embryonic Stem Cell Protocols (Methods in Molecular Biology) A comprehensive collection of diverse techniques for the molecular and cellular manipulation of human embryonic stem (hES) cells. These readily reproducible methods have been optimized for the derivation, characterization, and differentiation of hES cells, with special attention given to regenerative medicine applications. A companion CD provides color versions of all illustrations in the book.... |
 | Human Embryonic Stem Cells, Second Edition by Ann Kiessling, Scott C. Anderson The second edition of Kiessling and Anderson's text, Human Embryonic Stem Cells, continues to address the social, legal and ethical debates resulting from the Bush Administrations restriction of federal funding for embryonic stem cell therapy. The emerging field of human embryonic stem cell biomedicine crosses many disciplinary boundaries -- cell biology, reproductive biology,... |
 | Embryonic Stem Cell Protocols: Volume I: Isolation and Characterization (Methods in Molecular Biology) (Methods in Molecular Biology) Now in two volumes, this completely updated and expanded edition of Embryonic Stem Cells: Methods and Protocols provides a diverse collection of readily reproducible cellular and molecular protocols for the manipulation of nonhuman embryonic stem cells. Volume one, Embryonic Stem Cell Protocols: Isolation and Characterization, Second Edition, provides a diverse collection of readily reproducible... |
 | Embryonic Stem Cells: A Practical Approach (The Practical Approach Series) The groundbreaking isolation of embryonic stem cells (or 'ES cells') of the mouse in the early 1980s triggered a sustained expansion of global research into their exploitation. This led to the routine genetic engineering of the mouse and revolutionised our understanding of biological processes in the context of the whole animal. ES cell biology remains a crucial and growing area of research with... |
 | Embryonic Stem Cells (Human Cell Culture) (Human Cell Culture) If you wish to grow or characterize embryonic stem cells or persuade them to differentiate into a particular cell type, then this book contains information that is vital to your success. The aim is to provide clear simple instructions and protocols for growing, maintaining and characterizing embryonic stem cells and details of the various methods used to make stem cells differentiate into... |
 | Human Embryonic Stem Cells (Advanced Methods ( BIOS )) by J. S. Odorico Since the first successful isolation and cultivation of human embryonic stem cells at the University of Wisconsin - Madison in 1998, there have been high levels of both interest and controversy in this area of research. This book provides a concise overview of an exciting field, covering the characteristics of both human embryonic stem cells and pluripotent stem cells from other human cell... |
 | Handbook of Stem Cells, Two-Volume Set with CD-ROM, Volume 1-2: Volume 1-Embryonic Stem Cells; Volume 2-Adult & Fetal Stem Cells by Robert Lanza, Irving Weissman, James Thomson, Roger Pedersen, Brigid Hogan, John Gearhart, Helen Blau, Douglas Melton, Malcolm Moore, Catherine Verfaillie, E. Donnall Thomas, Michael West New discoveries in the field of stem cell research have frequently appeared in the news and in scientific literature. Research in this area promises to lead to new therapies for cancer, heart disease, diabetes, and a wide variety of other diseases. This two-volume reference integrates this exciting area of biology, combining the prerequisites for a general understanding of adult and embryonic... |
 | Methods in Enzymology, Volume 418: Embryonic Stem Cells This is the first of three planned volumes in the Methods in Enzymology series on the topic of stem cells. This volume is a unique anthology of stem cell techniques written by experts from the top laboratories in the world. The contributors not only have hands-on experience in the field but often have developed the original approaches that they share with great attention to detail. The chapters... |
| © 2008 BrightSurf.com |