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There are several cord blood banks that are accredited by the American Association of Blood Banks. Most offer information on cord blood banking and provide private cord blood banking services. With a little research, you should be able to locate a credible cord blood bank online.
If you received your information in the mail, you can give them the reminder post card that was sent to you. During the admission process you may be asked if you want to be a cord blood donor. In the event that you had not pre-registered, you can still donate and complete all the necessary paperwork at the hospital.
There are also hundreds of human clinical trials being performed using cord blood to treat conditions and diseases that affect millions of people in the U.S. alone. These trials involve regenerative medicine and other applications for the treatment of Diabetes, Cerebral Palsy, Autism, Strokes, Neonatal & Pediatric Brain Injury, Alzheimer’s & Spinal Cord Injury to name a few (see www.clinicaltrials.gov). The existence of clinical trials does not guarantee that cord blood will be successful in the treatment of those diseases in the future. While you can’t plan on health issues your child may face, you can have possible treatment options.
Cord blood banking is the process of collecting and storing your baby’s umbilical cord blood stem cells for potential medical use. ViaCord also offers parents the option to collect and store stem cells found in the tissue of the umbilical cord. This is known as cord tissue banking. Our approach to cord blood and cord tissue banking is simple: Apply the most advanced science to deliver the highest-quality stem cell collection and storage process in order to achieve the best results for families. That approach has guided our growth and success for nearly twenty-five years.
Current research aims to answer these questions in order to establish whether safe and effective treatments for non-blood diseases could be developed in the future using cord blood. An early clinical trial investigating cord blood treatment of childhood type 1 diabetes was unsuccessful. Other very early stage clinical trials are now exploring the use of cord blood transplants to treat children with brain disorders such as cerebral palsy or traumatic brain injury. However, such trials have not yet shown any positive effects and most scientists believe much more laboratory research is needed to understand how cord blood cells behave and whether they may be useful in these kinds of treatments
Once a cord blood donation has been saved, it may be listed on a national registry that can be searched to find a match for a transplant patient. The donation could be released to any recipient who is compatible.
From these findings, it is suggested that UCM cells offer advantages over stem cells as a source of therapeutic cells. First, UCM cells are derived from a noncontroversial, inexhaustible source, and can be harvested noninvasively at low cost. Second, unlike human ESCs, UCM cells did not induce teratomas or death after 1 × 106 to 6 × 106 human UCM cells were transplanted either intravenously or subcutaneously into severe combined immunodeficient beige mice (Rachakatla, Medicetty, Burton, Troyer, and Weiss, unpublished observations). Third, UCM cells are easy to start and do not require feeder layers or medium containing high serum concentrations to be maintained. Fourth, they are not acutely rejected when transplanted as xenografts in nonimmune-suppressed rats. For example, we demonstrated that pig UCM cells undergo a moderated expansion following transplantation into rat brain without obvious untoward behavioral effects or host immune response (25).
The Leading the Way LifeSaving Ambassadors Club is a recognition program honoring sponsor groups for outstanding performance in reaching or exceeding blood drive collections goals. CBC presents a Leading the Way plaque to winning sponsors on an annual basis. The award is based on three levels of achievement:
The stem cells from your baby’s cord blood may also be effective in treating certain diseases or conditions of a parent or sibling. Cord blood stem cells have similar ability to treat disease as bone marrow but with significantly less rejection.
Stem cells are defined simply as cells meeting three basic criteria (illustrated in Fig. 1. First, stem cells renew themselves throughout life, i.e., the cells divide to produce identical daughter cells and thereby maintain the stem cell population. Second, stem cells have the capacity to undergo differentiation to become specialized progeny cells (1). When stem cells differentiate, they may divide asymmetrically to yield an identical cell and a daughter cell that acquires properties of a particular cell type, for example, specific morphology, phenotype, and physiological properties that categorize it as a cell belonging to a particular tissue (2). Stem cells that may differentiate into tissues derived from all three germ layers, for example, ectoderm, endoderm, and mesoderm, are called “pluripotent.” The best example of pluripotent stem cells are the embryonic stem cells (ESCs) derived from the inner cell mass of early embryos. In contrast with ESCs, most stem cells that have been well characterized are multipotent, i.e., they may differentiate into derivatives of two of the three germ layers. The third property of stem cells is that they may renew the tissues that they populate. All tissue compartments contain cells that satisfy the definition of “stem cells” (3), and the rate at which stem cells contribute to replacement cells varies throughout the body. For example, blood-forming stem cells, gut epithelium stem cells, and skin-forming stem cells must be constantly replaced for normal health. In contrast, the stem cells in the nervous system that replace neurons are relatively quiescent and do not participate in tissue renewal or replace neurons lost to injury or disease.
There are some hospitals that have dedicated collections staff who can process mothers at the last minute when they arrive to deliver the baby. However, in the United States that is the exception to the rule.
And as Victor and Tracey Dones learned, a child’s own cord blood can’t always be used to treat him, even when he’s young. “Childhood leukemia is one of the diseases private banks like to play up, but most kids with leukemia are cured with chemotherapy alone. If a transplant is needed, we wouldn’t use a child’s tainted cord blood,” Dr. Kurtzberg says.
Genes: Segments of DNA that contain instructions for the development of a person’s physical traits and control of the processes in the body. They are the basic units of heredity and can be passed down from parent to offspring.
As most parents would like to bank their babies’ cord blood to help safeguard their families, it is often the cost of cord blood banking that is the one reason why they do not. Most cord blood banks have an upfront fee for collecting, processing and cryo-preserving the cord blood that runs between $1,000 and $2,000. This upfront fee often also includes the price of the kit provided to collect and safely transport the cord blood, the medical courier service used to expedite the kit’s safe shipment, the testing of the mother’s blood for any infectious diseases, the testing of the baby’s blood for any contamination, and the cost of the first full year of storage. There is then often a yearly fee on the baby’s birthday for continued storage that runs around $100 to $200 a year.
Recently the minimal defining characteristics of MSCs was the subject of a blue ribbon panel of scientists (24). This panel ascribed three defining characteristics to MSCs. First, MSCs are plastic-adherent when maintained in standard culture conditions. Second, MSCs express the cell surface markers CD105, CD73, and CD90 and lack expression of CD45, CD34, CD14 or CD11b, CD79 or CD19, and HLA-DR. Third, MSCs differentiate to osteoblasts, adipocytes, and chondroblasts in vitro. As shown in Table 1, mesenchymal-like cells collected from the umbilical cord, placenta, and from umbilical cord blood, perivascular space, and placenta all share a relatively consistent set of surface markers, which is apparently consistent with the hypothesis that they are MSC-like.
But considering the average cost of a new car or top-of-the-line stroller these days, many expectant parents feel it’s not an unreasonable price to pay to give their child the best chance in life. “Ultimately, my conscience wouldn’t let me not do it,” says Merilee Kern, of San Diego. “We could afford it, and the blood could someday save my daughter.”
HSCs can become any type of blood cell or cellular blood component inside the body, including white blood cells and red blood cells. These cells are found in umbilical cord blood and are multipotent, which means they can develop into more than one cell type.
CORD:USE is directed by leading doctors in cord blood transplantation. Public donations collected by CORD:USE are sent to the Carolinas Cord Blood Bank, a FACT-accredited laboratory under the direction of Dr. Joanne Kurtzberg.
Finally, the healthy stem cells are placed into long-term cryogenic storage. Compared to other stem cell sources, cord blood units are available very quickly since a doctor can remove them from storage and send them to the transplant hospital within a few days.
Students who register to donate blood three or more times during their high school career earn a Red Cord to wear during graduation events. Seniors must complete the requirement by May 15 (or by the date of their school’s final blood drive of the year, whichever is later).
Dr. C. L. Cetrulo is thanked for critically reviewing the manuscript. Thanks to Dr. M. S. Rao and the members of the stem cell laboratory at NIA for their hospitality during my sabbatical leave and their continued assistance with this work. Thanks to my wife, Betti, and my children, Rita, Jonathan, Ellen, and James, for their patience and understanding. Dr. S. Bennet is thanked for assisting with umbilical cord collection. The anonymous donors are thanked for donating their umbilical cords. The Midwest Institute for Comparative Stem Cell Biology members who contributed to this work: M. Pyle, J. Hix, R. Rakasheklar, D. Davis, R. Carlin, D. Davis, S. Medicety, K. Seshareddy, C. Anderson, and M. Burton are thanked for their assistance. Thanks to our collaborators at ViaCell, Inc. (E. Abraham and A. Krivtsov, M. Kraus, S. Wnendt, and J. Visser) and at Athersys, Inc. (R. Deans and A. Ting) for their assistance and support. Drs. H. Klingemann (Tufts) and F. Marini (MD Anderson) are thanked for sharing the results of their ongoing work. This work was supported by National Institutes of Health (NIH) (salary support during sabbatical leave), Department of Anatomy and Physiology, College of Veterinary Medicine Dean’s office, Terry C. Johnson center for Basic Cancer Research and NIH NS034160. MLW is a paid consultant for RMI (Las Vegas, NV).
While all three stem cell sources are used in similar procedures, they each have advantages and drawbacks. Bone marrow transplants are the traditional form of therapy, but peripheral blood cells are becoming more popular, since doctors often get more stem cells from the bloodstream.
If you or your spouse or partner has a family history of a disease that is treatable with stem cells, or if a family member is currently in need of a stem cell transplant, private cord blood banking could be the right choice for you. To read more reasons to consider private cord blood banking, click here.
2 – Cbr, cord blood registry, Cbr families’ stem cell units used to date. [Available at http://www.cordblood.com/best-cord-blood-bank/stem-cell-therapy/advancing-stem-cell-therapies (accessed Oct 13, 2015)].
In addition to hematopoietic cells, Mesenchymal cells derived from Wharton’s jelly are useful as feeder layers for the propagation of other stem cell types. For example, equine embryonic stem cell-like cells derived from the inner cell mass were propagated successfully for more than 350 divisions on a feeder layer derived from stem cells isolated from Wharton’s jelly of equine umbilical cords (74). The equine ES-like cells could be maintained without leukemia inhibitory factor (LIF) as long as they were on the cord matrix cells.
When a patient needs bone marrow for a transplant, stem cells are thawed and injected into the bloodstream. The cells then make their way to the bone marrow, and start producing new blood cells – this process usually takes a few weeks.
Since most banks require mothers to sign up for donation between the 28th and 34th week of pregnancy, families must decide to donate ahead of time. If you are considering a public bank for your child’s cord blood, contact the bank and make sure you still have time.
The blood that remains in the umbilical cord and the placenta after birth is called “cord blood”. Umbilical cord blood, umbilical cord tissue, and the placenta are all very rich sources of newborn stem cells. The stem cells in the after birth are not embryonic. Most of the stem cells in cord blood are blood-forming or hematopoietic stem cells. Most of the stem cells in cord tissue and the placenta are mesenchymal stem cells.
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Hematopoietic stem cells can be used to treat more than 70 types of diseases, including diseases of the immune system, genetic disorders, neurologic disorders, and some forms of cancer, including leukemia and lymphoma. For some of these diseases, stem cells are the primary treatment. For others, treatment with stem cells may be used when other treatments have not worked or in experimental research programs.
Banking your child’s cord blood really comes down your personal choice. Some people may seem the potential benefits, while others can’t justify the costs. No one debates cord blood cells being a lifesaver, and in recent years, more than 20,000 lives have been saved because of it; however, experts, such as The American Academy of Pediatrics, note that your odds of using this blood is about one in 200,000. Instead of buying into a company’s advertising scheme, be sure to do your own research and deem what’s best for your child’s future.
More cord blood donations are desperately needed to cover the transplant needs of adults. Cord blood donations from newborns of diverse ethnic and racial backgrounds are especially needed. Tissue types are inherited, so patients who need a stem cell transplant are more likely to find a matched cord blood unit from someone in their own race or ethnic group.
The range of diseases that doctors can treat with cord blood is vast. More than 80 diseases are currently known to respond to cord blood stem cells transplants and, as more are studied and tested, that number is sure to grow.
Another type of cell that can also be collected from umbilical cord blood are mesenchymal stromal cells. These cells can grown into bone, cartilage and other types of tissues and are being used in many research studies to see if patients could benefit from these cells too.
Umbilical cord blood was once discarded as waste material but is now known to be a useful source of blood stem cells. Cord blood has been used to treat children with certain blood diseases since 1989 and research on using it to treat adults is making progress. So what are the current challenges for cord blood research and how may it be used – now and in the future?
With the consent of the parents, blood can be collected from the umbilical cord of a newborn baby shortly after birth. This does not hurt the baby or the mother in any way, and it is blood that would otherwise be discarded as biological waste along with the placenta (another rich source of stem cells) after the birth.