They aren’t the only ones questioning the business practices of private cord-blood banks. Both the American College of Obstetricians and Gynecologists (ACOG) and the American Academy of Pediatrics (AAP) issued statements in the late 1990s opposing the use of for-profit banks — and criticizing their marketing tactics. Instead, they recommended that parents donate cord blood to public banks, which make it available for free to anyone who needs it. Globally, other organizations have done the same. Italy and France have banned private cord-blood banking altogether.
If you make a donation to a public cord blood bank, you can’t reserve it for your family, so it may not be available for your future use. Both the American Academy of Pediatrics (AAP) and American Medical Association (AMA) recommend public cord blood banking over private cord blood banking. Here’s why:
Not surprisingly, this emotional pitch is working — especially because the seemingly unlimited potential of stem cells has dominated the news in recent years. From 2003 to 2004, for example, the number of couples opting to use a private bank increased by 55 percent to 271,000. The three biggest companies — who have the majority of the approximately $250 million market — are vying for business.
Checked to make sure it has enough blood-forming cells for a transplant. (If there are too few cells, the cord blood unit may be used for research to improve the transplant process for future patients or to investigate new therapies using cord blood, or discarded.)
You and your baby’s personal information are always kept private by the public cord blood bank. The cord blood unit is given a number at the hospital, and this is how it is listed on the registry and at the public cord blood bank.
Blood from the umbilical cord and placenta is put into a sterile bag. (The blood is put into the bag either before or after the placenta is delivered, depending upon the procedure of the cord blood bank.)
It’s possible that storing your child’s cord blood cells now may be useful one day in combating these diseases. For now, these treatments are only theoretical. It’s also not clear if stem cells from cord blood — as opposed to stem cells from other sources — will be useful in these potential treatments.
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.”
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Stem cells from cord blood can be used for the newborn, their siblings, and potetinally other relatives. Patients with genetic disorders like cystic fibrosis, cannot use their own cord blood and will need stem cells from a sibling’s cord blood. In the case of leukemia or other blood disorders, a child can use either their own cord blood or their sibling’s for treatment.
Frances Verter, PhD, founded the Parent’s Guide to Cord Blood in 1998 and has been a Scientific Advisor to Community Blood Services since 2007. In 2011 the NMDP presented her with their Lifeline Award in recognition of her efforts to improve public education about cord blood donation.
The use of cord blood is determined by the treating physician and is influenced by many factors, including the patient’s medical condition, the characteristics of the sample, and whether the cord blood should come from the patient or an appropriately matched donor. Cord blood has established uses in transplant medicine; however, its use in regenerative medicine is still being researched. There is no guarantee that treatments being studied in the laboratory, clinical trials, or other experimental treatments will be available in the future.
Cord blood contains mesenchymal stem cells but is much more abundant in hematopoietic stem cells. Cord tissue, on the other hand, contains some hematopoietic stem cells but is much richer in mesenchymal stem cells. Cord tissue, or Wharton’s jelly, is the protective layer that covers the umbilical cord’s vein and other vessels. Its MSCs can become a host of cells including those found in the nervous system, sensory organs, circulatory tissues, skin, bone, cartilage, and more. MSCs are currently undergoing clinical trials for sports injuries, heart and kidney disease, ALS, wound healing and autoimmune disease. As with cord blood, cord tissue is easily collected at the type of birth and holds great potential in regenerative medicine. Learn more about cord tissue banking here.
While the transplantation of cord blood has its advantages, its main disadvantage is the limited amount of blood contained within a single umbilical cord. Because of this, cord blood is most often transplanted in children. Physicians are currently trying to determine ways that cord blood can be used in larger patients, such as transferring two cord blood units or increasing the number of cells in vitro before transplanting to the patient. It also takes longer for cord blood cells to engraft. This lengthier period means that the patient is at a higher risk for infection until the transplanted cells engraft. Patients also cannot get additional donations from the same donor if the cells do not engraft or if the patient relapses. If this is the case, an additional cord blood unit or an adult donor may be used. While cord blood is screened for a variety of common genetic diseases, rare genetic diseases that manifest after birth may be passed on. The National Cord Blood Program estimates that the risk of transmitting a rare genetic disorder is approximately 1 in 10,000.
There are many “what if” situations that we all consider in our life. One of the most serious is “What if a child or other family member was to become seriously ill?” Cord Blood Banking clinics have been growing exponentially in response to this…
The standard used to identify these cord blood banks was the number of cord blood and cord tissue units stored by each company. The purpose of this analysis is to compare pricing and services among the largest cord blood banks within the U.S., the most mature cord blood banking market in the world. These three industry giants also represent several of the largest cord blood banks worldwide.
The baby’s cord blood will be processed and stored in a laboratory facility, often referred to as a blood bank. The cord blood should be processed and stored in a facility that is accredited by the American Association of Blood Banks (AABB) for the purpose of handling stem cells.
Like most transplants, the stem cells must be a genetic match with the patients to be accepted by the body’s immune system. It goes without saying that a patient’s own cord blood will be a 100% match. The second highest chance of a genetic match comes from siblings.
Your child may never need it. Stem cell-rich cord blood can be used to treat a range of diseases, but Frances Verter, Ph.D., founder and director of Parent’s Guide to Cord Blood Foundation, estimates that there’s only a 1 in 217 chance that your child will ever need a stem cell transplant with cord blood (or bone marrow). This is particularly true if the child doesn’t have a family history of diseases such as leukemia, lymphoma, or sickle cell anemia. Although the American Academy of Pediatrics (AAP) states cord blood has been used to treat certain diseases successfully, there isn’t strong evidence to support cord blood banking. If a family does choose to bank cord blood, the AAP recommends public cord blood banking (instead of private) to cut down on expenditures.
After your baby is born, the umbilical cord and placenta are usually thrown away. Because you are choosing to donate, the blood left in the umbilical cord and placenta will be collected and tested. Cord blood that meets standards for transplant will be stored at the public cord blood bank until needed by a patient. (It is not saved for your family.)
However, parents should know that a child’s own cord blood (stored at birth), would rarely be suitable for a transplant today. It could not be used at present to treat genetic diseases, for example, because the cord blood stem cells carry the same affected genes and. if transplanted, would confer the same condition to the recipient. (See the story of Anthony Dones.) In addition, most transplant physicians would not use a child’s own cord blood to treat leukemia. There are two reasons why the child’s own cord blood is not safe as a transplant source. First, in most cases of childhood leukemia, cells carrying the leukemic mutation are already present at birth and can be demonstrated in the cord blood. Thus, pre-leukemic cells may be given back with the transplant, since there is no effective way to remove them (purge) today. Second, in a child with leukemia, the immune system has already failed to prevent leukemia. Since cord blood from the same child re-establishes the child’s own immune system, doctors fear it would have a poor anti-leukemia effect.
The Doneses were shocked, however, when doctors told them that Anthony’s cord blood couldn’t be used because the cells contained the same genetic defect that caused his condition. “The materials provided by the bank said this was Anthony’s life insurance and could save him if he needed it. They never mentioned that the cells could be diseased. We felt duped,” Tracey says. The Long Island, New York, couple has since filed a lawsuit against the bank alleging false advertising and consumer fraud.
On average, the transport time for stem cells from the hospital to CBR’s lab is 19 hours. CBR partners with Quick International, a private medical courier service with 30 years of experience in the transportation of blood and tissue for transplant and research.
When a child develops a condition that can be treated with stem cells, they undergo transplant. A doctor infuses stem cells from cord blood or bone marrow into the patient’s bloodstream, where they will turn into cells that fight the disease and repair damaged cells—essentially, they replace and rejuvenate the existing immune system.
To learn more about umbilical cord blood and banking please watch Banking on cord blood, Cord blood – banking and uses, Cord blood transplantation – how stem cells can assist in the treatment of cancer in our video library.
Yes, if you have any sick children who could benefit from umbilical cord blood. Public banks such as Carolinas Cord Bank at Duke University and private banks such as FamilyCord in Los Angeles offer programs in which the bank will assist with cord blood processing and storage if your baby has a biological sibling with certain diseases. FamilyCord will provide free cord blood storage for one year. See a list of banks with these programs at parentsguidecordblood.org/help.php.
LifebankUSA seeks mothers in NEW YORK & NEW JERSEY ONLY who will donate both their cord blood and their placenta. The donations support an international registry, clinical trials and research. Donations can be taken from any hospital, but mothers must register at least 8 weeks prior to delivery and pass a health screening.
The majority of programs that accept cord blood donations require the mother to sign up in advance. In the united States, the current requirement is to sign up by the 34th week of pregnancy. This cannot be over-stressed; time and time again, mothers who want to donate are turned away because they did not inquire about donation until it was too late.
The Celebration Stem Cell Centre (CSCC), offers both public donation and private “family banking” of umbilical cord blood. All cord blood collections are processed according to the highest standards in the industry in a new, state-of-the art facility located in Gilbert, Arizona. The public cord blood donation program is funded by the private “family banking” program and private philanthropy.
The umbilical cord blood contains haematopoietic stem cells – similar to those found in the bone marrow – and which can be used to generate red blood cells and cells of the immune system. Cord blood stem cells are currently used to treat a range of blood disorders and immune system conditions such as leukaemia, anaemia and autoimmune diseases. These stem cells are used largely in the treatment of children but have also started being used in adults following chemotherapy treatment.
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.
Private cord blood banking can benefit those with a strong family history of certain diseases that harm the blood and immune system, such as leukemia and some cancers, sickle-cell anemia, and some metabolic disorders. Parents who already have a child (in a household with biological siblings) who is sick with one of these diseases have the greatest chance of finding a match with their baby’s cord blood. Parents who have a family history of autism, Alzheimer’s, and type 1 diabetes can benefit from cord blood. Although these diseases aren’t currently treated with umbilical cord steam cells, researchers are exploring ways to treat them (and many more) with cord blood.
In Europe, Canada, and Australia use of cord blood is regulated as well. In the United Kingdom the NHS Cord Blood Bank was set up in 1996 to collect, process, store and supply cord blood; it is a public cord blood bank and part of the NHS.
As noted, there are different ways to process cord blood, and although the type of processing method doesn’t always enter the conversation on cord blood banking, it is a big part of the purity of any cord blood collection. Red blood cells can have a negative impact on a cord blood transfusion. In addition, there is a certain number of stem cells that need to be present in order for the cord blood to be effective in disease treatment. Each processing method has the ability to better reduce the number of RBCs and capture more stem cells. Some processing methods like AutoXpress and Sepax are automated to ensure a level of consistency across all collections. HES is preferred by some banks because it was the original processing method used by most banks and it has a proven track record. You can read more about the different cord blood processing methods here.