After all is said and done, the cost to collect, test, process and store a donated cord blood collection at a public bank is estimated to be $1,200 to $1,500 dollars for each unit banked. That does not include the expense for the regulatory and quality systems needed to maintain licensure, or the cost of collecting units that are discarded because they don’t meet standards.
Each cord blood bank has different directions for returning the consent form. Some banks may ask you to mail the consent form along with the health history forms or to bring the original consent form with you to the hospital. Other banks may have you finish the form at the hospital. Follow the directions from your public cord blood bank.
The next step at either a public or family bank is to process the cord blood to separate the blood component holding stem cells. The final product has a volume of 25 milliliters and includes a cryoprotectant which prevents the cells from bursting when frozen. Typical cost, $250 to $300 per unit.
Because of these limitations and the uncommon occurrence of the diseases treatable with stem cell transplant, there have been just more than 400 autologous cord blood transplants in United States in the last two decades. In contrast, more than 60,000 unrelated donor cord blood transplants have been performed worldwide.
If someone doesn’t have cord blood stored, they will have to rely on stem cells from another source. For that, we can go back to the history of cord blood, which really begins with bone marrow. Bone marrow contains similar although less effective and possibly tainted versions of the same stem cells abundant in cord blood. Scientists performed the first bone marrow stem cell transplant in 1956 between identical twins. It resulted in the complete remission of the one twin’s leukemia.
Medical staff at the public cord blood bank will check to see if you can donate. If you have had a disease that can be given to another person through blood-forming cells, such as hepatitis B, hepatitis C, or HIV (the AIDS virus), you will likely not be able to donate. However, other medical reasons may still allow you to donate, for example, hepatitis A or diabetes only during your pregnancy (gestational diabetes). The staff at the public cord blood bank will tell you.
To prevent graft-versus-host disease and help ensure engraftment, the stem cells being transfused need to match the cells of the patient completely or to a certain degree (depending on what is being treated). Cord blood taken from a baby’s umbilical cord is always a perfect match for the baby. In addition, immediate family members are more likely to also be a match for the banked cord blood. Siblings have a 25 percent chance of being a perfect match and a 50 percent chance of being a partial match. Parents, who each provide half the markers used in matching, have a 100% chance of being a partial match. Even aunts, uncles, grandparents and other extended family members have a higher probability of being a match and could possibly benefit from the banked cord blood. Read more reasons why you should bank cord blood.
Cord blood is currently approved by the FDA for the treatment for nearly 80 diseases, and cord blood treatments have been performed more than 35,000 times around the globe to treat cancers (including lymphoma and leukemia), anemias, inherited metabolic disorders and some solid tumors and orthopedic repair. Researchers are also exploring how cord blood has the ability to cross the blood–brain barrier and differentiate into neurons and other brain cells, which may be instrumental in treating conditions that have been untreatable up to this point. The most exciting of these are autism, cerebral palsy and Alzheimer’s.
Donating your baby’s umbilical cord blood may offer a precious resource to a patient in need of a life-saving stem cell transplant. Umbilical cord blood is rich in blood-forming stem cells, which can renew themselves and grow into mature blood cells. After your baby is born, these cord blood cells can be collected, preserved and later used as a source of stem cells for transplantation for patients with leukemia, lymphoma, and other life-threatening blood diseases.
In Europe and other parts of the world, cord blood banking is more often referred to as stem cell banking. As banking cord blood is designed more to collect the blood-forming stem cells and not the actual blood cells themselves, this term may be more appropriate.
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.
^ Reddi, AS; Kuppasani, K; Ende, N (December 2010). “Human umbilical cord blood as an emerging stem cell therapy for diabetes mellitus”. Current stem cell research & therapy. 5 (4): 356–61. doi:10.2174/157488810793351668. PMID 20528762.
Cord blood stem cells are classified as adult (or non-embryonic) stem cells. Embryonic stem cells (ESC) are believed to be more advantageous for the treatment of disease or injury due to their pluripotent nature; that is, they have the ability to differentiate into all the cells present in the human body derived from the three germ layers (endoderm, mesoderm, and ectoderm). Adult stem cells are multipotent, implying that they can only differentiate into a limited number of cells typically within the same “family” (e.g., hematopoietic stem cells give rise to red blood cells, white blood cells, and platelets).
Cord blood holds promise for future medical procedures. Scientists are still studying more ways to treat more diseases with cord blood. At Duke University, for example, researchers are using patients’ own cord blood in trials for cerebral palsy and Hypoxic ischemic encephalopathy (a condition in which the brain does not receive enough oxygen). Trials are also under way for the treatment of autism at the Sutter Neuroscience Institute in Sacramento, California.
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).
Complicating matters further, each public bank has its own registry, so transplant centers must search many different databases to find a match for a patient. Currently, a Caucasian patient has an 88 percent chance of finding a cord-blood match through a public-bank registry, and minorities have a 58 percent chance. (Collection hospitals tend to be in areas with higher rates of Caucasian births, and parents from certain ethnic groups are wary of donating for religious or cultural reasons.)
Cord Blood Registry offers two ways to save your newborn’s stem cells, and convenient payment options to fit your family’s needs. CBR recognizes that each family’s budget is unique. As a result, CBR does not take a one-size-fits-all approach to pricing and payments for cord blood and tissue banking. Calculate your stem cell banking costs and CBR will recommend payment plans that may fit your family’s budget.
In terms of performance, our PrepaCyte-CB processing method has taken the lead. PrepaCyte-CB greatly improves on parents’ returns on investment because it yields the highest number of stem cells while showing the greatest reduction in red blood cells.1–4 Clinical transplant data show that cord blood processed with PrepaCyte-CB engrafts more quickly than other processing methods.7 This means patients may start feeling better more quickly, may spend less time in the hospital and are less likely to suffer from an infection. The ability to get better more quickly and a reduced chance of infection can prove vital in certain cases. Learn more about PrepaCyte®-CB here.
Luckily for expectant parents, cord blood can be easily collected at the baby’s birth via the umbilical cord with no harm to the mother or baby. This is why pregnancy is a great time to plan to collect and bank a baby’s cord blood.
 American Academy of Pediatrics Section on Hematology/Oncology, American Academy of Pediatrics Section on Allergy/Immunology, Bertram H. Lubin, and William T. Shearer, “Cord Blood Banking for Potential Future Transplantation,” Pediatrics 119 (2007): 165-170.
Families have the additional option of storing a section of the umbilical cord, which is rich in unique and powerful stem cells that may help repair and heal the body in different ways than stem cells derived from cord blood.
In addition to the use of cord blood stem cells for transplantation, cord blood stem cells are currently being investigated for use in stem cell therapy. Cord blood stem cells are multipotent and are believed to have greater plasticity (the ability to form into different stem cell types) than adult hematopoietic stem cells found in bone marrow. HSCs are being investigated for use in autoimmune diseases such as diabetes, rheumatoid arthritis, and systemic lupus erythermatosis (SLE) in order to reprogram or reconstitute the immune system. Additionally, research is being conducted on differentiating HSCs into other tissue types such as skeletal and cardiac muscle, liver cells (hepatocytes), and neurons. HSCs are currently being used in gene therapy, due to their self-renewing properties, as a means of delivering genes to repair damaged cells. HSCs are the only cells currently being used in this manner in clinical gene therapy trials.
The parents who make the decision to store their baby’s cord blood and cord tissue are thinking ahead, wanting to do right from the start (even before the start), and taking steps to do whatever they can to protect their baby down the road. Today, many conscientious parents are also considering delayed cord clamping (DCC), a practice in which the umbilical cord is not clamped immediately but rather after it continues to pulse for an average of 30 seconds to 180 seconds. Many parents don’t realize that they can delay the clamping of the cord and still bank their baby’s cord blood. As noted early, our premium processing method, PrepaCyte-CB, is able to capture more immune system cells and reduce the greatest number of red blood cell contaminants. This makes it go hand in hand with delayed cord clamping because it is not as affected by volume, effectively making up for the smaller quantity with a superior quality. You can read more about delayed cord clamping vs. cord blood banking here.
ViaCord’s Lab is FDA registered, AABB accredited, CLIA certified and equipped with the same freezers used by major research institutions such as Centers for Disease Control and Prevention and the National Institutes of Health.
Here are 5 Things You Need to Know About Cord Blood Before You Deliver Your Baby according to @TodaysMama #cordblood #cordbloodbanking #cordbloodregistry #newborn #stemcell todaysmama.com/2017/12/5-thin… via @todaysmama
There have been several reports suggesting that cord blood may contain other types of stem cells which can produce specialised cells that do not belong to the blood, such as nerve cells. These findings are highly controversial among scientists and are not widely accepted.
There are so many things to think about when you have a child. One of them is the blood from your baby’s umbilical cord (which connects the baby to the mother while in the womb). It used to be thrown away at birth, but now, many parents store the blood for the future health of their child. Should you do it?
Throughout pregnancy your baby’s umbilical nurtures life. It carries oxygen-rich cells and nutrients from your placenta to your baby and then allows your baby to pump deoxygenated and nutrient-depleted blood back to your placenta. This constant exchange is protected by a special type of tissue that acts like a cushion, preventing twisting and compression to ensure that the cord blood flow remains steady and constant.
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.
It depends on who you ask. Although commercial cord blood banks often bill their services as “biological insurance” against future diseases, the blood doesn’t often get used. One study says the chance that a child will use their cord blood over their lifetime is between 1 in 400 and 1 in 200,000.
Some controversial studies suggest that cord blood can help treat diseases other than blood diseases, but often these results cannot be reproduced. Researchers are actively investigating if cord blood might be used to treat various other diseases.
In fact, the shocking truth is that the majority of all cord blood stored in private banks may be unusable. Approximately 75 percent of the units donated to public banks are discarded or used in research because they don’t contain enough stem cells for transplants, says Mary Halet, manager of cord-blood operations for the Center for Cord Blood at the National Marrow Donor Program, a Minneapolis-based nonprofit organization that maintains the nation’s largest public supply of cord blood. Yet private banks store every unit they collect, which means that you might pay to store blood that won’t be usable if you need it years later.