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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.
The harvested bone marrow is then processed to remove blood and bone fragments. Harvested bone marrow can be combined with a preservative and frozen to keep the stem cells alive until they are needed. This technique is known as cryopreservation. Stem cells can be cryopreserved for many years.
Cord Blood Registry is a registered trademark of CBR® Systems, Inc. Annual grant support for Parent’s Guide to Cord Blood Foundation is made possible by CBR® through the Newborn Possibilities Fund administered by Tides Foundation.
Cord tissue use is still in early research stages, and there is no guarantee that treatments using cord tissue will be available in the future. Cord tissue is stored whole. Additional processing prior to use will be required to extract and prepare any of the multiple cell types from cryopreserved cord tissue. Cbr Systems, Inc.’s activities for New York State residents are limited to collection of umbilical cord tissue and long-term storage of umbilical cord–derived stem cells. Cbr Systems, Inc.’s possession of a New York State license for such collection and long-term storage does not indicate approval or endorsement of possible future uses or future suitability of these cells.
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.
If you do decide to bank your baby’s cord blood, there’s one more thing to keep in mind: It’s best not to make it a last-minute decision. You should coordinate with the bank before your baby is born so nothing is left to chance.
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.
Sutter Neuroscience Institute has conducted a landmark FDA-regulated phase II clinical trial to assess the use of autologous stem cells derived from cord blood to improve language and behavior in certain children with autism.
There are over 130 public cord blood banks in 35 countries. They are regulated by Governments and adhere to internationally agreed standards regarding safety, sample quality and ethical issues. In the UK, several NHS facilities within the National Blood Service harvest and store altruistically donated umbilical cord blood. Trained staff, working separately from those providing care to the mother and newborn child, collect the cord blood. The mother may consent to donate the blood for research and/or clinical use and the cord blood bank will make the blood available for use as appropriate.
Banking cord blood is a new type of medical protection, and there are a lot of questions that parents may want to ask. The Parent’s Guide to Cord Blood organization even has questions it believes all parents should ask their cord blood banks. We have answers to these and other frequently asked cord blood questions in our FAQs. If you can’t find the answer for which you are looking, please feel free to engage one of our cord blood educators through the website’s chat interface.
Save by paying in advance for 21 years of storage through our long-term storage plan. This plan covers all the initial fees (collection kit, courier service, processing, and preservation) and the cost of 21 years of continuous storage. A lifetime plan is also available; call for details.
Upon arrival at CBR’s laboratory, the kit is immediately checked in and inspected. Next, the cord blood unit is tested for sterility, viability, and cell count. In addition, the cord tissue is tested for sterility. CBR processes cord blood using the AutoXpress® Platform* (AXP®) – a fully automated, functionally closed stem cell processing technology. The AXP platform is an integral component of CBR’s proprietary CellAdvantage® system. CBR has the industry’s highest published average cell recovery rate of 99%.
Bone marrow transplantation (BMT) and peripheral blood stem cell transplantation (PBSCT) are procedures that restore stem cells that have been destroyed by high doses of chemotherapy and/or radiation therapy. There are three types of transplants:
Cord Blood Registry is headquartered in South San Francisco, California. CBR owns their 80,000 square foot laboratory located in Tucson, Arizona. CBR’s laboratory processes cord blood collections seven days a week, 365 days a year. The state-of-the-art facility has the capacity to store the stem cell samples of five million newborns.
Once it arrives at the storage facility, the cord blood will be processed and placed in storage. The cord blood will either be completely immersed in liquid nitrogen or it will be stored in nitrogen vapor.
While banking cord blood is a new experience for many parents, it is a simple one. After all, most mothers are worried about how the delivery will go and don’t want to also be worried about the details of collecting, processing and cryo-preserving their babies’s cord blood. Thankfully, the healthcare provider and the cord blood bank do most of the work. Here are the steps found in cord blood banking:
A list of U.S. transplant centers that perform allogeneic transplants can be found at BeTheMatch.org/access. The list includes descriptions of the centers, their transplant experience, and survival statistics, as well as financial and contact information.
A major limitation of cord blood transplantation is that the blood obtained from a single umbilical cord does not contain as many haematopoeitic stem cells as a bone marrow donation. Scientists believe this is the main reason that treating adult patients with cord blood is so difficult: adults are larger and need more HSCs than children. A transplant containing too few HSCs may fail or could lead to slow formation of new blood in the body in the early days after transplantation. This serious complication has been partially overcome by transplanting blood from two umbilical cords into larger children and adults. Results of clinical trials into double cord blood transplants (in place of bone marrow transplants) have shown the technique to be very successful. Some researchers have also tried to increase the total number of HSCs obtained from each umbilical cord by collecting additional blood from the placenta.
Currently, ViaCord has released the most cord blood units for medical transplant and has the highest cord blood transplant survival rate among companies who have disclosed complete transplant data. The one-year survival rate of patients who were treated with ViaCord cord blood units is 88%, and the long-term patient survival rate is 82%.1
The use of hematopoietic stem cells, which can be found in the blood that remains in the vein of the umbilical cord and placenta after birth, is a proven treatment of more than 80 diseases. Mesenchymal stem cells, which can be found in the umbilical cord tissue and can become a host of cells including those found in your nervous system, sensory organs, circulatory tissues, skin, bone, cartilage, and more, are making progress in clinical trials. Some such trials show promise in treating strokes, heart disease, diabetes, autism, cerebral palsy and Alzheimer’s disease.
^ a b Walther, Mary Margaret (2009). “Chapter 39. Cord Blood Hematopoietic Cell Transplantation”. In Appelbaum, Frederick R.; Forman, Stephen J.; Negrin, Robert S.; Blume, Karl G. Thomas’ hematopoietic cell transplantation stem cell transplantation (4th ed.). Oxford: Wiley-Blackwell. ISBN 9781444303537.
Tracey Dones of Hicksville, N.Y., paid to bank her son Anthony’s cord blood. But four months after he was born, Anthony was diagnosed with osteopetrosis, a rare disease that causes the body to produce excess bone, leads to blindness, and can be fatal if left untreated.
Cord blood (short for umbilical cord blood) is the blood that remains in the umbilical cord and placenta post-delivery. At or near term, there is a maternal–fetal transfer of cells to boost the immune systems of both the mother and baby in preparation for labor. This makes cord blood at the time of delivery a rich source of stem cells and other cells of the immune system. Cord blood banking is the process of collecting the cord blood and extracting and cryogenically freezing its stem cells and other cells of the immune system for potential future medical use.
There are two main types of cord blood banks: public and private. Public cord blood banks are usually nonprofit companies that store your donated cord blood for free, to be used for any sick child in another family or for research purposes, so accessing and using your own cord blood is not guaranteed. Private cord blood banks are companies that require a registration fee (plus annual storage fees) for your cord blood, but it is saved specifically for your own family, so you’ll have ready access to it.
Parents who wish to donate cord blood are limited by whether there is a public bank that collects donations from the hospital or clinic where their baby will be born. Search our list of public banks in your country. Parents who wish to store cord blood and/or cord tissue for their family can find and compare private banks in your country. Family banks usually offer payment plans or insurance policies to lower the cost of cord blood banking.
Part of the reason for the dominance of these three companies in terms of the total number of units stored is that they are three of the oldest cord blood banks within the U.S., founded in 1992, 1993, and 1989, respectively. All three of these cord blood banks also support cord blood research and clinical trials.
Osteopetrosis is a genetic disease, so this means that doctors could use a sibling’s cord blood cells to treat Anthony, but they cannot use his own cells because the disease is in every cell in his body. In fact, a majority of the diseases listed in private banking firms’ marketing material as treatable with stem cells are genetic diseases.
When the medical courier delivers the cord blood collection kit to the cord blood bank, it is quickly processed to ensure the continued viability of the stem cells and immune system cells found in the cord blood. Firstly, a sample of the cord blood is tested for microbiological contamination, and the mother’s blood is tested for infectious diseases. As these tests are being conducted, the cord blood is processed to reduce the number of red blood cells and its total volume and isolate the stem cells and immune cells.
The syringe or bag should be pre-labeled with a unique number that identifies your baby. Cord blood may only be collected during the first 15 minutes following the birth and should be processed by the laboratory within 48 hours of collection.
A “mini-transplant” (also called a non-myeloablative or reduced-intensity transplant) is a type of allogeneic transplant. This approach is being studied in clinical trials for the treatment of several types of cancer, including leukemia, lymphoma, multiple myeloma, and other cancers of the blood.
Your baby’s newborn stem cells are transported to our banking facilities by our medical courier partner, and you can receive tracking updates. Each sample is processed and stored with great care at our laboratory in Tucson, Arizona. CBR’s Quality Standard means we test every cord blood sample for specific quality metrics.
Patients with leukemia, lymphoma, or certain inherited metabolic or immune system disorders have diseased blood-forming cells. For some patients, an umbilical cord blood or bone marrow transplant (also called a BMT) may be their best treatment option.
There is little doubt that scientists believe umbilical cord blood stem cells hold promise for the future. Cord blood stem cells are already used to treat blood disorders such as aplastic anemia, and research is underway to determine if they can treat other more common conditions like type 1 diabetes. But many experts question whether many companies’s marketing materials confuse or even mislead parents about the usefulness of private banking.
The area where the bone marrow was taken out may feel stiff or sore for a few days, and the donor may feel tired. Within a few weeks, the donor’s body replaces the donated marrow; however, the time required for a donor to recover varies. Some people are back to their usual routine within 2 or 3 days, while others may take up to 3 to 4 weeks to fully recover their strength.
Stem cells from cord blood can be given to more people than those from bone marrow. More matches are possible when a cord blood transplant is used than when a bone marrow transplant is used. In addition, the stem cells in cord blood are less likely to cause rejection than those in bone marrow.
To minimize potential side effects, doctors most often use transplanted stem cells that match the patient’s own stem cells as closely as possible. People have different sets of proteins, called human leukocyte-associated (HLA) antigens, on the surface of their cells. The set of proteins, called the HLA type, is identified by a special blood test.
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.
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.
In most cases, the success of allogeneic transplantation depends in part on how well the HLA antigens of the donor’s stem cells match those of the recipient’s stem cells. The higher the number of matching HLA antigens, the greater the chance that the patient’s body will accept the donor’s stem cells. In general, patients are less likely to develop a complication known as graft-versus-host disease (GVHD) if the stem cells of the donor and patient are closely matched.
CBR Cord Blood Education Specialists are available 7 days a week (Monday – Friday 6 AM – 9 PM PST and Saturday – Sunday 6 AM – 4 PM PST) to respond to consumer inquiries. In addition, consumers may request to schedule a call with a CBR Cord Blood Education Specialist at a specific date and time.
Current applications for newborn stem cells include treatments for certain cancers and blood, metabolic and immune disorders. Additionally, newborn stem cell preservation has a great potential to benefit the newborn’s immediate family members with stem cell samples preserved in their most pristine state.
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.
When the collection is complete, we send a courier to your location to pick up your collection kit and transport it to ViaCord’s Processing Lab. Once at our lab, our lab specialist get to work processing the cord blood to get you the highest volume and quality of stem cells possible.
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.
With allogeneic transplants, GVHD sometimes develops when white blood cells from the donor (the graft) identify cells in the patient’s body (the host) as foreign and attack them. The most commonly damaged organs are the skin, liver, and intestines. This complication can develop within a few weeks of the transplant (acute GVHD) or much later (chronic GVHD). To prevent this complication, the patient may receive medications that suppress the immune system. Additionally, the donated stem cells can be treated to remove the white blood cells that cause GVHD in a process called “T-cell depletion.” If GVHD develops, it can be very serious and is treated with steroids or other immunosuppressive agents. GVHD can be difficult to treat, but some studies suggest that patients with leukemia who develop GVHD are less likely to have the cancer come back. Clinical trials are being conducted to find ways to prevent and treat GVHD.