Cord blood (umbilical cord blood) is blood that remains in the placenta and in the attached umbilical cord after childbirth. Cord blood is collected because it contains stem cells, which can be used to treat hematopoietic and genetic disorders.
Constituents
Cord blood is composed of all the elements found in whole blood - red blood cells, white blood cells, plasma, platelets[1]. Compared to whole blood some differences in the blood composition exist, for example, cord blood contains higher numbers of natural killer cells, lower absolute number of T-cells and a higher proportion of immature T-cells[2]. However, the interest in cord blood is mostly driven by the observation that cord blood also contains various types of stem and progenitor cells, mostly hematopoietic stem cells[1][2][3]. Some non-hematopoietic stem cell types are also present in cord blood, for example, mesenchymal stem cells, however these are present in much lower numbers that can be found in adult bone marrow[2][3]. Endothelial progenitor cells and multipotent unrestricted adult stem cells can also be found in cord blood[3]. The stem cells found in cord blood are often confused with embryonic stem cells - unlike embryonic stem cells, cord blood stem cells are all types of adult stem cells, are lineage restricted and are not pluripotent[3][4][5].
Medical uses
Cord blood is used the same way that hematopoietic stem cell transplantation is used to reconstitute bone marrow following radiation treatment for various blood cancers, and for various forms of anemia.[6][7] Its efficacy is similar as well.[6]
Adverse effects
Adverse effects are similar to hematopoietic stem cell transplantation, namely graft-versus-host disease if the cord blood is from a genetically different person, and the risk of severe infection while the immune system is reconstituted.[6] To assure that the smallest amount of complications occur during transplantation, levels of engraftment must be present; specifically both neutrophils and platelets must be being produced [8]. This process of neutrophil and platelet production after the transplant, however, takes much longer than that of stem cells [9]. In many cases, the engraftment time depends on the cell dose, or the amount of stem cells obtained in the sample of blood [10]. In Dr. Moise’s article about umbilical cord blood [11] (as cited in [12]), it was found that there is approximately 10% less stem cells in cord blood than there is in bone marrow. Therefore a sufficient amount of cord blood must be obtained in order to collect an adequate cell dose, however this amount varies from infant to infant and is irreplaceable. Given that this idea is quite new, there is still a lot of research that needs to be completed. For example, it is still unknown how long cord blood can safely be frozen without losing its beneficial effects [13].
There is a lower incidence with cord blood compared with traditional HSCT, despite less stringent HLA match requirements. [6]
Collection and Storage
Umbilical cord blood is the blood left over in the placenta and in the umbilical cord after the birth of the baby. There are several methods for collecting cord blood. The method most commonly used in clinical practice is the "closed technique", which is similar to standard blood collection techniques. With this method, the technician cannulates the vein of the severed umbilical cord using a needle that is connected to a blood bag, and cord blood flows through the needle into the bag. On average, the closed technique enables collection of about 75 ml of cord blood.[14]
Collected cord blood is cryopreserved and then stored in a cord blood bank for future transplantation. Cord blood collection is typically depleted of red blood cells before cryopreservation to ensure high rates of stem cell recovery.[15]
History
The first successful cord blood transplant (CBT) was done in 1988 in a child with Fanconi anemia.[6] Early efforts to use CBT in adults led to mortality rates of about 50%, due somewhat to the procedure being done in very sick people, but perhaps also due to slow development of immune cells from the transplant.[6] By 2013, 30,000 CBT procedures had been performed and banks held about 600,000 units of cord blood.[7]
Society and Culture
Regulation
In the United States, the Food and Drug Administration regulates any facility that stores cord blood; cord blood intended for use in the person from whom it came is not regulated, but cord blood for use in others is regulated as a drug and as a biologic.[17] Several states also have regulations for cord blood banks.[16]
In Europe, Canada, and Australia use of cord blood is regulated as well.[16] 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.[18]
Private and Public Banks
A cord blood bank may be private (i.e. the blood is stored for and the costs paid by donor families) or public (i.e. stored and made available for use by unrelated donors). While public cord blood banking is widely supported, private cord banking is controversial in both the medical and parenting community. Although umbilical cord blood is well-recognized to be useful for treating hematopoietic and genetic disorders, some controversy surrounds the collection and storage of umbilical cord blood by private banks for the baby's use. Only a small percentage of babies (estimated at between 1 in 1,000 to 1 in 200,000[19]) ever use the umbilical cord blood that is stored.The American Academy of Pediatrics 2007 Policy Statement on Cord Blood Banking stated: "Physicians should be aware of the unsubstantiated claims of private cord blood banks made to future parents that promise to insure infants or family members against serious illnesses in the future by use of the stem cells contained in cord blood." and "private storage of cord blood as 'biological insurance' is unwise" unless there is a family member with a current or potential need to undergo a stem cell transplantation.[19][20] The American Academy of Pediatrics also notes that the odds of using a person's own cord blood is 1 in 200,000 while the Institute of Medicinesays that only 14 such procedures have ever been performed.[21]
Private storage of one's own cord blood is unlawful in Italy and France, and it is also discouraged in some other European countries. The American Medical Associationstates "Private banking should be considered in the unusual circumstance when there exists a family predisposition to a condition in which umbilical cord stem cells are therapeutically indicated. However, because of its cost, limited likelihood of use, and inaccessibility to others, private banking should not be recommended to low-risk families."[22] The American Society for Blood and Marrow Transplantation and the American Congress of Obstetricians and Gynecologists also encourage public cord banking and discourage private cord blood banking. Nearly all cord blood transplantations come from public banks, rather than private banks,[20][23] partly because most treatable conditions can't use a person's own cord blood.[19][24] The World Marrow Donor Association and European Group on Ethics in Science and New Technologies states "The possibility of using one’s own cord blood stem cells for regenerative medicine is currently purely hypothetical....It is therefore highly hypothetical that cord blood cells kept for autologous use will be of any value in the future" and "the legitimacy of commercial cord blood banks for autologous use should be questioned as they sell a service which has presently no real use regarding therapeutic options."[25]
The American Academy of Pediatrics supports efforts to provide information about the potential benefits and limitations of cord blood banking and transplantation so that parents can make an informed decision. In addition, the American College of Obstetricians and Gynecologists recommends that if a patient requests information on umbilical cord blood banking, balanced information should be given. Cord blood education is also supported by legislators at the federal and state levels. In 2005, the National Academy of Sciences published an Institute of Medicine (IoM) report titled "Establishing a National Cord Blood Stem Cell Bank Program".[26]
In March 2004, the European Union Group on Ethics (EGE) has issued Opinion No.19[27] titled Ethical Aspects of Umbilical Cord Blood Banking. The EGE concluded that "[t]he legitimacy of commercial cord blood banks for autologous use should be questioned as they sell a service, which has presently, no real use regarding therapeutic options. Thus they promise more than they can deliver. The activities of such banks raise serious ethical criticisms."[27]
Research
Though uses of cord blood beyond blood and immunological disorders is speculative, some research has been done in other areas.[28] Any such potential beyond blood and immunological uses is limited by the fact that cord cells are hematopoietic stem cells (which can differentiate only into blood cells), and not pluripotent stem cells (such as embryonic stem cells, which can differentiate into any type of tissue). Cord blood has been studied as a treatment for diabetes.[29] However, apart from blood disorders, the use of cord blood for other diseases is not in routine clinical use and remains a major challenge for the stem cell community.[28][29]
Along with cord blood, Wharton's jelly and the cord lining have been explored as sources for mesenchymal stem cells (MSC),[30] and as of 2015 had been studied in vitro, in animal models, and in early stage clinical trials for cardiovascular diseases,[31] as well as neurological deficits, liver diseases, immune system diseases, diabetes, lung injury, kidney injury, and leukemia.[32]
Cord blood is being used to get stem cells with which to test in people with type 1 diabetes mellitus.[33]
The stem cells from umbilical cord blood are also being used in the treatment of a number of blood diseases including blood cancers.[34]
Cord blood is also being studied as a substitute for normal blood transfusions in the developing world.[34][35] More research is necessary prior to the generalized utilization of cord blood transfusion.[34]
References
^ Jump up to:a b Pranke, Patricia; Failace, Renato R.; Allebrandt, Waldir F.; Steibel, Gustavo; Schmidt, Francisco; Nardi, Nance Beyer (2001). "Hematologic and Immunophenotypic Characterization of Human Umbilical Cord Blood". Acta Haematologica. 105 (2): 71–76. doi:10.1159/000046537. ISSN 0001-5792.^ Jump up to:a b c Newcomb JD, Sanberg PR, Klasko SK, Willing AE (2007). "Umbilical cord blood research: current and future perspectives". Cell Transplant. 16 (2): 151–8. PMC 2720821. PMID 17474296.^ Jump up to:a b c d Galieva, Luisa R.; Mukhamedshina, Yana O.; Arkhipova, Svetlana S.; Rizvanov, Albert A. (2017). "Human Umbilical Cord Blood Cell Transplantation in Neuroregenerative Strategies". Frontiers in Pharmacology. 8. doi:10.3389/fphar.2017.00628. ISSN 1663-9812.^ "Cord Blood Stem Cells: An Overview | The Center for Bioethics & Human Dignity". cbhd.org. Retrieved 9 December 2018. pluripote^ "How do embryonic stem cells, somatic stem cells, and cord blood stem cells differ? | NYSTEM". stemcell.ny.gov. Retrieved 9 December 2018. plurip^ Jump up to:a b c d e f Juric, MK; et al. (9 November 2016). "Milestones of Hematopoietic Stem Cell Transplantation - From First Human Studies to Current Developments". Frontiers in Immunology. 7: 470. doi:10.3389/fimmu.2016.00470. PMC 5101209. PMID 27881982.^ Jump up to:a b Ballen, KK; Gluckman, E; Broxmeyer, HE (25 July 2013). "Umbilical cord blood transplantation: the first 25 years and beyond". Blood. 122 (4): 491–8. doi:10.1182/blood-2013-02-453175. PMC 3952633. PMID 23673863.^ Waller-Wise, R. (2011). Umbilical Cord Blood: Information for Childbirth Educators. The Journal of Perinatal Education, 20(1), 54–60. http://doi.org/10.1891/1058-1243.20.1.54^ Waller-Wise, R. (2011). Umbilical Cord Blood: Information for Childbirth Educators. The Journal of Perinatal Education, 20(1), 54–60. http://doi.org/10.1891/1058-1243.20.1.54^ Waller-Wise, R. (2011). Umbilical Cord Blood: Information for Childbirth Educators. The Journal of Perinatal Education, 20(1), 54–60. http://doi.org/10.1891/1058-1243.20.1.54^ Moise K. J. (2005). Umbilical cord stem cells. Obstetrics and Gynecology, 106(6), 1393–1407 [PubMed]^ Waller-Wise, R. (2011). Umbilical Cord Blood: Information for Childbirth Educators. The Journal of Perinatal Education, 20(1), 54–60. http://doi.org/10.1891/1058-1243.20.1.54^ Waller-Wise, R. (2011). Umbilical Cord Blood: Information for Childbirth Educators. The Journal of Perinatal Education, 20(1), 54–60. http://doi.org/10.1891/1058-1243.20.1.54^ Christopher D. Hillyer; Ronald G. Strauss & Naomi L. C. Luban (2004). Handbook of Pediatric Transfusion Medicine. Academic Press. pp. 295, 296. ISBN 978-0-12-348776-6.^ Roura, S; Pujal, JM; Gálvez-Montón, C; Bayes-Genis, A (2 July 2015). "The role and potential of umbilical cord blood in an era of new therapies: a review". Stem Cell Research & Therapy. 6: 123. doi:10.1186/s13287-015-0113-2. PMC 4489204. PMID 26133757.^ Jump up to:a b c Armitage, S (8 January 2016). "Cord Blood Banking Standards: Autologous Versus Altruistic". Frontiers in Medicine. 2: 94. doi:10.3389/fmed.2015.00094. PMC 4705863. PMID 26779485.^ "Consumers (Biologics) - Cord Blood Banking - Information for Consumers". FDA Center for Biologics Evaluation and Research. July 23, 2012.^ "About the NHS Cord Blood bank". NHS Cord Blood Bank. Retrieved 28 November 2016.^ Jump up to:a b c American Academy of Pediatrics Section on Hematology/Oncology; American Academy of Pediatrics Section on Allergy/Immunology; Lubin, BH; Shearer, WT (January 2007). "Cord blood banking for potential future transplantation". Pediatrics. 119 (1): 165–70. doi:10.1542/peds.2006-2901. PMID 17200285.^ Jump up to:a b Thornley, I; et al. (March 2009). 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