Currently there have been no reported complications from Cord Blood Serum Drops, which has been used for dry eye, corneal neuropathy, corneal ulcers, graft versus host disease, and other severe ocular surface diseases.

The key risk of using cord blood serum drops is the possibility of transmission of blood-borne infectious or blood-borne diseases despite laboratory examination in pregnant donors. This has not been reported to date.

Bacterial contamination and allergy are other possible concern but has also not been reported to date to my knowledge.

The only other risk is a risk of graft versus host disease (GVHD) which is very unlikely given cord blood serum drops have been used to treat patients with GVHD, but when used as a hematopoietic transplantation (injected into the blood of a cancer patient whose immune cells have been wiped clean), cord blood serum has been shown to rarely (as less commonly than bone marrow transplantation) cause GVHD. CBS drops are very unlikely to cause GVHD but this was the only other risk I could think of.

I would have CBS drops for my eyes if needed.

Sandra Lora Cremers, MD, FACS

Review Article

Use of Umbilical Cord Serum in Ophthalmology Kyung Chul Yoon*

www.cmj.ac.kr

Department of Ophthalmology and Research Institute of Medical Sciences, Chonnam National University Medical School and Hospital, Gwangju, Korea

Among blood preparations, serum has been topically used in the management of vari- ous ocular diseases in ophthalmology. Like peripheral blood serum, umbilical cord blood serum contains a high concentration of essential tear components, growth factors, neurotrophic factors, vitamin A, fibronectin, prealbumin, and oil. Umbilical cord serum can provide basic nutrients for epithelial renewal and can facilitate the proliferation, migration, and differentiation of the ocular surface epithelium. Eye drops made from umbilical cord serum have been applied to treat various ocular surface diseases, includ- ing severe dry eye with or without Sjögren’s syndrome, ocular complications in graft-versus-host disease, persistent epithelial defects, neurotrophic keratopathy, re- current corneal erosions, ocular chemical burn, and surface problems after corneal re- fractive surgery. Because mesenchymal stem cells from umbilical cord blood can be used to regenerate corneal tissue and retinal nerve cells, umbilical cord serum might be applied for tissue engineering and regenerative medicine in the future.

Key Words: Ophthalmology; Umbilical cord; Serum; Dry eye

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Article History:

received 11 November, 2014 revised 19 November, 2014 accepted 20 November, 2014

Corresponding Author:

Kyung Chul Yoon

Department of Ophthalmology, Chonnam National University Medical School and Hospital, 42, Jebong-ro, Dong-gu, Gwangju 501-757, Korea TEL: +82-62-220-6741

FAX: +82-62-227-1642

E-mail: kcyoon@jnu.ac.kr

INTRODUCTION

Blood preparations including autologous serum (AS), plasma rich in growth factors, platelets, and umbilical cord serum (UCS) have been introduced to treat many ocular diseases because they contain a high concentration of bio- logically active components and growth factors. The tear film consists of mucin, aqueous, and lipid layers and con- tains many growth factors and vitamin A, which are essen- tial for regulating the proliferation, differentiation, and maturation of the ocular surface epithelium. Ocular sur- face disorders including dry eye disease or keratoconjuncti- vitis sicca are characterized by a decrease in quality and quantity of the tear film and squamous metaplasia of the conjunctival epithelium. Conventional treatments for ocu- lar surface disorders include the application of artificial tears, topical anti-inflammatory agents, secretagogues, therapeutic contact lenses, and punctal occlusion.1 Because peripheral blood serum (PBS) harbors essential tear com- ponents and growth factors, AS eye drops have been used for the treatment of severe ocular surface diseases. We found that UCS contains a higher level of essential tear components, growth factors, and neurotrophic factors than

http://dx.doi.org/10.4068/cmj.2014.50.3.82

C Chonnam Medical Journal, 2014 82

AS, and UCS eye drops can be applied in various ocular con- ditions such as severe dry eye disease, persistent epithelial defects, neurotrophic keratopathy, recurrent corneal ero- sions, ocular chemical burn, and corneal refractive sur- gery.2-8

CONVENTIONAL SERUM TREATMENT IN OPHTHALMOLOGY

Serum contains many growth factors [epidermal growth factor (EGF), acidic and basic fibroblast growth factors, platelet-derived growth factor, hepatocyte growth factors, and transforming growth factors (TGF-β)], fibronectin, se- rum antiprotease (α2-macroglobulin), vitamin A, neuro- trophic factors [substance P, insulin-like growth factor (IGF)-1, and nerve growth factor (NGF)], prealbumin, oil, and antioxidants. Therefore, it can provide the corneal and conjunctival epithelium with basic elements for epithelial regeneration that are lacking in artificial tears.9

PBS is known to have higher vitamin A, TGF-β1, IGF-1, NGF, fibronectin, and lysozyme concentrations and lower immunoglobulin A, EGF, and vitamin C concentrations than tears.10 In an animal model of corneal epithelial de-

Chonnam Med J 2014;50:82-85

fects after refractive surgery, 20% serum eye drops led to faster epithelial healing than artificial tears by decreasing apoptosis of keratocytes, migration of fibroblasts and my- ofibroblasts, and migration of inflammatory cells.11 Accor- ding to controlled studies, AS treatment was shown to pro- vide better improvement in symptoms and signs of ocular surface diseases than artificial tears did.12,13 Clinically, AS eye drops have been effectively used to treat dry eye asso- ciated with Sjögren’s syndrome2 or graft-versus-host dis- ease (GVHD),3 persistent epithelial defects,4,5 neuro- trophic keratopathy,6 superior limbic keratoconjunctivi- tis,7 and recurrent corneal erosions.8 AS has also been ap- plied during or after ocular surgeries including macular hole surgery, vitrectomy in patients with diabetes, and trabeculectomy.14-16

COMPARISON OF PERIPHERAL BLOOD SERUM AND UMBILICAL CORD SERUM

We have verified that UCS also harbors a high concen- tration of growth factors, neurotropic factors, and essential tear components.17,18 Compared with the levels in PBS, concentrations of EGF and TGF-β are 3 and 2 times higher, respectively, in UCS. Although the vitamin A concen- tration in UCS is lower than that in PBS, it is higher than the concentration in normal tears. UCS has higher NGF and substance P and lower IGF-1 concentrations compared with PBS. UCS-supplemented culture medium supports the proliferation and differentiation of epithelial cells in the conjunctiva and limbus, and UCS contains a higher concentration of growth factors and cytokines than fetal bo- vine serum and adult serum.19

Previous studies have also shown that UCS is superior

to AS in the treatment of various ocular surface diseases.20-23

An initial study showed that UCS could provide faster heal-

ing of the corneal epithelium than AS.20 We reported that

compared with AS, UCS was more effective in decreasing

symptoms and epithelial staining in severe dry eye and in-

creasing goblet cell density in Sjögren’s syndrome.21

Additionally, UCS eye drops were shown to be more effec-

tive in improving corneal wound healing and reducing cor-

neal haze compared with AS eye drops in ocular chemical burn.22,23

From a clinical aspect, UCS therapy has several advan- tages over AS therapy. A larger amount of serum can be col- lected from the umbilical vein at one time, and many pa- tients obtain benefit from this sampling without waiting for additional preparations. In addition, UCS therapy is feasible in patients who have a poor general condition or blood dyscrasia, especially hematologic malignancy.

PREPARATION OF UMBILICAL CORD SERUM EYE DROPS

Umbilical cord blood can be obtained from mothers dur- ing delivery. From donors, laboratory examination should be performed at 8 and 38 gestational weeks to test for hu-

man immunodeficiency and hepatitis B and C viruses. After fetal delivery, about 60 to 80 ml of umbilical cord blood is sampled from the umbilical cord vein. The blood is kept for 2 hours at room temperature. After 15 minutes of cen- trifugation at 3,000 ×g, the serum is carefully isolated un- der sterile conditions. The serum is then diluted to a 20% concentration with balanced salt solution. The aliquots of diluted serum are placed into sterile 5-ml bottles with ul- traviolet light protection. Opened bottles are kept in a re- frigerator at 4oC for 7 days, and unopened bottles are stored in a freezer at −20oC for 3 to 6 months. UCS eye drops are usually instilled 4 to 6 times per day as required in addition to artificial tears and antibiotics.

SAFETY AND STABILITY OF UMBILICAL CORD SERUM

Among the components of serum, EGF, vitamin A, and TGF-β are well preserved for up to 1 month in a refrigerator at 4oC and up to 3 months in a freezer at −20oC.4 A strict protocol for preparation and storage is essential for the safety of serum use.

Topical administration of UCS does not cause adverse effects on the eye, because the components of serum include growth factors and tear components, rather than umbilical cord tissue-derived cells, which may result in reduced immunogenicity.24 The titres of IgM and IgG2 antibodies are low in umbilical cord blood, and anti-A and anti-B anti- bodies are absent or only weakly detectable in UCS.25 Serum has a bacteriostatic effect because it contains anti- bacterial agents such as IgG, lysozyme, and complement. In addition, because serum contains no preservatives, se- rum therapy can avoid the risk of toxic reaction in the ocular surface.

CLINICAL APPLICATION OF UMBILICAL CORD SERUM IN OPHTHALMOLOGY

We have safely and effectively applied UCS eye drops for the treatment of intractable ocular conditions including dry eye disease with or without Sjögren’s syndrome, GVHD, persistent epithelial defects, neurotrophic kerat- opathy, recurrent corneal erosions, ocular chemical burn, and keratorefactive surgery.17,18,21,22,26-29

The efficacy of 20% UCS eye drops was evaluated in pa- tients with severe dry eye disease with or without Sjögren’s syndrome after 2 months of treatment.17 Tear film breakup time, corneal epithelial staining score, grade of con- junctival squamous metaplasia, goblet cell density, and symptom score significantly improved after UCS use. Our study comparing the therapeutic effect between AS and UCS in the treatment of severe dry eye disease revealed that, although both serum treatments led to improvement of symptoms and signs, symptom and corneal staining scores were lower in the UCS group after 1 and 2 months of treatment.21 In Sjögren’s syndrome patients, goblet cell density was higher in the UCS group than in the AS group

Kyung Chul Yoon

Umbilical Cord Serum in Ophthalmology

after 2 months of treatment.21 Recently, it was reported that the use of standardized and quality-controlled UCS eye drops was a promising therapy for the healing of se- verely injured corneal epithelium as well as the relief of subjective symptoms in severe cases of dry eye.30

GVHD, which is one of the major complications after allo- geneic hematopoietic stem cell transplantation, can result in many ocular diseases. Among the GVHD-related ocular diseases, dry eye is the most frequent manifestation, lead- ing to serious complications such as punctuate keratitis, persistent epithelial defects, and keratinization, ulcer- ation, or perforation of the cornea. The use of UCS can be an effective treatment option for severe ocular surface manifestations associated with GVHD. In patients with GVHD-related dry eye, symptom score, corneal sensitivity, tear film breakup time, and corneal staining score sig- nificantly improved after 2 months of UCS treatment, and the improvement was maintained by 6 months after treatment.27

Persistent epithelial defects of the cornea are caused by medications, chemical or thermal injury, secondary in- fection following herpetic keratitis, and autoimmune dis- eases such as rheumatoid arthritis, ocular cicatrical pem- phigoid, and erythema multiforme. The use of UCS could effectively decrease the defect size and shorten the healing time in patients with persistent corneal epithelial defects.20,26

Neurotrophic keratitis is characterized by impaired healing of the corneal epithelium due to damage to trigemi- nal innervations and depletion of trophic mediators. Causative factors include herpes simplex and zoster kera- titis; chemical, physical, and surgical injuries; neuro- surgical procedures for acoustic neuroma and meningi- oma; and systemic diseases such as diabetes, multiple scle- rosis, and leprosy. We applied UCS eye drops in patients with neurotrophic keratitis who did not respond to conven- tional treatment. The epithelial defect healed at around 4 weeks, and visual acuity as well as corneal sensitivity also improved after treatment.18

Recurrent corneal erosion syndrome is defined as re- peated episodes of corneal de-epithelization that result from trauma or dystrophy of the cornea, resulting in pain, tearing, and potential visual loss. We found that the use of 20% UCS eye drops significantly reduced the number of re- currences compared with artificial tears.28

In ocular chemical burn, early epithelial wound healing is essential to prevent serious long-term complications, which include ulceration, neovascularization, and opacifi- cation. UCS treatment showed better epithelial wound healing and lower corneal haze scores compared with PBS or conventional treatment.22,31 In addition, stromal in- flammation and the interleukin-1β level in the cornea were decreased in the UCS-treated group.22

Finally, UCS treatment can be tried for ocular complica- tions associated with Stevens-Johnson syndrome and ocu- lar cicatrical pemphigoid, ocular surface keratinization, Mooren’s ulceration, and epithelial maintenance after ocu-

lar surface reconstruction or corneal refractive surgery. Application of 20% UCS eye drops in addition to conven- tional treatment after laser epithelial keratomileusis could reduce early postoperative corneal haze and improve tear film and ocular surface parameters.29

COMPLICATIONS AND CONSIDERATIONS OF UMBILICAL CORD SERUM

Although no significant complications have been docu- mented, potential adverse effects should always be consid- ered when using UCS. Despite two laboratory examina- tions in pregnant donors, the possibility of transmission of blood-borne infectious or blood-borne diseases cannot be absolutely excluded. In addition, bacterial contamination and allergy are other possible problems. Legal and regu- latory issues as well as additional costs for serum prepara- tion should also be considered before obtaining the serum.

SUMMARY AND FUTURE APPLICATIONS

Owing to the high concentrations of essential tear com- ponents, growth factors, and neurotrophic factors in UCS, UCS eye drops can be safely and effectively applied in in- tractable ocular conditions such as severe dry eye disease with or without Sjögren’s syndrome, ocular GVHD, persis- tent epithelial defects, neurotrophic keratopathy, re- current corneal erosions, ocular chemical burn, and sur- face problems after corneal refractive surgery.

Mesenchymal stromal cells can be obtained from um- bilical cord blood, amniotic fluid, and adipose tissue as well as bone marrow. Umbilical cord blood contains not only hematopoietic progenitor cells but also mesenchymal pro- genitor cells.32 Corneal stromal cells have mesenchymal stromal cell-like characteristics.33 Therefore, it is expected that umbilical cord blood could be used in corneal tissue en- gineering and regeneration. Furthermore, human um- bilical cord blood cells can differentiate into retinal nerve cells.34 In the future, human cord blood cells may be used for the regeneration of retinal nerve cells in retinal degen- eration or dystrophy.

CONFLICT OF INTEREST STATEMENT

None declared.

REFERENCES

1. The definition and classification of dry eye disease: report of the Definition and Classification Subcommittee of the International Dry Eye WorkShop (2007). Ocul Surf 2007;5:75-92.

2. Tsubota K, Goto E, Fujita H, Ono M, Inoue H, Saito I, et al. Treatment of dry eye by autologous serum application in Sjögren’s syndrome. Br J Ophthalmol 1999;83:390-5.

3. Ogawa Y, Okamoto S, Mori T, Yamada M, Mashima Y, Watanabe R, et al. Autologous serum eye drops for the treatment of severe dry eye in patients with chronic graft-versus-host disease. Bone

Marrow Transplant 2003;31:579-83.

4. Tsubota K, Goto E, Shimmura S, Shimazaki J. Treatment of per-

sistent corneal epithelial defect by autologous serum application.

Ophthalmology 1999;106:1984-9.

5. Young AL, Cheng AC, Ng HK, Cheng LL, Leung GY, Lam DS. The

use of autologous serum tears in persistent corneal epithelial

defects. Eye (Lond) 2004;18:609-14.

6. Matsumoto Y, Dogru M, Goto E, Ohashi Y, Kojima T, Ishida R,

et al. Autologous serum application in the treatment of neuro-

trophic keratopathy. Ophthalmology 2004;111:1115-20.

7. Goto E, Shimmura S, Shimazaki J, Tsubota K. Treatment of supe- rior limbic keratoconjunctivitis by application of autologous

serum. Cornea 2001;20:807-10.

8. del Castillo JM, de la Casa JM, Sardiña RC, Fernández RM, Feijoo

JG, Gómez AC, et al. Treatment of recurrent corneal erosions us-

ing autologous serum. Cornea 2002;21:781-3.

9. Higuchi A, Shimmura S, Takeuchi T, Suematsu M, Tsubota K.

Elucidation of apoptosis induced by serum deprivation in cul- tured conjunctival epithelial cells. Br J Ophthalmol 2006;90: 760-4.

10. Tsubota K, Higuchi A. Serum application for the treatment of ocu- lar surface disorders. Int Ophthalmol Clin 2000;40:113-22.

11. Esquenazi S, He J, Bazan HE, Bazan NG. Use of autologous serum

in corneal epithelial defects post-lamellar surgery. Cornea 2005;

24:992-7.

12. Noble BA, Loh RS, MacLennan S, Pesudovs K, Reynolds A,

Bridges LR, et al. Comparison of autologous serum eye drops with conventional therapy in a randomised controlled crossover trial for ocular surface disease. Br J Ophthalmol 2004;88:647-52.

13. Kojima T, Ishida R, Dogru M, Goto E, Matsumoto Y, Kaido M, et al. The effect of autologous serum eyedrops in the treatment of severe dry eye disease: a prospective randomized case-control study. Am J Ophthalmol 2005;139:242-6.

14. Banker AS, Freeman WR, Azen SP, Lai MY. A multicentered clin- ical study of serum as adjuvant therapy for surgical treatment of macular holes. Vitrectomy for Macular Hole Study Group. Arch Ophthalmol 1999;117:1499-502.

15. Schulze SD, Sekundo W, Kroll P. Autologous serum for the treat- ment of corneal epithelial abrasions in diabetic patients under- going vitrectomy. Am J Ophthalmol 2006;142:207-11.

16. Matsuo H, Tomidokoro A, Tomita G, Araie M. Topical application of autologous serum for the treatment of late-onset aqueous ooz- ing or point-leak through filtering bleb. Eye (Lond) 2005;19:23-8.

17. Yoon KC, Im SK, Park YG, Jung YD, Yang SY, Choi J. Application of umbilical cord serum eyedrops for the treatment of dry eye syndrome. Cornea 2006;25:268-72.

18. Yoon KC, You IC, Im SK, Jeong TS, Park YG, Choi J. Application of umbilical cord serum eyedrops for the treatment of neuro- trophic keratitis. Ophthalmology 2007;114:1637-42.

19. Ang LP, Do TP, Thein ZM, Reza HM, Tan XW, Yap C, et al. Ex vivo expansion of conjunctival and limbal epithelial cells using

cord blood serum-supplemented culture medium. Invest

Ophthalmol Vis Sci 2011;52:6138-47.

20. Vajpayee RB, Mukerji N, Tandon R, Sharma N, Pandey RM,

Biswas NR, et al. Evaluation of umbilical cord serum therapy for persistent corneal epithelial defects. Br J Ophthalmol 2003;87: 1312-6.

21. Yoon KC, Heo H, Im SK, You IC, Kim YH, Park YG. Comparison of autologous serum and umbilical cord serum eye drops for dry eye syndrome. Am J Ophthalmol 2007;144:86-92.

22. Oh HJ, Jang JY, Li Z, Park SH, Yoon KC. Effects of umbilical cord serum eye drops in a mouse model of ocular chemical burn. Curr Eye Res 2012;37:1084-90.

23. Sharma N, Goel M, Velpandian T, Titiyal JS, Tandon R, Vajpayee RB. Evaluation of umbilical cord serum therapy in acute ocular chemical burns. Invest Ophthalmol Vis Sci 2011;52:1087-92.

24. Cho PS, Messina DJ, Hirsh EL, Chi N, Goldman SN, Lo DP, et al. Immunogenicity of umbilical cord tissue derived cells. Blood 2008; 111:430-8.

25. Denomme GA, Ryan G, Seaward PG, Kelly EN, Fernandes BJ. Maternal ABO-mismatched blood for intrauterine transfusion of severe hemolytic disease of the newborn due to anti-Rh17. Trans- fusion 2004;44:1357-60.

26. Yoon KC, Heo H, Jeong IY, Park YG. Therapeutic effect of um- bilical cord serum eyedrops for persistent corneal epithelial defect. Korean J Ophthalmol 2005;19:174-8.

27. Yoon KC, Jeong IY, Im SK, Park YG, Kim HJ, Choi J. Therapeutic effect of umbilical cord serum eyedrops for the treatment of dry eye associated with graft-versus-host disease. Bone Marrow Transplant 2007;39:231-5.

28. Yoon KC, Choi W, You IC, Choi J. Application of umbilical cord serum eyedrops for recurrent corneal erosions. Cornea 2011;30: 744-8.

29. Yoon KC, Oh HJ, Park JW, Choi J. Application of umbilical cord serum eyedrops after laser epithelial keratomileusis. Acta Ophthalmol 2013;91:e22-8.

30. Versura P, Profazio V, Buzzi M, Stancari A, Arpinati M, Malavolta N, et al. Efficacy of standardized and quality-controlled cord blood serum eye drop therapy in the healing of severe corneal epithelial damage in dry eye. Cornea 2013;32:412-8.

31. Erdem E, Yagmur M, Harbiyeli I, Taylan-Sekeroglu H, Ersoz R. Umbilical cord blood serum therapy for the management of per- sistent corneal epithelial defects. Int J Ophthalmol 2014;7: 807-10.

32. Erices A, Conget P, Minguell JJ. Mesenchymal progenitor cells in human umbilical cord blood. Br J Haematol 2000;109:235-42. 33. Choong PF, Mok PL, Cheong SK, Then KY. Mesenchymal stromal cell-like characteristics of corneal keratocytes. Cytotherapy

2007; 9:252-8.

34. Koike-Kiriyama N, Adachi Y, Minamino K, Iwasaki M, Nakano

K, Koike Y, et al. Human cord blood cells can differentiate into retinal nerve cells. Acta Neurobiol Exp (Wars) 2007;67:359-65.

Kyung Chul Yoon

Journal of Ocular Pharmacology and Therapeutics

Mary Ann Liebert, Inc.

Allogeneic Serum Eye Drops for the Treatment of Dry Eye Patients with Chronic Graft-Versus-Host Disease

Kyung-Sun Na and Man Soo Kim

Additional article information

Abstract

Purpose

To evaluate the therapeutic effect of allogeneic serum eye drops for the treatment of dry eye in patients with chronic graft-versus-host disease (cGVHD) following bone marrow transplantation.

Methods

Sixteen patients with cGVHD following allogeneic hematological stem cell transplantation (allo-SCT) and diagnosed with dry eye syndrome refractory to conventional treatment were prospectively enrolled in this study. Allogeneic serum eye drops were obtained from healthy related donors after serologic testing. Symptom scores, tear breakup time (tBUT), the Schirmer test without anesthesia (Schirmer I test), tear osmolarity, corneal staining score, impression cytology grade, and goblet cell densities were evaluated before and 4 weeks after administration of allogeneic serum eye drops.

Results

Enrolled patients included 6 females and 10 males between 20 and 61 years of age (mean age, 37.2±11.6 years). After 4 weeks of treatment, the Ocular Surface Disease Index (OSDI) symptom scores decreased significantly (32.5–8.9). Tear osmolarity showed a significant decrease from 311.1 to 285.1 milliosmol. The corneal staining scores significantly decreased from 2.5 to 1.8. Impression cytology grade and goblet cell density improved from 3.4 to 2.4 and from 90.6 to 122.6 cell/mm2, respectively. tBUT also significantly improved from 2.9 to 4.4 s, and the Schirmer I test results showed improvement, but lacked statistical significance (1.7–2.4 mm). No significant side effects were detected as a result of the allogeneic serum treatment during the follow-up period.

Conclusions

Allogeneic serum can be used for the treatment of severe dry eye in patients with cGVHD when autologous serum is unavailable. Care should be taken to avoid the risk of blood-borne diseases.

Umbilical cord blood transplantation: basic biology and clinical challenges to immune reconstitution.

Review article

Brown JA, et al. Clin Immunol. 2008.

Authors

Brown JA¹, Boussiotis VA.

Author information

1: Department of Surgical Oncology, Cancer Center, Massachusetts General Hospital, Harvard Medical School, Boston, MA 02114, USA.

Citation

Clin Immunol. 2008 Jun;127(3):286-97. doi: 10.1016/j.clim.2008.02.008. Epub 2008 Apr 18.

Abstract

Allogeneic stem cell transplantation has continued to evolve as a common procedure for the treatment of hematological malignancies and bone marrow failure. Donor bone marrow and mobilized peripheral stem cells are routinely employed for the reconstitution of immune function in leukemia and lymphoma patients following radiation and/or chemotherapy. Unfortunately, only 30% of patients have an HLA-identical sibling donor and the identification of matched unrelated donors, particularly for minorities, can present an exceptional challenge. The transplantation of umbilical cord blood (UCB) represents the most recent strategy to expand the potential donor pool while maintaining an acceptable level of treatment-related complications. First utilized in children, UCB transplantation permits a higher degree of HLA disparity while demonstrating a reduction in the incidence and severity of graft-versus-host disease (GvHD) compared to previous transplantation modalities. Despite the apparent decrease in GvHD, relapse rates remain comparable to transplantation with bone marrow or mobilized peripheral blood suggesting a strong graft-versus-leukemia/lymphoma (GvL) effect. However, several issues complicate the use of UCB transplantation and its extension to the treatment of adults. Many infections that afflict transplant patients are particularly frequent and more severe in the context of UCB transplantation. UCB T-cells are naive and therefore display less proliferation and IFN-gamma production in response to cognate antigen and also appear to demonstrate defects in signal transduction mechanisms. In addition, UCB contains T regulatory cells (Treg) with more potent suppressor function than adult Treg. Furthermore, adult patients often require more total cells and CD34+ progenitors for transplantation than a single UCB unit can provide. Thus, strategies to expand selected subpopulations from UCB and the use of multi-unit transplantation are areas of active research. This review will provide a condensed summary of the clinical history of UCB transplantation and emphasize the advantages and disadvantages of this approach to hematological malignancies in comparison to other methods of hematopoietic stem cell transplantation. Subsequently, it will mainly focus on the current challenges to immune reconstitution presented by UCB transplantation, recent research into their cellular and molecular mechanisms, and experimental approaches to overcome them.

———

Umbilical Cord Blood-Derived Therapies as a Treatment for Graft-Versus-Host Disease

By Richard Duggleby, Steve Cox, J Alejandro Madrigal and Aurore Saudemont

Submitted: March 23rd 2016Reviewed: July 18th 2016Published: January 11th 2017

DOI: 10.5772/64945

Home > Books > Umbilical Cord Blood Banking for Clinical Application and Regenerative Medicine

Downloaded: 611

Abstract

Umbilical cord blood (UCB) has been increasingly used as a source of haematopoietic stem cells (HSCs) for transplantation. UCB transplantation (UCBT) has some advantages such as less stringent human leucocyte antigen (HLA) matching and lower impact of graft-versus-host disease (GvHD). UCBT is also characterised by a high rate of infections, graft failure, delayed engraftment and slow recovery of the immune system. UCB contains HSC as well as immune cells that could be considered to develop new treatments for the main complications post-UCBT but also to treat other diseases. GvHD remains a major complication post-CBT and post-haematopoietic stem cell transplantation (HSCT). In view of their ability to induce tolerance and suppress the functions of effector T cells, regulatory T (Treg) cells have been proposed as an adoptive therapy to modulate GvHD post-HSCT. In addition, we showed that UCB contains soluble NKG2D ligands that can modulate the functions of NKG2D expressing cells, making UCB plasma a product of interest to modulate inflammation and in particular skin GvHD. Here, we aim to describe some of the therapies currently developed using UCB, focusing on Treg cells and UCB plasma for the treatment of GvHD.

———

Biology of blood and marrow transplantation : journal of the American Society for Blood and Marrow Transplantation

Author Manuscript

HHS Public Access

Graft-versus-host Disease After Double-Unit Cord Blood Transplantation Has Unique Features and an Association with Engrafting Unit-Recipient HLA-match

D. M. Ponce, A. Gonzales, […], and J. N. Barker

Additional article information

Abstract

Manifestations and risk factors of graft-versus-host disease (GVHD) after double-unit cord blood transplantation (DCBT) are not firmly established. We evaluated 115 DCBT recipients (median age 37 years) transplanted for hematologic malignancies with myeloablative or non-myeloablative conditioning and calcineurin-inhibitor/ mycophenolate mofetil immunosuppression. Incidences of day 180 grade II–IV and III–IV acute GVHD (aGVHD) were 53% (95%CI: 44–62) and 23% (95%CI: 15–31), respectively, with a median onset of 40 days (range 14–169). Eighty percent of patients with grade II–IV aGVHD had gut involvement, and 79% and 85% had day 28 treatment responses to systemic corticosteroids or budesonide, respectively. Of 89 engrafted patients cancer-free at day 100, 54% subsequently had active GVHD with 79% of those affected having persistent or recurrent aGVHD or overlap syndrome, whereas late GVHD in the form of classical chronic GVHD was uncommon. Notably, grade III–IV aGVHD incidence was lower if the engrafting unit human leukocyte antigen (HLA)-A,-B,-DRB1 allele match was > 4/6 to the recipient (HR 0.385, p = 0.031), whereas engrafting unit infused nucleated cell dose and unit-unit HLA-match were not significant. GVHD after DCBT was common in our study, predominantly affected the gut, had a high therapy response, and late GVHD frequently had acute features. Our findings support the consideration of HLA- A,-B,-DRB1 allele donor-recipient (but not unit-unit) HLA-match in unit selection, a practice change in the field. Moreover, new prophylaxis strategies that target the gastrointestinal tract are needed

Original Article | Published: 18 February 2013

Cord Blood Stem Cells

Impact of ABO-mismatch on risk of GVHD after umbilical cord blood transplantation

Bone Marrow Transplantation volume48, pages1046–1049 (2013) | Download Citation

Abstract

Recent advances in allogeneic hematopoietic cell transplant (allo-HCT) have led to an increasing use of alternative donors, including banked umbilical cord blood (UCB). Despite these advances, acute GVHD (aGVHD) and chronic GVHD (cGVHD) continue to be the leading causes of early and late transplant-related mortality. ABO-mismatch has been frequently reported as a risk factor for GVHD, however, data in the UCB recipients are limited. We hypothesized that as the lymphocytes in the cord blood are thought to be naive, they will therefore be less likely to mediate GVHD. Therefore, we analyzed the impact of ABO-mismatch on aGVHD and cGVHD in recipients of single and double UCB-HCT. In both univariate and multivariate analyses, presence of ABO-mismatch did not have an impact on aGVHD or cGVHD. Whereas ABO-compatible donors are preferred in recipients of URD-HCT, ABO compatibility generally need not be considered in recipients of UCB-HCT

[Umbilical cord blood as a source of stem cells].

Review article

Bojanić I, et al. Acta Med Croatica. 2006.

Show full citation

Abstract

Umbilical cord blood (UCB) is a source of the rare but precious primitive hematopoietic stem cells (HSC) and progenitor cells that can reconstitute the hematopoietic system in patients with malignant and nonmalignant disorders treated with myeloablative therapy. UCB cells possess an enhanced capacity for progenitor cell proliferation and self-renewal in vitro. UCB is usually discarded, and it exists in almost limitless supply. The blood remaining in the delivered placenta is safely and easily collected and stored. The predominant collection procedure currently practiced involves a relatively simple venipuncture, followed by gravity drainage into a standard sterile anti-coagulant-filled blood bag, using a closed system, similar to the one utilized on whole blood collection. After aliquots have been removed for routine testing, the units are cryopreserved and stored in liquid nitrogen. UCB banks are being established throughout the world and UCB units are collected for allogeneic unrelated and related HSC transplantation. In unrelated cord blood banks donated UCB units are collected and stored for allogeneic use in patients who do not have an identified HLA matched relative. UCB banks report available units to national and international donor registries. The second model of UCB banking is referred to as family banking, where UCB is stored for the benefit of the donor or their family members. After more than one decade of clinical experience, it is currently accepted that UCB transplants, related and unrelated, are equivalent to or might compare favorably with bone marrow (BM) transplants, especially in children. Initial studies of long-term survival in children with both malignant and non-malignant hematologic disorders, who were transplanted with UCB from a sibling donor, demonstrated comparable or superior survival to children who received BM transplantation. One factor that limits the use of UCB transplantation in adult patients is the relatively limited number of HSC that may be harvested from umbilical cord, resulting in a slower time to engraftment and higher transplant related mortality, mainly due to the long aplasia period after transplantation and susceptibility to viral and fungal infections. Despite prolonged periods of aplasia, the apparent reduction in the incidence and severity of graft versus host disease (GVHD) may in turn underline comparable rates of survival in some series comparing UCB to adult-donor sources. The “naive” nature of UCB lymphocytes may explain the lower incidence and severity of GVHD encountered in UCB transplantation compared to the allogeneic BM transplant setting. UCB transplantation does not seem to be associated with increased rates of disease relapse. The available data suggest that nucleated cell dose in UK unit should be the primary criterion for donor selection. In 1991, the UCB transplantation program was established at the Zagreb University Hospital Center for related transplants, and until now 4 UCB transplantations have been performed successfully. In order to speed up the engraftment rate, several strategies such as multiple UCB transplants and ex vivo expansion of HSC have been assayed. The current strategies are focused on the development of much more efficient technologies for ex vivo production of progenitor cells, but whether expansion will speed engraftment and improve outcome after UCB remains to be determined. UCB is known to contain extremely immature stem cells. Consequently, such pluripotent or, perhaps, multipotent stem cells have been proposed as elements suitable for cellular therapy and regenerative medicine. Up to date there are no conclusive data regarding these possibilities but preliminary in vitro and animal studies in the field of tissue regeneration suggest some degree of plasticity and/or transdifferentiation. UCB cells are showing their unique qualities and potential, and consequently UCB banks might dramatically increase the scope of their clinical application.