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CLINICAL OBSERVATIONS, INTERVENTIONS, AND THERAPEUTIC TRIALS
From Leiden University Medical Center, The Netherlands
(J.J.V., M.O., F.C.); Histocompatibility Committee of the International
Bone Marrow Transplant Registry, Health Policy Institute, Medical
College of Wisconsin, Milwaukee (F.R.L., M.J.Z., M.M.H.); Children's
Hospital of New York (M.S.C.); University of Texas MD Anderson Cancer
Center, Houston (R.E.C.); Center for Advanced Studies in Leukemia, Los
Angeles, CA (R.P.G.); Huddinge University Hospital, Sweden (O.R.); and
University of Bristol, United Kingdom (J.M.H.).
In haploidentical transplantation, the mismatched haplotype of the
donor can originate from either of the parents. We refer to such
mismatched haplotypes as noninherited maternal antigens (NIMA
haplotype) or noninherited paternal antigens (NIPA haplotype). To
determine whether exposure to maternal HLA antigens benefits patients
undergoing bone marrow transplantation, we analyzed graft failure and
graft-versus-host disease (GVHD) after transplantations from parental
or haploidentical sibling donors. We studied 269 patients receiving 1 or 2 HLA-A, -B, -DR antigen-mismatched sibling or parental
non-T-cell-depleted bone marrow transplants for acute myelogenous
leukemia, acute lymphoblastic leukemia, or chronic myelogenous leukemia
between 1985 and 1997 that were reported to the International Bone
Marrow Transplant Registry. Included were 121 (45%) NIMA-mismatched
and 148 (55%) NIPA-mismatched transplantations. Sixty-three
(52%) of the NIMA-mismatched transplants and 69 (47%) of the
NIPA-mismatched transplants were from haploidentical sibling donors.
Sibling transplantations mismatched for NIMA had similar rates of graft
failure but lower rates of acute GVHD (P < .02) than
NIPA-mismatched sibling transplantations. In the first 4 months after
transplantation, mother-to-child transplantations involved
significantly less chronic GVHD than father-to-child transplantations
(P < .02). Treatment-related mortality (TRM) was
significantly higher after parental transplantations
(P = .009 for mother; P = .03 for father)
than after haploidentical sibling transplantations mismatched for the
NIMA. Non-T-cell-depleted bone marrow transplants donated by
haploidentical siblings to recipients mismatched for NIPA and
transplants donated by parents caused more acute and chronic GVHD and
TRM than transplants donated by haploidentical siblings mismatched for NIMA.
(Blood. 2002;99:1572-1577) Allogeneic bone marrow transplantation can cure
several hematologic malignancies. The outcome of this procedure depends
to a large extent on the degree of human leukocyte antigen (HLA) identity between donor and recipient. Unfortunately, only 25% to 30%
of transplant candidates have a genotypically HLA-identical sibling
donor.1 Bone marrow from haploidentical family members is
also used for transplantation.2 If the unshared HLA
haplotype is partially matched with the recipient, transplantation
outcome is acceptable though significantly inferior to HLA-identical
sibling transplantation. The important influence of the degree of HLA matching on bone marrow and organ transplantation outcome is documented in many publications. Few studies address why a sizable percentage of
HLA-mismatched stem cell or organ grafts function as well as HLA-identical ones.3,4
It is possible that exposure, during in utero development or nursing,
to maternal HLA antigens has a lifelong influence on the immune system.
Two separate studies demonstrate that approximately 50% of patients
with antibodies against a large number of HLA antigens have not formed
antibodies against maternal HLA antigens that the patient did not
inherit, the noninherited maternal antigens (NIMA) (Figure
1).5,6 Reactivity against
noninherited paternal antigens (NIPA) is significantly higher.
It was speculated that exposure to NIMA in utero or while nursing
induces (partial) tolerance to NIMA in approximately 50% of patients.
It was expected, on the basis of these findings and of corroborating
evidence from the literature,7-9 that kidney allografts
donated by the mother would have superior graft survival than those
donated by the father. This turned out not to be true.10 However, a collaborative study of 9 transplantation centers showed that
graft survival of kidneys donated by haploidentical siblings mismatched
(like the mother) for the NIMA haplotype was similar to that of kidneys
donated by an HLA-identical sibling.4 Why a kidney donated
by a haploidentical sibling mismatched for NIMA would fare better than
a similarly NIMA-mismatched maternal graft was unclear.
In another study, transplanted kidneys donated by unrelated donors
mismatched for 1 or 2 HLA-A antigens identical to the HLA-A NIMA of the
recipient had graft survival rates significantly superior to those of
other HLA-A-mismatched grafts.11 No such differences were
observed for HLA-B and -DR-mismatched grafts.
In bone marrow transplantation, the situation is more complex (Figure
1). If durable engraftment can be compared to the survival of an organ
allograft, the expectation is that there will be less graft rejection
if the donor is mismatched for the NIMA of the recipient than if the
donor is mismatched for the NIPA. Similarly, there should be less
graft-versus-host disease (GVHD) with NIMA- than with NIPA-mismatched
transplantations. Because graft failure and GVHD contribute to
transplantation success, treatment-related mortality (TRM) and overall
survival might also differ between NIMA and NIPA mismatches. We tested
these assumptions in 269 recipients of non-T-cell-depleted parental
or haploidentical sibling bone marrow transplantations for acute
myelogenous leukemia (AML), acute lymphoblastic lymphoma (ALL), and
chronic myelogenous leukemia (CML) reported to the International Bone
Marrow Transplant Registry (IBMTR) between 1985 and 1997. The study
compares graft failure, acute and chronic GVHD, TRM, and survival with
NIMA- versus NIPA-mismatched transplantations.
Data collection
Inclusion criteria
End points The study considered graft failure, acute and chronic GVHD, TRM, and overall survival. Graft failure was defined as failure to achieve a neutrophil count greater than 0.5 × 109/L or the achievement of a neutrophil count greater than 0.5 × 109/L followed by a decrease to less than 0.5 × 109/L. Incidence and time to development of grades 2 to 4 acute GVHD were evaluated in patients surviving 21 days with evidence of engraftment.13 Time to occurrence of any chronic GVHD was evaluated in patients surviving 90 days after transplantation with engraftment.14 TRM was defined as death in continuous complete remission.15 The end point for survival analyses was death from any cause.Statistical analysis Patient-, disease-, and transplant-related variables between groups were compared using the 2 statistic for
categorical variables and the Mann-Whitney U test for
continuous variables. Probabilities of survival were calculated using
the Kaplan-Meier estimator, censored at the last day of contact; the
log-rank test was used for univariate comparisons of survival
probabilities. Cumulative incidence curves were used to calculate
probabilities of graft failure, acute GVHD, chronic GVHD, and
TRM.16 Death was used as the competing risk for graft failure, acute GVHD, and chronic GVHD. Hematologic relapse was used as
the competing risk for TRM.
Differences in outcomes of NIMA- versus NIPA-mismatched transplantation were evaluated in multivariate analyses using Cox proportional hazards regression to adjust for other potentially confounding differences between the cohorts.17 Variables considered were recipient age and sex, Karnofsky performance score at diagnosis, disease type, disease stage and duration at transplantation, donor age and sex, conditioning regimen, GVHD prophylaxis, calendar year of transplantation, and number and class of HLA-antigen mismatches. Only factors significantly (P < .05) associated with outcome were retained in the final models. For each variable and outcome, the assumption of proportional hazards was tested using a time-dependent covariate. When this indicated differential effects over time (nonproportional hazards), models were constructed breaking the posttransplantation course into 2 time periods, using the maximized partial likelihood method to find the most appropriate breakpoint. NIPA-mismatched sibling donor for the end point of time to acute GVHD and paternal donor for the end point of time to chronic GVHD were 2 variables with nonproportional hazards. Forward stepwise variable selection at a .05 significance level was used to identify covariates other than HLA mismatch that were associated with outcome. In each step of the analysis, the covariate for NIMA versus NIPA mismatch was included in the model. First-order interactions between NIMA versus NIPA mismatch and all significant covariates were considered. Overall covariate effects were analyzed using the Wald test. Examination for center effects used a random effects model or a frailty model18; there was no evidence of confounding of main effects by center effects. All P values were 2-sided.
Patients Donor-recipient relationship, sex match, and histocompatibility are listed in Table 1. One hundred thirty-two transplant donors were haploidentical siblings, and 137 transplant donors were parents.
Patient and disease characteristics are listed in Table 1. The only statistically significant difference between the NIMA- and NIPA-mismatched sibling transplant recipients was disease duration before transplantation, which was longer in patients mismatched for NIMA (P < .03). Transplantation characteristics are listed in Table 1. No statistically significant differences were observed between NIMA- and NIPA-mismatched sibling transplantations. Of note, parental donors were older and parental grafts had higher degrees of HLA mismatch than sibling grafts, but characteristics of paternal and maternal grafts were similar. Univariate outcomes Unadjusted probabilities of graft failure, GVHD, TRM, and survival by donor type are given in Table 2.
Multivariate analyses Table 3 shows relative risks of transplantation outcomes by donor type, adjusting for other factors associated with transplantation outcome, including degree of donor-recipient histocompatibility.
Relative risks of graft failure and GVHD after NIPA-mismatched
sibling transplantations, maternal transplantations, and paternal transplantations versus NIMA-mismatched sibling transplantations are
shown in Table 3. NIPA-mismatched sibling transplantations involved
significantly more acute grades 2 to 4 GVHD than NIMA-mismatched sibling transplantations, starting 7 days after transplantation (P = .02) (Figure 2). A
similar but not statistically significant trend was observed for
chronic GVHD.
Maternal and paternal transplantations were associated with significantly more acute and chronic GVHD and TRM than NIMA-mismatched but not NIPA-mismatched sibling transplantations (Table 3). Graft failure and survival did not differ by donor type. Table 3 also shows results of separate multivariate analyses comparing maternal and parental transplantations. Although graft failure appeared to occur less often with maternal versus than with paternal donors, this did not reach statistical significance. In the first 4 months after transplantation, the risk for chronic GVHD was significantly higher in patients who received paternal grafts than in those who received maternal grafts. Acute GVHD, TRM, and overall survival rates were similar.
This study provides evidence that exposure to maternal HLA antigens during the prenatal and the perinatal periods can have lifelong significance, at least with respect to GVHD risk. Transplantation from a haploidentical sibling donor to a recipient mismatched for maternal antigens is associated with less GVHD than transplantation from a sibling donor mismatched for paternal antigens and with less GVHD and TRM than transplantation from the mother or the father. This study may indicate that exposure to NIMA has a strong lifelong modulating impact on the immune response, resulting in a down-regulation of this response to later antigen challenge. No statistically significant differences in graft failure rates were found. This is not surprising considering the drastic immune ablation of pretransplantation conditioning regimens and the limited statistical power of the study. Maternal grafts tended to involve less graft failure and significantly less early chronic GVHD than grafts from the father, but they were not associated with less acute GVHD, less TRM, or better survival than paternal grafts. This is contrary to expectation, if one assumes that the mother develops, during pregnancy, partial tolerance to the haplotypes of the father. Such an assumption is, however, an oversimplification. Evidence for a tolerising effect through pregnancy exists, but a large percentage of pregnant women form antibodies against paternal HLA antigens.19 This tolerising effect is certainly not always present. Priming of T cells against paternal antigens has also been documented. This does not exclude the possibility that partial tolerance to paternal HLA antigens might exist in some women. The situation is further complicated by the fact that such partial tolerance to the paternal HLA antigens might be counteracted by priming of T (and B?) cells to paternal minor histocompatibility antigens. Our findings show striking similarity to the results of a recent study on the outcome of parental and haploidentical sibling kidney allografts4 and to those of a small (n = 15) study of haploidentical sibling cord blood transplantations.20 In the first study, grafts from haploidentical siblings mismatched for NIMA had significantly better survival than those from parents or from siblings mismatched for paternal antigens. In contrast to that study, in which there was no difference between maternal and paternal transplantations, the current study found less chronic GVHD with maternal than with paternal grafts. Comparing the outcome of a transplant donated by a haploidentical sibling with one donated by a parent is further complicated by the fact that the shared haplotypes differ (Figure 1). If the mother is the donor, her T cells might be primed against the minor histocompatibility antigens of the father through restriction by the shared maternal haplotype. If a sibling is the donor, the shared haplotype originates from the parent other than the one contributing the mismatched haplotype. This might reduce T-cell reactivity to the minor histocompatibility antigens. The mother and the child have been exposed to the other's histocompatibility antigens. However, during this exposure, the immune system of the child is more naive than that of the mother. It is possible that this, too, plays a role in the different outcome for maternal grafts than for sibling grafts mismatched for maternal antigens. It should be noted that the parental donors in this study tended to have more HLA disparity with the recipient than the sibling donors. In addition, transplants from older donors are more often associated with GVHD. Although we attempted to adjust for this effect in multivariate analysis, it is possible that it contributed to the observed differences in outcome between parental and sibling transplantations. Another limitation of the study is that no information on (mis)matches of HLA-C, -DQ, or -DP was available, nor was information available on HLA typing at the allele level. These shortcomings will be addressed during the forthcoming 13th International Histocompatibility Workshop. It may be of interest that transplants mismatched for HLA-A with the recipient, in which the HLA-A-mismatched antigens were for the donor NIMA, involved the least GVHD (P = .10) (data not shown). Although our data are not statistically significant, similar and significant observations have been reported in kidney transplantation.11 Whether our findings can be used to improve the results of hematopoietic stem cell transplantation from unrelated donors remains to be investigated. Taken together, our observations could be interpreted as evidence for a lifelong(!) immune-modulating effect of pregnancy. Unraveling the cellular and molecular mechanism underlying this effect might provide information regarding allograft recognition and its regulation. The mechanism whereby exposure to maternal cells or soluble HLA antigens minimizes the risk for GVHD and, consequently, TRM remains unclear. Several interactions are possible and have been discussed elsewhere, but none of them have been formally tested and shown to be correct.4,21-23 The recent observation that the stimulation of umbilical cord blood T
cells with peripheral blood lymphocytes of the mother causes a
significant increase in immune-modulating CD8dim T
cells
Submitted June 5, 2001; accepted October 24, 2001.
Supported by Public Health Service grant U24-CA76518 from the National Cancer Institute, the National Institute of Allergy and Infectious Diseases, and the National Heart, Lung and Blood Institute; grants from Amcell; Amgen; Anonymous; Aventis Pharmaceuticals; Baxter Oncology; Berlex Laboratories; Blue Cross and Blue Shield Association; Lynde and Harry Bradley Foundation; Ceros; Chimeric Therapies; Chiron Therapeutics; Eleanor Naylor Dana Charitable Trust; Empire Blue Cross Blue Shield; Fujisawa Healthcare; Gambro BCT; Center for Advanced Studies in Leukemia; Genentech; GlaxoSmithKline; Human Genome Sciences; ICN Pharmaceuticals; IDEC Pharmaceuticals; Immunex Corporation; IntraBiotics Pharmaceuticals; Kettering Family Foundation; Kirin Brewery; Robert J. Kleberg Jr and Helen C. Kleberg Foundation; LifeTrac/Allianz; Nada and Herbert P. Mahler Charities; Market Certitude; Mayer Ventures; MedImmune; Merck; Milliman & Robertson; Milstein Family Foundation; Greater Milwaukee Foundation/Elsa Schoeneich Research Fund; NeoRx; Novartis Pharmaceuticals; Orphan Medical; Ortho Biotech; John Oster Family Foundation; Pfizer; Pharmacia; Principal Life Insurance; Response Oncology; RGK Foundation; Roche Laboratories; SangStat; Schering AG; Schering Oncology/Biotech; Stackner Family Foundation; The Starr Foundation; SuperGen; TheraTechnologies; Unicare Life and Health Insurance; Wyeth/Genetics Institute; and Macropa Foundation.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Mary M. Horowitz, IBMTR/ABMTR Statistical Center, Medical College of Wisconsin, PO Box 26509, Milwaukee, WI 53226; e-mail: marymh{at}mcw.edu.
1.
Thomas AD.
Marrow transplantation for malignant diseases.
J Clin Oncol.
1983;1:517-531
2.
Szydlo R, Goldman JM, Klein JP, et al.
Results of allogeneic bone marrow transplants for leukemia using donors other than HLA-identical siblings.
J Clin Oncol.
1997;15:1767-1777 3. van Rood JJ. Why does the exposure to allogeneic cells sometimes lead to immunization and sometimes not. (Niels Jerne Lecture) Res Immunol. 1990;141:783-794[CrossRef][Medline] [Order article via Infotrieve].
4.
Burlingham WJ.
The effect of tolerance to non-inherited maternal HLA antigen on the survival of renal transplants from sibling donors.
N Engl J Med.
1998;339:1657-1664
5.
Claas FH, Gijbels Y, van der Velden-de Munck J, van Rood JJ.
Induction of B cell unresponsiveness to non-inherited maternal HLA antigens during fetal life.
Science.
1988;241:1815-1817 6. van Rood JJ, Zhang L, van Leeuwen A, Claas FH. Neonatal tolerance revisited. Immunol Lett. 1989;21:51-54[CrossRef][Medline] [Order article via Infotrieve]. 7. Campbell DA Jr, Lorber MI, Sweeton JC, Turcotte JG, Niederhuber JE, Beer AE. Breast feeding and mother-donor renal allografts: possibly the original donor-specific transfusion. Transplantation. 1984;37:340-344[Medline] [Order article via Infotrieve].
8.
Owen RD, Wood HR, Foord AG, Sturgeon P, Baldwin LG.
Evidence for actively acquired tolerance to Rh antigen.
Proc Natl Acad Sci U S A.
1954;40:420-424 9. Bean MA, Mickelson E, Yanagida J, Ishioka S, Brannen GE, Hansen JA. Suppressed anti-donor MLC responses in renal transplant candidates conditioned with donor-specific transfusions that carry the recipients' non-inherited maternal HLA haplotype. Transplantation. 1990;49:382-386[Medline] [Order article via Infotrieve]. 10. Opelz G. Analysis of the "NIMA effect" in renal transplantation. In: Terasaki PI, ed. Clinical Transplants. Los Angeles: UCLA Tissue Typing Laboratory.; 1990:63-67. 11. Smits JM, Claas FH, van Houwelingen HC, Persijn GG. Do non-inherited maternal antigens (NIMAs) enhance renal allograft survival? Transplant Int. 1998;11:82-88[CrossRef][Medline] [Order article via Infotrieve]. 12. Horowitz MM, Bortin MM. The role of registries in evaluating the results of bone marrow transplantation. In: Treleaven JG,Barrett AJ, eds. Bone Marrow Transplantation in Practice. London, England: Churchill Livingstone; 1992:367-377. 13. Hagglund H, Bostrom L, Remberger M, Ljungman P, Nilsson B, RingdJn O. Risk factors for acute graft-versus-host disease in 291 consecutive HLA-identical bone marrow transplant recipients. Bone Marrow Transplantation. 1995;16:747-753[Medline] [Order article via Infotrieve]. 14. Weisdorf D, Hakke R, Blazar B, et al. Risk factors for acute graft-versus-host disease in histocompatible donor bone marrow transplantation. Transplantation. 1991;51:1197-1203[Medline] [Order article via Infotrieve].
15.
Deeg HJ, Storb R, Thomas ED, et al.
Cyclosporine as prophylaxis for graft-versus-host disease: a randomized study in patients undergoing marrow transplantation for acute nonlymphoblastic leukemia.
Blood.
1985;65:1325-1334 16. Gooley TA, Leisenring W, Crowley JA, Storer BE. Estimation of failure probabilities in the presence of competing risks: new representations of old estimators. Stat Med. 1999;18:665-706. 17. Klein JP, Moeschberger ML. Survival Analysis: Techniques for Censored and Truncated Data. New York, NY: Springer Verlag; 1996:334-336. 18. Andersen PK, Klein JP, Zhang MH. Testing for center effects in multi-centre survival studies: a Monte Carlo comparison of fixed and random effects tests. Stat Med 1999;18:1489-1500[CrossRef][Medline] [Order article via Infotrieve]. 19. van Rood JJ. Eernisse JG, van Leeuwen A. Leucocyte antibodies in sera of pregnant women. Nature. 1958;181:1735-1736[CrossRef][Medline] [Order article via Infotrieve]. 20. Wagner JE. Allogeneic umbilical cord blood transplantation. Cancer Treat Res. 1997;77:187-216[Medline] [Order article via Infotrieve].
21.
van Rood JJ, Claas FH.
The influence of allogeneic cells on the human T and B cell repertoire.
Science.
1990;248:1388-1393 22. van Rood JJ, Claas FH. Both self and non-inherited maternal HLA antigens influence the immune response. Immunol Today. 2000;21:269-273[CrossRef][Medline] [Order article via Infotrieve]. 23. van Rood JJ, Claas FH. Non-inherited maternal HLA antigens: a proposal to elucidate their role in the immune response. Hum Immunol. 2000;61:1390-1394[CrossRef][Medline] [Order article via Infotrieve]. 24. Moretta A, Locatelli F, Mingrat G, et al. Characterisation of CTL directed towards non-inherited maternal allo-antigens in human cord blood. Bone Marrow Transplant. 1999;24:1161-1166[CrossRef][Medline] [Order article via Infotrieve]. 25. Leonard AA, Jonker M, Lagaaij EL. Complete withdrawal of immuno-suppression in allograft recipients: a study in rhesus monkeys. Transplantation. 1996;61:1648-1651[CrossRef][Medline] [Order article via Infotrieve]. 26. Jonker M, van de Hout Y, Neuhaus P, et al. Complete withdrawal of immuno-suppression in kidney allograft recipients: a prospective study in rhesus monkeys. Transplantation. 1998;66:925-927[CrossRef][Medline] [Order article via Infotrieve].
© 2002 by The American Society of Hematology.
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  W. J. Burlingham A Lesson in Tolerance -- Maternal Instruction to Fetal Cells N. Engl. J. Med., March 26, 2009; 360(13): 1355 - 1357. [Full Text] [PDF]
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 K. Aoyama, M. Koyama, K.-i. Matsuoka, D. Hashimoto, T. Ichinohe, M. Harada, K. Akashi, M. Tanimoto, and T. Teshima Improved outcome of allogeneic bone marrow transplantation due to breastfeeding-induced tolerance to maternal antigens Blood, February 19, 2009; 113(8): 1829 - 1833. [Abstract] [Full Text] [PDF]
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F. Ciceri, M. Labopin, F. Aversa, J. M. Rowe, D. Bunjes, P. Lewalle, A. Nagler, P. Di Bartolomeo, J. F. Lacerda, M. T. Lupo Stanghellini, et al. A survey of fully haploidentical hematopoietic stem cell transplantation in adults with high-risk acute leukemia: a risk factor analysis of outcomes for patients in remission at transplantation Blood, November 1, 2008; 112(9): 3574 - 3581. [Abstract] [Full Text] [PDF]
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 A. L. Feitsma, J. Worthington, A. H. M. van der Helm-van Mil, D. Plant, W. Thomson, J. Ursum, D. van Schaardenburg, I. E. van der Horst-Bruinsma, J. J. van Rood, T. W. J. Huizinga, et al. Protective effect of noninherited maternal HLA-DR antigens on rheumatoid arthritis development PNAS, December 11, 2007; 104(50): 19966 - 19970. [Abstract] [Full Text] [PDF]
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 M. L. Molitor-Dart, J. Andrassy, J. Kwun, H. A. Kayaoglu, D. A. Roenneburg, L. D. Haynes, J. R. Torrealba, J. L. Bobadilla, H. W. Sollinger, S. J. Knechtle, et al. Developmental Exposure to Noninherited Maternal Antigens Induces CD4+ T Regulatory Cells: Relevance to Mechanism of Heart Allograft Tolerance J. Immunol., November 15, 2007; 179(10): 6749 - 6761. [Abstract] [Full Text] [PDF]
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|
D.-P. Lu, L. Dong, T. Wu, X.-J. Huang, M.-J. Zhang, W. Han, H. Chen, D.-H. Liu, Z.-Y. Gao, Y.-H. Chen, et al. Conditioning including antithymocyte globulin followed by unmanipulated HLA-mismatched/haploidentical blood and marrow transplantation can achieve comparable outcomes with HLA-identical sibling transplantation Blood, April 15, 2006; 107(8): 3065 - 3073. [Abstract] [Full Text] [PDF]
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J. J. van Rood You will never forget your mother! Blood, January 1, 2006; 107(1): 7 - 8. [Full Text] [PDF]
|
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K.-i. Matsuoka, T. Ichinohe, D. Hashimoto, S. Asakura, M. Tanimoto, and T. Teshima Fetal tolerance to maternal antigens improves the outcome of allogeneic bone marrow transplantation by a CD4+CD25+ T-cell-dependent mechanism Blood, January 1, 2006; 107(1): 404 - 409. [Abstract] [Full Text] [PDF]
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|
 C. Vernochet, S. M. Caucheteux, M.-C. Gendron, J. Wantyghem, and C. Kanellopoulos-Langevin Affinity-Dependent Alterations of Mouse B Cell Development by Noninherited Maternal Antigen Biol Reprod, February 1, 2005; 72(2): 460 - 469. [Abstract] [Full Text] [PDF]
|
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 T. R. Spitzer Haploidentical Stem Cell Transplantation: The Always Present but Overlooked Donor Hematology, January 1, 2005; 2005(1): 390 - 395. [Abstract] [Full Text] [PDF]
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|
T. Ichinohe, T. Uchiyama, C. Shimazaki, K. Matsuo, S. Tamaki, M. Hino, A. Watanabe, M. Hamaguchi, S. Adachi, H. Gondo, et al. Feasibility of HLA-haploidentical hematopoietic stem cell transplantation between noninherited maternal antigen (NIMA)-mismatched family members linked with long-term fetomaternal microchimerism Blood, December 1, 2004; 104(12): 3821 - 3828. [Abstract] [Full Text] [PDF]
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 K. M. Adams and J. L. Nelson Microchimerism: An Investigative Frontier in Autoimmunity and Transplantation JAMA, March 3, 2004; 291(9): 1127 - 1131. [Abstract] [Full Text] [PDF]
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J. Andrassy, S. Kusaka, E. Jankowska-Gan, J. R. Torrealba, L. D. Haynes, B. R. Marthaler, R. C. Tam, B. M.-W. Illigens, N. Anosova, G. Benichou, et al. Tolerance to Noninherited Maternal MHC Antigens in Mice J. Immunol., November 15, 2003; 171(10): 5554 - 5561. [Abstract] [Full Text] [PDF]
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Top
Abstract
Introduction
in contrast to an increase of cytotoxic CD8bright T
cells after stimulation with the paternal cells