ABSTRACT
Therapy for post-transplant relapse of paediatric ALL is limited. Standardised curative approaches are not available. We hereby describe our local procedure in this life-threatening situation. A total of 101 ALL patients received their first allogeneic stem cell transplantation (SCT) in our institution. After relapse, our primary therapeutic goal was to cure the patient with high-dose chemotherapy or specific immunotherapy (HDCHT/SIT) followed by a second SCT from a haploidentical donor (transplant approach). If this was not feasible, low-dose chemotherapy and donor lymphocyte infusions (LDCHT+DLI) were offered (non-transplant approach). A total of 23 patients suffered a post-transplant relapse. Eight patients received HDCHT/SIT, followed by haploidentical SCT in 7/8. Ten received LDCHT+DLI. The eight patients treated with a second transplant and the ten treated with the non-transplant approach had a 4-year overall survival of 56% and 40%, respectively (P=0.232). Prerequisites for successful treatment of post-transplant relapse by either a second transplant or experimental non-transplant approaches are good clinical condition and the capacity to achieve haematological remission by the induction treatment element.
Subject(s)
Immunotherapy , Lymphocyte Transfusion , Precursor Cell Lymphoblastic Leukemia-Lymphoma/therapy , Stem Cell Transplantation , Tissue Donors , Adolescent , Allografts , Child , Child, Preschool , Female , Germany , Humans , Infant , Male , Recurrence , Retrospective StudiesABSTRACT
HLA-C*15:103 allele is characterised by one amino acid substitution in the alpha 2 domain.
Subject(s)
Alleles , Exons , HLA-C Antigens/genetics , Hematopoietic Stem Cell Transplantation/methods , Leukemia/therapy , Polymorphism, Single Nucleotide , Unrelated Donors , Aged , Amino Acid Substitution , Base Sequence , Child , Codon/chemistry , Female , Genotype , HLA-C Antigens/immunology , Histocompatibility Testing , Humans , Leukemia/immunology , Leukemia/pathology , Male , Middle Aged , Pedigree , Polymerase Chain Reaction , Protein Domains , Sequence Alignment , Sequence Analysis, DNA , Treatment OutcomeABSTRACT
BACKGROUND: T-cell-depleted allografts may exhibit delayed T-cell recovery, severe infections, and relapse after haploidentical hematopoietic stem cell transplantation (HSCT). Required donor lymphocyte infusions containing nonalloreactive cells may transfer immune function without causing graft-versus-host disease. METHODS: We developed an ex vivo approach for the immunomagnetic depletion of alloreactive CD25+, CD69+, and HLA-DR+ T-cells. To achieve highest rates of alloantigen expression, we cocultured peripheral blood mononuclear cells (PBMNCs) with PBMNCs (A/B*), dendritic cells (A/B* DCs), or cytokine-pretreated PBMNCs (A/B* cyt cells). Functional analyses were performed after depletion. RESULTS: After coculture with PBMNCs (A/B* cells), 29% of T-cells became CD25+, CD69+, and HLA-DR+. In modified mixed lymphocyte reactions (MLR) (A/B* cyt cells and A/B* DCs), 35% and 37% of T-cells became CD25+, CD69+, and HLA-DR+. Alloactivation was confirmed by interferon gamma release and proliferation. Immuno-magnetic depletion produced <1% alloactivated cells. Furthermore, this depletion strategy was allospecific and hardly impaired the immune function of the retained cells. DISCUSSION: The efficiency of immunomagnetic depletion depended on the stimulatory capacity of stimulator cells and was improved by using cytokine-pretreated PBMNCs for alloactivation. Overall, this approach might be a promising strategy for restoration of the immune system, particularly after haploidentical HSCT.
Subject(s)
Immunotherapy, Adoptive , Lymphocyte Depletion/methods , Magnetics , Coculture Techniques , Dendritic Cells , Flow Cytometry , Humans , Leukocytes, MononuclearABSTRACT
Enrichment of cell subpopulations is a prerequisite for lineage-specific chimerism analysis (LCA), a frequent approach in follow-up after allo-SCT. An efficient enrichment technique is Magnetic Cell Sorting (MACS) using the AutoMACS separator. However, evaluation of purity, recovery and applicability for PCR-based chimerism analysis of MACS-enriched subpopulations from post-transplant peripheral blood, providing reduced cell numbers and/or unbalanced proportions of subpopulations, is currently unavailable. We performed enrichment of CD3-, CD14-, CD15-, CD19- and CD56-positive subpopulations using 'Whole Blood MicroBeads' and AutoMACS separator in 137 prospectively collected peripheral blood samples from 15 paediatric patients after allo-CD3-/CD19-depleted SCT. Purity was assessed by immune phenotyping. Recovery and applicability for chimerism analysis was evaluated. Excellent purity >90% was achieved in CD14-, CD15-positive cells in 81%, 95% of the isolates and in 86% of CD3 and CD19 isolates, if ACC was >400 cells per mul. Median purity of CD56-positive isolates was 78.9%. Recovery >90% was between 93 (CD56) and 37% (CD15). Conventional and real-time PCR-based chimerism analysis was feasible in virtually all samples. Isolation of cell subpopulations by automated cell enrichment in post-transplant peripheral blood is feasible and fast providing excellent purity and recovery for routine lineage-specific chimerism analysis.
