Radiotherapy-based conditioning is effective immunosuppression for patients undergoing transplantation with T-cell depleted stem cell grafts for severe aplasia

BACKGROUND: We studied the outcome of individuals with aplastic anemia conditioned with a radiation-containing regimen followed by an infusion of stem cell grafts that had been depleted of lymphocytes with CAMPATH-1H (antiCD52; humanised). METHODS: The conditioning regime consisted of fractionated (f) TBI 8 Gy followed by f total nodal irradiation (TNI) 6 Gy. In addition, patients received CY 60 mg/kg on 2 consecutive days. Cytokine-mobilized peripheral blood grafts from HLA-identical siblings were T-cell depleted with CAMPATH-1H 'in the bag'. CsA was commenced on day -1 and continued until day +90. RESULTS: Seventeen heavily transfused patients with aplastic anemia, median age 18 years (range 14-56 years), were studied. The median time from diagnosis to transplantation was 172 days (range 34-443 days). The median CD34(+) cell number infused was 3.47 x 10(6)/kg (range 1.03-18.4 x 10(6)/kg). All patients engrafted. Recovery was fast and patients reached 0.5 x 10(9)/L polymorphs by median day 11 (range 9-17 days). Toxicity from the conditioning included grade 4 hematologic toxicity in all patients. Another major toxicity was gastrointestinal mucosal damage, which exceeded grade 2 in two instances. One patient developed thrombotic thrombocytopenic purpura, which responded to substitution of CsA with tacrolimus and plasmapheresis. Another patient, who had normal blood counts, died of infection on day 241. Chimerism studies at 6 months post-transplantation confirmed the donor origin of hematopoiesis in all seven patients tested. None of the patients developed acute or chronic GvHD. There was no delayed graft failure and 94% of patients had survived disease free at a median of 1303.5 days (range 216-2615 days) from graft infusion. DISCUSSION: In this cohort of multiply transfused patients, the radiation-containing schedules described in this study led to universal engraftment with limited toxicity despite T-cell depletion. No patient developed GvHD or late graft failure. Lower doses of radiation-containing conditioning should be explored further.     

Number of megakaryocytic progenitors and adhesion molecule expression of stem cells predict platelet engraftment after allogeneic hematopoietic stem cell transplantation

BACKGROUND: The mechanism of platelet recovery after hematopoietic stem cell transplantation and the factors that influence its time-course are not fully understood. Rapid hematopoietic recovery results in a reduction of transplantation-related complications. In the present study, we questioned and analyzed whether there were important factors predicting the speed of platelet engraftment. METHODS: Thirty-seven patients with various hematologic diseases transplanted with allogeneic BM between January 2002 and December 2005 were included. We investigated the differences in mononuclear cell counts (MNC), numbers of infused CD34(+), CD34(+) CD41(+) and CD34(+) CD61(+) cells and phenotypic analysis of homing-associated cell adhesion molecules (CXCR4, CD49d and CD49e). The number of megakaryocytes formed in vitro (colony-forming unit-megakaryocytes; CFU-Mk) was also measured. RESULTS: Median days of ANC >/=0.5x10(9)/L and platelet count >/=20x10(9)/L were 14.8 and 17.3, respectively. The number of infused CD34(+) CD41(+) and CD34(+) CD61(+) cells correlated much better with the time to platelet engraftment than that of infused CD34(+)cells (P<0.05 each). Rapid platelet recovery also occurred in patients receiving both higher homing-associated cell adhesion molecule doses and CFU-Mk (P<0.05 each). DISCUSSION: Rapid platelet recovery has several advantages, including reducing the cost of supportive therapy and reducing the risk of fatal bleeding as a result of severe thrombocytopenia. Our findings suggest that phenotypic and clonogenic assessment of infused progenitor cells can identify patients in whom platelet engraftment is likely to be significantly delayed, and new strategies to overcome related problems might be employed in the very near future.     

Sepsis, low platelet nadir at mobilization and previous IFN use predict stem cell mobilization failure in patients with multiple myeloma

BACKGROUND: Successful stem cell mobilization is a prerequisite for autologous blood cell transplantation. We analyzed factors that may predict the success of stem cell mobilization in patients with multiple myeloma (MM). METHODS: We analyzed 124 consecutive patients and compared those who failed to mobilize a sufficient amount of CD34(+) cells (peak blood CD34(+) cell count <20x10(6)/L) (n=20) with those with successful mobilization (n=104). The peak blood CD34(+) cell count after mobilization was used as the marker of mobilization success against which the various predictive factors were tested. RESULTS: In univariate analysis the best predictive factors for mobilization failure were the number of different chemotherapy regimens (P<0.001), number of chemotherapy cycles (P<0.001), time from diagnosis to mobilization (P<0.001) and previous use of IFN (P<0.001). The distributions of treatment responses at mobilization were similar in the groups with successful and unsuccessful mobilization, and were CR or VGPR in 10% of all patients, PR in 54% and stable or progressive disease in 36%. Regarding the mobilization-related factors, lower leukocyte nadir (P<0.001), longer duration of leukocyte counts <1x10(9)/L (P<0.001), lower platelet nadir (P=0.001), longer duration of platelet counts <20x10(9)/L (P<0.001) and the occurrence of sepsis after the mobilization therapy (P=0.001) were significantly associated with mobilization failure. In multivariate analysis, the amount of earlier chemotherapy cycles (P=0.002), low platelet nadir (P=0.020), occurrence of sepsis at mobilization (P=0.040) and previous use of IFN (P=0.052) remained as significant predictive factors for mobilization failure. DISCUSSION: Predicting the success of stem cell mobilization beforehand may have important practical consequences. By identifying those patients who will fail to mobilize stem cells, unnecessary mobilization and collection attempts can be avoided.     

A French single-center experience on allogeneic stem cell transplant cryopreservation during severe acute respiratory syndrome coronavirus 2 pandemic

Background aimsAllogeneic hematopoietic stem cell transplantation (allo-SCT) is a curative treatment for chemo-resistant hematological malignancies. Because of transport restriction imposed by the coronavirus disease 2019 pandemic, regulatory bodies and societies recommended graft cryopreservation before recipient conditioning. However, the freezing and thawing processes, including washing steps, might impair CD34+ cell recovery and viability, thereby impacting the recipient engraftment. Over 1 year (between March 2020 and May 2021), we aimed to analyze the results of frozen/thawed peripheral blood stem cell allografts in terms of stem cell quality and clinical outcomes.MethodsTransplant quality was evaluated by comparing total nucleated cells (TNCs), CD34+ cells and colony-forming unit–granulocyte/macrophage (CFU-GM)/kg numbers as well as TNC and CD34+ cell viabilities before and after thawing. Intrinsic biological parameters such as granulocyte, platelet and CD34+ cell concentrations were analyzed, as they might be responsible for a quality loss. The impact of the CD34+ cell richness of the graft on TNC and CD34 yields was evaluated by designing three groups of transplants based on their CD34 /kg value at collection: >8 × 10 ⁶/kg, between 6 and 8 × 10⁶/kg and <6 × 10⁶/kg. The consequences of cryopreservation were compared in the fresh and thawed group by evaluating the main transplant outcomes.ResultsOver 1 year, 76 recipients were included in the study; 57 patients received a thawed and 19 patients a fresh allo-SCT. None received allo-SCT from a severe acute respiratory syndrome coronavirus 2–positive donor. The freezing of 57 transplants led to the storage of 309 bags, for a mean storage time (between freezing and thawing) of 14 days. For the fresh transplant group, only 41 bags were stored for potential future donor lymphocyte infusions. Regarding the graft characteristics at collection, median number of cryopreserved TNC and CD34+ cells/kg were greater than those for fresh infusions. After thawing, median yields were 74.0%, 69.0% and 48.0% for TNC, CD34+ cells and CFU-GM, respectively. The median TNC dose/kg obtained after thawing was 5.8 × 10⁸, with a median viability of 76%. The median CD34+ cells/kg was 5 × 10⁶, with a median viability of 87%. In the fresh transplant group, the median TNC/kg was 5.9 × 10⁸/kg, and the median CD34+ cells/kg and CFU-GM/kg were 6 × 10⁶/kg and 276.5 × 10⁴/kg, respectively. Sixty-one percent of the thawed transplants were out of specifications regarding the CD34+ cells/ kg requested cell dose (6 × 10⁶/kg) and 85% of them would have had this dose if their hematopoietic stem cell transplant had been infused fresh. Regarding fresh grafts, 15.8% contained less than 6 × 10⁶ CD34+ cells /kg and came from peripheral blood stem cells that did not reach 6 × 10⁶ CD34+ cells /kg at collection. Regarding the factor that impaired CD34 and TNC yield after thawing, no significant impact of the granulocyte count, the platelet count or the CD34+ cells concentration/µL was observed. However, grafts containing more than 8 × 10 ⁶/kg at collection showed a significantly lower TNC and CD34 yield.ConclusionsTransplant outcomes (engraftment, graft-versus-host disease, infections, relapse or death) were not significantly different between the two groups.     

Hemopoietic stem and precursor cell analysis in umbilical cord blood using the Sysmex SE-9000 IMI channel

Circulating hematopoietic progenitor cells (HPCs) are routinely measured by flow cytometry using CD34 expression. As an alternative, the "immature information" (IMI) channel measurement of the automated hematology analyzer Sysmex SE machines was developed. We tested the IMI channel HPC method with umbilical cord blood specimens. The IMI-HPCs were compared with CD34 counts and numbers of colony-forming units (CFUs). The IMI-HPC data were reproducible and dilution experiments yielded a log-linear relationship. The mean percentage of CD34(+) cells in 50 umbilical cords was 0.43 versus 0.11 of HPCs in the IMI channel (correlation coefficient r = 0.67). Absolute numbers yielded 96.79 x 10(6)/L CD34(+), 33.17 x 10(6)/L IMI-HPC, and 35.04 x 10(6)/L CFU-HPC. Receiver operating characteristics curves were made at various cutoff levels for CD34(+) cells to visualize sensitivity and specificity profiles. With median values of 13.56 x 10(6)/L for IMI-HPC and 20 x 10(6)/L for CD34(+) as cutoff points (the levels used in the laboratory to start stem cell pheresis), the percentage of false-negative observations was 70.4%. To exclude the influence of storage time, tests were repeated until 72 h after umbilical cord collection. Total white blood cell count decreased in most cases, whereas absolute number of IMI-HPC tended to increase in time. In conclusion, if HPC measurements in the IMI channel are used to monitor circulating stem cells during mobilization, one has to be aware of a very low correlation between these results and those of other methods such as CD34(+) analysis and colony growth. False-negative results do occur, but if events are seen in the IMI channel, this simple monitoring technique is useful to predict the presence of circulating stem cells.     

Correlation of residual leukocyte subsets with neutropenic fever during severe leukopenia after high-dose chemotherapy and autologous stem cell transplantation

BACKGROUND: High-dose chemotherapy with autologous stem cell transplantation is the standard treatment of eligible patients with multiple myeloma. However, this treatment is associated with a substantial risk of infectious complications during leukopenia. The aim of our pilot study was to determine the residual leukocyte subsets during severe cytopenia after high-dose melphalan and to correlate this with the occurrence of neutropenic fever. METHODS: Residual leukocyte subsets in the peripheral blood on days 4-7 following autologous stem cell transplantation were analyzed by three-color flow cytometry in 20 patients with multiple myeloma. In addition, we determined the number of T cells that were transfused with the autografts. RESULTS: Absolute numbers of lymphocytes (mean 25/microL) and monocytes (mean 4/microL) were strongly reduced but rather constant during the period of severe neutropenia. Neutrophil engraftment and duration of neutropenia were very similar in patients with and without neutropenic fever. Low absolute lymphocyte counts and absolute CD4+ T-cell counts on days 4-7 after stem cell transplantation correlated with neutropenic fever. Furthermore, T-cell numbers in the autologous stem cell grafts that the patients received were significantly lower in patients with neutropenic fever. DISCUSSION: These observations suggest that the number of T cells, and in particular CD4+ T cells, in the blood during severe cytopenia is playing a role in defense of infection. T-cell numbers in the graft could provide a predictive factor for the risk of infection in the post-transplant period. However, this needs to be confirmed in a larger study.     

CD34(+) CD38(-) and CD34(+) HLA-DR(-) cells in BM stem cell grafts correlate with short-term engraftment but have no influence on long-term hematopoietic reconstitution after autologous transplantation

BACKGROUND: Prior studies have demonstrated that relatively immature hematopoietic stem cells, including CD34(+) CD38(-) and CD34(+) HLA-DR(-) subsets, correlate with short-term hematopoietic reconstruction (SHR) after transplantation. The aim of this study was to investigate whether these immature CD34(+) subsets also correlate with long-term hematopoietic reconstitution (LHR) in recipients of ABMT. METHODS: We examined stem cell grafts from 58 patients with B-cell lymphoma or CLL who underwent ABMT after myeloablative conditioning. We determined whether total mononuclear cell dose (MNC), colony-forming unit-granulocyte-monocyte (CFU-GM), CD34(+) cell dose and CD34(+) cell subsets (CD34(+) CD38(-) and CD34(+) HLA-DR(-) were associated with SHR and/or LHR. Time to neutrophil engraftment (TNE) and time to platelet engraftment (TPE) were used to measure SHR, while platelet counts at day 100 and 1 year post-ABMT were used as indicators for LHR. RESULTS AND DISCUSSION: CD34(+) cell dose and CD34(+) cell subsets were significantly associated with SHR. However, at day 100 and 1 year post-transplant only total CD34(+) cell dose was associated with LHR. The association of total CD34(+) cell dose with LHR persisted after adjusting for age, sex and disease. None of the CD34(+) cell subsets analyzed showed evidence of significant association with LHR.     

Peripheral blood and BM CD34+ CD38- cells show better resistance to cryopreservation than CD34+ CD38+ cells in autologous stem cell transplantation

BACKGROUND: We and others have shown a critical role for CD34+ CD38- cells in hematopoietic recovery after autologous stem cell transplantation (ASCT), in particular for platelet reconstitution. Thus a routine assessment of CD34+ CD38- cells in freezing-thawing procedures for autografting could represent an important tool for predicting poor engraftment. METHODS: To compare the impact of cryopreservation on CD34+ CD38+ and CD34+ CD38- hematopoietic stem cell subsets, 193 autograft products collected in 84 patients with malignancies were assessed before controlled-rate cryopreservation in 10% DMSO and after thawing for autografting. RESULTS: Cell counts after thawing were significantly different from the pre-freezing counts for total CD34+ (P<0.0001) and CD34+ CD38+ (P<0.0001) cells, but not for CD34+ CD38- cells (P=0.252). Median losses for CD34+, CD34+ CD38+ and CD34+ CD38- cells were, respectively, 11.8%, 11.4% and 0.0%. The magnitude of fresh/post-thawing percentage cell variation was significantly different when comparing between the CD34+ CD38+ and CD34+ CD38- cell subsets (P<0.001). Moreover, CD34+ CD38- cells exhibited recovery values > or =100% in 85/160 graft products, compared with 51/193 in CD34+ CD38+ cells (P<0.0001). Also, recovery values > or =90% were significantly better in the CD34+ CD38- (98/160 grafts) than in the CD34+ CD38+ subsets (89/193 grafts) (P<0.01). DISCUSSION: In this work we have demonstrated that CD34+ cells that do not express the CD38 Ag show a significantly better resistance to cryopreservation. This could represent another example of the particular ability of less committed progenitor cells to overcome environmental injuries. Moreover, we consider routine assessment of CD34+ CD38- cells before freezing as clinically relevant, but post-thawing controls may be avoided because of their good resistance to freezing.     

A randomized controlled clinical trial to determine the optimum duration of G-CSF priming prior to BM stem cell harvesting

BACKGROUND: Harvesting of hemopoietic stem cells (HSC) from G-CSF-primed BM for autologous transplantation is an alternative to collection of unprimed BM or G-CSF-primed peripheral blood (PB). However, the optimum number of days of G-CSF administration for this purpose is unknown. We set out to determine whether cell yields could be optimized by varying the number of days of G-CSF administration prior to BM stem cell harvesting. METHODS: We conducted a randomized controlled single-center trial of 6 days (the standard) vs. 4 days of G-CSF administration and compared yields of total nucleated cells (TNC), CD34(+) HSC and CFU-GM cells per kilogram patient body weight. Statistical analysis was by Student's t-test. RESULTS: Twenty-four patients were enrolled; 13 received 6 days and 11 received 4 days of G-CSF administration. Analysis of the first harvest aspirate showed higher proportions of CD34(+) HSC (P=0.02) and CFU-GM (P=0.03) in the 4-day group. For the 6-day and 4-day groups, respectively, the median yield of TNC/kg was 6.5 x 10(8) and 5.4 x 10(8) (P=0.28), of CD34(+) cells/kg 0.56 x 10(6) and 0.98 x 10(6) (P=0.04) and of CFU-GM cells/kg 1.66 x 10(5) and 1.55 x 10(5) (P=0.75). DISCUSSION: These results suggest that by 6 days the HSC-stimulating effect of G-CSF has passed its peak and that 4 days should be adopted as the standard for G-CSF priming prior to BM stem cell harvesting for autologous transplantation.     

Reduced bone marrow stem cell pool and progenitor mobilisation in multiple myeloma after melphalan treatment

The content of stem cells was analysed in bone marrow samples from 75 multiple myeloma patients. In unstimulated bone marrow the percentage of CD34+cells was significantly reduced in 11 patients previously treated with melphalan-prednisolone (MP)(median= 0.15%) compared to median 0.87% in 31 untreated patients (P=0.0001). The bone marrow cellularity in the two groups did not differ. There was no correlation between the number of courses or total dose of melphalan and content of CD34+cells in the bone marrow. The clonogenicity as, well as the ability to expand the marrow stem cell pool during growth factor treatment were also reduced in MP treated patients compared to untreated patients. Analysis of different subsets of CD34+ cells revealed no influence on the pre B cell compartment in the bone marrow by MP treatment, but the committed stem cells (CD34+CD38+) were reduced more than the uncommitted stem cells (CD34+CD38—) in the MP treated group compared to the untreated patients. Mobilisation to and harvest of total number of CD34+ cells from peripheral blood was also reduced in the MP treated group. There was, however, no difference in the distribution between CD34+CD38+and CD34+CD38—populations in the leukapheresis products in the untreated and the melphalan-treated group, suggesting selective mobilisation of CD34+CD38+ cells and/or differentiation of CD34+ CD38-cells during growth factor stimulation. We conclude that melphalan decreased the number of stem cells in the bone marrow, the ability to expand the stem cell pool and mobilise stem cells to the pheripheral blood.     

The history and future prospective of haplo-identical stem cell transplantation

Initial attempts at haplo-identical transplantation with T-cell replete bone marrow (BM) were associated with a high transplant-related mortality (TRM), mainly caused by severe graft-versus-host disease (GvHD), and previous efforts to prevent GvHD by ex vivo T-cell depletion of haplo-identical BM were associated with a high risk of graft failure and other complications. Improvements in large-scale T-cell depletion techniques of haplo-identical peripheral mobilized stem cells (PBSC) have overcome the human leukocyte antigen (HLA) barrier by using megadose numbers of stem cells obtained by either highly purified CD34(+) selection or negative depletion of T cells. In addition, recent insights into the role of graft-facilitating and anti-leukemic alloreactive natural killer (NK) cells, the permanent availability of the haplo-identical donor post-transplant and continuous improvements in graft-engineering techniques for the generation of effector cells for post-transplant adoptive transfer, have facilitated the development of strategies to decrease regimen-related toxicity through the use of less intensive preparative regimens, prevent severe infections by rebuilding the immune system and decrease the risk of relapse by exploiting the alloreactivity of donor NK cells and other donor-derived effector cells.     

Comparison of single and dual platform methodologies for the estimation of CD34+ hematopoietic progenitor cells: correlation with colony assay

In this study three assays for the enumeration of CD34+ progenitors were compared: 1) a modified version of the Milan protocol, used in the standard dual-platform format; 2) a dual-platform version of the ISHAGE protocol; 3) the ProCOUNT software version 2.0/ProCOUNT kit. The assays were compared to validate the accuracy of CD34+ cell counts in mobilized peripheral blood (PB), apheresis products (AP), and cord blood (CB). The ProCOUNT protocol uses reference beads for absolute CD34+ cell counting, whereas CD34 counts by other techniques are derived from a separate leukocyte count performed by a hematology analyzer. A good correlation between the ISHAGE and ProCOUNT methods was obtained for estimation of CD34+ counts in PB (n=42 samples analyzed) and AP (n=35)--except for samples having a leukocyte count >25 x 10(9)/L or a CD34 count <0.0025 x 10(9)/L)--while a suboptimal correlation between the methods was observed for CB (n=30). The ProCOUNT system proved to be effective in reducing the variability in CD34+ cell counting and appeared to be useful for intralaboratory methodology standardization. The main disadvantage of the ProCOUNT assay was its inability to calculate CD34 counts in leukopenic samples and in CB samples showing a high erythroblast count. As far as the correlation with hematopoietic colonies is concerned, data collected from apheresis samples showed a good correlation between the three flow cytometry methods and colony-forming unit granulocyte-macrophage (CFU-GM) counts, confirming the value of the flow cytometric test as a real-time, truly predictive test to measure the hematopoietic potential of the graft. In summary, all methods are suitable for enumeration of most PB samples, while the single-platform methodology should be preferred for the analysis of AP and CB. We also found the dual-platform format of the ISHAGE method precise and accurate for the estimation of CD34+ cells from CB samples. Based on these data it can be concluded that the single-platform flow cytometry assay format should be the preferred approach for CD34+ stem cell enumeration in different types of samples.     

Unraveling stem cell and progenitor subsets in autologous grafts according to methods of mobilization: implications for prediction of hematopoietic recovery

Background aimsIn the autologous setting, granulocyte colony-stimulating factor (G-CSF) (G), or, when failing, G plus plerixafor (G+P), are common regimens for mobilization of stem cells into peripheral blood. To delineate mobilization effects on graft composition and hematopoietic recovery, we compared contents of stem cells and progenitor cells in products of G+P- and G patients. Paired samples of G+P patients and prior insufficient G mobilization were available for analyses.MethodsSubset analyses of grafts were performed by flow cytometry and myeloid colony-forming assay. In search of new markers to ascertain graft quality, we determined the fractions of aldehyde dehydrogenase bright (ALDH^br) cells.ResultsG grafts contained higher percentages of CD34+ cells, CD34+CD38- cells, and committed progenitors (CD34+CD38+) compared with G+P grafts. A detailed characterization of the mobilized CD34+ cell subset showed higher percentages of CD38– among the CD34+ cells of the G+P group (P = 0.032). In contrast, the CD34+ cell subset in G grafts was characterized by a higher percentage of ALDH^br cells (P < 0.0001). Studying engraftment and day +100 graft function the G and G+P transplanted patients were comparable with respect to neutrophils, whereas in platelets they differed. In the prediction of engraftment and hematopoietic recovery, the dose of infused ALDH^br cells correlated best to both platelet (r = 0.565, P = 0.002) and neutrophil reconstitution (r = 0.366, P = 0.06).ConclusionsBesides showing dissimilar distributions of CD34+CD38– cells and progenitors in G and G+P grafts, this study further designated ALDH^br as a promising marker in determination and prediction of graft quality and hematopoietic recovery.     

IL-9 enhances the growth of human mast cell progenitors under stimulation with stem cell factor

We examined the effects of IL-9 on human mast cell development from CD34(+) cord blood (CB) and peripheral blood cells in serum-deprived cultures. IL-9 apparently enhanced cell production under stimulation with stem cell factor (SCF) from CD34(+) CB cells. A great majority of the cultured cells grown with SCF + IL-9 became positive for tryptase at 4 wk. In methylcellulose cultures of CD34(+) CB cells, IL-9 increased both the number and size of mast cell colonies grown with SCF. Furthermore, SCF + IL-9 caused an exclusive expansion of mast cell colony-forming cells in a 2-wk liquid culture of CD34(+) CB cells, at a level markedly greater than for SCF alone. Clonal cell cultures and RT-PCR analysis showed that the targets of SCF + IL-9 were the CD34(+)CD38(+) CB cells rather than the CD34(+)CD38(-) CB cells. IL-9 neither augmented the SCF-dependent generation of progeny nor supported the survival of 6-wk-cultured mast cells. Moreover, there was no difference in the appearance of tryptase(+) cells and histamine content in the cultured cells between SCF and SCF + IL-9. The addition of IL-9 increased numbers of mast cell colonies grown with SCF from CD34(+) peripheral blood cells in children with or without asthma. It is of interest that mast cell progenitors of asthmatic patients responded to SCF + IL-9 to a greater extent than those of normal controls. Taken together, IL-9 appears to act as a potent enhancer for the SCF-dependent growth of mast cell progenitors in humans, particularly asthmatic patients.     

异基因造血干细胞移植后激素耐药胃肠道急性移植物抗宿主病的临床分析

目的探讨异基因造血干细胞移植后激素耐药胃肠道急性移植物抗宿主病(aGVHD)的影响因素。方法回顾性分析西安交通大学第一附属医院2012年1月至2019年12月期间行异基因造血干细胞移植,术后发生胃肠道aGVHD 20例患者的临床资料。按照一线糖皮质激素治疗后的反应分为激素敏感组(13例)和激素耐药组(7例)。单因素Logistics回归分析患者性别、年龄、诊断、移植前微小残留病灶、移植类型、供者年龄、供受者关系、供受者ABO血型、输注单个核细胞数、CD34+细胞数、CD3+细胞数、中性粒细胞及血小板植入时间、CMV及EB病毒感染、胃肠道aGVHD发生的时间等与激素耐药胃肠道aGVHD的关系。观察激素耐药患者治疗后的转归,采用Kaplan-Meier生存分析激素耐药及敏感患者的预后差异。结果20例胃肠道aGVHD患者中7例存在激素耐药。胃肠道GVHD发生时间<1个月,激素耐药的风险增加(OR=13.500,95﹪CI=1.197~152.211,P=0.035),患者性别、年龄、诊断、移植前MRD、移植类型、供者年龄、供受者关系、供受者ABO血型、输注的单个核细胞、CD34+细胞、CD3+细胞、中性粒细胞和血小板植入时间、CMV和EB病毒感染均不影响激素耐药(P>0.05)。7例激素耐药胃肠道aGVHD患者均接受二线CD25单克隆抗体治疗,治疗后5例有效,2例无效死亡。与激素敏感组比较,激素耐药组患者1年总生存率(64﹪比52﹪)降低及无进展生存率(28﹪比32﹪)升高,差异无统计学意义(P>0.05)。结论异基因造血干细胞移植后胃肠道aGVHD激素耐药可能与其发生时间相关,发生时间越早,越容易出现激素耐药。     

Impaired PBPC collection in patients with myeloma after high-dose melphalan

BACKGROUND: Tandem stem cell transplantation is an important treatment option for patients with myeloma and some additional tumors. In an attempt to reduce the contamination of the stem cell graft with tumor cells, patients with myeloma who entered complete remission after the first transplant underwent a second episode of mobilization to obtain progenitor cells for the second transplant. METHODS: Twenty-two patients with myeloma participated in the study. The first mobilization utilized CY, etoposide and filgrastim. The second mobilization used the same regimen, but seven patients received only filgrastim. The interval between the two collection periods was 6 months (median; range 4-9 months). The preparative regimen for the first transplant consisted of melphalan 200 mg/m(2). RESULTS: The number of total white cells collected during the two collection episodes was similar: 10.8+/-1.6 x 10(8)/kg white cells vs. 11.8+/-1.7 x 10(8)/kg white cells (P=0.63). The collected CD34(+) cell dose was much larger during the first collection: 45.2+/-8.4 x 10(6)/kg vs. 6.9+/-2.7 x 10(6)/kg (P<0.001). Similarly, the collected colony-forming unit (CFU)-GM dose was much larger during the first collection: 295.4+/-59.3 x 10(4)/kg vs. 67.3+/-21.6x10(4)/kg (P<0.001). While the CD34(+) cells collected during the two collection episodes correlated significantly (r=0.55, P<0.01); the first dose was a median of 14.9-fold larger. DISCUSSION: No laboratory parameter was able reliably to predict the results of the second collection. A second mobilization/collection episode as part of a tandem transplant approach carries a considerable risk of failing to obtain sufficient progenitor cells.     

Flow cytometric enumeration of CD34+ hematopoietic stem and progenitor cells in leukapheresis product and bone marrow for clinical transplantation: a comparison of three methods

Flow cytometric enumeration of CD34+ hematopoietic stem and progenitor cells (HSCs) is widely used for evaluation of graft adequacy of peripheral blood and bone marrow stem cell grafts. In the present study, we review and compare the major counting techniques of stem and progenitor cells. The methods are: the Milan/Mullhouse protocol, two-platform ISHAGE (International Society of Hematotherapy and Graft Engineering) and single-platform ISHAGE analysis system. According to the Milan/Mulhouse protocol, HSCs are identified by CD34 antibody staining and easy gating strategy. The ISHAGE guidelines for detection of CD34+ cells are based on a four-parameter flow cytometry method (CD34PE/CD45PerCP staining, side and forward angle light scatter) thus employing multiparameter gating strategy. With two-platform ISHAGE protocol, an absolute CD34+ count is generated by incorporating the leukocyte count from an automated hematology analyser. The single-platform ISHAGE method to determine the absolute CD34+ count directly from a flow cytometer includes the use of Trucount tubes (Becton Dickinson) with a known number of fluorescent beads. CD34+ cells were quantified in mobilized peripheral blood, collected by leukapheresis, and bone marrow from 42 samples from patients with hematological malignancies. The differences against the means display low disagreement between the Milan/Mulhouse and ISHAGE protocols, with discrepancies of up to 2.5% (two-platform ISHAGE)--2.6% (single-platform ISHAGE) in enumeration of CD34+ cells in leukapheresis product and 4.8% (two-platform ISHAGE)--4.9% (single-platform ISHAGE) in bone marrow. Our results show high correlation among all three methods. Since the three protocols are compatible, choosing the most convenient in terms of costs, simplicity and compliance with clinical results appears to be a logical consequence.     

Expression of CD34 in hematopoietic cancer cell lines reflects tightly regulated stem/progenitor-like state

Hematopoietic cancer stem cells preserve cellular hierarchy in a manner similar to normal stem cells, yet the underlying regulatory mechanisms are poorly understood. It is known that both normal and malignant stem/progenitor cells express CD34. Here, we demonstrate that several cell lines (HL-60, U266) derived from hematopoietic malignancies contain not only CD34(-) but also CD34(+) subpopulations. The CD34(+) cells displayed a stem/progenitor-like phenotype since, in contrast to CD34(-) cells, they frequently underwent cellular division and rapidly formed colonies in methylcellulose-based medium. Strikingly, a constant fraction of the CD34(+) and CD34(-) cell subpopulations, when separated, rapidly switched their phenotype. Consequently, both separated fractions could generate tumors in immunocompromised NOD/LtSz-scid/scid mice. Cultures in vitro showed that the proportion of CD34(+) stem/progenitor-like cells in the population was decreased by cell-cell contact and increased by soluble factors secreted by the cells. Using cytokine arrays, we identified some of these factors, notably thymopoietin that was able to increase the proportion of CD34(+) cells and overall colony-forming capacity in tested cell lines. This action of thymopoietin was conserved in mononuclear cells from bone marrow. Therefore, we propose that hematopoietic cancer cell lines containing subpopulations of CD34(+) cells can provide an in vitro model for studies of cancer stem/progenitor cells.     

脐血干细胞移植对儿童重组活化基因突变重症联合免疫缺陷病疗效分析

目的探讨脐血干细胞移植(UCBT)治疗儿童重组活化基因(RAG)突变重症联合免疫缺陷病(SCID)的疗效。方法回顾性分析2015年1月至2019年6月于复旦大学附属儿科医院明确诊断为RAG突变并接受UCBT的8例SCID患儿,其中男6例,女2例。所有患儿均接受白消安(BU)/环磷酰胺(CY)为主的减低毒性预处理方案,采用他克莫司单药预防移植物抗宿主病(GVHD),收集脐血干细胞移植前后的临床及实验室资料,评估患儿治疗效果。不符合正态分布的连续性变量资料用中位数(最小值~最大值)表示,分类资料用例数(相对比)表示。结果8例接受UCBT的RAG突变患儿分析结果显示,脐带血输注中位总有核细胞数为14.73(5.06~27.27)×10^7个/kg,中位CD34+细胞数为4.14(1.75~13.30)×10^5个/kg。8例患儿中7例成功植入,中性粒细胞植入时间25(15~45)d,血小板植入时间34(33~43)d。中位随访时间9.2(0.3~31.3)个月。3例患儿移植早期死亡,5例患儿无病生存并获得免疫重建,脱离静脉丙种球蛋白输注的时间为84(63~100)d。结论UCBT治疗RAG突变所致SCID取得一定疗效。