粒细胞集落刺激因子对供体造血干细胞移植物中树突状细胞的影响

目的 探讨粒细胞集落刺激因子(G-CSF)对正常异基因造血干细胞移植供者外周血与骨髓移植物中Ⅰ型树突状细胞(DC1)、Ⅱ型树突状细胞(DC2)的数量及DC2/DC1比例的影响.方法 以G-CSF每天10μg/kg动员5 d后,以流式细胞术(FCM)检测11例G-CSF动员的异基因外周血造血干细胞移植物及20例G-CSF动员的异基因骨髓移植物中的DC1、DC2数量及DC2/DC1比例,并与8例正常供者动员前外周血及10例健康者动员前骨髓进行比较.结果 动员前后骨髓DC2由14.37×106/L增至29.68×106/L(t=2.433,P=0.022),而骨髓DC1分别为13.77×10a/L和18.88×106/L(t=0.625,P=0.541);DC2/DC1比例在动员后为1.83±0.81,较动员前的1.12±0.32明显升高(t=2.685,P=0.013).正常供者以G-CSF动员前、后移植物中外周血DC2数量分别为14.92×106/L和26.76×106/L(t=2.390,P=0.029),DC2/DC1比例分别为1.00±0.37和2.02±1.43(t=2.158,P=0.044),但外周血DC1分别为14.21×106/L和18.02×106/L(t=0.625,P=0.541).结论 移植前以G-CSF动员正常异基因干细胞移植供者,可选择性提高外周血及骨髓移植物中DC2的数量,而DC1数量无明显增加.     

供者外周血干细胞动员采集198例临床分析

目的 研究外周血造血干细胞移植( PBSCT)供者外周血干细胞动员采集的方法及其效 果。方法 198名健康供者每天皮下注射重组人粒细胞集落刺激因子(rhG-CSF)(5～10) μg/kg进行外周血干细胞动员,第5天开始采集。采用血细胞分析仪行单个核细胞( MNC)计数,流式细胞术(FCM)行CD34+细胞计数。分析供者性别、身高、年龄、采集当天外周血白细胞(WBC)计数对动员采集效果的影响。结果所有供者均成功动员采集,采集当天的MNC计数平均为(4.19±1.96)×108/kg,CD34+细胞计数平均为(2.98±1.40) ×106/kg; MNC和CD34+细胞计数与供者性别、身高、年龄无关;采集当天外周血WBC计数与MNC、CD34+细胞计数呈正相关(r= 0.9201,P=0.0035;r=0.8420,P= 0.0149);采集当天外周血WBC计数≥20.0×109/L的供者比＜20.0×109/L的供者采集效果更显著(F=4.688,P= 0.0013;F= 4.622,P=0.0006)。结论rhG-CSF动员的健康供者采集当天外周血WBC计数是一项预测CD34+细胞采集数量的简单、可行的指标。     

伊马替尼联合粒细胞集落刺激因子治疗慢性粒细胞白血病11例

目的 研究伊马替尼(IM)联合粒细胞集落刺激因子(G-CSF)降低单药IM疗效欠佳的慢性粒细胞白血病(CML)残留病的疗效.方法 采用IM联合G-CSF治疗11例IM治疗后Ph染色体转阴率≥35%的CML患者.起始治疗量为IM 400或600 mg/d,G-CSF 5μg·kg-1·d-1,皮下注射.白细胞计数≥30×109/L者,延迟或间断使用G-CSF直至白细胞＜20×109/L.治疗过程中定期检测外周血bcr-abl转录水平,治疗6个月后转录水平降低未超过0.5个对数(log)者,停用G-CSF.bcr-abl转录水平持续下降但仍未获得完全分子生物学缓解者,继续使用该方案治疗1～6个月.结果 11例患者中9例出现bcr-abl转录水平的明显下降(包括7例下降＞1个对数和2例下降＞0.5个对数),2例出现bcr-abl转录水平的下降小于0.5个对数.7例下降＞1个对数者,其中2例获得完全分子生物学缓解,5例原为部分细胞遗传学缓解的患者获得完全细胞遗传学缓解.所有患者均能耐受,未出现因不良反应中断治疗和治疗相关性死亡病例.结论 IM联合G-CSF方案治疗单药lM治疗反应欠佳的CML患者有效、安全.     

重组人粒细胞集落刺激因子注射液动员外周血干细胞10例

目的:探讨临床常见的重组人粒细胞集落刺激因子注射液动员外周血干细胞分析.方法:选择2008年8月到2011年2月在我院员11例进行研究,其中其中男性为8例,女性为3例.结果:研究人群外周血干细胞采集结果分析发现MNC总数量为(21.1±9.5)*108,依照研究人群体重计算为(3.7±0.9)*108/kg,其中CD+34占总MNC总量为(1.8-3.9)%,依照研究人群体重计算为(4.6±2.1)*106/kg,CFU-GM为(4.9±2.8)*104/kg,依照研究人群体重计算为(5.2±3.0)*104/kg,自体供应者和异体供应者之间比较没有统计学意义(P>0.05).结论:来源于自体供应者和异体供应者之间的重组人粒细胞集落刺激因子没有差异,说明只要对供体人群进行有效地动员,就可以达到手术所需.     

非T细胞去除单倍体造血干细胞移植治疗T淋巴母细胞性淋巴瘤的初步临床研究

目的 探讨非T细胞去除单倍体造血干细胞移植(haplo-HSCT)治疗T淋巴母细胞性淋巴瘤(T-LL)的疗效.方法 3例确诊的T-LL患者获得缓解后接受了粒细胞集落刺激因子(G-CSF)动员后的非T细胞去除的单倍体亲缘供体的骨髓干细胞输注.其中2例患者预处理采用包含环磷酰胺(CTX)、全身照射(TBI)和阿糖胞苷(Ara-C)的清髓性方案,另1例患者采用包含CTX和白消安(BU)、Ara-C的清髓性方案;3例患者都采用了包含兔抗人胸腺细胞球蛋白(ATG)的加强的急性移植物抗宿主病预防方案.结果 所有患者均获得快速完全的造血重建,中性粒细胞和血小板中位恢复时间分别为12 d和13 d.3例患者中位随访24个月(9～75个月),均无瘤生存.结论 非T细胞去除haplo-HSCT治疗T-LL的相关不良反应可以耐受,患者可能获得长期生存.     

重组人白细胞介素-11治疗恶性血液病化疗相关性血小板减少30例

目的 观察重组人白细胞介素-11(rhIL-11,商品名:巨和粒)治疗恶性血液病化疗相关性血小板减少的疗效及安全性方法随机选取确诊的常规化疗的恶性血液病30例,化疗后加用rhIL-11作为治疗组,并随机选取同期化疗的恶性血液病患者35例作为对照组,分析比较两组病例血小板减少程度、血小板≤100×109/L的持续天数、血小板输注次数及其不良反应结果治疗组在化疗结束时血小板计数为(41.22±23.67)×109/L,化疗后1周及2 周时血小板计数分别为(82.22±46.72)×109/L及(119.67±34.12)×109/L;治疗组化疗期间输注血小板例数7例;治疗组在化疗结束后第7天及第14天时,血小板计数恢复正常(≥100×109/L)分别为12例(40.00%)和26例(86.67%),与对照组比较差异有统计学意义(P＜0.05).且治疗组治疗过程中不良反应轻微,有良好的耐受性和安全性.结论 rhIL-11治疗细胞毒药物化疗所致血小板减少安全、有效,值得在恶性血液病的治疗中推广使用.     

CAG方案治疗低增生性急性髓系白血病29例

目的 观察CAG方案治疗低增生性急性髓系白血病(AML)的临床疗效.方法 对29例低增生性AML患者采用CAG方案,阿柔比星(Acla)14 mg/m2,第1天至第4天,静脉注射;阿糖胞苷(Ara-C)10 mg/m2,第1天至第14天,每12 h皮下注射;粒细胞集落刺激因子(G-CSF)200μg/m2,第1天至第14天,皮下注射,并于第1次注射Ara-C之前12 h开始使用,最后一次注射Ara-C前12 h停用;当中性粒细胞＞10×109/L时,暂时减少或停用G-CSF.结果 29例患者中完全缓解(CR)14例(48.3%),部分缓解(PR)7例(24.1%),总有效率72.4%,治疗失败(NR)7例,早期死亡1例.结论 CAG方案治疗低增生性AML安全有效,可有效缩短外周血粒细胞减少的时间,降低化疗相关死亡率.     

自体外周血干细胞加激活骨髓联合移植治疗T细胞淋巴瘤的诱导移植物抗宿主病

目的 研究自体造血干细胞( APBSC)加激活骨髓(ABM)联合移植治疗淋巴瘤过程中ABM诱导移植物抗宿主病(GVHD)的作用。方法一例T免疫母细胞非霍奇金淋巴瘤(NHL)患者行APBSC+ABM联合移植治疗，观察皮疹、腹泻及黄疸的发生。结果皮肤出现Ⅰ～Ⅱ度GVHD改变，无腹泻及黄疸，已无瘤生存13年。结论APBSC加ABM联合移植能诱导GVHD，并获得长期无病生存的疗效。     

PDCD5蛋白在恶性淋巴瘤患者血清中的异常表达

目的 研究恶性淋巴瘤患者血清中凋亡促进蛋白PDCD5的表达,以探讨PDCD5蛋白在恶性淋巴瘤发病及疾病进展中的作用.方法 利用酶联免疫吸附法检测恶性淋巴瘤患者及健康人血清中PDCD5蛋白的水平.结果 41例未治及复发恶性淋巴瘤患者血清中PDCD5蛋白的表达明显低于37例健康人,分别为(10.227±3.595)ng/ml和(15.597±6.432)ng/ml(t=-4.609,P＜0.01),其中临床分期为Ⅰ～Ⅱ期与Ⅲ～Ⅳ期患者血清PDCD5蛋白表达分别为(11.297±3.584)ng/ml和(9.543±3.502)ng/ml,差异无统计学意义(t=1.550,P＞0.05);原发部位于结内与结外患者血清PDCD5蛋白表达分别为(10.758±3.301)ng/ml和(9.613±3.907)ng/ml,差异无统计学意义(t=1.018,P＞0.05).结论 未治及复发淋巴瘤患者与健康人相比血清中PDCD5蛋白表达降低,PDCD5蛋白的表达水平在不同临床分期及不同原发部位病变的淋巴瘤患者中无明显差异.PDCD5的异常表达可能在淋巴瘤发病机制中起一定作用.     

芯针穿刺活检在恶性淋巴瘤诊断中的应用

目的:探讨芯针穿刺活检诊断恶性淋巴瘤的临床应用价值,阐明其有效性.方法:采用HE和免疫组织化学染色方法,对88例芯针穿刺活检诊断为恶性淋巴瘤及淋巴组织非典型增生的病例进行回顾性研究,观察芯针穿刺活检诊断的准确率.结果:本组患者穿刺活检诊断恶性淋巴瘤的准确率为87.5%(77/88),恶性淋巴瘤90%(70/77)可区分组织类型.诊断为淋巴组织非典型增生11例,其中5例通过手术切除活检确诊为恶性淋巴瘤,6例不能明确诊断.在住院患者中,恶性淋巴瘤诊断的准确率为91%(53/58).结论:芯针穿刺活检是诊断恶性淋巴瘤可靠的方法,绝大多数患者可得到明确的分类.     

2-Hydroxyisonicotinate dehydrogenase isolated from Mycobacterium sp. INA1

The objective of this study was to identify factors associated with poor mobilization of peripheral blood progenitor cells (PBPCs) or delayed platelet engraftment after high-dose therapy and autologous stem cell transplantation in patients with lymphoma. Fifty-eight patients with Hodgkin's disease or non-Hodgkin's lymphoma underwent PBPC transplantation as the "best available therapy" at Memorial Sloan-Kettering Cancer Center (New York, NY) between 1993 and 1995. PBPCs were mobilized with either granulocyte colony-stimulating factor (G-CSF) alone (n = 19) or G-CSF following combination chemotherapy (n = 39). Forty-eight of these patients underwent a PBPC transplant, receiving a conditioning regimen containing cyclophosphamide, etoposide, and either total body irradiation, total lymphoid irradiation, or carmustine. A median number of 4.6 x 10(6) CD34+ cells/kg were obtained with a median of three leukapheresis procedures. Mobilization of PBPCs using chemotherapy plus G-CSF was superior to G-CSF alone (6.7 x 10(6) versus 1.5 x 10(6) CD34+ cells/kg; P = 0.0002). Poorer mobilization of progenitor cells was observed in patients who had previously received stem cell-toxic chemotherapy, including (a) nitrogen mustard, procarbazine, melphalan, carmustine or > 7.5 g of cytarabine chemotherapy premobilization (2.0 x 10(6) versus 6.0 x 10(6) CD34+ cells/kg; P = 0.005), or (b) > or = 11 cycles of any previous chemotherapy (2.6 x 10(6) versus 6.7 x 10(6) CD34+ cells/kg; P = 0.02). Platelet recovery to > 20,000/microliter was delayed in patients who received < 2.0 x 10(6) CD34+ cells (median, 13 versus 22 days; P = 0.06). Patients who received > or = 11 cycles of chemotherapy prior to PBPC mobilization tended to have delayed platelet recovery to > 20,000/microliter and to require more platelet transfusions than less extensively pretreated patients (median, 13.5 versus 23.5 days; P = 0.15; median number of platelet transfusion episodes, 13 versus 9; P = 0.17). These data suggest that current strategies to mobilize PBPCs may be suboptimal in patients who have received either stem cell-toxic chemotherapy or > or = 11 cycles of chemotherapy prior to PBPC mobilization. Alternative approaches, such as ex vivo expansion or the use of other growth factors in addition to G-CSF, may improve mobilization of progenitor cells for PBPC transplantation.     

Peripheral blood progenitor cell mobilization with Dexa-Beam/G-CSF, ether lipid purging, and autologous transplantation after high-dose CBV treatment: a safe and effective regimen in patients with poor risk malignant lymphomas

High-dose chemotherapy followed by autologous peripheral blood progenitor cell transplantation (PBPCT) is increasingly applied in patients with relapsed, poor risk malignant lymphomas. Different strategies for progenitor cell mobilization using cytoreductive chemotherapy, hematopoietic growth factors, or both have been described. We studied the safety and efficacy of a modified DexaBEAM regimen (dexamethasone, BCNU [carmustine], etoposide, ara-C, melphalan) followed by granulocyte-colony stimulating factor (G-CSF) that was administered in order to minimize any residual disease and to obtain a sufficient amount of progenitor cells in the autografts. Until now, 16 patients at poor risk (8 with Hodgkin's disease, 8 with non-Hodgkin's lymphoma) entered the study. All the 12 patients with measurable disease at study entry responded to DexaBEAM. Median time of subsequent leukopenia (leukocytes < 1.000/microL) was 6 days (range 5-8 days). Peak numbers of CD34+ hematopoietic progenitor cells appeared in the peripheral blood after a median of 20 days (range 18-22 days) after onset of therapy. At that time, peripheral mononuclear cells were collected for autografting. Thereafter, the leukapheresis products were frozen until the day of transplantation, either unpurged in the case of Hodgkin's disease or purged with the ether lipid edelfosine in cases of non-Hodgkin's lymphoma. After high-dose chemotherapy with the CBV regimen (cyclophosphamide, BCNU, etoposide) the patients received their autografts, followed again by G-CSF treatment. A stable hematopoietic recovery was reached with granulocytes > 2.000/muL within 11 days (range 8-17 days), and platelets > 50.000/microL within 15 days (range 10-31 days), respectively, without significant differences between the purged and unpurged transplants. After a median follow-up of 28 months (range 1-40 months) 7 patients are alive without signs of recurrent disease, while 1 patient has died due to acute treatment related toxicity. Three patients had refractory disease, and 5 have relapsed of whom 4 have died. In summary, the DexaBEAM/G-CSF/CBV strategy appears to be safe and effective for salvage treatment in patients with poor risk malignant lymphomas.     

High-dose etoposide with granulocyte colony-stimulating factor for mobilization of peripheral blood progenitor cells: efficacy and toxicity at three dose levels

High-dose etoposide (2.0-2.4 g m(-2)) with granulocyte colony-stimulating factor (G-CSF) is an effective strategy to mobilize peripheral blood progenitor cells (PBPCs), although in some patients this is associated with significant toxicity. Sixty-three patients with malignancy were enrolled into this non-randomized sequential study. The majority (55/63, 87%) had received at least two prior regimens of chemotherapy, and seven patients had previously failed to mobilize following high-dose cyclophosphamide with G-CSF. Consecutive patient groups received etoposide at three dose levels [2.0 g m(-2) (n = 22), 1.8 g m(-2) (n = 20) and 1.6 g m(-2) (n = 21)] followed by daily G-CSF. Subsequent leukaphereses were assayed for CD34+ cell content, with a target total collection of 2.0 x 10(6) CD34+ cells kg(-1). Toxicity was assessed by the development of significant mucositis, the requirement for parenteral antibiotics or blood component support and rehospitalization incidence. Ten patients (16%) had less than the minimum target yield collected. Median collections in the three groups were 4.7 (2 g m(-2)), 5.7 (1.8 g m(-2)) and 6.5 (1.6 g m(-2)) x 10(6) CD34+ cells kg(-1). Five of the seven patients who had previously failed cyclophosphamide mobilization achieved more than the target yield. Rehospitalization incidence was significantly lower in patients receiving 1.6 g m(-2) etoposide than in those receiving 2.0 g m(-2) (P = 0.03). These data suggest that high-dose etoposide with G-CSF is an efficient mobilization regimen in the majority of heavily pretreated patients, including those who have previously failed on high-dose cyclophosphamide with G-CSF. An etoposide dose of 1.6 g m(-2) appears to be as effective as higher doses but less toxic.     

Recombinant human granulocyte and granulocyte-macrophage colony-stimulating factor (G-CSF and GM-CSF) administered following cytotoxic chemotherapy have a similar ability to mobilize peripheral blood stem cells

The availability of hematopoietic growth factors has greatly facilitated the mobilization and collection of peripheral blood stem cells (PBSC). It was the aim of this double-blind study to compare the PBSC-mobilizing efficacy of recombinant human G-CSF and GM-CSF when administered post-chemotherapy. Twenty-six patients with relapsed Hodgkin's disease were included in the study. Their median age was 31 years (range, 22-59) and 14 patients were males and 12 were females. Patients were pretreated with a median of eight cycles of cytotoxic chemotherapy, while 18 patients had undergone extended field irradiation. The patients received dexamethasone 24 mg days 1-7, melphalan 30 mg/m2 day 3, BCNU 60 mg/m2 day 3, etoposide 75 mg/m2 days 4-7, Ara-C 100 mg/m2 twice daily days 4-7 (Dexa-BEAM). Twelve patients were randomized to receive 5/microg/kg/day G-CSF and 14 patients to receive 5 microg/kg/day GM-CSF, both administered subcutaneously starting on day 1 after the end of Dexa-BEAM. Primary endpoints of the study were the number of CD34+ cells harvested per kg body weight on the occasion of six consecutive leukaphereses and the time needed for hematological reconstitution following autografting. Twenty-one patients completed PBSC collection, and six patients of the G-CSF group and nine of the GM-CSF group were autografted. No difference was observed with respect to the median yield of CFU-GM and CD34+ cells: 32.5 x 10(4)/kg vs 31.3 x 10(4)/kg CFU-GM, and 7.6 x 10(6)/kg vs 5.6 x 10(6)/kg CD34+ cells, for G-CSF and GM-CSF, respectively (U test, P= 0.837 and 0.696). High-dose chemotherapy consisted of cyclophosphamide 1.7 g/m2 days 1-4, BCNU 150 mg/m2 days 1-4, etoposide 400 mg/m2 days 1-4. All patients transplanted with more than 5 x 10(6) CD34+ cells/kg had a rapid platelet recovery (20 x 10(9)/l) between 6 and 11 days and neutrophil recovery (0.5 x 10(9)/1) between 9 and 16 days, while patients transplanted with less than 5 x 10(6)/kg had a delayed reconstitution, regardless of the kind of growth factor used for PBSC mobilization. In conclusion, our data indicate that in patients with Hodgkin's disease G-CSF and GM-CSF given after salvage chemotherapy appear to be not different in their ability to mobilize PBSC resulting in a similar time needed for hematological reconstitution when autografted following high-dose therapy.     

Combination chemotherapy with mitoguazon, ifosfamide, MTX, etoposide (MIME) and G-CSF can efficiently mobilize PBPC in patients with Hodgkin's and non-Hodgkin's lymphoma

Many centers use CY and G-CSF to mobilize PBPC. In this study we explored whether a standard chemotherapy regimen consisting of mitoguazon, ifosfamide, MTX and etoposide (MIME) combined with G-CSF was capable of mobilizing PBPC in lymphoma patients. Twelve patients with Hodgkin's disease (HD) and 38 patients with non-Hodgkin's lymphoma (NHL) were mobilized with MIME/G-CSF. Most patients were heavily treated with different chemotherapy regimens receiving a median of 11 cycles (range 3 to 20) of chemotherapy prior to mobilization. It was found that the optimal time of PBPC harvest was at days 12 and 13 after initiating the mobilization regimen. The median number of collected CD34+ cells per kg body weight was 7.1 x 10(6) (range 0.5-26.2). More than 2.0 x 10(6) CD34+ cells/kg were achieved in 69% of the patients after one apheresis. When additional cycles of apheresis were done, only 6% failed to harvest this number of CD34+ cells. There was a statistically significant inverse correlation between the number of prior chemotherapy cycles and CD34+ cell yield (P = 0.003). No such association was found between CD34+ cell yield and prior radiotherapy. When MIME/G-CSF was compared with Dexa-BEAM/G-CSF, it was found that MIME/G-CSF tended to be more efficient in mobilizing PBPC in spite of being less myelotoxic. All patients transplanted with MIME/G-CSF mobilized PBPC had fast and sustained engraftment. These results demonstrate that an ordinary salvage chemotherapy regimen, such as MIME combined with G-CSF can be successfully used to mobilize PBPC.     

Effect of protective colloids on the induction of polymorphic changes in indomethacin agglomerates after solvent evaporation from o/w emulsions

BACKGROUND: It was previously reported that the combination of granulocyte-macrophage-colony-stimulating factor (GM-CSF) and granulocyte-CSF (G-CSF) for 4 days mobilized more primitive CD34+ subsets than did either G-CSF or GM-CSF alone. STUDY DESIGN AND METHODS: The studies determine the optimal number of days of growth factor dosing for mobilization and collection of peripheral blood progenitor cells, by increasing the days of administration of GM-CSF and/or G-CSF or employing the sequential administration of GM-CSF followed by G-CSF. Sixty normal subjects were given injections of G-CSF or GM-CSF alone; GM-CSF and G-CSF concurrently for 4, 5, or 6 days; or a sequential regimen of GM-CSF for 3 or 4 days followed by G-CSF for 2 or 3 days. A 10-L apheresis was performed 24 hours after the last dose. RESULTS: The three most efficacious mobilization regimens consisted of sequential GM-CSF for 3 days followed by G-CSF for either 2 or 3 days and G-CSF alone for 5 days. Each of these regimens resulted in the collection of significantly greater numbers of CD34+ cells by apheresis than any of the 4-day dosing regimens with G-CSF and/or GM-CSF (sequential GM-CSF/G-CSF: 3 days/2 days = 3.58 +/- 0.53 x 106 CD34+ cells/kg; GM-CSF/G-CSF: 3 days/3 days = 4.45 +/- 1.08 x 10(6) CD34+ cells/kg; G-CSF: 5 days = 3.58 +/- 0.97 x 10(6) CD34+ cells/kg; all p<0.05 vs. G-CSF and/or GM-CSF for 4 days). Clonogenic assays generally paralleled the level of CD34+ cells. Regimens containing GM-CSF resulted in a higher percentage of the cells from primitive CD34+/CD38-/HLA-DR+ subset than G-CSF alone. CONCLUSION: Compared with 4-day dosing regimens with G-CSF and/or GM-CSF, mobilization of CD34+ cells in normal subjects using sequential GM-CSF for 3 days followed by G-CSF for 2 or 3 days or using G-CSF alone for 5 days increased the number CD34+ cells that can be collected by a single 10-L apheresis 24 hours after the last dose of cytokine.     

Mobilization of hematopoietic stem and progenitor cell subpopulations from the marrow to the blood of mice following cyclophosphamide and/or granulocyte colony-stimulating factor

Committed progenitor cells and primitive stem cells mediate early and sustained engraftment, respectively, after lethal irradiation and stem cell transplantation. Peripheral blood stem cells (PBSC) from unstimulated mice are deficient in both cell types. To study techniques to mobilize both progenitor cells and primitive stem cells from the marrow to the blood, we collected peripheral blood from C57BL/6 mice 6 to 7 days after a single dose of cyclophosphamide (CY; 200 mg/kg intraperitoneally), after recombinant human granulocyte colony-stimulating factor (rhG-CSF) (250 micrograms/kg/d twice per day subcutaneously for 4 days), or after CY followed by G-CSF. Significant increases in white blood cell counts (1.6- to 2.7-fold) and circulating day 8 colony-forming unit spleen (CFU-S) (11- to 36-fold) were seen with all three mobilization methods compared with unstimulated control mice. Transplantation of mobilized blood stem cells into lethally irradiated hosts decreased the time to erythroid engraftment. Blood stem cells were analyzed for primitive stem cell content by Rs, an assay for CFU-S self-renewal, and competitive repopulation index (CRI), an assay of long-term repopulating ability. The primitive stem cell content of unstimulated blood was clearly deficient, but was significantly increased following mobilization, approaching normal bone marrow levels. These results were confirmed by an in vitro limiting dilution long-term culture assay that measures the frequency of progenitor cells and primitive stem cells. Mobilization following CY + G-CSF was accompanied by a marked loss of both progenitor cells and primitive stem cells in the marrow. In contrast, following G-CSF alone the progenitor cell and primitive stem cell content of the marrow was unchanged. Stem cell mobilization following CY + G-CSF was not affected by previous exposure of donors to cytosine arabinoside or cyclophosphamide, but was significantly reduced by previous exposure to busulfan. These data show that stem cell content in the blood may reach near-normal marrow levels after mobilization, the mobilization from the marrow to the blood is temporary and reversible, the specific technique used may mobilize different subpopulations of stem cells, and the type of prior chemotherapy may influence the ability to mobilize stem cells into the blood.     

Does eradication of Helicobacter pylori impair healing of nonsteroidal anti-inflammatory drug associated bleeding peptic ulcers? A prospective randomized study

High-dose therapy with peripheral blood stem cell (PBSC) support is a frequently used treatment option in younger patients with poor prognosis histologically indolent (low-grade) non-Hodgkin's lymphoma (NHL), usually at the time of second or subsequent response to conventional-dose therapy. We have undertaken PBSC collection in 57 patients with histologically indolent NHL mobilized with either cyclophosphamide 1.5 g/m2 or the ESHAP regimen, followed by daily G-CSF. Progenitor cell yields were determined by quantification of CD34+ cells and GM-CFC. Twelve patients (21%) failed to achieve the minimum progenitor cell requirements of 1 x 10(6)/kg CD34+ cells or 1 x 10(5)/kg GM-CFC in their pooled harvests and 40 patients (70%) failed to achieve the optimal harvest thresholds of 3.5 x 10(6)/kg CD34+ cells or 3.5 x 10(5)/kg GM-CFC. This high failure rate is significantly higher than that in patients with histologically aggressive NHL or Hodgkin's disease. A multivariate analysis was performed to identify factors contributing to the low stem cell yields in this group. This identified the time interval from the last chemotherapy to the priming chemotherapy as the most important predictive factor. With respect to CD34 and GM-CFC numbers, on the single harvest on the day the white cell count first exceeded 5 x 10(9)/l the P values were 0.0078 and 0.0065, respectively, and for the progenitor cell values on the pooled harvests the P values were 0.004 for CD34+ cells and 0.015 for GM-CFC. Progenitor cell yields may therefore be improved in patients with low grade lymphoma by harvesting at diagnosis if no marrow disease is present, or by delaying mobilization for 6 months post-chemotherapy in patients in first or subsequent remission.     

Dendritic cell-based vaccines in the setting of peripheral blood stem cell transplantation: CD34+ cell-depleted mobilized peripheral blood can serve as a source of potent dendritic cells

We are investigating the use of tumor-pulsed dendritic cell (DC)-based vaccines in the treatment of patients with advanced cancer. In the current study, we evaluated the feasibility of obtaining both CD34+ hematopoietic stem/ progenitor cells (HSCs) and functional DCs from the same leukapheresis collection in adequate numbers for both peripheral blood stem cell transplantation (PBSCT) and immunization purposes, respectively. Leukapheresis collections of mobilized peripheral blood mononuclear cells (PBMCs) were obtained from normal donors receiving granulocyte colony-stimulating factor (G-CSF) (for allogeneic PBSCT) and from intermediate grade non-Hodgkin's lymphoma or multiple myeloma patients receiving cyclophosphamide plus G-CSF (for autologous PBSCT). High enrichment of CD34+ HSCs was obtained using an immunomagnetic bead cell separation device. After separation, the negative fraction of mobilized PBMCs from normal donors and cancer patients contained undetectable levels of CD34+ HSCs by flow cytometry. This fraction of cells was then subjected to plastic adherence, and the adherent cells were cultured for 7 days in GM-CSF (100 ng/ml) and interleukin 4 (50 ng/ml) followed by an additional 7 days in GM-CSF, interleukin 4, and tumor necrosis factor alpha (10 ng/ml) to generate DCs. Harvested DCs represented yields of 4.1+/-1.4 and 5.8+/-5.4% of the initial cells plated from the CD34+ cell-depleted mobilized PBMCs of normal donors and cancer patients, respectively, and displayed a high level expression of CD80, CD86, HLA-DR, and CD11c but not CD14. This phenotypic profile was similar to that of DCs derived from non-CD34+ cell-depleted mobilized PBMCs. DCs generated from CD34+ cell-depleted mobilized PBMCs elicited potent antitetanus as well as primary allogeneic T-cell proliferative responses in vitro, which were equivalent to DCs derived from non-CD34+ cell-depleted mobilized PBMCs. Collectively, these results demonstrate the feasibility of obtaining both DCs and CD34+ HSCs from the same leukapheresis collection from G-CSF-primed normal donors and cancer patients in sufficient numbers for the purpose of combined PBSCT and immunization strategies.