High-dose ara-C with autologous peripheral blood progenitor cell support induces a marked progenitor cell mobilization: an indication for patients at risk for low mobilization.

A high-dose (HD) chemotherapy scheme was designed for the collection of large numbers of peripheral blood progenitor cells (PBPC) in lymphoma patients who were candidates for myeloablative therapy with autograft. The scheme included the sequential administration of HD cyclophosphamide (CY) (7 g/m(2)) and HD ara-C (2 g/m(2) twice a day for 6 consecutive days), followed by final consolidation with PBPC autograft. PBPC harvests were scheduled following both HD CY and HD ara-C. To minimize hematologic toxicity, small aliquots of PBPC (20 circulating CD34(+) cells/microl, whereas the remaining 19 'low-mobilizer' patients did not reach this cut-off value. In spite of poor mobilization after HD CY, 16 out of 19 low mobilizers provided good harvests following HD ara-C; overall, median collected CD34(+) cells x 10(6)/kg were 1.4 (0-3.1) and 10.2 (0-37) after HD CY and HD ara-C, respectively (P = 0.00007). Similar patterns were observed when PBPC were evaluated by CFU-GM/kg. Complete and durable hemopoietic reconstitution followed autograft with post HD ara-C PBPC. Within the high-mobilizer group, 88 patients received HD ara-C and 79 (90%) still showed high mobilization; overall, median collected CD34(+)cells x 10(6)/kg were 17.8 (range 3-94) and 19 (range 0-107) after HD CY and HD ara-C respectively (P = NS). Thus, the scheme allowed sufficient PBPC collections for autografting in low mobilizer patients; in addition, the scheme could be considered whenever extensive chemotherapy debulking is needed prior to PBPC collection.

Feasibility of peripheral blood progenitor cell mobilization and harvest to support chemotherapy intensification in elderly patients with poor prognosis: non-Hodgkin's lymphoma.

Mobilized peripheral blood progenitor cells (PBPC) are widely employed in the management of adult patients with high-risk non-Hodgkin's lymphoma (NHL), though their use in the elderly has received little attention. This study was mounted to assess the feasibility of the mobilization, harvesting, and reinfusion of PBPC in NHL patients aged >60. Twenty patients (median age: 67, range: 61-80) with poor-prognosis NHL entered the pilot study: nine others were discarded for various reasons. Thus, the program was applicable to 69% of potential candidates. Fourteen patients were at onset and six were being treated for refractory disease or relapses. Mobilization was induced with cyclophosphamide 4 g/m(2), followed by 5 micro g/kg per day granulocyte-colony stimulating factor (G-CSF) s.c. until PBPC collection or hemopoietic recovery. Sixteen patients (80%) displayed some signs of mobilization (CD34+: >5/ micro l). Maximum mobilization varied with median circulating CD34+ cells and colony forming units-granulocyte/macrophage (CFU-GM) peaks of 17.2/ micro l (range: 8.1-210) and 1,650/ml (range: 540-62,900), respectively. A median of two leukaphereses resulted in the harvesting of a median of 6.7x10(6) (range: 0.3-33.6) CD34+/kg and 21.1x10(4) (range: 1.2-209) CFU-GM/kg. Intensified therapy with intermediate-dose melphalan, associated or not with mitoxantrone, was delivered with autologous PBPC support to 13 patients and always resulted in rapid and stable hemopoietic reconstitution. The program was well tolerated and no treatment-related deaths occurred. Twelve patients are still alive with a 5-year survival projection of 59%. In conclusion, the results demonstrate the feasibility of using autologous PBPC to support therapy intensification even in elderly patients.

Concurrent administration of high-dose chemotherapy and rituximab is a feasible and effective chemo/immunotherapy for patients with high-risk non-Hodgkin's lymphoma.

The aim of this study was to investigate feasibility, tolerability and efficacy of rituximab-supplemented high-dose sequential chemotherapy (R-HDS) with peripheral blood progenitor cell autografting as frontline or salvage treatment in patients with advanced non-Hodgkin's lymphoma (NHL). Thirty-two patients have been treated: 14 at disease onset and 18 with relapsed or progressive disease. R-HDS regimens included six courses of rituximab. Rituximab was delivered either concurrently with high-dose chemotherapy to exploit the in vivo purging properties of the drug as well as at the end of the treatment plan to target minimal residual disease. All patients treated at disease onset completed their treatment with no life-threatening toxicity, while two toxic deaths due to severe bilateral pneumonia were observed among patients treated due to relapsed or refractory disease. Thirteen of 14 patients treated up-front achieved CR. Among pre-treated patients 10 of 18 achieved CR with better results in patients with relapsed (seven of eight) compared to progressive disease (three of 10). PCR analysis was carried out in indolent lymphoma patients: nine of nine follicular lymphomas and three of six CD5-positive NHL collected PCR-negative peripheral blood progenitor cell harvests. The results of this pilot study show that R-HDS is feasible and effective with acceptable toxicity when used at disease onset. In pre-treated patients this treatment also showed promising results, although the risk of severe infections needs to be considered.

Negative immunomagnetic ex vivo purging combined with high-dose chemotherapy with peripheral blood progenitor cell autograft in follicular lymphoma patients: evidence for long-term clinical and molecular remissions.

The feasibility and efficacy of a novel immunomagnetic ex vivo negative purging method was evaluated on peripheral blood progenitor cells (PBPC) from 13 non-Hodgkin's lymphoma patients (eight follicular, FL; three mantle cell, MCL; two FL with histologic transformation). A peculiar feature of the study was the collection of PBPC after prolonged tumor debulking. Our method included a stem cell enrichment phase followed by cell incubation with anti-B cell MoAbs (anti-CD19, CD20, CD22, CD23), addition of immunobeads, and then positive cell removal by passage on a Max-Sep (Baxter Immunotherapy) cell separator. Engraftment was rapid and stable. Hematological values were assessed 1 and 2 years after the autograft. Purging efficacy was molecularly assessed in a panel of 11 patients who showed persistence of PCR-detectable lymphoma cells on PBPC harvests despite intensified chemotherapeutic debulking. PCR-negativity was obtained in vitro and persisted in vivo after autograft in three FL patients; five more FL patients, whose purged PBPC were PCR+, converted to stable (3 patients) or fluctuating (two patients) PCR negativity after autograft. MCL patients never reached PCR negativity. Thus, ex vivo purging may have a role for FL patients harvesting PCR-positive PBPC after intensified chemotherapy. In contrast, the addition of ex vivo purging seems to be of little if any benefit for MCL patients.

Hemopoietic progenitor cell mobilization and harvest following an intensive chemotherapy debulking in indolent lymphoma patients.

An in vivo purging with intensive debulking chemotherapy prior to peripheral blood progenitor cell (PBPC) collection may reduce the risk of tumor contamination of the harvest products; however, it is usually associated with a marked reduction in PBPC mobilization. These issues have been considered while designing an adapted version of the high-dose sequential regimen for patients with lymphoid malignancies and bone marrow involvement. To reduce tumor contamination risks, PBPC collection was postponed to the end of the high-dose phase; however, in order to enhance progenitor cell mobilization, a chemotherapy-free lag period was introduced prior to the final mobilizing course. Thirty-nine patients (median age 47 years, range 26-62) with previously untreated indolent lymphoma entered this pilot study; all had advanced-stage disease, and 29 had overt marrow involvement. Sufficient numbers of PBPC to perform autograft with safety were harvested in 34 patients, with a median of 3 (range 2-5) leukaphereses. A median of 14.8 x 10(6) (range 2-51) CD34+/kg and 32.6 x 10(4) (range 1.77-250) colony forming units-granulocyte/macrophage/kg were collected per patient. In univariate analysis, the duration of the chemotherapy-free interval prior to the final mobilizing course, i.e. > or <65 days, was the most significant variable influencing progenitor mobilization. These data suggest that extensive in vivo tumor debulking is feasible provided that a sufficient chemotherapy-free period preceding the mobilizing course is allowed in order to allow a full recovery of marrow functions.

A single step density gradient separation for large scale enrichment of mobilized peripheral blood progenitor cells collected for autotransplantation.

Peripheral blood leukocytes are becoming the preferred source of hematopoietic progenitor/stem cells for autologous transplantation. However, in vitro purging procedures are complex and expensive when applied to peripheral blood progenitor cells harvests. This is mainly due to the large quantities of nucleated cells present in leukapheresis collections. Aiming to reduce total cellularity without significant loss of CD34+ cells, we developed an in vitro cell separation procedure based on ficoll/metrizoate gradient used at a final density of 1.067 g/ml. To obtain this density, standard Lympho-prep (1.077 g/ml) was diluted with normal saline solution (NaCl 9 g/l). Twenty-six leukapheresis collections (median cellularity 21.1 x 10(9), range 2.8-60) from 14 patients with non-Hodgkin's lymphoma, multiple myeloma or plasma cell leukemia were processed (median two leukaphereses per patient). Mean (+/- s.d.) recovery of total nucleated cells, CD34+ cells and CFU-GM was 20.9 +/- 10%, 74.7 +/- 22% and 70.5 +/- 19%, respectively. Cumulative per patient progenitor cell recovery was always above 50%, and as high as 80% in 10/14 patients, while total cellularity was reduced to a median 21.5% (10-33%) of pre-separation values. Contaminating neoplastic cells, identified by immunofluorescence in five collections, were reduced by 1-2 logs. The results indicate that our density gradient separation is an effective method to reduce total cellularity prior to immunological purging, without significant loss of progenitor cells.

Peripheral blood progenitor cell mobilization in patients with primary refractory lymphoma or at first relapse: comparison with patients at diagnosis and impact on clinical outcome.

Peripheral blood progenitor cell (PBPC) mobilization was evaluated in 53 patients receiving the high-dose sequential (HDS) regimen: 27 had non-Hodgkin's lymphoma or Hodgkin's disease, primary refractory or at first relapse, 26 had non-Hodgkin's lymphoma at diagnosis. Mobilization was assessed following either 7 g/m2 cyclophosphamide (48 patients) or 2 g/m2 etoposide, both followed by G-CSF (filgrastim) at 5 microg/kg/d. PBPC mobilization was significantly higher in patients at diagnosis compared to refractory/relapsed patients (median peak values of circulating CFU-GM: 25,209/ml v 4270/ml, P < 0.0001 and CD34+ cells: 286/microl v 47/microl, P < 0.0001). All patients receiving HDS as up-front treatment mobilized enough PBPC for an autograft, often requiring a single leukapheresis; whereas only 15 patients under salvage treatment with HDS were able to complete PBPC autograft. Bone marrow (BM) cells, alone or with PBPC, were needed in six patients, and autograft could not be performed in six patients. Among refractory/relapsed patients, those having a high PBPC mobilization experienced a significantly longer EFS compared to those who had not; autograft completion also significantly enhanced EFS. Thus, the use of an effective mobilizing protocol does not ensure adequate PBPC mobilization in moderately pretreated patients; low mobilization must be considered as an early sign of poor outcome in patients receiving a high-dose salvage programme.

Both early and committed haemopoietic progenitors are more frequent in peripheral blood than in bone marrow during mobilization induced by high-dose chemotherapy + G-CSF.

Haemopoietic growth factor administration following high-dose chemotherapy markedly amplifies progenitor cell pool in the peripheral blood (PB). Collection and reinfusion of these cells enable rapid haemopoietic reconstitution following autograft. Less is known on engraftment potentiality of bone marrow (BM) cells taken under analogous conditions. To investigate this tissue, PB and BM were evaluated simultaneously during maximal mobilization in a series of 14 patients undergoing the HDS chemotherapy programme. A significantly higher growth of committed progenitors was found from PB rather than from BM (663 +/- 123 v 267 +/- 40 CFU-GM/10(5) MNC, respectively). Also, significantly more CFU-GM could be collected by a median of three leukaphereses, compared to those harvested from BM (158 +/- 31 v 16 +/- 4 x 10(4) CFU-GM/kg, respectively). Most mobilized CFU-GM were phenotypically immature (CD15-); in addition, circulating cells included primitive progenitors, as assessed by LTC-IC assay, or by evaluation of non-proliferating pre-CFU-GM, selected by an anti-CD71 immunotoxin. The amount of pre-CFU-GM determined by both techniques was consistently higher in PB than in BM. Moreover, a direct correlation could be established between circulating CFU-GM and primitive precursors. Thus, during optimally induced mobilization, PB contains many more haemopoietic progenitors, of both committed and primitive stages, than does BM. Under such conditions, PB is probably the best source of material for graft purposes.

Circulating progenitors following high-dose sequential (HDS) chemotherapy with G-CSF: short intervals between drug courses severely impair progenitor mobilization.

Sequential administration of high-dose chemotherapy courses possibly allows extensive in vivo purging before circulating progenitor collection for autograft. To evaluate whether progenitor cell mobilization was negatively affected by repeated high-dose chemotherapy courses, we studied 23 lymphoma patients undergoing the HDS regimen. The scheme includes the sequential administration of cyclophosphamide (CY) given at 7 g/m2 and etoposide (VP16) given at 2 g/m2, each followed by G-CSF (filgrastim) at 5 micrograms/kg/day. Eleven patients received the standard HDS sequence, with a short interval between first and second myelotoxic courses of less than 45 days (median: 30 days); the remaining 12 patients received a modified HDS where the interval between first and second high-dose course was protracted over 2 months (median: 70 days); in this latter group, 2 to 4 conventional debulking courses were delivered prior to HDS. In patients receiving the standard HDS, progenitor mobilization following the first course was consistently high (median circulating CFU-GM/ml peak value: 29,022); however, significantly lower values were observed at the second course (median CFU-GM/ml peak value 3757, P = 0.002). Circulating BFU-E and CD34+ cell values paralleled those of CFU-GM. No significant difference was observed in progenitor mobilization following either course in patients receiving HDS with extended interval (median circulating CFU-GM/ml peak value: 14,363 vs 9208, at first and second course respectively, P = 0.27). Eleven patients had their progenitor cells harvested following the second delayed course and 2-4 leucaphereses allowed very satisfactory harvests in all of them (CFU-GM/kg ranging from 39-340 x 10(4)).(ABSTRACT TRUNCATED AT 250 WORDS)

Selection and characterization of early hematopoietic progenitors using an anti-CD71/S06 immunotoxin.

Most recently reported methods to select early hematopoietic cells basically rely on the depletion of committed progenitors. This task is generally accomplished by laborious procedures, which are sometimes difficult to reproduce. To simplify the selection method, we took advantage of the expression of the transferrin receptor (CD71) by proliferating committed progenitors and the lack of CD71 on noncycling immature progenitors. A monoclonal antibody (MAB) reactive with CD71 has been conjugated to the Saponaria officinalis seed ribosome-inactivating protein (SO6). The immunotoxin (IT) complex was used at increasing concentrations on normal non-phagocytizing bone marrow cells. A complete and reproducible killing effect on myeloid (colony-forming unit-granulocyte/macrophage [CFU-GM]) and erythroid (burst-forming unit-erythroid [BFU-E]) progenitors was observed for IT concentrations of 1 x 10(-7) M. Unconjugated SO6 or anti-CD71 MAB had no effect on cell growth and viability. IT-resistant cells were able to generate CFU-GM after 7, 14, and 21 days of suspension culture in the presence of 5637 CM. Maximal CFU-GM values were obtained at day 21 and nearly approached the pretreatment values (mean 2587 vs. 3877 CFU-GM/mL). Growth factor enhancement of CFU-GM yield was obtained only by stem cell factor (SCF) at day 7; SCF, as well as granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-3 (IL-3), had an enhancing effect at days 14 and 21. IT toxicity on highly immature progenitors was ruled out by evaluating the growth of long-term culture-initiating cells (LTC-IC) from IT-treated cultures. LTC-IC frequency was found to be 1 out of 1506 seeded cells, which is within the range of normal untreated BM cells. In conclusion, anti-CD71 IT allows a simple and complete depletion of committed progenitors while sparing immature hematopoietic cells. The high CD71 expression by leukemic cells makes the procedure potentially suitable for in vitro purging.

High-dose sequential (HDS) chemotherapy with blood and marrow cell autograft as salvage treatment in very poor prognosis, relapsed non-Hodgkin's lymphoma.

We tested the feasibility and efficacy of a novel high-dose sequential chemoradiotherapy programme (HDS) in 14 relapsed or refractory non-Hodgkin's lymphoma patients with very poor prognostic features, i.e. transformed histology, marrow invasion, low performance status. This regimen included the sequential administration of high-dose cyclophosphamide (CY) 7 g/m2 followed by high-dose methotrexate (MTX) 8 g/m2 and high-dose VP16 2 g/m2 and finally by total body irradiation (TBI)-melphalan and autograft of bone marrow and peripheral blood progenitor cells. No hemopoietic growth factor support was employed in any phase. There was one treatment-related death during the high-dose phase; three other patients did not complete the programme. All 10 patients concluding the programme achieved complete remission, with four patients in complete clinical remission at a median follow up of 34 months. Median overall survival was 27 months and median failure-free survival (FFS) was 12 months. Twenty-six well comparable patients received conventional salvage therapy during the same period. Their projected median overall survival (8 months) and median FFS (4 months) were shorter than in the HDS group (p = 0.06 for overall survival and p = 0.03 for FFS). Thus, HDS is a feasible programme and may offer superior results than conventional therapy in poor-prognosis NHL patients.

Role of chemotherapy and GM-CSF on hemopoietic progenitor cell mobilization in multiple myeloma.

Circulating hemopoietic progenitors were evaluated in 19 multiple myeloma patients at diagnosis. Eleven patients received either high-dose cyclophosphamide (7 g/m2, 8 patients) or etoposide (2 g/m2, 3 patients) followed by GM-CSF administration; the remaining 8 patients received intermediate-dose cyclophosphamide (1.2 g/m2 on days 1 and 3), 4 of them with GM-CSF support. The highest levels of circulating progenitor cells were observed among patients in the high-dose chemotherapy group (median CFU-GM peak value of 6432 per ml), while in patients receiving intermediate-dose, with or without GM-CSF, median peak values were 2588 and 462 per ml, respectively. In all groups a remarkable heterogeneity in the yield of circulating progenitors was observed; this was particularly pronounced in the high-dose group, where CFU-GM peak values ranged between 200 and 38,070 per ml. At variance with the effect observed in previously untreated patients with lymphoma or breast cancer, the degree of mobilization in myeloma patients was rather unpredictable. The only pre-treatment characteristic correlating to some extent with a poor expansion of the circulating progenitor pool was heavy BM infiltration with plasma cells. The mobilizing effect was not restricted to the myeloid lineage, as demonstrated by the rise of BFU-E; CD34+ cells were increased as well. Indeed, a simultaneous evaluation of CFU-GM and CD34+ cells was carried out and a highly significant correlation (r = 0.9) was observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Conditions influencing the expansion of the circulating hemopoietic progenitor cell compartment.

Eighteen patients (6 breast cancer, 10 non-Hodgkin's lymphoma, 2 Hodgkin's disease) were treated with high-dose cyclophosphamide (7 gr/mq), while 12 (2 breast cancer, 5 non-Hodgkin's lymphoma, 5 multiple myeloma) were additionally treated with rhGM-CSF for 14 days after cyclophosphamide. During recovery, increased peak values of circulating CFU-GM were observed in 23 out of 30 patients (13 patients after cyclophosphamide, median: 5,000 CFU-GM/ml; 10 patients after cyclophosphamide + rhGM-CSF, median: 20,150 CFU-GM/ml); five of these "high releaser patients" were in 1st relapse after MACOP-B. Seven patients showed low release of CFU-GM; they had either a history of multiple exposures to chemoradiotherapeutic treatments or bone marrow replacement by neoplastic cells or both. Four out of 23 patients with high CFU-GM release were subsequently studied after administration of high-dose etoposide (2 gr/mq): increased levels of circulating progenitors were seen again, although peak values were reduced when compared to post-cyclophosphamide period. Three patients with low release and bone marrow involvement had a clear increase of circulating CFU-GM after etoposide. The results show the influence of high-dose chemotherapy, rhGM-CSF, type of previous treatment and bone marrow involvement on the degree of circulating CFU-GM release.