[Treatment of chemotherapy-induced nausea and vomiting with 5-hydroxytryptamine type 3 receptor antagonists]. / Antiemetische Therapie mit 5-HT(3)-Antagonisten in der onkologischen Praxis.

BACKGROUND AND OBJECTIVE: 5-hydroxytryptamine 3 (5-HT3) receptor antagonists have proved to be highly efficacious in the prevention and treatment of chemotherapy-induced nausea and vomiting (CINV). However, several questions remain concerning the relative efficacy of various approved anti-emetics, especially with respect to dosage, duration and timing of administration, as well as differences in toxicity profiles. Thus it seemed appropriate to assess the current therapeutic results in routine daily practice, when applying antiemetic therapy according to established guidelines. PATIENTS AND METHODS: Within LINO e.V., a group of medical oncologists in private ambulant practice (LINO: Association of private-practice medical oncologists in Bavaria), a total of 738 cycles of moderately or highly emesis-inducing chemotherapy were randomly assigned to three treatment options: (1)granisetron 1 mg (GRA1). (2) 3 mg (GRA3), and (3) ondansetron 8 mg (OND8), each combined with 8 mg dexamethasone. Incidence and severity of acute (day 1) and delayed CINV (day 2-5) and the subjective assessment of efficacy were documented on questionnaires filled in by the patients. RESULTS: All of the three regimens adequately prevented vomiting in the majority of the patients. However, all measured effects showed an uniform trend towards slightly decreased efficacy with 8 mg of ondansetron. These differences were predominantly detected with respect to delayed CINV on days 2 to 5, especially after chemotherapy with anthracyclin/cyclophosphamide combination therapy. CONCLUSION: Granisetron, at two different dosage regimens, and ondasetron showed adequate reduction in chemotherapy-induced nausea and vomiting, but ondansetron worked slightly less so.

Hemolytic uremic syndrome following prolonged gemcitabine therapy: report of four cases from a single institution.

Hemolytic uremic syndrome (HUS) has been described following the administration of multiple antineoplastic agents, most notably mitomycin C. More recently, several cases of gemcitabine-induced HUS have been observed with the overall incidence of gemcitabine-induced HUS estimated at 0.015-0.25%. We here report on four patients who developed HUS following gemcitabine therapy at our institution within the last year (incidence 1.4%). All these patients had advanced-stage disease, were heavily pretreated, and received prolonged gemcitabine application, suggesting that in this subgroup of patients HUS may be more frequently encountered than documented so far.

Thalidomide in combination with vincristine, epirubicin and dexamethasone (VED) for previously untreated patients with multiple myeloma.

The present study aimed to evaluate the side-effects and efficacy of thalidomide in combination with an anthracycline-containing chemotherapy regimen in previously untreated myeloma patients. Thalidomide (400 mg/d) was combined with bolus injections of vincristine and epirubicin and oral dexamethasone (VED). Chemotherapy cycles were repeated every 3 wk until no further reduction in myeloma protein was observed, whereas the treatment with thalidomide was continued until disease progression. Thirty-one patients were enrolled, 12 patients were exclusively treated with thalidomide in combination with VED and 19 patients additionally received high-dose melphalan, for consolidation. Adverse events and response to therapy were assessed prior to treatment with high-dose chemotherapy. Response to thalidomide combined with VED was complete remission in six patients (19%), partial remission in 19 patients (61%), stable disease in five patients (16%), and progressive disease in one patient (3.2%). Grade 3 and 4 adverse events consisted of leukocytopenia in 10 patients (32%), and thrombocytopenia and anemia in one patient each (3.2%). Neutropenic infections grade 3 and 4 occurred in seven (23%) and three patients (9.7%), respectively, including two patients (6.5%) who died from septic shock. Deep vein thrombosis occurred in eight patients (26%), constipation in 20 patients (65%), and polyneuropathy in 20 patients (65%). The probability of event-free survival and overall survival in the whole group of patients at 36 months were 26 and 62%, respectively. In conclusion, the combination of thalidomide with VED appears to be highly effective in previously untreated patients with multiple myeloma, but it is associated with a high rate of thrombotic events, polyneuropathy, and neutropenic infections.

Comparison of lenograstim and filgrastim: effects on blood cell recovery after high-dose chemotherapy and autologous peripheral blood stem cell transplantation.

PURPOSE: The aim of the study was to evaluate whether glycosylated granulocyte colony-stimulating factor (G-CSF) (lenograstim) offers a benefit over non-glycosylated G-CSF (filgrastim) in clinically relevant end points after high-dose chemotherapy (HDC) and autologous peripheral blood stem cell transplantation (PBSCT). METHODS: We retrospectively analyzed the outcome of 261 patients treated with either lenograstim (n=68) or filgrastim (n=193). Time to blood cell recovery, toxicities, and infectious complications were analyzed in a total of 469 G-CSF treatment cycles. RESULTS: Mean time to leukocyte recovery was 10.7 days (SD+/-0.9) (lenograstim) and 10.8 days (SD+/-0.6) (filgrastim), respectively. Likewise, time to thrombocyte engraftment, febrile days, duration of therapeutic antibiotic treatment, severity of non-hematological toxicities, duration of in-hospital stay, and duration of G-CSF treatment were similar in both groups. Owing to the physicochemical and pharmacokinetic properties of lenograstim, the required dose until leukocyte recovery was significantly smaller as compared to filgrastim (38.5 vs 54.0 microg/kg of body weight). CONCLUSIONS: Collectively, our data indicate that both G-CSF preparations are equally effective in hastening leukocyte recovery in the setting of high-dose chemotherapy followed by autologous PBSCT.

High-dose chemotherapy with autologous stem cell transplantation in patients with oligometastatic breast cancer.

The purpose of this prospective trial was to study a combined-modality treatment including local consolidation by surgery or radiotherapy and high-dose chemotherapy (HDC) followed by peripheral-blood stem-cell (PBSC) transplantation. In all, 48 patients with oligometastatic breast cancer amenable to local treatment after induction chemotherapy with epirubicin and cyclophosphamide or paclitaxel and cisplatin, depending on prior adjuvant chemotherapy, were enrolled. The median follow-up was 41 months (range, 7-85 months). PBSC were collected in 47 patients, and 40 received one or two courses of HDC. Local therapy was given in 37 patients. No treatment-related deaths occurred. Of 47 evaluable patients, 36 (75% of intention-to-treat population) had no evidence of disease or complete remission after completion of therapy. Six patients (12.5%) had partial response, two patients (4%) no change, and three patients (6%) progressive disease. The median time to progression and overall survival was 17.5 (95% confidence interval (CI), 14-21 months) and 42.2 months (95% CI, 33-52 months), respectively, and 27% of patients were progression free after 5 years. In conclusion, patients with oligometastatic breast cancer can be treated safely with this combined modality protocol with promising relapse-free survivals.

Outcome of 67 patients with solid tumors relapsed after high-dose chemotherapy and peripheral blood stem cell transplantation.

We retrospectively analyzed the outcome of 67 patients with breast (n=24), ovarian (n=11) or testicular cancer (n=32) treated for relapse after high-dose chemotherapy (HDC) and peripheral blood stem cell (PBSC) transplantation. Treatment, survival and toxicity were analyzed. Patients with breast, ovarian or testicular cancer received a mean of 5.9 (range 1-24), 5.1 (1-13) and 4.6 (1-13) regimens for relapse after HDC. Overall response at the end of the observation period was 20.8% for patients with breast cancer (three complete (CR) and two partial responses (PR)), 45.5% (one CR, four PR) for ovarian and 9.4% (three PR) for testicular cancer patients. The mean overall-survival (OAS) from first relapse was 28 (range 3-44), 17 (2-24) and 10 (1-28) months, respectively. Leukocytopenia grade 3/4 occurred in 27-63% of patients, and thrombocytopenia grade 3/4 was observed in 58-88%, respectively. Nonhematological grade 3/4 toxicities were below 20%. In conclusion, patients with relapse after HDC usually have a poor outcome but long-term survivors are observed. Hematological toxicity is common, while other severe side effects are less frequent.

Impact of chemotherapy regimen and hematopoietic growth factor on mobilization and collection of peripheral blood stem cells in cancer patients.

Various chemotherapy regimens, combined with recombinant human granulocyte colony-stimulating factor(rhG-CSF) or recombinant granulocyte-macrophage CSF (rhGM-CSF) are used in cancer patients to mobilize and collect peripheral blood stem cells (PBSC). In this retrospective study, we evaluated and compared the efficacy of such regimens in 262 patients with different types of malignant diseases. The following chemotherapy regimens were applied: ifosfamide-etoposide-cisplatin or bleomycin (n = 96; mainly patients with testicular cancer); ifosfamide-etoposide plus or minus cytosine arabinoside (Ara-C) or vincristine (VCR)(n = 52; mainly patients with lymphoma); cyclophosphamide-anthracycline (n = 53; mainly patients with breast cancer); intermediate to high dose (ID-HD) cyclophosphamide (n = 37; mainly patients with breast or ovarian cancer. or multiple myeloma; and others (n = 24). rhG-CSF or rhGM-CSF, each at an average daily dose of 5 microg/kg body weight, were used in 166 and 96 patients, respectively. The study evaluated and compared the efficacy of these two cytokines. In patients receiving rhG-CSF, CD34+ cells could be collected earlier (median: day 14 versus day 16) and there was a significantly higher white blood cell count (WBC)(median 11,350 versus 5550/microl) and CD34+ cell count (median 88 versus 43/microl) at the start of apheresis, and a significantly higher CD34+ cell yield (median 7.4 x 10(6) versus 4.6 x 10(6)/kg) than in patients who receivedrhGM-CSF. Among the various chemotherapeutic regimens used, each combined with rhG-CSF, ifosfamide-etoposide plus or minus Ara-C or VCR mobilized a significantly higher number of CD34+ cells (median 119/microl) and produced a significantly higher harvest of these cells (median 13 x 10(6)/kg) than cyclophosphamide-anthracycline (median 87/microl and 7 x 10(6)/kg, respectively) or ID-HD cyclophosphamide (median 59/microl and 5 x I 0(6)/kg, respectively). Ifosfamide-etoposide plus or minus Ara-C or VCR was also superior to ifosfamide-etoposide-cisplatin or bleomycin (median 78/microl and 9 x 10(6)/kg, respectively), but at borderline significance. The outcome of PBSC mobilization and collection appeared to be negatively influenced by the number of relapses before the current salvage treatment. These data indicate that mobilization and collection of PBSCstrongly depend on the type of hematopoietic growth factor and chemotherapeutic regimen used. The data further show rhG-CSF is a more effective growth factor than rhGM-CSF and ifosfamide-etoposide-based regimens, particularly ifosfamide-etoposide plus or minus Ara-C or VCR, are highly effective regimens in mobilizing and collecting CD34+ cells.

Femoral head necrosis in three patients with relapsed ovarian cancer receiving high-dose chemotherapy followed by autologous peripheral blood stem cell transplantation.

We report three patients with relapsed ovarian cancer who developed femoral head necrosis requiring endoprosthetic hip surgery 16-35 months after high-dose chemotherapy (HDC) with treosulfan (47 and 56 g/m(2) body-surface area (BSA)) given as 3-25 h infusions and followed by autologous peripheral blood stem cell (PBSC) transplantation. One woman received two courses of single agent treosulfan while the other two patients received one course of high-dose treosulfan either preceded or followed by high-dose carboplatin, etoposide and cyclophosphamide. A total of 30 women with ovarian cancer were treated with HDC at our unit and 21 of them received treosulfan-containing regimens. Femoral head necrosis was not observed in patients either receiving conditioning regimens without treosulfan (n=9) or when the total treosulfan dose was given over 3 consecutive days (n=3) or in patients with a diagnosis other than ovarian cancer and treated with high-dose treosulfan (n=10). We conclude that women with relapsed ovarian cancer receiving HDC with excessive single-dose treosulfan might be at an increased risk of developing bone necrosis.

Flt3 ligand and thrombopoietin serum levels during peripheral blood stem cell mobilization with chemotherapy and recombinant human glycosylated granulocyte colony-stimulating factor (rhu-G-CSF, lenograstim) and after high-dose chemotherapy.

The purpose of this investigation was to study thrombopoietin (TPO) and Flt3 ligand (FL) serum levels in the course of peripheral blood stem cell (PBSC) mobilization and high-dose chemotherapy (HDC) and to correlate the values with stem cell yield and engraftment. Thirty-nine patients were included. PBSC were mobilized by chemotherapy followed by two body surface area-dependent doses of glycosylated recombinant human granulocyte colony-stimulating factor (rhu-G-CSF, lenograstim). PBSC could be harvested in 35 patients and 30 received a total of 62 courses of HDC (1-3 per patient). Fifty-six were analyzed and TPO and FL serum levels were measured at the start of PBSC mobilization, at the first PBSC collection, on the day of PBSC infusion, and until engraftment. Mean baseline TPO and FL serum levels were 173 pg/ml and 192 pg/ml and increased to 493 and 323 pg/ml at the start of PBSC collection. Maximum values were 2279 pg/ml TPO after HDC 1 and 2375 pg/ml after HDC 2, while the mean maximum serum levels for FL were 1181 and 1236 pg/ml after HDC 1 and 2 and PBSC transfusion, respectively. FL serum levels at the start of PBSC mobilization correlated with the total yield of CD34+ cells (17.61+/-18.8x10(6)/kg body weight, r=0.81), while TPO serum levels on days 11-13 after PBSC infusion were inversely correlated with the amount of transfused CD34+61+62+ cells (r=-0.88 and -0.79 for HDC 1 and 2). There was no strong correlation between TPO or FL serum levels and WBC and platelet engraftment. In conclusion, chemotherapy followed by glycosylated rhu-G-CSF induced elevated serum levels of TPO and to a lower degree of FL at the start of PBSC collection. The maximum increase was 13.7-fold for TPO and 6.4-fold for FL after PBSC infusion indicating endogenous release which should be considered if the clinical use of these cytokines is intended in this setting.

Comparison of processing four and five times the patients' blood volume during peripheral blood stem cell collection and analysis of CD34+38--and CD34+49d+ subsets during apheresis.

PURPOSE: We investigated whether increasing the patients' processed blood volume (BV) during peripheral blood stem cell collection (PBSCC) from four to five times leads to a greater yield of CD34+ cells. We also studied the kinetics of CD34+38- and CD34+49d+ subsets and compared the amount of transfused cells with engraftment. METHODS: All patients ( n=20) received chemotherapy followed by G-CSF for PBSC mobilization. Samples from the patients' peripheral blood and the PBSC harvests were taken after processing 1-, 4-, and 5 times the patients' calculated BV. RESULTS: The mean total yields of CD34+, CD34+38-, and CD34+49d+ cells were 15.69-, 1.13- and 4.17 x 10(6)/kg body weight, respectively. The mean increase for these subsets between 4- and 5 BV was 10%, 8%, and 21%, respectively. Based on the mean number of 2.25 (range 2-3) planned courses of high-dose chemotherapy (HDC) per patient, the mean yield of CD34+ cells per kg body weight and intended course of HDC after 4- and 5 BV was 6.31- and 6.97 x 10(6) ( P=0.014). Twenty HDC were evaluable for engraftment. There was some correlation between the number of transfused CD34+ and CD34+38- cells and WBC engraftment ( r = -0.66 and --0.69; P<0.01) and CD34+ cells and platelet engraftment ( r = -0.56; P= 0.013). No toxicity occurred during PBSCC, although the mean platelet count dropped by 50% which must be kept in mind regarding the additional application of anti-coagulants and the fact that most patients had large indwelling catheters. CONCLUSION: Processing 4 BV is sufficient to collect >5 x 10(6) CD34+ cells/kg body weight and intended course of HDC in most patients, although extension to 5 BV further increases the total yield of CD34+ cells.

Survival of tumor cells in stem cell preparations and bone marrow of patients with high-risk or metastatic breast cancer after receiving dose-intensive or high-dose chemotherapy.

PURPOSE: We evaluated whether dose-intensive or high-dose chemotherapy can eliminate micrometastases in high-risk breast cancer patients. EXPERIMENTAL DESIGN: We monitored cytokeratin (CK)/17-1A positive cells in the bone marrow (BM) and peripheral blood stem cells (PBSC) and studied Her-2/neu serum levels of patients with locally advanced (n = 13; group 1) and metastatic breast cancer (n = 30; group 2) using immunomagnetic separation, immunocytochemistry, and ELISA. RESULTS: CK+ cells were found in the BM of 3 of 13 (23%) group 1 patients before but not after chemotherapy, resulting in an overall survival (OS) of 92% after a median follow-up of 33 months. Contamination of PBSC in 2 of 9 (22%) patients was not associated with decreased survival. In group 2 patients, the CK+ rate was 60% (18 of 30 patients) before and 40% (4 of 10 patients) after therapy with an OS rate of 43% after 29 months. PBSC samples were positive in 7 of 24 (29%) patients. CK+ BM and PBSC led to a rapid progress and short OS, whereas tumor cell-free BM and PBSC resulted in a mean OS of 30 months. The antigen 17-1A was detected on most CK+ cells in both patient groups before therapy, on all of CK+ PBSC, and on CK+ cells in group 2 patients after therapy. Increased Her-2/neu levels were found in group 2 patients before chemotherapy. CONCLUSION: Micrometastatic cells are present in PBSC grafts and can survive even high-dose chemotherapy. The presence of immunotherapeutic target antigens supports the idea that a combined chemoimmunotherapy might be successful in eliminating minimal residual disease.

High-dose chemotherapy with peripheral blood stem cell transplantation for patients with advanced ovarian cancer.

PURPOSE: We report the results of high-dose chemotherapy (HDC) with peripheral blood stem cell transplantation in twenty-one patients with primarily advanced or relapsed ovarian cancer. METHODS: Twenty-five women underwent stem cell collection, and 21 were finally treated with different regimens of HDC containing cyclophosphamide, etoposide, carboplatin, and treosulfan. The patients received cyclophosphamide +/- cisplatin and cisplatin + paclitaxel, respectively, followed by G-CSF (n = 24) or GM-CSF (n = 1) for stem cell mobilization. RESULTS: A mean of 7.2 +/- 6.1 x 10(6) CD34+ cells per kg bw were collected. Thirteen patients received double transplants and one patient received a triple transplant. The median age was 47 years (range 24-61 years) and the mean number of prior regimens was three (range 1-8). Engraftment occurred on time in all patients and there was one treatment-related death resulting in an overall mortality rate of 4.8% among the 21 patients treated with HDC. The response rate was 72% (48% CR, 24% PR) and the mean time to progression and overall survival after HDC were 7 and 32 months, respectively. CONCLUSION: HDC could be performed safely in patients with advanced ovarian cancer. However, even with a high response rate, the duration of response is short, warranting new treatment approaches to further improve the outcome of this population of patients with unfavorable prognosis.

Clinical phase I dose escalation and pharmacokinetic study of high-dose chemotherapy with treosulfan and autologous peripheral blood stem cell transplantation in patients with advanced malignancies.

A Phase I dose escalation and pharmacokinetic study of the alkylating cytotoxic agent treosulfan was conducted to evaluate the maximum tolerated dose and the dose-limiting toxicities in patients with advanced malignancies rescued by autologous peripheral blood stem cell transplantation. Twenty-two patients (15 ovarian and 7 other carcinomas/lymphomas) with a median age of 48 years were treated with 28 high-dose courses. Treosulfan was infused over 2 h at escalating doses from 20 to 56 g/m2, and pharmacokinetic parameters were analyzed. At 56 g/m2, three of six patients experienced dose-limiting toxicities: diarrhea grade III/IV in three patients; mucositis/stomatitis grade III in one patient; toxic epidermal necrolysis in one patient; and grade III acidosis in one patient. Other low-grade side effects, including erythema, pain, fatigue, and nausea/vomiting, were recorded. Two patients died within 4 weeks after treatment because of rapid tumor progression and fungal infection, respectively. Plasma half-life, distribution volume, and renal elimination of treosulfan were independent of dose, whereas the increase in area under the curve was linear up to 56 g/m2 treosulfan. The maximum tolerated dose of high-dose treosulfan is 47 g/m2. A split-dose or continuous infusion regimen is recommended for future high-dose trials. In consideration of antineoplastic activity and limited organ toxicity, inclusion of high-dose treosulfan in combination protocols with autologous peripheral blood stem cell transplantation seems worthwhile.

Thrombopoietin serum levels at the start of mobilization, collection, and transfusion of autologous peripheral blood stem cells.

Thrombopoietin (TPO) serum levels in 14 patients (9 male and 5 female, mean age 36 years, range 16 to 55 years) with breast cancer (n = 5), testicular cancer (n = 7), or lymphoma (n = 2), undergoing high dose chemotherapy with peripheral blood stem cell (PBSC) transplantation, were evaluated at the first day of the mobilization chemotherapy (1), at the day of the first apheresis (2), and at the day of stem cell transfusion (3). All patients have been pretreated (one to four regimens) and received chemotherapy and granulocyte colony stimulating factor (G-CSF) or granulocyte-macrophage colony stimulating factor (GM-CSF) both at 5 microg/kg body weight (bw). for stem cell mobilization. TPO was measured with a human TPO immunoassay. Mean TPO serum levels were: (1) 274+/-248.8 pg/ml (range 0 to 953 pg/ml), (2) 518+/-399.1 pg/ml (range 118 to 1,283 pg/ml), and (3) 556+/-506.4 pg/ml (range 147 to 1,570 pg/ml). The CD34+ cell concentration in the peripheral blood at the time of apheresis was 65+/-48.2/microl (7 to 148/microl), and the number of transfused CD34+ cells was 3.0+/-1.0x10(6)/kg bw (1.7 to 5.5x10(6)/kg bw). TPO levels showed some weak inverse correlation (r = -0.64) with the platelet counts at the day of the first apheresis that increased to -0.70 if a semilog correlation was done (plt[log] vs. TPO). The number of platelet transfusions after HDCT correlated to some degree (r = 0.61) with the TPO serum level at the day of PBSC transfusion. There was no correlation between any TPO serum level and the CD34+ cell concentration in the peripheral blood or neutrophil and platelet engraftment. We conclude from this study that TPO serum levels do not seem to correlate with the CD34+ cell concentration in the peripheral blood and the time to engraftment, although there was some weak correlation with the number of platelet transfusions.

Kinetic study of CD34+ cells during peripheral blood stem cell collections.

The impact of the separated volume on the yield of CD34+ cells during peripheral blood stem cell collections (PBSCC) remains controversial. We therefore studied the CD34+ cell concentration in the peripheral blood of patients (pts) during PBSCC as well as the total amount of CD34+ cells collected after each blood volume (BV) processed and engraftment data for each cycle of high dose chemotherapy (HD Ctx). A total of 21 PBSCC from 20 patients with different malignancies were analyzed. Stem cells were mobilized by chemotherapy and G-CSF (14 pts) or GM-CSF (6 pts). Samples from the pts peripheral blood and the collection bag were taken after each BV processed and analyzed for CD34+ cells, WBC, platelets (plt), and hemoglobin (Hb). The total volume processed was two to five times the pts calculated BV (mean value 17.4 L, range 9.0-24.0 L). Sixteen pts could be evaluated for engraftment. The mean peripheral blood CD34+ cell count was 116+/-103.5/microl at the start of PBSCC and decreased to 57+/-61.6/microl after processing of four times the pts BV. The mean number of CD34+ cells collected after each BV was 2.3+/-2.4, 5.8+/-5.2, 8.5+/-7.2, and 11.8+/-10.3x10(6) per kg body weight, respectively. The mean plt count decreased by 53+/-40.2/nl, Hb by 1.+/-0.5 g/dl and WBC by 0.+/-6.1/nl after separation of 4 BV. All but two pts reached the target value of 1.5x10(6) CD34+ cells/kg body weight and planned cycle of HD Ctx with 1 PBSCC. All pts engrafted and reached neutrophils>500/microl and plt>20,000/microl at a median of 11 and 13 days, respectively. We could demonstrate, that the yield of CD34+ cells during PBSCC increased continuously with the volume of the separated BV and that up to 5x the patients' BV could be processed safely without serious side effects. Most pts had to undergo only 1 PBSCC to collect sufficient numbers of CD34+ cells to support sequential courses of HD Ctx without delayed engraftment.

Identification of megakaryocyte precursors in peripheral blood stem cell collections from normal donors.

Platelet engraftment, the time course and magnitude of platelet recovery (PR) post-transplant, is imprecisely defined but is most often reported as the time to transfusion (tx) independence and/or a platelet count > or = 20,000/microl. While correlations between engraftment time for granulocytes (PMN) and the dose of CD34-positive cells per kilogram are established, such associations have not been established for platelet engraftment. The objective of this study was to quantify subpopulations of CD34-positive cells in peripheral blood stem cell (PBSC) collections of normal, colony-stimulating factor-granulocyte) (G-CSF) primed donors that might represent megakaryocyte (MK) precursors, and to determine whether there is a statistical association between the dose transfused and the time course of the recovery. Based on previously published data of the sequential expression of CD34, HLA-DR, and CD61, among others, during MK maturation, a combination of corresponding antibodies for the detection of various antigen coexpressions by flow cytometry fluorescence-activated cell sorting [FACS] was chosen. CD34-positive cells were further subdivided into CD34++ (bright) and + (dim). Ploidy of density-gradient separated cells was examined in subsequent donor samples by FACS. For the entire group of patients, there was no strong correlation between any of the studied subpopulations and time to PR. Only in a selected groups of patients whose platelet counts showed a sustained increase during the first 6 days after engraftment, there was a weak correlation between the time to PR and the quantity of CD34+/+CD61+ (r = -0.57) and CD34++HLA-DR-CD61+ (r = -0.62) cells infused. The magnitude of platelet production in these pt., a product of the peripheral blood platelet count and the patient's blood volume, was correlated with the time to PR (r = -0.73). We conclude from this study that subpopulations within CD34+ cells are making some contribution to PR in allogeneic peripheral blood stem cell transplantation, but the correlations are not sufficiently strong because there are probably too many unpredictable and unknown variables in the allogeneic setting that influence the pattern of engraftment.

Delayed effects of rhG-CSF mobilization treatment and apheresis on circulating CD34+ and CD34+ Thy-1dim CD38- progenitor cells, and lymphoid subsets in normal stem cell donors for allogeneic transplantation.

Allogeneic transplantation of peripheral blood progenitor cells (PBPC) is emerging as a new stem cell transplant modality. Rather than undergoing general anesthesia for bone marrow harvest, normal blood stem cell donors are subjected to rhG-CSF mobilization treatment followed by single or multiple apheresis. Whereas the effects of cytokine treatment and apheresis on stem cell peripheralization and collection have been described, little is known about delayed effects of rhG-CSF treatment and apheresis on a normal hematopoietic system, and there are no long-term data that address safety issues. Ten normal, patient-related donors underwent a 3 or 4 day rhG-CSF (filgrastim) treatment (12 micrograms/kg/day) followed by single or tandem apheresis. We monitored peripheral blood (PB) cellularity including CD34+ and lymphoid subsets at baseline, during cytokine treatment, prior to apheresis, and at days 2, 4, 7, 30 and 100 post-apheresis. The PB progenitor cell concentration peak prior to apheresis was followed by a nadir by day 7 and normalized by day 30, with the exception of the most primitive CD34+ Thy-1dim CD38- progenitor subset that reached a nadir by day 30. Lymphoid subsets such as CD3, 4, 8, suppressor cells (CD3+ 4- 8- TCR+ alpha beta), and B cells (CD19+) showed a similar pattern with a nadir concentration by day 7, followed, except for B cells, by a rebound by day 30 and subnormal counts at day 100. The PB concentrations of hemoglobin and platelets dropped mainly due to the apheresis procedure itself, and normalized by day 30. With cytokine treatment, the PB alkaline phosphatase and lactate dehydrogenase concentrations increased 2.2- and 2.8-fold, respectively, over baseline, and returned to normal range by day 30. Based on the preliminary nature of this study, the clinical relevance of these findings is still unclear.

Allogeneic peripheral blood stem cell transplantation using normal patient-related pediatric donors.

Successful allogeneic peripheral blood progenitor cell (PBPC) transplantation has recently been reported by several transplant centers. This is a first report describing allogeneic PBPC transplantation in five patients using related pediatric donors between the ages of 4 and 13 years. Donors underwent 3 or 4 days of rhG-CSF treatment (6 micrograms/kg q 12 h) for stem cell peripheralization prior to PBPC collection, which was performed by continuous-flow apheresis on day 4 or 5. Venous access was exclusively by ante-cubital veins. A median of 2.2 times (range 1.4-3.6) the donor's total blood volume (TBV) was processed per procedure. In cases where the donor's TBV was < 2 liters, the blood cell separator was primed with human serum albumin (HSA-5%), and anticoagulation was performed using a combination of heparin (pre-apheresis bolus + continuous infusion (CI)) and/or ACD-A (CI at a reduced rate). The median number of CD34+ cells collected per kg of donor body weight (b.w.) and per liter of donor blood processed during each procedure was 128 x 10(4) (range 58 x 10(4)-314 x 10(4)). Between one and two aphereses were sufficient to collect a safe CD34+ cell engraftment dose of 3 or 4 x 10(6)/kg of recipient b.w. Two PBPC recipients were parents, and three were siblings. After freezing and thawing, the median number of CD34+ cells per kg of recipient b.w. thawed and transfused was 8.5 x 10(6) (range 3.2 x 10(6)-9.7 x 10(6)). The time to PMN > 1000/microliters was between 10 and 16 days (four out of five evaluable patients), and platelets > 20000/microliters were reached between day 13 and 14 post-transplantation (three out of five evaluable patients). Two out of three evaluable patients developed grades one and three acute GVHD, and one out of three developed chronic GVHD. Two patients died of sepsis and VOD at day 10 and 19, respectively. Two adult patients are alive and in cytogenetic and molecular remission of CML at +339 and +227 days post-allotransplantation. One 3-year-old girl with hemophagocytic lymphohistiocytosis is in remission at +304 days post-transplantation. Using pediatric donors for allogeneic PBPC transplantation appears to be safe, yields a sufficient amount of progenitors for prompt engraftment, and results in clinical outcome similar to adult PBPC allotransplantation.

Integration of biological, procedural, apheresis principles of peripheral blood stem cell transplantation programs.

Collection and use of peripheral blood stem cells have rapidly replaced harvesting of pelvic bone marrow for transplant protocols. The mobilization of progenitor populations into the peripheral blood by chemotherapy and/or cytokine stimulation of marrow hematopoietic production has made it possible, in general, to collect larger quantities of progenitor populations than obtained in a single harvest of marrow. Technological advances through flow cytometry and generation of monoclonal antibodies to identify CD34 antigen expression on cells has provided a rapid means of assessing leukapheresis products for the presence of progenitor populations and has largely replaced the laborious 14 day culture assays' to measure colony forming units. Unlike apheresis platelet collection, where the yields are predictable through integration of donor biological variability, total volume of blood processed, and machine efficiency, CD34+ cell yields are not predictable. This has led to great diversity in stem cell collection procedures. Analyses of the same variables used to predict platelet yields, if applied to CD34+ cell collection, might lead to useful algorithms for development of standardized guidelines for stem cell collection.