UMLS:C1140680 - FACTA Search

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Query: UMLS:C1140680 (ovarian cancer)
28,141 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The standard approach for epithelial ovarian cancer has been maximum cytoreductive surgery followed by combination therapy. Several prospective control studies individually failed to demonstrate improved survival advantage for the Adriamycin containing combination compare with cisplatin plus cyclophosphamide. The two drug combination of carboplatin plus cyclophosphamide will be thought to become the treatment of choice, because it is equally effective as and less toxic than a regimen of cisplatin plus cyclophosphamide. Clinical trials are also in progress with more dose-intense regimens based on considerable retrospective evidence that survival is correlated with the dose intensity of platinum compounds. Currently, high dose carboplatin plus Gm-CSF, two-drug combination of carboplatin and cisplatin and super high dose carboplatin combined with autologous bone marrow transplantation are undergoing clinical trials. Taxol and taxotere, most important cancer drugs after emergence of cisplatin compound, has been shown to have clinical activity in drug resistant ovarian cancer patients. Majority of patients even with advanced germ cell tumors of the ovary is now cured because of the development of effective platinum-based combination chemotherapy of PVB or BEP.
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PMID:[Recent advances in ovarian cancer chemotherapy]. 138 36

The use of intravenous melphalan at higher doses is limited by severe myelosuppression. It was postulated that GM-CSF would permit the use of higher dose melphalan with only moderate myelosuppression easily manageable in an outpatient setting. Therefore, a phase I study of intravenous melphalan utilizing GM-CSF (recombinant granulocyte-macrophage colony-stimulating factor) support was initiated. Intravenous melphalan at doses of 15-45 mg/m2 was administered every 28 days. GM-CSF was utilized at doses of 10-20 micrograms/kg/day subcutaneously Days 2-21 on a 28-day cycle. Twenty-five patients received 53 courses of therapy. The dose-limiting toxicities were severe or life-threatening granulocytopenia and thrombocytopenia. Utilizing 20 micrograms/kg/day GM-CSF, the maximum tolerated dose (MTD) of melphalan is 30 mg/m2 and, with 10 mg/kg/day GM-CSF, the maximum tolerated melphalan dose is only 20 mg/m2. One patient with ovarian cancer achieved a partial response. Because the reported MTD of intravenous melphalan without GM-CSF is 30 mg/m2, GM-CSF has not allowed sufficient escalation of the intravenous melphalan dose for routine outpatient use.
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PMID:SWOG 8825: melphalan GM-CSF: a phase I study. 173 Apr 28

Recombinant human granulocyte-macrophage colony-stimulating factor (rHuGM-CSF) may reduce myelosuppression and, thus, allow dose escalation of certain chemotherapeutic agents. We conducted two sequential phase I trials of escalating doses of carboplatin and a fixed dose and schedule of rHuGM-CSF in ovarian cancer patients who had not previously had chemotherapy, i.e., chemotherapy-naive patients. In the first trial, patients were assigned to regimens of increasing dose levels of carboplatin (starting at 400 mg/m2) and fixed doses and schedules of cyclophosphamide (600 mg/m2) and rHuGM-CSF (10 micrograms/kg given subcutaneously once daily on days 2-11). Chemotherapy was given every 3 weeks (regimen A). In the subsequent trial, the design was the same except that cyclophosphamide was omitted (regimen B). Fifteen patients received regimen A, and seven patients received regimen B. In regimen A, all three patients treated at the first dose level tolerated five cycles at full doses. Hematologic toxicity was dose limiting at the 600-mg/m2 dose level. When 500 mg/m2 carboplatin was given, six of eight patients tolerated three or four cycles at full doses before requiring dose reductions or treatment delays. In regimen B, doses could not be escalated above the first dose level (600 mg/m2) because of severe hematological toxicity. Nonhematological toxicity was tolerable and managed with acetaminophen, antihistamines, and/or nonsteroidal, anti-inflammatory medication. Compliance was excellent. We conclude that (a) rHuGM-CSF can be given safely and reliably to chemotherapy-naive ovarian cancer patients receiving these treatment regimens, (b) early and severe thrombocytopenia was a major problem with or without cyclophosphamide with doses of carboplatin at or above 600 mg/m2, and (c) 500 mg/m2 carboplatin administered every 3 weeks is the highest dose in regimen A that can be given safely in the outpatient setting.
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PMID:Two phase I studies of carboplatin dose escalation in chemotherapy-naive ovarian cancer patients supported with granulocyte-macrophage colony-stimulating factor. 177 May 54

The combined use of rG-CSF in ovarian cancer chemotherapy prevents a decrease in the number of neutrophils and promotes their recovery. rG-CSF also protects against infections, enhancing chemotherapeutic effectiveness. It is reported that neutrophils produced by rG-CSF not only increase in number but also in function. Some clinicians, however, doubt whether neutrophils mobilized or produced by rG-CSF have sufficient ability to function practically in clinical cases. We therefore examined, by means of flow cytometry, the neutrophils' phagocytosis and bactericidal ability and we found both normal. No morphological abnormalities were seen in these neutrophils. In our observations, moreover, no effect was exerted on the leukocyte-membrane antigen. It was concluded that (a) rG-CSF was very effective in protecting against the diminution of neutrophils by chemotherapy and (b) in promoting their recovery, and (c) also the function, morphology and leukocyte-membrane antigen of these neutrophils were normal.
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PMID:[Effect of rG-CSF on the morphology and function of neutrophils in ovarian cancer chemotherapy]. 750 28

Human recombinant colony-stimulating factors may be used to treat or prevent neutropenia caused by marrow toxic chemotherapeutic agents administered to patients with cancer. Despite their common clinical use, little is known about the potential adverse effects that these cytokines may have on the growth of malignant cells. Indeed, several in vitro reports have indicated that colony-stimulating factors may act as stimulating growth factors in some human malignancies. To evaluate these effects in ovarian cancer, we investigated the possible growth effects of granulocyte colony-stimulating factor (G-CSF/Filgrastim) and granulocyte-macrophage colony-stimulating factors (GM-CSF/Sargramostim) on four established ovarian cancer cell lines, as well as five primary ovarian cancer cultures over a wide range of pharmacologic doses. Cell viability was measured by an ATP bioluminescence assay and expressed as a percentage of untreated control cultures. G-CSF showed no growth-stimulating effects in any of the four established cell lines tested. In the OVCAR-3 cell line, a decrease in growth (> 10%) was seen at 10, 100, and 1000 ng/ml after 5 days of continuous treatment. In the same cell line, GM-CSF caused an increase (> 10%) in growth at the same doses. However, these changes did not demonstrate statistical significance in a dose-dependent fashion. In the five primary cultures treated with G-CSF, only one demonstrated statistically significant increases in growth in a dose-dependent manner. GM-CSF treatment had no significant growth alterations in these same five primary cultures. These results would suggest that colony-stimulating factors may act as growth factors in some but not all ovarian cancer cells. Further investigations into the receptor status of ovarian cancer cells for these cytokines are underway to clarify this issue.
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PMID:In vitro growth effects of colony-stimulating factors in ovarian cancer. 751 21

We tested in vitro the effect of recombinant human erythropoietin (rhEPO) plus recombinant human G-CSF (rhG-CSF) on purified human CD34+ haemopoietic progenitors (HP) and in vivo in patients who had undergone anti-cancer chemotherapy for advanced ovarian cancer. In this preliminary experience we found that, in vitro, rhEPO potentiates the effect of rhG-CSF on HP growth and differentiation toward the granulocyte-macrophage lineage. rhEPO plus rhG-CSF produced in vitro a proliferative stimulus of HP which represents 26% of the maximum stimulation obtained using IL-1, IL-3, IL-6, G-CSF, GM-CSF and stem cell factor in combination. In the patients treated with rhEPO plus rhG-CSF after chemotherapy, we observed a favourable trend for platelet and neutrophil recoveries compared with a control group treated with rhG-CSF alone and a significantly higher haematocrit nadir was observed in the rhEPO plus rhG-CSF series. In the patients treated with rhEPO plus rhG-CSF we observed a significant increase of circulating colony-forming unit granulocyte-macrophage (CFU-GM) and burst forming unit-erythroid (BFU-e) compared with the rhG-CSF series. Our results, in vitro and in vivo, encourage the in vivo use of rhEPO plus rhG-CSF to improve blood cell recoveries of patients who have undergone conventional or high-dose chemotherapy. Moreover, rhEPO plus rhG-CSF was demonstrated to be a good HP mobilising treatment for blood stem cell collection after chemotherapy.
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PMID:In vitro and in vivo effects of recombinant human erythropoietin plus recombinant human G-CSF on human haemopoietic progenitor cells. 752 5

In patients with extensive chemotherapy, G-CSF abrogated leukopenia following administration of cytotoxic agents. Six women with ovarian cancer and chemotherapy-induced leukopenia received 300 micrograms Filgrastrim (r-metHuG-CSF, Neupogen 30; AMGEN, Germany) daily for 10 days. Leukocytes and lymphocyte subsets of peripheral blood were determined before, throughout and after subcutaneous injections of G-CSF by flow cytometry using monoclonal antibodies to CD3, CD4, CD8, CD14, CD16/56, CD19 and CD45. It could be observed that not only neutrophils (23 fold) but also lymphocytes (6 fold) and monocytes (10 fold) showed a dramatic increase in cell counts throughout and after G-CSF administration. This is in contrast to previous reports, where only effects on neutrophils were described. In spite of the increase in lymphocytes the relative percentage of CD3+, CD19+, CD3-CD16/CD56+, CD3+, CD8+ and CD3+ CD4+ lymphocyte subsets did not change throughout and after therapy, except for an increased expression of HLA-DR on CD3+ lymphocytes.
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PMID:[Effect of granulocyte colony stimulating factor (G-CSF) on peripheral blood leukocytes and lymphocytes in patients with chemotherapy-induced leukopenia]. 753 60

Peripheral blood progenitor cells (PBPC) can be mobilized using cytotoxic chemotherapy and cytokines. There is a substantial variability in the yield of hematopoietic progenitor cells between patients. We were looking for predictive parameters indicating a patient's response to a given mobilization regimen. Multiparameter flow-cytometry analysis and clonogenic assays were used to examine the hematopoietic progenitor cells in bone marrow (BM) and peripheral blood (PB) before filgrastim (R-metHuG-CSF; Amgen, Thousand Oaks, CA)-supported chemotherapy and in PB and leukapheresis products (LPs) in the recovery phase. Fifteen patients (four with high-grade non-Hodgkin's lymphoma [NHL], two with low-grade NHL, two with Hodgkin's disease, two with multiple myeloma, three with breast cancer, one with ovarian cancer, and one with germ cell tumor) were included in this study. The comparison of immunofluorescence plots showed a homogenous population of strongly CD34+ cells in steady-state and mobilized PB whereas in steady-state BM, the CD34+ cells ranged from strongly positive with continuous transition to the CD34- population. Consistent with the similarity in CD34 antigen expression, a correlation analysis showed steady-state PB CD34+ cells (r = .81, P < .001) and colony-forming cells (CFCs; r = .69, P < .01) to be a measure of a patient's mobilizable CD34+ cell pool. Individual estimates of progenitor cell yields could be calculated. With a probability of 95%, eg, 0.4 steady-state PB CD34+ cells x 10(6)/L allowed to collect in six LPs 2.5 x 10(6) CD34+ cells/kg, the reported threshold-dose of progenitor cells required for rapid and sustained engraftment after high-dose therapy. For the total steady-state BM CD34+ cell population, a weak correlation (r = .57, P < .05) with the mobilized CD34+ cells only became apparent when an outlier was removed from the analysis. Neither the CD34+ immunologic subgroups defined by the coexpression of the myeloid lineage-associated antigens CD33 or CD45-RA or the phenotypically primitive CD34+/HLA-DR- subset nor the BM CFC count had a predictive value for the mobilization outcome. This may be caused by the additional presence of maturing progenitor cells in BM, which express lower levels of the CD34 antigen and do not circulate. Our results permit us to recognize patients who are at risk to collect low numbers of progenitor cells and those who are likely to achieve sufficient or high progenitor cell yields even before mobilization chemotherapy is administered.
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PMID:Peripheral blood progenitor cell (PBPC) counts during steady-state hematopoiesis allow to estimate the yield of mobilized PBPC after filgrastim (R-metHuG-CSF)-supported cytotoxic chemotherapy. 860 80

This retrospective study was undertaken to investigate whether paclitaxel was associated with cumulative bone marrow toxicity in patients undergoing salvage chemotherapy for refractory ovarian cancer. Seventy-seven patients were treated with paclitaxel 135 mg/m2 every 21 days, with granulocyte-colony-stimulating factor (G-CSF) support as necessary according to standard criteria. The mean white blood cell nadir was significantly higher and the incidence of severe leukopenia (Gynecologic Oncology Group grade 3-4) significantly lower after ten cycles than after the first cycle for the entire study population (3.4 vs. 1.6 x 10(3)/mm3 and 29 vs. 77%, respectively) and the patients who received G-CSF (3.5 vs. 1.4 x 10(3)/mm3 and 33 vs. 89%, respectively), but did not differ significantly for the patients who did not require G-CSF (2.9 vs. 2.5 x 10(3)/mm3 and 40 vs. 59%, respectively). The mean hematocrit and platelet nadirs, as well as the incidence of severe anemia and thrombocytopenia, did not differ significantly after ten cycles from those after the first cycle for the entire study population and both subgroups. Thirty-two (42%) patients received G-CSF, each initiated within four cycles. The indications for initiating G-CSF support were febrile leukopenia (53%) and treatment delay (47%). The average duration of G-CSF support was 4.6 days, and did not increase significantly as the number of paclitaxel cycles increased. We conclude that paclitaxel was not associated with cumulative bone marrow toxicity in patients undergoing salvage chemotherapy for refractory ovarian cancer.
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PMID:Absence of cumulative bone marrow suppression in heavily pretreated ovarian cancer patients undergoing salvage chemotherapy with paclitaxel. 754 68

We investigated the serum concentrations of a variety of cytokines [granulocyte-macrophage-colony-stimulating factor (GM-CSF), granulocyte colony stimulating factor (G-CSF), interleukin (IL) 1 alpha, IL-3, IL-6, IL-8, erythropoietin, tumor necrosis factor alpha, gamma-interferon in 10 patients with advanced ovarian cancer undergoing autologous peripheral blood stem cell (PBSC) harvesting followed by treatment with high-dose cisplatin, etoposide, and carboplatin and PBSC transplantation (chemotherapy was administered on days 1 through 3, PBSCT on day 6). Preliminary observations on cytokine serum levels were performed for 4 patients; on this basis, the kinetics of cytokines was then investigated in greater detail at closely sequential times in 6 further patients. We observed a consistent pattern of sequential GM-CSF, G-CSF, and IL-8 release after chemotherapy/PBSCT in all 10 cases, including the 6 patients monitored in detail: (a) at days 5-10 a GM-CSF peak; (b) at days 12-14 a pronounced release of both G-CSF and IL-8, which always preceded granulocyte recovery by approximately 7 days. At days 17-23, a second GM-CSF peak was monitored in 5 of the 6 patients analyzed in detail, as well as in the other 4 cases. Particularly relevant are the observations that: (a) the peak of G-CSF serum concentration and neutrophil number in the recovery phase are strikingly and directly correlated, thus indicating a key role for G-CSF in granulocyte rescue; (b) the time courses of G-CSF and IL-8 levels are strictly parallel, thereby suggesting a coordinate stimulus for production of granulocytes, mediated by G-CSF, and their activation/migration capacity, mediated by IL-8. Results were essentially negative for IL-3, tumor necrosis factor alpha, and gamma-interferon concentrations (except in one case for each cytokine). An early peak of IL-1 alpha was observed in all 3 analyzed patients, while an IL-6 peak was monitored at days 13-15 in all 4 patients analyzed in detail. The present results indicate a sequential coordinate pattern of cytokine release after ablative therapy and PBSCT and shed light on the mechanisms mediating the recovery of granulocytes, and more generally of hematopoiesis, after stem cell transplantation. Furthermore, these studies may contribute to the design of improved protocols for cytokine administration following myelosuppressive anticancer therapy, as well as to the prediction of granulocytic response.
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PMID:Autologous stem cell transplantation: sequential production of hematopoietic cytokines underlying granulocyte recovery. 768 Feb 83

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