Reduction of oral mucositis by filgrastim (r-metHuG-CSF) in patients receiving chemotherapy.

Mucositis, the inflammation and necrosis of mucosal membranes, is a serious and debilitating consequence of many cancer therapies. We were interested in the potential role of filgrastim (recombinant methionyl human granulocyte colony-stimulating factor, r-metHuG-CSF) in the reduction of mucositis. Patients with newly diagnosed small-cell lung cancer (SCLC) were treated with CAE chemotherapy (cyclophosphamide, doxorubicin, and etoposide) and placebo or filgrastim. If patients had an episode of febrile neutropenia, they received unblinded filgrastim in subsequent CAE cycles. Oral mucositis was considered to have occurred if a patient reported any clinical sign or symptom of oral mucositis with or without oral candidiasis. Oral mucositis was analyzed using the unadjusted chi-square test, and time to first episode of mucositis was analyzed using the stratified log-rank test as well as the Cox proportional hazards regression model. During cycle 1, placebo-treated patients had more episodes of mucositis (47%) compared with those patients randomized to filgrastim (28%). Across all cycles of treatment, 70% of placebo-treated patients experienced mucositis, compared with 53% of patients randomized to filgrastim. A significant reduction in the incidence of chemotherapy-related oral mucositis occurred across multiple cycles of treatment in patients treated with filgrastim.

High-dose cyclophosphamide, carmustine, and etoposide with autologous transplantation in Hodgkin's disease: a prognostic model for treatment outcomes.

PURPOSE: To identify clinical factors predictive of treatment outcome after high-dose chemotherapy (HDC) for Hodgkin's disease and to develop a prognostic model for progression-free and overall survival. PATIENTS AND METHODS: 102 patients with relapsed or refractory Hodgkin's disease were treated with high-dose cyclophosphamide, carmustine, and etoposide and autologous marrow and/or peripheral blood progenitor cell support. Median follow-up of survivors is 4.1 years (1.8-7.5 years). Factors potentially important for treatment outcome were examined in univariate analysis, and Cox regression with forward selection was performed. A prognostic model was developed. RESULTS: Poorer progression-free and overall survival were associated with nodular sclerosis histology, abnormal performance status, progressive disease at HDC, more than one extranodal site of disease, and shorter time from initial diagnosis to HDC. These factors and the presence of B symptoms at relapse also predicted for decreased overall survival. Progressive disease immediately prior to HDC, more than one extranodal disease site, and abnormal performance status retained significance for both progression-free and overall survival in multivariate analysis. Progression-free and overall survival are 42% (95% confidence interval, CI, 34 to 53) and 65% (95% CI 54 to 73) at three years. A model based on number of risk factors present divides patients into low, intermediate, and high risk groups with three-year actuarial survival of 82%, 56%, and 19% respectively. Treatment outcome for patients treated with HDC at first chemotherapy relapse was not significantly different from that of the group overall (p > 0.3). CONCLUSIONS: Asymptomatic patients with Hodgkin's disease involving at most one extranodal site whose disease is controlled by conventional dose chemotherapy or radiation therapy at the time of HDC have good outcomes after this therapy. Presence of increasing numbers of risk factors are associated with poorer outcomes. Results of HDC compare favorably to those of standard dose salvage therapy. These data can be used to estimate likely outcomes in patients undergoing HDC for Hodgkin's disease, to identify potential candidates for innovative therapies, and to evaluate strategies for the optimal use of HDC in Hodgkin's disease.

Phase I study of high-dose ifosfamide, carboplatin and etoposide with autologous hematopoietic stem cell support.

More effective high-dose combination regimens are needed which have broad cytotoxic activity, steep dose-response relations and non-overlapping non-hematologic toxicities (to allow administration of full doses of each agent). This study was designed to define the dose-limiting toxicities and maximum tolerated doses of ifosfamide, carboplatin and etoposide (ICE) with hematopoietic stem cell support. Ifosfamide and carboplatin were initially fixed at 75% and 80% of the single agent maximum tolerated doses, respectively, and etoposide added to the combination. After the dose-limiting toxicity of etoposide was reached, its dose was fixed and ifosfamide and carboplatin were individually dose escalated as tolerated. All agents were given by 96h continuous infusion (days -7 to -3). Autologous marrow, with or without peripheral blood progenitor cells, was reinfused on day 0. Forty eight adults with advanced malignancies were enrolled in cohorts of three to five patients. At the maximum tolerated doses of ifosfamide 16 g/m2, carboplatin 1.8 g/m2 and etoposide 1.2 g/m2, renal toxicity precluded further dose escalation. Two patients died of organ (renal, CNS) toxicity (4%). Renal toxicity was particularly prominent in patients with prior cisplatin exposure. An early chemotherapy-stopping rule was developed, supported by pharmacologic analysis, which resulted in immediate discontinuation of ifosfamide and carboplatin if the serum creatinine, monitored twice daily during chemotherapy, exceeded 1.5 mg/dl and was > 0.5 mg/dl above baseline. High-dose ICE is well tolerated if serum creatinines are carefully monitored during chemotherapy administration. The early chemotherapy-stopping rule may enhance safety of the regimen but requires validation by addition correlation with pharmacokinetic data for each of the chemotherapeutic agents.(ABSTRACT TRUNCATED AT 250 WORDS)

High-dose ifosfamide/carboplatin/etoposide with autologous hematopoietic stem cell support: safety and future directions.

Agents with broad cytotoxic activity, steep linear log dose-response relationships, relative non-cross-resistance, and nonoverlapping nonhematologic toxicities can be combined to create new high-dose combination regimens. We have previously reported phase I dose-escalation studies of ifosfamide, carboplatin, and the combination of the two. Etoposide has reported synergism with these alkylators and produces mucositis as its dose-limiting toxicity. The current study was designed to define the maximum tolerated doses of high-dose combination ifosfamide/carboplatin/etoposide (ICE), with stem cell support for amelioration of hematologic toxicity. Forty-eight adults with advanced malignancy received ICE chemotherapy by 96-hour continuous infusion. Initially, etoposide was added to fixed-dose ifosfamide and carboplatin, then the maximum tolerated dose of etoposide was fixed while doses of the alkylators were individually escalated. Autologous marrow, with or without peripheral blood progenitor cells, was reinfused 3 days after completing chemotherapy. The maximum tolerated doses of ifosfamide, carboplatin, and etoposide were identified as 16 g/m2, 1.8 g/m2, and 1.2 g/m2, respectively. Mortality was 4%. Patients who had prior cisplatin exposure were at increased risk for renal toxicity. If serum creatinine levels (monitored twice daily) rose sharply during chemotherapy, ifosfamide and carboplatin were immediately stopped. Severe multiorgan toxicity developed in the few patients who experienced early renal toxicity. Early stopping enhanced the safety of this regimen. Interpatient differences in chemotherapy drug metabolism or reduced renal clearance may predispose individuals to severe toxicity by increasing overall drug exposure. It was concluded that the ICE regimen is well tolerated and warrants further exploration as treatment of patients with small cell lung cancer, ovarian and germ cell carcinomas, and lymphomas in phase II trials.

Recombinant human erythropoietin for the treatment of the anaemia associated with autologous bone marrow transplantation.

Patients with solid tumours undergoing high-dose chemotherapy with autologous bone marrow transplantation use an average of 10 units of packed red blood cells (PRBC) while awaiting haemopoietic reconstitution. They are also known to have inappropriately low endogenous erythropoietin levels for their degree of anaemia. This pilot study was designed to determine the effects of recombinant human erythropoietin (rHuEPO) on erythroid recovery and PRBC transfusion requirements. Ten patients received high-dose chemotherapy (days -7 to -3), bone marrow reinfusion (day 0), and then rHuEPO (day 1 onward). RHuEPO (200 units/kg intravenous bolus daily), along with iron supplementation, was administered for 28 d or until a haematocrit (Hct) of 35% (independent of transfusions) was reached, whichever occurred first. PRBCs were routinely given for Hct < or = 25% and platelets for counts < 20,000/microliters. Eight (80%) patients developed a brisk reticulocytosis (median peak reticulocyte count 0.32 x 10(9)/l) and a haematocrit > or = 30% independent of red blood cell transfusions within 32 d of receiving marrow, as compared to 20/37 (54%) similarly treated controls. An unexpected finding was the more rapid engraftment in myeloid and platelet lineages in a subset of rHuEPO-treated patients. Quick return of red blood cells (17 v 33 d) (P = 0.0001), platelets (14 v 19 d) (P = 0.04), and neutrophils (13 v 25 d) (P = 0.01) (with circulating myeloblasts and early myeloid forms) characterized recovery from an ifosfamide-based intensification with rHuEPO support. Similar trilineage enhancement of haemopoiesis did not occur with the possibly more myeloablative cyclophosphamide-based regimens. Despite the enhancement by rHuEPO on reticulocytosis, there was no significant decrease in PRBC transfusion requirements. RHuEPO proved to be a well-tolerated agent in enhancing reticulocytosis following high-dose chemotherapy. Further study to elucidate the activity of erythropoietin on both erythroid and non-erythroid growth and maturation appears warranted.

Double dose-intensive chemotherapy with autologous marrow and peripheral-blood progenitor-cell support for metastatic breast cancer: a feasibility study.

PURPOSE: Twenty-seven percent of responding metastatic breast cancer patients remain progression-free a median 29 months following one intensification course of cyclophosphamide (6,000 mg/m2), thiotepa (500 mg/m2), and carboplatin (800 mg/m2) (CTCb) with autologous bone marrow transplantation (ABMT). European investigators report high complete response (CR) rates with melphalan for breast cancer. This trial studied the feasibility of two tandem high-dose intensification therapies in an attempt to optimize disease response and duration. PATIENTS AND METHODS: Women with at least partial responses (PRs) to induction therapy received melphalan (140 to 180 mg/m2), followed 24 hours later by chemotherapy and granulocyte colony-stimulating factor (G-CSF)-mobilized peripheral-blood progenitor cells (PBPCs) and subsequent G-CSF until WBC recovery. The women were monitored as outpatients. After recovery, patients were hospitalized for CTCb with marrow, PBPC, and G-CSF support. RESULTS: Twenty women were assessable. Fourteen (70%) required admission for fever (10% infection) or mucositis (35%) after melphalan (median stay, 5 days). Median days of absolute neutrophil count (ANC) less than 500/microL and platelet count less than 20,000/microL were 6 and 5.5, respectively. Patients received CTCb 25 days after starting melphalan and had a hospital stay of 25 days. After CTCb, median days of ANC less than 500/microL and platelet count less than 20,000/microL were 11.5 and 24, respectively. Grade 3 toxicities included venoocclusive disease (VOD) (10%), mucositis (45%), and infection (20%). Toxicities were reversible without mortality. CONCLUSION: With mobilized PBPCs and growth factors, double dose-intensive chemotherapy is feasible with acceptable toxicity. When compared with trials using marrow alone, these supportive adjuncts decrease sepsis and organ toxicity. The concepts of dose and dose-intensity may now be more effectively and safely studied in chemosensitive tumors, including breast cancer.

High-dose cyclophosphamide, thiotepa, and carboplatin with autologous marrow support in women with measurable advanced breast cancer responding to standard-dose therapy: analysis by age.

The analysis was undertaken to determine if the time to progression and survival for women with breast cancer treated with high-dose chemotherapy after a conventional-dose induction therapy differs significantly for women younger and older than 40 years of age. All patients treated in phase II or III protocols of high-dose chemotherapy for breast cancer are included in this analysis. Women were treated on one of six protocols: four sequential phase II protocols for metastatic breast cancer involving cyclophosphamide at a dose of 6000 mg/m2, thiotepa at 500 mg/m2, and carboplatin at 800 mg/m2 (CTCb) chemotherapy; one phase II study of CTCb chemotherapy for stage III or inflammatory breast cancer; and a Cancer and Leukemia Group B phase III study of cyclophosphamide, carmustine, and cisplatin for women with more than 10 involved lymph nodes after primary therapy. Eligibility criteria for the patients with metastatic disease included histologically documented breast cancer, at least a partial response to conventional dose therapy, no prior pelvic radiotherapy, cumulative doxorubicin of less than 500 mg/m2, and physiologic age of 18-55 years. Patients with inadequate renal, hepatic, pulmonary, and cardiac function or tumor involvement of marrow or central nervous system were excluded. Of 99 registered patients, three (3%) died of toxicity. There were no toxic deaths in protocols for stage II and III disease, and to date none of these patients have relapsed. Thus, there are no differences by age for these studies.(ABSTRACT TRUNCATED AT 250 WORDS)

Phase IV trial of daily oral etoposide in the treatment of advanced soft-tissue sarcoma.

Intravenous-bolus etoposide has modest activity in sarcomas when given daily for 3-5 days. Low frequent doses theoretically inhibit topoisomerase II activity over a longer duration and have been reported to have increased activity in small-cell lung cancer. A phase I trial of oral etoposide resulted in partial responses in two patients with soft-tissue sarcomas. To estimate more accurately the response rate for daily oral etoposide in sarcomas, we treated 25 patients with 50 mg/m2 per day by mouth for 21 days every 4 weeks. Treatment-related toxicity included > or = grade 2 neutropenia in 6 of the 25 patients and thrombocytopenia in 3. One brief partial response was observed (4%; 95% confidence interval for true response rate, 0-11%). Disease stabilized in five patients for periods ranging from 3 to 18 months. At this dose and on this schedule, daily oral etoposide appears to have little activity against soft-tissue sarcomas.

High-dose combined alkylating agent therapy with autologous stem cell support and chest radiotherapy for limited small-cell lung cancer.

Although initially responsive to chemotherapy, patients with small-cell lung cancer (SCLC) almost invariably suffer relapse. Recurrent SCLC responds poorly to treatment. Previous trials using high-dose chemotherapy with bone marrow support have commonly used single agents or combined alkylating agents without chest radiotherapy. Among patients with limited disease receiving dose-intensive chemotherapy, locoregional relapse remained the predominant site of first failure. Recent phase II trials using intensive locoregional therapy (aggressive concurrent chemoradiotherapy) have resulted in promising survival. Our trial used combined alkylating agents with autologous marrow support and chest radiotherapy in patients with limited disease in response to conventional-dose induction chemotherapy. Of 19 patients treated, the actuarial survival was 56% with a median follow-up of 18 months following high-dose therapy. Patients who achieved complete or near-complete response prior to high-dose therapy enjoyed the best prognosis. Continued evaluation of intensive systemic and local therapy for SCLC is indicated.

Intensive combined modality therapy for limited-stage small-cell lung cancer.

BACKGROUND: Conventional-dose chemotherapy for small-cell lung cancer has resulted in high response rates but rarely in a cure. The addition of thoracic radiotherapy (chemoradiotherapy) has improved survival for patients having limited disease, resulting in a median survival of 14-18 months. Previous trials evaluating high-dose chemotherapy and autologous bone marrow transplantation have demonstrated enhanced complete response rates without documenting overall survival benefit. PURPOSE: The purpose of this phase II trial was to determine the disease-free and overall survival, toxic effects, and relapse patterns in patients with limited small-cell lung cancer who were in partial or complete response to first-line conventional-dose chemotherapy and then received intensive systemic combined modality therapy. METHODS: Adults with stage III small-cell lung cancer who had achieved at least a partial response to conventional-dose induction chemotherapy were treated with high-dose cyclophosphamide, cisplatin, and carmustine combined with autologous bone marrow transplantation. Cumulative doses of the three drugs were 5625, 165, and 480 mg/m2, respectively. After recovery, patients received thoracic radiotherapy (50-60 Gy in 25-30 fractions over 5-6 weeks) and cranial radiotherapy (30 Gy in 15 fractions during 3 weeks). RESULTS: Of 19 patients in the study, six had achieved complete response, eight had a greater than 90% reduction in tumor size, and five had a 50%-90% reduction in tumor size. After high-dose therapy, 15 of the 19 were in complete response. Overall, median time to treatment failure after high-dose therapy was 12 months. Overall survival was 73% (95% confidence interval [CI] = 42%-89%) at 1 year and 53% (95% CI = 22%-77%) at 2 years. Of the 14 patients in or near complete response before high-dose therapy, 10 remain disease free with no further chemotherapy a median of 15 (4-69+) months after therapy. Actuarial 2-year disease-free survival is 57% (95% CI = 20%-82%). One patient died of Candida sepsis. Morbidity was low, and most patients returned to full-time work. With the exception of herpes zoster, there were no complications more than 3 months after high-dose therapy. CONCLUSIONS: The majority of the patients in this study are experiencing prolonged and unmaintained disease-free survival. Our findings suggest that patients in or near complete response before high-dose therapy have the most favorable prognosis. IMPLICATIONS: A randomized comparison between this approach and conventional-dose therapy is planned to define the utility of dose intensification with autologous bone marrow transplantation in the treatment of patients with limited-stage small-cell lung cancer who are in or near complete response.

The use of G-CSF or GM-CSF mobilized peripheral blood progenitor cells (PBPC) alone or to augment marrow as hematologic support of single or multiple cycle high-dose chemotherapy.

High dose chemotherapy with autologous bone marrow support (ABMT) can achieve prolonged relapse-free survival in relapsed lymphomas, leukemias, and certain solid tumors. The principal morbidity and mortality relate to the infectious complications that occur during the 3-4 week aplasia until the marrow autograft recovers. Progenitor cells can be mobilized into the peripheral blood compartment by hematopoietic growth factors, used alone or after chemotherapy. We describe four trials using cytokine-mobilized peripheral blood progenitor cells (PBPC). In the first trial, PBPC collected after GM-CSF administration were used to augment marrow. Reconstitution of trilineage marrow function occurred promptly, resulting in short hospital stays and fewer platelet transfusions. In a second study, GM-CSF/chemotherapy-mobilized PBPC were used as the sole hematopoietic support during high dose chemotherapy. Granulocyte and platelet reconstitution was rapid. Time to hematopoietic recovery, transfusion requirements, and duration of hospital stay were all significantly improved for the patients receiving PBPC compared with similar patients receiving marrow alone. While most patients experienced prompt hematopoietic recovery they showed sluggish platelet engraftment. The next two trials built on the observation that a few PBPC alone could support both granulocyte and platelet recovery and were designed to test the feasibility of sequential high-dose therapies. In one trial, PBPC given with and without marrow made it possible to deliver two sequential cycles of high-dose therapy. The second trial utilized PBPC plus cytokines to deliver four cycles of dose-intensive chemotherapy at doses that could not be given with cytokine support alone.(ABSTRACT TRUNCATED AT 250 WORDS)

Mobilization of peripheral blood progenitor cells by chemotherapy and granulocyte-macrophage colony-stimulating factor for hematologic support after high-dose intensification for breast cancer.

High-dose therapy with autologous marrow support results in durable complete remissions in selected patients with relapsed lymphoma and leukemia who cannot be cured with conventional dose therapy. However, substantial morbidity and mortality result from the 3- to 6-week period of marrow aplasia until the reinfused marrow recovers adequate hematopoietic function. Hematopoietic growth factors, particularly used after chemotherapy, can increase the number of peripheral blood progenitor cells (PBPCs) present in systemic circulation. The reinfusion of PBPCs with marrow has recently been reported to reduce the time to recovery of adequate marrow function. This study was designed to determine whether granulocyte-macrophage colony-stimulating factor (GM-CSF)-mobilized PBPCs alone (without marrow) would result in rapid and reliable hematopoietic reconstitution. Sixteen patients with metastatic breast cancer were treated with four cycles of doxorubicin, 5-fluorouracil, and methotrexate (AFM induction). Patients responding after the first two cycles were administered GM-CSF after the third and fourth cycles to recruit PBPCs for collection by two leukapheresis per cycle. These PBPCs were reinfused as the sole source of hematopoietic support after high doses of cyclophosphamide, thiotepa, and carboplatin. No marrow or hematopoietic cytokines were used after progenitor cell reinfusion. Granulocytes greater than or equal to 500/microL was observed on a median of day 14 (range, 8 to 57). Transfusion independence of platelets greater than or equal to 20,000/microL occurred on a median day of 12 (range, 8 to 134). However, three patients required the use of a reserve marrow for slow platelet engraftment. In retrospect, these patients were characterized by poor baseline bone marrow cellularity and poor platelet recovery after AFM induction therapy. When compared with 29 historical control patients who had received the same high-dose intensification chemotherapy using autologous marrow support, time to engraftment, antibiotic days, transfusion requirements, and lengths of hospital stay were all significantly improved for the patients receiving PBPCs. Thus, autologous PBPCs can be efficiently collected during mobilization by chemotherapy and GM-CSF and are an attractive alternative to marrow for hematopoietic support after high-dose therapy. The enhanced speed of recovery may reduce the morbidity, mortality, and cost of high-dose treatment. Furthermore, PBPC support may enhance the effectiveness of high-dose therapy by facilitating multiple courses of therapy.

Adjuvant therapy for sarcomas.

Adjuvant therapy is currently established in the treatment of osteosarcoma, Ewing's sarcoma and rhabdomyosarcoma. Of the 12 reported randomized studies of adjuvant chemotherapy for soft tissue sarcoma, only 2 show a significant overall survival advantage for chemotherapy (the most important endpoint). In three randomized trials, the survival of the observation arm exceeds that of the chemotherapy arm. In two additional studies, subset analyses currently indicate a significant DFS advantage for adjuvant chemotherapy in extremity lesions, but no significant improvement in survival. Although initial NCI reports showed significantly prolonged survival for the subset of chemotherapy-treated extremity primaries, survival on longer follow-up is no longer significantly different. In the subset analysis of retroperitoneal sarcomas in the same NCI study, the survival of the control group is superior to the treatment group. Doxorubicin associated cardiotoxicity has occurred in about 10% of treated patients, occasionally contributing to treatment-related deaths. Based on these data, adjuvant chemotherapy should be considered investigational for adult soft-tissue sarcomas of any primary site. Future randomized trials should include patients at high risk for metastases (large, high-grade lesions) with a reasonable likelihood of local control by radical resection, or resection with uninvolved margins and subsequent radiotherapy. Low-grade sarcomas are currently cured by surgical resection in 80% of cases, and thus should not be included in adjuvant trials.

GM-CSF potentiated peripheral blood progenitor cell (PBPC) collection with or without bone marrow as hematologic support of high-dose chemotherapy: two protocols.

High-dose chemotherapy with autologous bone marrow support (ABMS) achieves prolonged relapse-free survival in relapsed lymphomas and leukemias and has provided durable complete responses in certain solid tumors. The principal morbidity and mortality result from the infectious and bleeding complications during the 3-4 week aplasia until the bone marrow autograft can recover. Hematopoietic growth factors, alone or used after chemotherapy, increase the number of circulating progenitor cells in the peripheral blood compartment. In one trial, 12 patients with solid tumors were treated with high-dose chemotherapy and supported with both bone marrow and peripheral blood progenitor cells (PBPC) collected after GM-CSF administration. Reconstitution of bone marrow function occurred quickly (ANC greater than 500/microliters by day 17; platelet-transfusion independence by day 16), resulting in short hospital stays (median, 28 days). In a second study, 12 patients with metastatic breast cancer responding to induction chemotherapy (doxorubicin, 5-fluorouracil, and methotrexate) were given GM-CSF during induction to collect PBPCs during leukocyte recovery. These PBPCs were used as the sole hematopoietic support during high-dose chemotherapy with cyclophosphamide, thiotepa, and carboplatin. Granulocyte and platelet reconstitution were extremely rapid (median, 14 and 12 days, respectively). When compared with 29 patients undergoing the same intensification therapy using ABMT as sole support, time to hematopoietic recovery, transfusion requirements, and duration of hospital stay were all significantly improved for the patients receiving PBPC. PBPC with or without marrow may enhance the safety, tolerance, and cost of high-dose therapy. Moreover, PBPC may render multiple course combination, high-dose therapy feasible.

Sarcomas of soft tissue and bone.

Sarcomas arise primarily from mesenchymal structures at any site in the body, even within visceral stroma and neurovascular bundles. Sarcomas have been associated with prior radiation therapy, toxic exposures, and genetic conditions and soft tissue sarcomas have been distinguished from bone sarcomas. For localized soft tissue sarcoma, tumor grade is the most important prognostic variable. Low-grade tumors are generally cured by wide surgical excision, but there is a significant rate of both local recurrence and development of distant metastasis in high-grade lesions. The treatment of soft tissue sarcoma histologic subtypes is generally similar grade-for-grade, with the exception of rhabomyosarcoma, Kaposi's sarcoma, and mesothelioma. Tumor location strongly influences resectability. Radiation therapy has been used successfully in conjunction with conservative surgery to improve local control rates for soft tissue sarcomas, particularly in extremity lesions. Currently, adjuvant chemotherapy remains unproven for most adult soft tissue sarcomas, but is established in the treatment of rhabdomyosarcomas, osteosarcomas, and Ewing's sarcomas.