Filgrastim (r-metHuG-CSF) in the 21st century: SD/01.

SD/01, a sustained-duration molecule, has been developed by adding a poly [ethylene glycol] molecule to the filgrastim molecule. The pegylation does not change the properties of filgrastim, except that the plasma clearance is decreased and plasma half-life is increased. Increasing the duration of the biological effects of filgrastim may offer certain groups of patients better benefits. Early clinical studies have been encouraging with no serious toxicities noted.

Hematopoietic growth factors in cancer chemotherapy.

Hematopoietic growth factors have made a significant impact on the treatment of cancer, primarily in the prevention of infections associated with chemotherapy-induced neutropenia, in progenitor cell transplantation, in chemotherapy-induced thrombocytopenia, and in chemotherapy-induced anemia. As seen with this review, our basic understanding of hematopoietic growth factors and their clinical potential continue to expand. Work will need to continue, especially with the new thrombopoietic factors, megakaryocyte growth and developing factor, thrombopoietin, and IL-11, to fully categorize their biology and clinical characteristics.

Clinical benefits of improving host defences with rHuG-CSF.

Recombinant human granulocyte colony-stimulating factor (rHuG-CSF) has been shown to stimulate the production and function of neutrophils in vitro and in vivo. Clinical studies in patients receiving myelosuppressive chemotherapy showed earlier neutrophil recovery, a reduction in infectious complications of neutropenia, and the use of fewer antibiotics. Its use has also been established for mitigating the infectious complications associated with severe chronic neutropenia (SCN). Data are emerging that neutropenia also contributes to the risk of infections in patients with acquired immunodeficiency syndrome (AIDS) and in neonates with presumed sepsis, and that rHuG-CSF may be a useful adjunct therapy in these patients. More recent studies have focused on enhancing neutrophil number and function in patients with infections not associated with neutropenia. These studies were approached cautiously because of the suggestion that neutrophils might non-selectively amplify the body's inflammatory response in the immunocompetent host and lead to inadvertent tissue injury. Preclinical models have provided a strong rationale for clinical studies to determine whether rHuG-CSF lessens the severity or duration of serious infections or their complications in patients with suboptimal outcome from antibiotics. These studies suggest that elevation of neutrophil levels in these settings is not only safe but has clinical benefit.

Filgrastim in patients with chemotherapy-induced febrile neutropenia. A double-blind, placebo-controlled trial.

OBJECTIVE: To determine if filgrastim (recombinant human methionyl granulocyte colony-stimulating factor) used in addition to standard inpatient antibiotic therapy accelerated recovery from infection associated with chemotherapy-induced neutropenia. DESIGN: Randomized, double-blind, placebo-controlled trial. SETTING: Hematology and oncology wards of four teaching hospitals. PATIENTS: 218 patients with cancer who had fever (temperature > 38.2 degrees C) and neutropenia (neutrophil count < 1.0 x 10(9)/L) after chemotherapy. INTERVENTION: Patients were randomly assigned to receive filgrastim (12 micrograms/kg of body weight per day) (n = 109) or placebo (n = 107) beginning within 12 hours of empiric therapy with tobramycin and piperacillin. Patients received treatment and remained in the study until the neutrophil count was greater than 0.5 x 10(9)/L and until 4 days without fever (temperature < 37.5 degrees C) had elapsed. MEASUREMENTS: Days of neutropenia and fever and days in the study (hospitalization); time to resolution of fever and febrile neutropenia; and frequency of the use of alternative antibiotics. RESULTS: Compared with placebo, filgrastim reduced the median number of days of neutropenia (3.0 compared with 4.0 days of a neutrophil count of < 0.5 x 10(9)/L; P = 0.005) and the time to resolution of febrile neutropenia (5.0 compared with 6.0 days; P = 0.01) but not days of fever (3.0 days for both groups). The frequency of the use of alternative antibiotics was similar in the two groups (46% compared with 41%; P = 0.48). The median number of days patients were hospitalized while on study was the same (8.0 days; P = 0.09); however, filgrastim decreased the risk for prolonged hospitalization (> 11 days, 4th quartile) by half (relative risk, 2.1 [95% CI, 1.1 to 4.1]; P = 0.02). In exploratory subset analyses, filgrastim appeared to provide the greatest benefit in patients with documented infection and in patients presenting with neutrophil counts of less than 0.1 x 10(9)/L. CONCLUSIONS: Filgrastim treatment used with antibiotics at the onset of febrile neutropenia in patients with cancer who have received chemotherapy accelerated neutrophil recovery and shortened the duration of febrile neutropenia.

Protection from lethal irradiation by the combination of stem cell factor and tempol.

Cytokines that stimulate growth and differentiation of hematopoietic precursor cells have been used as protectors in vivo against ionizing radiation. Recently, we have shown that the nitroxide tempol is also an effective radiation protector in vivo. The purpose of the present study was to determine if the combination of tempol with stem cell factor (SCF, c-kit ligand) would provide enhanced radiation protection in C57 mice compared with the protection afforded by either agent alone. Mice were exposed to whole-body irradiation and assessed for survival at 30 days after irradiation. No control mice survived doses of more than 9 Gy. Treatment of mice before and after radiation with SCF alone (100 micrograms/kg at -20 h, -4 h and +4 h) protected mice from radiation at doses of as high as 10 Gy (76% survival). Tempol (350 mg/kg) given 10 min prior to radiation was a radioprotector at 9 Gy (55% survival). The combination of SCF and tempol increased the survival of mice exposed to radiation doses up to 11 Gy (32% survival for the combination vs 4% for SCF alone and 0% for tempol alone; P < 0.001 for the combination vs either agent alone). Lower doses of SCF alone (1 microgram/kg) or tempol alone (275 mg/kg) did not protect mice from radiation. However, the combination of these reduced doses of SCF and tempol protected mice from lethal irradiation at 10 Gy. Stem cell factor and tempol given either singly or together were well tolerated by the animals. These data show that SCF and tempol are radiation protectors and that their radioprotective effects are more than additive when the agents are given together.

Stem cell factor is a potent synergistic factor in hematopoiesis.

Stem cell factor (SCF), a ligand for c-kit, has a broad range of activities including effects on cells at or near the level of the multipotential stem cell as well as on committed cells. Preclinical studies show that SCF can protect against lethal irradiation, elicit multilineage responses in peripheral blood and bone marrow cellularity, and increase circulating peripheral blood progenitor cells (PBPC) in a dose-dependent manner. Recombinant human SCF has major clinical potential through its synergy with other factors, especially recombinant human granulocyte colony-stimulating factor, to enhance mobilization of PBPC.

Endogenous haemopoietic growth factors in neutropenia and infection.

Haemopoietic growth factors (HGFs) are being administered to patients with neutropenic fever; however, little is known about the endogenous HGF response in these patients. Specific assays were used to study four HGFs, granulocyte (G-) CSF, granulocyte-macrophage (GM-) CSF, macrophage (M-) CSF and interleukin (IL-) 6 levels in the blood of patients with neutropenic fever (46 episodes). For comparison, levels were also measured in three control populations: normals (20), afebrile neutropenic (14), and bacteraemic but not neutropenic patients (20). In febrile patients, levels of G-CSF (median, range) (0.46, < 0.10-142 ng/ml). IL-6 (0.054, 0.005-24.3 ng/ml) and M-CSF (18.5, 9.9-79.1 ng/ml) were elevated compared with afebrile subjects (< 0.10, < 0.10-1.62 ng/ml). (0.008, 0.002-0.024 ng/ml) and (6.45, < 5.0-31.3 ng/ml) respectively. GM-CSF was not elevated (< 0.02, < 0.02-8.0 ng/ml) compared with afebrile subjects (0.021, < 0.02-0.20 ng/ml). Variables significantly associated (P < 0.05) with elevated cytokine levels were determined by multiple regression analyses. Factors associated with G-CSF elevation were fever, neutropenia, pathogen type and raised bilirubin and creatinine. In contrast, neutropenia was not associated with IL-6 elevation although there was an association between IL-6 elevation and fever, Gram-negative and fungal infections and raised creatinine and bilirubin. M-CSF elevation was associated with fever, renal impairment and known pathogen. Elevated G-CSF and IL-6 levels normalized rapidly (hours-days) with the resolution of infection, whereas M-CSF concentrations remained elevated for up to 10 d. Cytokine levels remained elevated in septic neutropenic patients who did not recover. In summary, G-CSF, IL-6 and M-CSF levels were significantly elevated in sepsis. In contrast, GM-CSF levels were not elevated. These studies should assist the development of therapeutic strategies using HGFs in the treatment of sepsis.

The clinical utility of granulocyte colony-stimulating factor: early achievements and future promise.

Recombinant granulocyte colony-stimulating factor (rHuG-CSF) is a hematopoietic growth factor that acts selectively on the neutrophil lineage, and has had a major impact on clinical practice. Two forms are in clinical use: filgrastim has been approved for use in more than 45 countries for the amelioration of chemotherapy-induced neutropenia and restoration of granulopoiesis following bone-marrow transplantation and lenograstim has been approved in Europe and Japan. In some countries, rHuG-CSF is also approved for various other indications, such as severe chronic neutropenia. Infection and neutropenia are a major cause of morbidity and mortality following cytotoxic chemotherapy, and there is a known correlation between neutropenia and the risk of infection. Hematopoietic growth factors have been used successfully in the prevention and treatment of neutropenia. There is evidence to suggest that use of rHuG-CSF before the onset of neutropenia allows patients to receive the maximum benefit; however, patients who do not receive rHuG-CSF prophylactically still benefit from the use of rHuG-CSF for the treatment of febrile neutropenia. These patients have an accelerated neutrophil recovery and a shorter duration of febrile neutropenia. These effects seem to translate into a significant reduction in the number of patients requiring prolonged hospitalization. This paper reviews the use of rHuG-CSF in the treatment of febrile neutropenia and describes how it is routinely used by hematologists and oncologists in non-clinical trial settings.

Recombinant methionyl human granulocyte colony-stimulating factor for the prevention and treatment of non-neutropenic infectious diseases.

Recombinant methionyl human granulocyte colony-stimulating factor (r-metHuG-CSF, hereafter G-CSF) has been demonstrated in clinical trials to be effective in correcting iatrogenic neutropenia by stimulating the production of neutrophils. Not surprisingly, G-CSF has also been found to induce neutrophilia in non-neutropenic hosts. Experimental data suggest that G-CSF leads to the enhancement of neutrophil function. Endogenous G-CSF levels are elevated over a broad spectrum of serious infectious diseases, suggesting the clinical importance of G-CSF in these settings. These findings have stimulated research on the use of G-CSF alone or as an adjunct to conventional antimicrobial therapy in a number of non-neutropenic animal models of infections. In total these studies suggest that G-CSF may be useful in the prevention or therapy of infections in both non-neutropenic and neutropenic clinical settings.

Effect of peripheral blood progenitor cells mobilised by filgrastim (G-CSF) on platelet recovery after high-dose chemotherapy.

The haematopoietic growth factor (HGF), granulocyte colony stimulating factor (G-CSF; filgrastim) substantially shortens the period of severe neutropenia that follows high-dose chemotherapy and autologous bone marrow infusion by stimulating granulopoiesis. Filgrastim also increases numbers of circulating progenitor cells. We have studied the ability of filgrastim to mobilise peripheral blood progenitor cells (PBPC) and assessed their efficacy when infused after chemotherapy on recovery of neutrophil and platelet counts. Seventeen patients with non-myeloid malignant disorders received filgrastim (12 micrograms/kg daily for six days) by continuous subcutaneous infusion. Numbers of granulocyte-macrophage progenitors in peripheral blood increased a median of 58-fold over pretreatment values, and numbers of erythroid progenitors increased a median of 24-fold. Three leukapheresis procedures collected a mean total of 33 (SEM 5.7) x 10(4) granulocyte-macrophage progenitors per kg body weight. After high-dose chemotherapy in 14 of the patients (busulphan and cyclophosphamide), these cells were used to augment autologous bone marrow rescue and post-transplant filgrastim treatment. Platelet recovery was significantly faster in these patients than in controls who received the same treatment apart from the infusion of peripheral blood progenitors; the platelet count reached 50 x 10(9)/L a median of 15 days after infusion of haematopoietic cells in the study patients compared with 39 days in controls (p = 0.0006). The accelerated neutrophil recovery associated with filgrastim treatment after chemotherapy was maintained. Subsequently, 10 patients received filgrastim-mobilised PBPC without marrow after high-dose chemotherapy. The rate of platelet and neutrophil recovery in these patients was at least equal to that observed in the patients receiving PBPC and bone marrow.(ABSTRACT TRUNCATED AT 250 WORDS)

Studies of oral neutrophil levels in patients receiving G-CSF after autologous marrow transplantation.

Patients are at risk of mucositis and infections in the oral cavity during the neutropenic period after chemotherapy, which are significant causes of morbidity. In phase I/II studies with the haemopoietic growth factor granulocyte colony stimulating factor (G-CSF), a reduction in post-chemotherapy mucositis has been observed in addition to haematologic effects. To understand this phenomenon better in patients receiving G-CSF following high-dose chemotherapy with autologous bone marrow transplantation (ABMT), we studied the effects of G-CSF on levels of neutrophils recoverable from the oral cavity using a quantitative mouthrinse assay. In normal subjects, mouthrinses contained 472 +/- 329 x 10(3) neutrophils/mouthrinse. After chemotherapy followed by ABMT, mouthrinse neutrophil levels decreased to undetectable levels during the neutropenic period, but recovered 1-2 and 3-9 d before circulating neutrophil levels reached 0.1 and 1 x 10(9)/l respectively, whether or not patients received G-CSF. In patients who received G-CSF, the mean cumulative mucositis score was reduced from 35 +/- 9 to 21 +/- 12 (P < 0.05), and the maximum mean daily mucositis score was reduced from 2.8 +/- 0.5 to 1.7 +/- 0.9 (P < 0.01), compared to patients who did not receive G-CSF after ABMT. These studies provide in vivo evidence that neutrophils produced during G-CSF therapy are available to leave the circulation and enter tissues where their function is required for host defence. Since the usual temporal relationship between oral and peripheral blood neutrophil recovery was preserved during G-CSF administration after ABMT, these data support the hypothesis that the reduction in post-ABMT mucositis observed with G-CSF therapy may reflect a beneficial effect of G-CSF on the kinetics of oral mucosal neutrophil recovery in addition to the effect of G-CSF to accelerate peripheral blood neutrophil recovery.

Clinical uses of growth factors.

The haemopoietic growth factors are a diverse group of hormones with effects on different haemopoietic cell lineages and at various points in their developmental differentiation. The biology of many of these factors is now well understood. They have entered clinical trials and have demonstrated benefits in particular clinical situations. The thrust of current phase II and III clinical investigations now is to use these factors, alone or in combinations, to modify various disease states and to ameliorate many of the side-effects of other therapeutic agents, particularly cytotoxic anticancer agents. Many other disease states also lend themselves to therapy with these growth factors. Other haemopoietic growth factors have not been as extensively studied in humans but hold great promise. In this chapter, the current status of the haemopoietic growth factors presently under clinical trial has been reviewed. In addition, several factors which have been recently described but which have not yet entered clinical trials have been discussed.

Effect of peripheral-blood progenitor cells mobilised by filgrastim (G-CSF) on platelet recovery after high-dose chemotherapy.

The haemopoietic growth factor granulocyte colony-stimulating factor (G-CSF; filgrastim) substantially shortens the period of severe neutropenia that follows high-dose chemotherapy and autologous bone-marrow infusion by stimulating granulopoiesis. Filgrastim also increases numbers of circulating progenitor cells. We have studied the ability of filgrastim to mobilise peripheral-blood progenitor cells and assessed their efficacy when infused after chemotherapy on recovery of neutrophil and platelet counts. 17 patients with non-myeloid malignant disorders received filgrastim (12 micrograms/kg daily for 6 days) by continuous subcutaneous infusion. Numbers of granulocyte-macrophage progenitors in peripheral blood increased a median of 58-fold over pretreatment values, and numbers of erythroid progenitors increased a median of 24-fold. Three leucapheresis procedures collected a mean total of 33 (SEM 5.7) x 10(4) granulocyte-macrophage progenitors per kg body weight. After high-dose chemotherapy in 14 of the patients (busulphan and cyclophosphamide), these cells were used to augment autologous bone-marrow rescue and post-transplant filgrastim treatment. Platelet recovery was significantly faster in these patients than in controls who received the same treatment apart from the infusion of peripheral-blood progenitors; the platelet count reached 50 x 10(9)/l a median of 15 days after infusion of haemopoietic cells in the study patients compared with 39 days in controls (p = 0.0006). The accelerated neutrophil recovery associated with filgrastim treatment after chemotherapy was maintained. This method may be widely applicable to aid both neutrophil and platelet recovery after high-dose chemotherapy; it will allow investigation of peripheral-blood progenitor-cell allotransplantation.

Marrow proliferation and the appearance of giant neutrophils in response to recombinant human granulocyte colony stimulating factor (rhG-CSF).

During a study of recombinant human granulocyte colony stimulating factor (rhG-CSF) administration, 15 patients received twice daily i.v. infusions and nine patients received daily s.c. infusions of rhG-CSF for 5 d prior to cytotoxic therapy, and then a second course subsequent to melphalan administration. There was a striking dose-related neutrophilia and the appearance in the blood of early myeloid cells that express the intercellular adhesion molecule CD54. In addition, giant neutrophils or macropolycytes were observed in the peripheral blood of all patients. These cells were evident on the display of the Technicon H*1 as a population of large peroxidase positive cells, and using Feulgen staining these cells were shown to be tetraploid. Bone marrow kinetics studies performed on Day 4 or 5 indicated an increase in the proportion of bone marrow cells in S phase, G2 and mitosis, reflecting a proliferative response of the marrow. Large myeloid precursors and occasional binucleate promyelocytes were seen in the bone marrows done on Days 14 and 18 but not on Day 5. These findings indicate that administered G-CSF has both quantitative and qualitative effects on myeloid cells in vivo.