Abstract
Purpose
Risk of infection increases with severity and duration of chemotherapy-induced neutropenia (CIN). Pegfilgrastim is approved for use on the day after chemotherapy to reduce incidence of infection, as manifested by febrile neutropenia (FN), in patients receiving myelosuppressive chemotherapy. In this study, we compared severity and duration of absolute neutrophil count (ANC) suppression in patients who received pegfilgrastim on the same day as chemotherapy versus the next day.
Methods
We combined individual patient data from four Amgen-sponsored clinical trials in which patients with cancer were randomized to receive pegfilgrastim either the same day as chemotherapy or the next day. Severity and duration of ANC suppression were calculated using area over the curve (AOC, the area over the ANC–time response curve and below a given clinical threshold). AOC of ANC and incidences of CIN and FN were compared by day of pegfilgrastim use.
Results
The analysis included 95 same-day patients and 97 next-day patients. Despite similar ANC at baseline, ANC at nadir was higher among next-day patients than same-day patients. Mean AOC of ANC (cutoff 0.5 × 109/L) among next-day patients was lower by 0.30 (95 % confidence interval: 0.16, 0.43) 109/L × day than same-day patients in cycle 1. Next-day patients had lower incidences of CIN than same-day patients, but there were no significant differences in incidences of FN.
Conclusions
Patients who received pegfilgrastim the day after chemotherapy had less severe and shorter suppression of ANC than patients who received pegfilgrastim the same day as chemotherapy.
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Introduction
Neutrophils, the most abundant leukocytes in circulation, play a crucial role in innate immune responses against infections [1]. Cytotoxic chemotherapy suppresses the hematopoietic system and may lead to chemotherapy-induced neutropenia (CIN), a condition that makes patients vulnerable to potentially life-threatening infections [2]. Following initiation of myelosuppressive chemotherapy, absolute neutrophil count (ANC) follows a trajectory that includes a decline to its lowest point (the nadir) and subsequent rise as the bone marrow recovers [3]. Lower ANC (or leukocytes) at nadir and longer duration of severe CIN (or leukopenia) have been shown to be associated with higher risk of infection [4–6].
Neutropenia blunts the inflammatory response to nascent infections and reduces the signs and symptoms of infection; therefore, the only sign of infection in the presence of neutropenia is often fever [2]. Febrile neutropenia (FN), the combination of neutropenia and fever, is a serious toxicity of myelosuppressive chemotherapy that can lead to chemotherapy dose delays and reductions as well as increased morbidity, mortality, and healthcare resource use [7–9].
Granulocyte colony-stimulating factor (G-CSF) regulates the production of neutrophils within the bone marrow and induces proliferation and differentiation of neutrophil precursors [10, 11]. Pegfilgrastim (Neulasta®, Amgen Inc., Thousand Oaks, CA, USA) is a pegylated recombinant human G-CSF that is indicated to decrease the incidence of infection, as manifested by FN, in patients with non-myeloid malignancies receiving myelosuppressive anti-cancer drugs [12, 13].
Neulasta® prescribing information specifies that pegfilgrastim should not be administered between 14 days before and 24 h after administration of chemotherapy [13]. Theoretically, the simultaneous administration of exogenous G-CSF and chemotherapy may lead to an increased pool of neutrophil precursors susceptible to destruction by chemotherapy, leading paradoxically to an increased risk of neutropenia [14, 15]. Nevertheless, some patients still receive pegfilgrastim on the same day as chemotherapy rather than the next day [16–18].
In the current study, we pooled individual patient data from four Amgen-sponsored clinical trials in which patients were randomized to receive pegfilgrastim on the same day as chemotherapy versus the next day. The objectives of this study were to compare several metrics for severity and duration of ANC suppression and incidence proportions of CIN and FN among patients who received pegfilgrastim on the same day as chemotherapy versus the next day.
Materials and methods
Study design and data source
The current study is a secondary analysis of individual patient data collected in four randomized phase 2 clinical trials sponsored by Amgen Inc. The trials were conducted between 2003 and 2005 in patients with non-Hodgkin’s lymphoma, breast cancer, relapsed or refractory ovarian cancer, and advanced or metastatic non-small cell lung cancer. The primary objective of the trials was to provide data on the safety and efficacy of pegfilgrastim administered on the same day as chemotherapy (within 24 h of chemotherapy completion) versus the next day (24 h after chemotherapy completion). The primary efficacy endpoint of all four trials was duration of grade 4 neutropenia. Criteria for the inclusion of these four trials in this analysis are shown in Supplementary material 1. Key information regarding these four trials is summarized in Supplementary material 2. In three of four trials (Amgen studies 20020134, 20020778, and 20030123), chemotherapy was administered only on day 1 of the chemotherapy cycle, and the same-day and next-day patients received pegfilgrastim on day 1 and day 2 of the cycle, respectively. In Amgen study 20030122, chemotherapy was administered over the first 5 days of the chemotherapy cycle, and the same-day and next-day patients received pegfilgrastim on day 5 and day 6 of the cycle, respectively (Supplementary material 2).
Study population
Patients were included in this analysis if they were enrolled in one of the four aforementioned randomized clinical trials and met all of the following additional inclusion criteria: baseline ANC ≥ 1500/µL at initiation of chemotherapy, ANC measured at least four times per cycle in at least one cycle of the chemotherapy course under study, and normal body temperature (<38 °C) at initiation of chemotherapy. Patients were excluded if they had an active infection that required treatment with anti-infectives within 72 h of chemotherapy, received prophylactic antibiotics, received pelvic irradiation or radiation therapy extending beyond a single involved field within 4 weeks of chemotherapy initiation, or had a prior malignancy in the previous 5 years.
Patients in two of the included clinical trials (Amgen studies 20020778 and 20030122) had ANC measured at least four times per cycle in both cycle 1 and cycle 3. Patients in the other two trials (Amgen studies 20020134 and 20030123) had ANC measured at least four times per cycle only in cycle 1. All the ANC-related analyses in the current study were conducted in cycles in which ANC was measured at least four times per cycle.
Endpoints
The primary endpoint of this study was area over the ANC–time response curve (AOC). AOC of ANC is the area above the ANC–time response curve and below the thresholds of 0.5 × 109/L or 1.0 × 109/L in a given chemotherapy cycle (shown graphically in Fig. 1). AOC of ANC measures both severity and duration of neutropenia. The more severe and the longer the duration of neutropenia, the higher the AOC. The thresholds of 0.5 × 109/L and 1.0 × 109/L are based on the Common Terminology Criteria for Adverse Events (CTCAE): an ANC < 0.5 × 109/L is categorized as grade 4 neutropenia, while an ANC between 0.5 × 109/L and 1.0 × 109/L is categorized as grade 3 neutropenia [19].
The secondary endpoints of this study were ANC at nadir, time to ANC nadir, and incidence proportions of grade 4 CIN (ANC < 0.5 × 109/L), grade 3/4 CIN (ANC < 1.0 × 109/L), grade 4 FN, and grade 3/4 FN within a chemotherapy cycle. Grade 4 and grade 3/4 FN were defined as an infectious episode (body temperature ≥38.2 °C, infection-related hospitalization, or infection-related adverse event) occurring on the same day or within 1 day of grade 4 or grade 3/4 neutropenia, respectively.
Statistical analysis
Descriptive analyses were conducted to characterize demographics, disease characteristics, and chemotherapy treatments in the overall study population and in each of the treatment groups (same-day versus next-day pegfilgrastim use). The two-sample t test was used to assess differences in continuous variables, and the Chi-square test was used to assess differences in categorical variables between the treatment groups. No multiplicity adjustment was used, and p values should be considered nominal. Body surface area was calculated using the Mosteller formula [20]. Risk of FN for each chemotherapy regimen was based on the National Comprehensive Cancer Network (NCCN) guidelines [21]. For regimens that remain unclassified, FN incidence in the placebo arms (no G-CSF) of Amgen-sponsored clinical trials and FN risk reported in the literature were used to determine FN risk category [22].
Baseline ANC values, ANC at nadir, and time to ANC nadir were described by treatment group for each cycle with ≥4 ANC measurements (cycles 1 and 3). The log-linear interpolation technique [23] was used to derive ANC on days without a measurement using the adjacent ANC measurements from each patient. ANC nadir was the lowest ANC value that occurred during the chemotherapy cycle. Time to ANC nadir was calculated as the number of days from chemotherapy initiation to ANC nadir. Distributions of all ANC metrics were skewed; thus, the Wilcoxon rank sum test was used to compare the differences between the two treatment groups. Differences in the distribution of time to ANC nadir (<7, 7, 8, and >8 days) between the two groups were tested using the Chi-square test or Fisher’s exact test (if expected cell frequency was <5). A sensitivity analysis was performed to compare time to ANC nadir for the studies in which chemotherapy was administered only on day 1 of the chemotherapy cycle (Amgen studies 20020134, 20020778, and 20030123), and a separate sensitivity analysis was performed to compare time to ANC nadir for the study in which chemotherapy was administered over the first 5 days of the chemotherapy cycle (Amgen study 20030122).
AOC of the ANC–time response curve (below the thresholds of 0.5 × 109/L or 1.0 × 109/L) was calculated using the Riemann sum method, assuming ANC values to be constant within each day [24]. Due to the large proportion of patients with an AOC of 0 (e.g., 35.8 % of same-day patients and 51.0 % of next-day patients had an AOC of 0 below the threshold of 0.5 × 109/L in cycle 1), median AOC might not be meaningful. Mean AOC of ANC was therefore calculated for each group as were differences in mean AOC of ANC between patients who received pegfilgrastim on the same day as chemotherapy versus the next day. Differences in mean AOC were calculated in cycle 1 or cycle 3 separately using linear regression and in the two cycles combined using linear mixed-effect regression to control for within-patient and within-study correlations. Age (as a linear continuous variable) and Eastern Cooperative Oncology Group (ECOG) performance status (0, 1, and 2–3 as a categorical variable), the covariates with imbalanced distributions between the two groups, were controlled for in the adjusted model. A bootstrap procedure was used to estimate the 95 % confidence intervals (CIs) for mean AOC difference. One thousand bootstrap samples were first selected from AOC estimates using stratified random sampling (by day of pegfilgrastim use and study) with replacement. Mean AOC differences by day of pegfilgrastim use within each of the 1000 replicates were then estimated. The 2.5th and 97.5th percentiles of the bootstrap samples were used as the 95 % CIs of the mean AOC difference.
Incidence proportions of CIN and FN within a chemotherapy cycle were calculated by day of pegfilgrastim use for cycles 1 and 3. A generalized linear mixed model with logit link function was used to compare the odds of CIN and FN in next-day versus same-day patients, adjusting for age (as a linear continuous variable) and ECOG performance status (0, 1, and 2–3 as a categorical variable) in cycle 1, cycle 3, and cycles 1 and 3 combined. Within-study correlation and within-patient correlation in the combined analysis of cycles 1 and 3 were controlled for by including random intercepts in the mixed model.
Results
Clinical trials and patients
Four randomized phase 2 clinical trials were identified in which patients were allocated to receive pegfilgrastim on the same day as chemotherapy versus the next day. A total of 192 patients in these trials were eligible for inclusion in the current study: 95 patients who received pegfilgrastim on the same day as chemotherapy and 97 who received pegfilgrastim on the next day. Patient disposition by inclusion and exclusion criteria for each of the studies and for all studies combined is shown in Table 1.
Of the eligible patients, most were female (67.7 %), white (80.7 %), and had an ECOG performance status of 0 (54.7 %). Mean (±standard deviation [SD]) age of the patients was 58.9 (±12.7) years. Primary tumor types were breast cancer (32.3 %), non-small cell lung cancer (31.8 %), non-Hodgkin’s lymphoma (30.2 %), and ovarian cancer (5.7 %). About half of the patients (48.4 %) had advanced tumors (stage IV or “extensive”). Most patients (62.0 %) received chemotherapy regimens with an intermediate risk (10–20 %) of FN. Demographics, disease characteristics, and chemotherapy regimen FN risk are shown in Table 2. Overall, demographics and disease characteristics were balanced between the same-day and next-day groups.
ANC trajectory
ANC trajectories of the patients who received pegfilgrastim on the same day as chemotherapy and those who received pegfilgrastim the next day are shown in Fig. 1. In both cycle 1 (Fig. 1a) and cycle 3 (Fig. 1b), the ANC trajectories of same-day patients and next-day patients began to diverge on the day after chemotherapy (day 2). ANC at nadir was lower among same-day patients than among next-day patients in both cycle 1 and cycle 3. ANC values returned to baseline sooner and remained higher throughout the cycle among next-day patients than among same-day patients in both cycles.
Key statistics of the ANC trajectory of patients in this study are shown in Table 3. Baseline ANC values were not different between same-day and next-day patients (p > 0.05). In contrast, ANC at nadir was significantly lower among same-day patients than among next-day patients in both cycle 1 (median [Q1, Q3]: 0.13 [0.04, 1.31] versus 0.54 [0.11, 2.04] × 109/L, p = 0.003) and cycle 3 (median [Q1, Q3]: 0.07 [0.04, 0.27] versus 0.37 [0.14, 1.00] × 109/L, p < 0.001). Although the mean or median time to ANC nadir was similar between the two treatment groups in cycle 1, same-day patients tended to reach ANC nadir earlier than next-day patients: 22.1 versus 7.3 % reached ANC nadir within 7 days after chemotherapy in cycle 1 (Table 3). No significant differences in time to ANC nadir were observed in cycle 3 (Table 3). In the sensitivity analysis, we observed that same-day patients tended to reach ANC nadir earlier than next-day patients in cycle 1 for studies in which chemotherapy was administered only on day 1 of the chemotherapy cycle (Supplementary material 3). Only one study with a very small sample size (n = 11 in cycle 1, n = 7 in cycle 3) had chemotherapy administered over multiple days of the chemotherapy cycle. In this study, no difference in time to ANC nadir was observed between same-day and next-day patients (Supplementary material 4).
Area over the ANC–time response curve
AOC of ANC, a composite measure of duration and severity of ANC suppression, was significantly higher among same-day patients than among next-day patients (Table 4). In cycle 1, when ANC < 0.5 × 109/L was used as the threshold, mean AOC of ANC was higher by 0.30 (95 % CI 0.16, 0.43) 109/L × day among same-day patients than among next-day patients. When ANC < 1.0 × 109/L was used as the threshold, mean AOC of ANC was higher by 0.73 (95 % CI 0.37, 1.05) 109/L × day among same-day patients. In cycle 3, when both ANC < 0.5 × 109/L and ANC < 1.0 × 109/L were used as the thresholds, AOC was significantly higher among same-day patients than among next-day patients. Similar findings were observed in the analysis of cycles 1 and 3 combined (Table 4).
Chemotherapy-induced neutropenia and febrile neutropenia
Incidence proportions of CIN and FN within the chemotherapy cycle among same-day and next-day patients are shown in Table 5. Incidence proportion of grade 4 CIN was significantly lower among next-day patients than among same-day patients in both cycle 1 (49.0 versus 64.2 %, adjusted odds ratio [OR] [95 % CI] 0.23 [0.09, 0.62]) and cycle 3 (57.6 versus 83.3 %, adjusted OR [95 % CI] 0.19 [0.04, 0.79]). In cycles 1 and 3 combined, next-day patients had significantly lower odds of having grade 4 CIN (adjusted OR [95 % CI] 0.23 [0.10, 0.49]).
Incidence proportion of grade 3/4 CIN was not significantly different between same-day versus next-day patients in cycles 1 and 3 separately: cycle 1 (65.6 versus 72.6 %, adjusted OR [95 % CI] 0.48 [0.17, 1.35]) and cycle 3 (72.7 versus 93.3 %, adjusted OR [95 % CI] 0.13 [0.02, 1.02]). However, in cycles 1 and 3 combined, the incidence proportion of grade 3/4 CIN was statistically lower among next-day patients than among same-day patients (adjusted OR [95 % CI] 0.36 [0.15, 0.87]).
No statistically significant differences were observed between same-day and next-day patients in the incidence proportions of grade 4 FN or grade 3/4 FN in cycle 1, cycle 3, or cycles 1 and 3 combined (Table 5).
Discussion
Several randomized, placebo-controlled clinical trials have shown that patients with cancer who were treated with chemotherapy and prophylactic G-CSF experienced substantially less severe suppression of ANC, more rapid recovery of ANC, and lower incidence of infection (characterized by FN) than patients who did not receive prophylactic G-CSF [12, 25, 26]. In the current study, patients who received pegfilgrastim prophylaxis on the day after chemotherapy (24 h after chemotherapy completion) had a less severe fall in ANC and more rapid recovery of ANC than patients who received pegfilgrastim on the same day as chemotherapy (within 24 h of chemotherapy completion).
Previous studies have provided some evidence that patients with cancer who had lower ANCs and longer duration of severe CIN following chemotherapy were at higher risk of developing infection [4, 27]. Each unit increase in AOC of ANC (109/L × day) below the threshold of ANC < 0.5 × 109/L was found to be associated with a significantly increased risk of infection-related hospitalization (hazard ratio [95 % CI] 1.98 [1.35, 2.90]) [28]. In this study, we did not find a statistically significant difference in the incidences of FN between patients who received pegfilgrastim prophylaxis on the same day as chemotherapy versus the next day. This is likely due to the limited statistical power of the study. The study included 192 patients and had about 30 % power to detect a relative risk of 0.6.
Burris et al. [29] analyzed ANC data from the same four clinical trials included in this analysis; however, the objectives and analytical approaches of that study were different from the current study. Burris et al. presented ANC data, such as ANC nadir and incidence and duration of grade 4 neutropenia in cycle 1, for each individual trial. We pooled individual patient data from the four trials and performed a statistical analysis of the shape of the ANC trajectories by using AOC of ANC. Two additional clinical trials evaluated the difference between same-day and next-day pegfilgrastim prophylaxis. Saven et al. [30] reported higher incidence of grade 4 CIN among same-day patients but similar incidence of FN, while Belani et al. [31] reported no difference in the incidences of CIN or FN by day of pegfilgrastim use. Results from observational studies are also inconsistent, which might be explained by heterogeneous study designs, possible selection bias, and confounding [18, 32–35]. Also, most of the observational studies had relatively small sample sizes [32–35]. One recent observational study retrospectively analyzed 45,592 patients (4336 same day, 32,759 next day) from two private US healthcare claims databases. The study reported that odds of FN were significantly higher among patients who received pegfilgrastim on the same day as chemotherapy versus the next day (OR [95 % CI] 1.6 [1.3, 1.9] for cycle 1; OR [95 % CI] 1.5 [1.3, 1.6] for all cycles combined) [18]. The direction and magnitude of the associations reported in that study are similar to those reported here.
The 2015 update to the American Society of Clinical Oncology Clinical Recommendations for the Use of White Blood Cell (WBC) Growth Factors states that, “Evidence suggests that pegfilgrastim administered 1–3 days after chemotherapy results in a lower risk of infection than pegfilgrastim administered on the same day as chemotherapy” [36]. The current version of the NCCN Guidelines® for Myeloid Growth Factors states that, “Beginning pegfilgrastim the day after chemotherapy is preferred” [21]. The favorable ANC trajectory and lower incidence proportion of CIN observed in the current study support these recommendations.
This study has several strengths. By performing a pooled analysis of clinical trial data from patients who were randomized to receive pegfilgrastim on the same day as chemotherapy or the next day, we avoided bias due to confounding, an issue that might affect other study designs. Our data included frequent measurements of ANC, which enabled good estimation of ANC trajectory and of the difference in AOC of ANC between the patients who received pegfilgrastim on the same day as chemotherapy versus the next day. Severity and duration of CIN were simultaneously captured by using AOC of ANC in this analysis, and potential covariates with imbalanced distributions were adjusted for when comparing AOC of ANC between the two treatment groups. Inclusion and exclusion criteria were applied in addition to the original criteria used in each trial (e.g., baseline ANC and body temperature and ANC measurement frequency within each chemotherapy cycle) to standardize patient selection in this analysis. Standardized definitions of study endpoints and covariates were also developed and applied in this study.
This study also has limitations. The original primary efficacy endpoint of the four clinical trials included in this analysis was duration of grade 4 neutropenia, and the trials were not designed to detect a difference in risk of infection/FN. The sample size in this pooled analysis was not sufficient to detect possible difference in the incidence proportions of FN between patients who received pegfilgrastim on the same day as chemotherapy versus the next day. Another limitation is that patients in the original studies did not have frequent enough measurements of ANC to allow examination of the ANC trajectory in all cycles of chemotherapy. In addition, patients enrolled in the original clinical trials might not be representative of patients with cancer treated in routine clinical practice today; thus, the results from this pooled analysis of clinical trial data might have limited generalizability.
Conclusions
In this secondary analysis of individual patient data from four randomized clinical trials, we found that patients who received pegfilgrastim as indicated, on the day after chemotherapy, had less severe and less sustained suppression of ANC as manifested by higher ANC nadirs and smaller AOC of ANC than patients who received pegfilgrastim on the same day as chemotherapy. Next-day patients also had lower incidence proportions of grade 3 or 4 CIN than same-day patients. No significant differences were observed in the incidence proportions of FN, likely due to the lack of statistical power in the study. Together, these results support administration of pegfilgrastim as indicated, on the day after chemotherapy.
References
Amulic B, Cazalet C, Hayes GL, Metzler KD, Zychlinsky A (2012) Neutrophil function: from mechanisms to disease. Annu Rev Immunol 30:459–489. doi:10.1146/annurev-immunol-020711-074942
Crawford J, Dale DC, Lyman GH (2004) Chemotherapy-induced neutropenia: risks, consequences, and new directions for its management. Cancer 100(2):228–237. doi:10.1002/cncr.11882
Crawford J, Kreisman H, Garewal H, Jones SE, Shoemaker D, Pupa MR, Armstrong S, Tomita D, Dziem G (1997) The impact of Filgrastim schedule variation on hematopoietic recovery post-chemotherapy. Ann Oncol 8(11):1117–1124
Bodey GP, Buckley M, Sathe YS, Freireich EJ (1966) Quantitative relationships between circulating leukocytes and infection in patients with acute leukemia. Ann Intern Med 64(2):328–340
Rivera E, Haim Erder M, Fridman M, Frye D, Hortobagyi GN (2003) First-cycle absolute neutrophil count can be used to improve chemotherapy-dose delivery and reduce the risk of febrile neutropenia in patients receiving adjuvant therapy: a validation study. Breast Cancer Res 5(5):R114–R120. doi:10.1186/bcr618
Silber JH, Fridman M, DiPaola RS, Erder MH, Pauly MV, Fox KR (1998) First-cycle blood counts and subsequent neutropenia, dose reduction, or delay in early-stage breast cancer therapy. J Clin Oncol 16(7):2392–2400
Kuderer NM, Dale DC, Crawford J, Cosler LE, Lyman GH (2006) Mortality, morbidity, and cost associated with febrile neutropenia in adult cancer patients. Cancer 106(10):2258–2266. doi:10.1002/cncr.21847
Shayne M, Crawford J, Dale DC, Culakova E, Lyman GH, A. N. C. Study Group (2006) Predictors of reduced dose intensity in patients with early-stage breast cancer receiving adjuvant chemotherapy. Breast Cancer Res Treat 100(3):255–262. doi:10.1007/s10549-006-9254-4
Weycker D, Edelsberg J, Kartashov A, Barron R, Lyman G (2012) Risk and healthcare costs of chemotherapy-induced neutropenic complications in women with metastatic breast cancer. Chemotherapy 58(1):8–18. doi:10.1159/000335604
Bhana N (2007) Granulocyte colony-stimulating factors in the management of chemotherapy-induced neutropenia: evidence based review. Curr Opin Oncol 19(4):328–335. doi:10.1097/01.cco.0000275309.58868.11
Lyman GH, Shayne M (2007) Granulocyte colony-stimulating factors: finding the right indication. Curr Opin Oncol 19(4):299–307. doi:10.1097/CCO.0b013e3281a3c0ba
Crawford J, Ozer H, Stoller R, Johnson D, Lyman G, Tabbara I, Kris M, Grous J, Picozzi V, Rausch G, Smith R, Gradishar W, Yahanda A, Vincent M, Stewart M, Glaspy J (1991) Reduction by granulocyte colony-stimulating factor of fever and neutropenia induced by chemotherapy in patients with small-cell lung cancer. N Engl J Med 325(3):164–170. doi:10.1056/NEJM199107183250305
Neulasta® (pegfilgrastim) prescribing information. Amgen
Chabner B, Longo DL (2011) Cancer chemotherapy and biotherapy: principles and practice, 5th edn. Wolters Kluwer Health/Lippincott Williams & Wilkins, Philadelphia
Meropol NJ, Miller LL, Korn EL, Braitman LE, MacDermott ML, Schuchter LM (1992) Severe myelosuppression resulting from concurrent administration of granulocyte colony-stimulating factor and cytotoxic chemotherapy. J Natl Cancer Inst 84(15):1201–1203. doi:10.1093/jnci/84.15.1201
Weycker D, Wu H, Hagiwara M, Li X, Barron RL (2014) Use of chemotherapy and same-day pegfilgrastim prophylaxis in US clinical practice. Blood 124(21):4825
Li S, Sosa IR, Molony JT, Page JH, Barron RL, Liu J, Morrow PK, Stryker S, Acquavella JF, Collins AJ (2014) Timing of primary prophylaxis G-CSF use during chemotherapy in elderly patients with NHL. Blood 124(21):6013
Weycker D, Li X, Figueredo J, Barron R, Tzivelekis S, Hagiwara M (2015) Risk of chemotherapy-induced febrile neutropenia in cancer patients receiving pegfilgrastim prophylaxis: does timing of administration matter? Support Care Cancer. doi:10.1007/s00520-015-3036-7
National Cancer Institute (2009) Common Terminology Criteria for Adverse Events (CTCAE) v4.0. National Cancer Institute. http://ctep.cancer.gov/protocolDevelopment/electronic_applications/ctc.htm
Mosteller RD (1987) Simplified calculation of body-surface area. N Engl J Med 317(17):1098. doi:10.1056/NEJM198710223171717
National Comprehensive Cancer Network. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®). Myeloid Growth Factors. Version 1.2015. www.NCCN.org. Accessed 20 August 2015
Millward MJ, Boyer MJ, Lehnert M, Clarke S, Rischin D, Goh BC, Wong J, McNeil E, Bishop JF (2003) Docetaxel and carboplatin is an active regimen in advanced non-small-cell lung cancer: a phase II study in Caucasian and Asian patients. Ann Oncol 14(3):449–454. doi:10.1093/annonc/mdg118
Lidstone GJ (1945) Note on logarithmic interpolation. Trans Fac Actuar 17:216–218. doi:10.1017/S0071368600002998
Petrovic JS (2014) Definite integral. In: Advanced calculus: theory and practice. CRC Press, Boca Raton, pp 135-168
Trillet-Lenoir V, Green J, Manegold C, Von Pawel J, Gatzemeier U, Lebeau B, Depierre A, Johnson P, Decoster G, Tomita D et al (1993) Recombinant granulocyte colony stimulating factor reduces the infectious complications of cytotoxic chemotherapy. Eur J Cancer 29A(3):319–324
Brugger W, Bacon P, Lawrinson S, Romieu G (2009) Neutrophil recovery in elderly breast cancer patients receiving adjuvant anthracycline-containing chemotherapy with pegfilgrastim support. Crit Rev Oncol Hematol 72(3):265–269. doi:10.1016/j.critrevonc.2009.05.002
Meza L, Baselga J, Holmes F, Liang B, Breddy J, for the Pegfilgrastim Study Group (2002) Incidence of febrile neutropenia (FN) is directly related to duration of severe neutropenia (DSN) after myelosuppressive chemotherapy. J Clin Oncol 21:255b (abstr 2840)
Li Y, Shih X, Klippel ZK, Reiner M, Page JH (2014) Relationship between severity and duration of chemotherapy induced neutropenia and risk of infection among patients with non-myeloid malignancies. Blood 124(21):4960
Burris HA, Belani CP, Kaufman PA, Gordon AN, Schwartzberg LS, Paroly WS, Shahin S, Dreiling L, Saven A (2010) Pegfilgrastim on the same day versus next day of chemotherapy in patients with breast cancer, non-small-cell lung cancer, ovarian cancer, and non-Hodgkin’s lymphoma: results of four multicenter, double-blind, randomized phase II studies. J Oncol Pract 6(3):133–140. doi:10.1200/JOP.091094
Saven A, Schwartzberg L, Kaywin P, Bartlett N, Dean L, Shahin S, Dreiling L (2006) Randomized, double-blind, phase 2, study evaluating same-day vs next-day administration of pegfilgrastim with R-CHOP in non-Hodgkin’s lymphoma patients. J Clin Oncol 24 (18_suppl; abstr 7570)
Belani CP, Ramalingam S, Al-Janadi A, Eskander E, Ghazal H, Schwartzberg L, Elliott M, Shahin S, Dreiling L (2006) A randomized double-blind phase II study to evaluate same-day vs next-day administration of pegfilgrastim with carboplatin and docetaxel in patients with NSCLC. J Clin Oncol 24 (18_suppl; abstr 7110)
Hoffmann PS (2005) Administration of pegfilgrastim on the same day or next day of chemotherapy. J Clin Oncol 23 (16_suppl; abstr 8137)
Whitworth JM, Matthews KS, Shipman KA, Numnum TM, Kendrick JE, Kilgore LC, Straughn JM Jr (2009) The safety and efficacy of day 1 versus day 2 administration of pegfilgrastim in patients receiving myelosuppressive chemotherapy for gynecologic malignancies. Gynecol Oncol 112(3):601–604. doi:10.1016/j.ygyno.2008.10.025
Karol J, Rybicki L, Sweetenham J, Smith MR, Hill BT, Pohlman B, Jagadeesh D, Gazdick E, Fenner K, Maggiotto AL, Dean RM (2013) Similar incidence of febrile neutropenia with same-day versus subsequent day G-CSF administration in non-Hodgkin lymphoma patients receiving R-CHOP chemotherapy. Blood 122(21):4357
Cheng C, Gallagher EM, Yeh JY, Earl MA (2014) Rates of febrile neutropenia with pegfilgrastim on same day versus next day of CHOP with or without rituximab. Anticancer Drugs 25(8):964–969. doi:10.1097/CAD.0000000000000115
Smith TJ, Bohlke K, Lyman GH, Carson KR, Crawford J, Cross SJ, Goldberg JM, Khatcheressian JL, Leighl NB, Perkins CL, Somlo G, Wade JL, Wozniak AJ, Armitage JO (2015) Recommendations for the use of WBC growth factors: American Society of Clinical Oncology clinical practice guideline update. J Clin Oncol 33(28):3199–3212. doi:10.1200/JCO.2015.62.3488
Kaufman PA, Paroly W, Rinaldi D, Sonnier S, Shahin S, Dean L, Dansey R, Burris S (2004) Randomized, double-blind, phase 2 study evaluating same-day vs next-day administration of pegfilgrastim with docetaxel, doxorubicin, and cyclophosphamide (TAC) in women with early stage and advanced breast cancer. Breast Cancer Res Treat 88(1 suppl):S59 (abstr 1054)
Acknowledgments
Micah Robinson, Ph.D., provided medical writing support on behalf of Amgen Inc.
Funding
This study was funded by Amgen Inc.
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Yanli Li, Zandra Klippel, Maureen Reiner, and John H. Page are employees of and own stock in Amgen Inc. Xiaolong Shih and Hong Wang are consultants to Amgen and are funded by Amgen Inc.
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Li, Y., Klippel, Z., Shih, X. et al. Trajectory of absolute neutrophil counts in patients treated with pegfilgrastim on the day of chemotherapy versus the day after chemotherapy. Cancer Chemother Pharmacol 77, 703–712 (2016). https://doi.org/10.1007/s00280-016-2970-5
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DOI: https://doi.org/10.1007/s00280-016-2970-5