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Review

Anaplastic Lymphoma Kinase Inhibitor-Induced Neutropenia: A Systematic Review

by
Fabien Moinard-Butot
,
Simon Nannini
,
Cathie Fischbach
,
Safa Abdallahoui
,
Martin Demarchi
,
Thierry Petit
,
Laura Bender
and
Roland Schott
*
Department of Medical Oncology, Institut de Cancérologie Strasbourg Europe, 17 Rue Albert Calmette, 67033 Strasbourg, France
*
Author to whom correspondence should be addressed.
Cancers 2023, 15(20), 4940; https://doi.org/10.3390/cancers15204940
Submission received: 25 September 2023 / Revised: 8 October 2023 / Accepted: 9 October 2023 / Published: 11 October 2023
(This article belongs to the Special Issue ALK in Cancer: Lessons from the Future)
Browse Figure
Review Reports Versions Notes

Abstract

:

Simple Summary

ALK inhibitors have improved survival and quality of life for patients compared to chemotherapy. These treatments can cause haematological toxicities, particularly neutropenia. The management of side effects to avoid treatment interruptions is essential. Our literature review aims to improve the knowledge of ALK inhibitor-induced neutropenia in order to improve their management.

Abstract

Lung cancers with ALK rearrangement represent less than 5% of all lung cancers. ALK inhibitors are currently used to treat first-line metastatic non-small cell lung cancer with ALK rearrangement. Compared to chemotherapy, ALK inhibitors have improved progression-free survival, overall survival, and quality of life for patients. The results of several phase 3 studies with a follow-up of over 6 years suggest that the life expectancy of these patients treated with targeted therapies is significantly higher than 5 years and could approach 10 years. Nevertheless, these treatments induce haematological toxicities, including neutropenia. Few data are available on neutropenia induced by ALK inhibitors and on the pathophysiological mechanism and therapeutic adaptations necessary to continue the treatment. Given the high efficacy of these treatments, managing side effects to avoid treatment interruptions is essential. Here, we have reviewed the data from published clinical studies and case reports to provide an overview of neutropenia induced by ALK inhibitors.

1. Introduction

Lung cancer is one of the most frequently diagnosed cancers and the leading cause of cancer-related death worldwide, with a 5-year OS rate of <20% for newly diagnosed patients [1]. Histologically, lung cancer is divided into two subtypes: small cell lung cancer (15–20%) and non-small cell lung cancer (NSCLC) (80–85%). In addition, there has been evidence of oncogenic drivers, such as EGFR mutation (10–15% NSCLC), BRAF mutation (approximately 7% NSCLC), ALK rearrangement (3–8% NSCLC), and ROS1 translocation (approximately 2% NSCLC), that confer sensitivity to tyrosine kinase inhibitors (TKIs) [2]. The anaplastic lymphoma kinase (ALK) gene encodes a receptor tyrosine kinase enzyme that was discovered in 2007 [3]. In NSCLC, alteration of this gene leads to pro-oncogenic features. EMLA is a common gene fusion partner of ALK. Clinical features associated with this distinct subgroup of NSCLC patients include young age, nonsmoking history, and more frequent brain metastasis. In first-line metastatic lung cancer with ALK rearrangement, there is an overall survival benefit from ALK inhibitors versus chemotherapy [4,5,6]. More recently, second- and third-generation ALK inhibitors have shown a survival benefit over first-generation inhibitors. ESMO and NCCN recommend alectinib, brigatinib, or lorlatinib as a first-line treatment for metastatic ALK-rearranged lung cancer. Ceritinib and crizotinib are other treatment options [7,8].
The historical 5-year OS rate for molecularly unselected stage IV NSCLC is approximately 2% [9]. With chemotherapy, the median overall survival is approximately 20 months [10,11]. With second- and third-generation ALK inhibitors, the overall survival of patients with ALK-translocated NSCLC is beyond 55 months [12,13,14]. With a median follow-up time of 68.6 months with alectinib and 68.0 months with crizotinib, the median overall survival has still not been reached [15]. However, these inhibitors can cause side effects such as gastrointestinal and hepatic complications, fatigue, upper respiratory infections, and visual impairment that can lead to treatment interruptions and reduced efficacy [12,16,17,18]. Among them, neutropenia induced by ALK inhibitors has been reported, but its incidence and management are not addressed in recommendations. However, given the effectiveness of these treatments, it is necessary to obtain a better understanding of this side effect to optimize its management and diminish the risk of prolonged interruption.
We performed a systematic review of neutropenia induced by ALK inhibitors to assess the incidence of grade 3–4 and febrile neutropenia and to assess data on the management of this toxicity.

2. Materials and Methods

PubMed was systematically searched for articles published up to 19 March 2023. The keywords used for searching were “crizotinib”, “ceritinib”, “alectinib”, “brigatinib”, “lorlatinib”, “entrectinib”, “ensartinib”, “repotrectinib”, “foretinib”, “TQ-B3139”, “ALK inhibitor”, “neutropenia”, and “safety”. We used the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) method. We summarized primary prospective and retrospective articles to provide a systematic overview of the subject. The full search strategy is provided in Figure 1.

3. Results

Overall, 613 records were identified from PubMed. The titles and abstracts of 583 records were screened, and 532 were excluded. The full texts of the remaining 97 reports were assessed, and 46 articles did not report neutropenia. Thus, the full texts of 51 reports were assessed, and these studies were considered eligible. An overview of the results is presented in Table 1. In our systematic review, 51 articles on ALK inhibitor-induced neutropenia were reviewed. Their main points are summarized in the following sections in parallel with a description of the case series.

3.1. Population Characteristics

A total of 8593 patients were treated with ALK inhibitors in the clinical studies reported in this review. In all, 8398 (98%) were adults and 195 (2%) were children; 7865 patients (92%) were treated for lung cancer, of whom 7270 (92%) had an ALK rearrangement, 290 (4%) had an ROS1 rearrangement and 305 (4%) had another molecular abnormality, such as in RET, MET, or NTRK. In addition, 728 patients (8%) were treated for another type of tumour, such as lymphoma, brain tumour, sarcoma, or kidney cancer. The majority of patients had received prior systemic therapy (5599 patients, 65%), and 2994 patients (35%) had received ALK inhibitor therapy as a first-line therapy.
In total, neutropenia of any grade was reported in 1058 patients (12%). Grade 3 or 4 neutropenia was reported in 557 patients (6%) (Table 1).

3.2. First-Generation ALK Inhibitors Induce Neutropenia

Neutropenia of any grade is reported in 3 to 41% of patients treated with the first-generation ALK inhibitor crizotinib. Grade 3/4 neutropenia is reported in 0 to 30% of patients (Table 1). Neutropenia is one of the most common side effects of crizotinib treatment, as shown in the data from a phase 1 study of crizotinib in ALK-positive NSCLC patients. Thirty-six patients experienced grade 3 or 4 treatment-related adverse events (TRAEs), including nine patients with neutropenia (one with grade 4) [19]. Moreover, in all studies comparing ALK inhibitors to chemotherapy, neutropenia remained more common in those treated with chemotherapy. In a phase 3 study, grade 3 neutropenia was reported in 16.3% of patients administered crizotinib and 20.8% of patients administered chemotherapy [30]. Few data have been reported on the occurrence of neutropenia according to the sex of the patient. Blackhall et al. [23] reported a higher frequency of neutropenia (≥10% points higher) in females than in males in the PROFILE 1005 study. Regarding the timing of neutropenia onset, in a retrospective study in Japan, neutropenia developed within 12 weeks in 210 patients, 12–24 weeks in 31 patients, and 24–52 weeks in 36 patients. The discontinuation rate for crizotinib due to neutropenia was 7.9% [38]. Neutropenia induced by ALK inhibitors is sometimes responsible for treatment interruption and may require dose reduction. In a phase 1 study of crizotinib in ALK-positive NSCLC patients, 20% of patients needed a dose reduction because of neutropenia (n = 2) [18]. In the phase 1 study in children with ALK-positive tumours, crizotinib dose reductions due to toxicity were reported for four patients with grade 4 neutropenia. Two patients were administered crizotinib at 365 mg/m2, one patient at 280 mg/m2, and one patient at 165 mg/m2. Neutropenia arrived between cycles 1 and 7 [22]. In the PROFILE 1005 trial, neutropenia (4%) was one of the TRAEs most commonly associated with dose reductions. The most frequent TRAE associated with dosing interruptions was neutropenia (11%) [22]. Dose reductions were performed due to neutropenia (8.8%; n = 3; all grade 3) in the EUCROSS trial [28].

3.3. Second- and Third-Generation ALK Inhibitors Induce Neutropenia

Between 0 and 26% of patients treated with second- and third-generation ALK inhibitors have been reported to exhibit neutropenia of any grade, and between 0 and 20% of patients have been reported to have grade 3 and 4 neutropenia (Table 1). Regarding second-generation ALK inhibitors, in a real-world surveillance study of alectinib in Japan, grade 1 neutropenia was reported in 50/1221 patients (4.1%), grade 2 neutropenia events in 41/1221 patients (3.4%), and grade ≥ 3 neutropenia events in 14/1221 patients (1.1%). The median time from the start of treatment to the onset of these events was 12.0 days (range 1–550). Overall, 93.3% of events resulted in patient recovery or improvement, with a median time from onset to outcome of 28.5 days (range 1–617) [47]. In a phase 1/2 trial of alectinib, dose-limiting neutropenia was reported in one patient in the 900 mg twice daily alectinib cohort who developed grade 3 neutropenia. In the 900 mg bridging cohort, one patient developed grade 3 neutropenia that required a delay in administration of more than 7 days [41]. When looking at the data for third-generation ALK inhibitors, all grades of neutropenia have been observed in between 0 and 7% of cases. Grade 3/4 neutropenia has been reported in between 0 and 1% of cases (Table 1).

3.4. ALK Inhibitors Induce Neutropenia in Asian Populations

There are differences in the efficacy of ALK inhibitors between Asian and non-Asian populations in clinical studies, as higher objective response rates (ORRs) have been frequently reported in Asian patients than in non-Asian patients [19,30]. Regarding side effects, one study reported the efficacy and safety data from the phase 3 PROFILE 1007 study of second-line treatment and the PROFILE 1014 study of first-line treatment of metastatic NSCLC. Regarding neutropenia, in the PROFILE 1007 study, crizotinib-induced neutropenia of any grade occurred in 27% of patients, while grade 3/4 neutropenia occurred in 13%. In an Asian population, neutropenia of all grades occurred in 38% of patients, and grade 3/4 neutropenia was reported in 19%. This difference was not found in the PROFILE 1014 study, with 21% of patients exhibiting neutropenia of any grade in general and Asian populations [11].

3.5. Febrile Neutropenia

Febrile neutropenia has been reported in 0 to 10% of patients treated with first- and second-generation ALK inhibitors (Table 2). No febrile neutropenia has been described with third-generation ALK inhibitors.

3.6. Neutropenia Management

There are few data on the management of neutropenia induced by ALK inhibitors. Rindone et al. [32], in a retrospective single-centre study, described grade 1/2 neutropenia in 2/27 patients and grade 3/4 neutropenia in 8/27 patients treated with crizotinib. The authors described neutropenia that resolved spontaneously within a few weeks or required a short course of oral steroids. Neutropenia usually developed within 6 months of starting crizotinib. They also described two cases of late neutropenia after 8 months and 60 months of crizotinib treatment [32]. In another retrospective study, six patients had grade 3 neutropenia, and crizotinib was interrupted until the neutropenia levels decreased to grade 2 and then continued at the same dose without recurrence [58]. A case report described a patient treated with third-line crizotinib (500 mg/day). At 36 weeks, he developed grade 4 neutropenia. After discontinuation of crizotinib, neutrophils normalized, but upon reintroduction at 400 mg/day, the patient developed grade 4 neutropenia. A further reduction in dose to 250 mg/day allowed the patient to continue treatment for 20 weeks before disease progression [59]. Another case report described a patient treated with crizotinib at 500 mg/day who developed neutropenia after 2 weeks of treatment. Prednisolone 10 mg/day was introduced, and then crizotinib was resumed with a partial response at 6 months [60]. No toxicity management data were found for second- and third-generation ALK inhibitors.

3.7. Physiopathological Hypotheses

Crizotinib inhibits hepatocyte growth factor (HGF), which plays a role in haematopoiesis, and inhibits mesenchymal epithelial growth factor (cMET), which prevents neutrophil recruitment to the tumour [61]. Neutrophils also play a role in promoting cancer growth by releasing growth factors, including epidermal growth factor, hepatocyte growth factor (HGF), and platelet-derived growth factor [62]. Inflammation is known to promote tumour development and angiogenesis and to inhibit apoptosis [63]. Studies show that high neutrophil counts or a neutrophil-to-lymphocyte ratio ≥ 3 are associated with a poor prognosis [64]. Only one retrospective study of 36 patients showed a prognostic role for neutropenia induced by ALK inhibitors [58]. An immune-related cause has also been described in the literature. Toyota et al. [60] reported on a patient who developed neutropenia after crizotinib treatment. The neutropenia improved only with low-dose steroids [59]. Zeng et al. [65] reported an activated pathway in sepsis involving AKL and STING in the involvement of innate immunity. Using several ALK inhibitors, such as ceritinib and brigatinib, they were able to modulate the activity of STING and thus the innate immune response [65]. Interestingly, one team identified a nonreceptor tyrosine kinase as a potential target to suppress neutrophils. In this study, lorlatinib inactivated FES signalling in neutrophils and suppressed neutrophil expansion in the bone marrow. They demonstrated that lorlatinib reduces tumour-induced granulopoiesis and neutrophil motility [66]. Other ALK inhibitors have shown activity with low concentrations on FES (IC50 < 10 nM). FES is a proto-oncogene present in the myeloid lineages of haematopoietic cells and plays a role in the innate immune response and in myeloid differentiation [67]. These off-target effects of ALK inhibitors may explain the reported neutropenia.

4. Discussion

ALK inhibitors have revolutionized the management of cancers with ALK rearrangement abnormalities, improving PFS and OS in patients compared with chemotherapy. These treatments are currently recommended as a first-line therapy for ALK lung cancer. The management of even rare adverse events, such as neutropenia, is essential for good adherence to these treatments to improve patient survival.
Neutropenia is more frequent with first-generation ALK TKIs than with second- and third-generation TKIs [12,53]. Crizotinib most likely induces haematological toxicity and notably neutropenia. However, these treatments are still better tolerated than chemotherapy, with significantly less haematological toxicity [5,10]. Furthermore, the incidence of neutropenia induced by second-generation ALK inhibitors like ceritinib, alectinib, and brigatinib or third-generation ALK inhibitors like lorlatinib is minimal. The incidence of febrile neutropenia is low, particularly for second- and third-generation treatments, with less than 10% of cases reported.
Due to its rarity, very few data on the management of neutropenia during treatment with ALK inhibitors are available. Moreover, all data concern crizotinib and not second- or third-generation ALK inhibitors. According to the cases reported, management depends, as usual, on the toxicity grade. For grade 3 and higher, treatment is usually stopped until neutrophil count normalization or at least less than or equal to that of grade 2. With a half-life of 40 h, neutropenia induced by crizotinib usually persists for 3 to 4 weeks after treatment arrest. In cases of prolonged neutropenia, there are reports of a benefit of short-term low-dose steroids. After recovery, one patient with grade 3 neutropenia resumed crizotinib at the same dose without recurrence. Other reported cases have reduced the dose of treatment, but one of them, with grade 4 neutropenia, showed recurrence of neutropenia. The dose dependence of neutropenia and crizotinib is not clear and dose reduction may favour loss of efficacy more than prevention of this toxicity. For second-generation TKIs, data have been reported on the use of ceritinib and alectinib, but there is no information on management or specific recommendations. Brigatinib and third-generation lorlatinib appear to be less likely to cause neutropenia.
Regarding the prognostic value of induced neutropenia, the scarcity of data makes it impossible to conclude any correlation. In other situations, treatment-induced side effects may have predictive value. The example of high blood pressure has been reported as an efficacy marker for bevacizumab or some anti-VEGF TKIs [68,69]. In another example, in metastatic renal cell carcinoma, TKI-induced high blood pressure may be a good predictor for a better prognosis in patients [70]. For ALK inhibitors, only one case report has described an association between the occurrence of neutropenia and improved progression-free survival with crizotinib treatment [58]. For second- and third-generation therapies, despite a clear relationship between treatment concentration and progression-free survival, especially for alectinib and crizotinib, no evidence has been reported on side effects and efficacy [71]. Additionally, risk factors have not been clearly identified. Hypotheses about a sex or ethnic predisposition to neutropenia require further exploration.
Pharmacovigilance studies would remain the best way to assess the haematological toxicity of ALK inhibitors and obtain a better understanding of the underlying management.
In view of the data in the literature, we propose the management of neutropenia induced by ALK inhibitors. In the event of neutropenia below 500 mm3, we propose temporary interruption of treatment, followed by resumption with a reduction in dosage. In the event of recurrence, we suggest the introduction of corticosteroid therapy. This management is essential to maintain treatment, given its survival benefit for patients. There are no data in the literature on changing ALK inhibitor treatment. In our experience, in the event of recurrence of neutropenia despite discontinuation of treatment, changing the molecule does not eliminate this haematological toxicity.

5. Conclusions

Neutropenia induced by ALK inhibitors is a common side effect of first-generation therapies and less common with second- and third-generation therapies. Dose reduction is sometimes required to continue treatment, and in a few patients, a low dose of corticosteroids allowed treatment to continue. There are fewer data on the new generation of ALK inhibitors currently used in practice, but these treatments seem less likely to cause neutropenia. Given the metastatic survival data on lung cancer treated with ALK inhibitors, it is important to manage the toxicity associated with these treatments. Several pathophysiological hypotheses have been described, but further studies are needed, especially pharmacovigilance studies.

Author Contributions

F.M.-B. and R.S. provided direction and guidance throughout the writing of this manuscript. F.M.-B. collected and interpreted the studies and data. F.M.-B., L.B., C.F., S.N., S.A., T.P., M.D. and R.S. made substantial contributions to the writing of the manuscript and generation of the figures and tables. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

R.S. declared Roche for an advisory role, Pfizer, and Takeda for travel and accommodation.

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Cancers 15 04940 g001
Figure 1. Study selection.
Figure 1. Study selection.
Cancers 15 04940 g001
Table 1. ALK inhibitors induced neutropenia of all grades and grades 3–4.
Table 1. ALK inhibitors induced neutropenia of all grades and grades 3–4.
Ref.Study DesignPopulation Treated with ALK InhibitorsCancer TypeLines of Treatment before Metastatic DiseaseTreatment and DoseRegionNeutropenia
All Grade
n (%)		Neutropenia
G3–4
n (%)
[19]Phase 1, single-arm, multicentreAdults
n = 149		ALK-positive lung cancer16% of patients had no previous treatment regimen
Other patients had 1–4 or more previous lines of treatment		Crizotinib 250 mg twice per dayUSA, Australia, and South KoreaNR9 (25)
[20]Phase 1, open-label, expansion cohort, multicentreAdults
n = 53		ROS1-rearranged lung cancer13% of patients had no previous treatment
65% of patients had 1–2 previous lines of treatment
23% of patients had 3 or more previous lines of treatment		Crizotinib 250 mg twice per dayInternational8 (15)5 (9)
[21]Phase 1b, open-label, single-arm, multicentreAdults
n = 44		ALK-positive tumours (excluding lung cancer)16% of patients had no prior systemic therapy
Other patients had 1 or more prior lines of treatment		Crizotinib 250 mg twice per dayInternational14 (32)10 (23)
[22]Phase 1, open-label, multicentreChildren
n = 65		ALK-positive solid tumours, lymphomas, CNS tumoursRefractory to therapyDose escalationcrizotinib 100, 130, 165, 215, 280, and 365 mg/m2 twice per dayUSA21 (32)10 (15)
[23]Phase 2, multicentre, single-armAdults
n = 1069		ALK-positive lung cancer25% of patients had 1 prior line of systemic therapy
74% had 2 or more prior lines of treatment		Crizotinib 250 mg twice per dayInternational226 (21)137 (13)
[24]Phase 2, multicentre, nonrandomized, open-labelAdults
n = 34		MET alterations clear cell sarcoma26% had previous systemic therapyCrizotinib 250 mg twice per dayEurope6 (18)2 (6)
[25]Phase 2, multicentre, single-agent, open-labelAdults
n = 48		Rearrangement of TFE3 alveolar soft part sarcoma48% had received systemic therapyCrizotinib 250 mg twice per dayEurope8 (17)2 (4)
[26]Phase 2, single-arm, multicentreAdults
n = 127		ROS1-rearranged lung cancer19% of patients had no prior therapy
42% had 1 prior line of therapy
39% had 2 or more prior lines of therapy		Crizotinib 250 mg twice per dayEast Asia43 (34)15 (12)
[27]Phase 2, multicentre, single-armAdults
n = 20		Inflammatory myofibroblastic tumours40% of patients had prior systemic therapyCrizotinib 250 mg twice per dayEurope4 (20)2 (10)
[28]Phase 2, multicentre, single-armAdults
n = 34		ROS1-rearranged lung cancer21% of patients had no prior therapy
Other patients had 1 or more prior lines of therapy		Crizotinib 250 mg twice per dayEurope11 (32)3 (9)
[29]Phase 2, open-label, randomizedAdults
n = 152		Papillary renal cell carcinoma7% of patients had prior systemic therapyCrizotinib 250 mg twice per dayUSA and Canada1 (3)0 (0)
[5]Phase 3, randomized, open-label, multicentreAdults
n = 171		ALK-positive lung cancerNo prior therapyCrizotinib 250 mg twice per dayInternational42 (25)26 (15)
[30]Phase 3, randomized, open-label, multicentreAdults
n = 104		ALK-positive lung cancerNo prior therapyCrizotinib 250 mg twice per dayEast Asia43 (41)17 (16)
[31]Prospective, multicentre studyAdults
n = 11		ALK-positive anaplastic large T-cell lymphomaPrevious chemotherapyCrizotinib 250 mg twice per dayEurope and North America2 (18)0 (0)
[32]Retrospective, monocentricAdults
n = 27		ALK-positive anaplastic large T-cell lymphoma Lymphoma2 median previous lines (range 1–6)Crizotinib 250 mg twice per dayEurope10 (37)8 (30)
[33]Retrospective, national cohortAdults
n = 90		c-MET and ROS1-positive lung cancerBetween 1–7 previous lines of systemic therapyCrizotinib 250 mg twice per dayFrance21 (23)9 (10)
[34]Retrospective, monocentreAdults
n = 35		ROS1-rearranged lung cancer49% of patients had 1 previous line of therapy
31% of patients had 2 previous lines of therapy
20% of patients had 3 or more previous lines of therapy		Crizotinib 250 mg twice per dayChina5 (14)1 (3)
[35]Retrospective, monocentreAdults
n = 7		ALK-positive lung cancerNo prior therapyCrizotinib 250 mg twice per dayChina1 (14)0 (0)
[36]Chart review, retrospective studyAdults
n = 38		ALK-positive lung cancer55% had prior chemotherapyCrizotinib 250 mg twice per dayKuwait and Saudi Arabia6 (16)0 (0)
[37]Retrospective, single-centreAdults
n = 104		ALK-positive lung cancer61% of patients had no prior therapy
Other patients had 1 or more prior lines of therapy		Crizotinib 250 mg twice per dayChina20 (19)3 (3)
[38]Retrospective, multicentreAdults
n = 2028		ALK-positive lung cancer28% of patients had no prior lines of therapy
Other patients had 1 or more prior lines of therapy		Crizotinib 250 mg twice per dayJapan278 (14)183 (9)
[39]Retrospective, multicentreAdults
n = 91		ALK-positive lung cancer44% of patients had no prior chemotherapyCrizotinib 250 mg twice per daySpain8 (9)4 (4)
[40]Phase 1/2, multicentre, open-labelAdults
n = 28		RET-rearranged lung cancer21% of patients had 1 prior line of chemotherapy
79% had 2 or more prior lines of chemotherapy		Alectinib 450 mg twice per dayJapan1 (4)1 (4)
[41]Phase 1/2, single-arm, open-labelAdults
n = 47		ALK-positive lung cancer13% of patients had no prior therapy
57% had 1 or 2 prior lines of therapy
30% had 3 or more prior lines of therapy		Dose escalation Alectinib 300 mg, 460 mg, 600 mg, 760 mg, 900 mg twice per dayUSA3 (6)2 (4)
[42]Phase 1/2, single-arm, open-labelAdults
n = 58		ALK-positive lung cancer2% of patients had no prior therapy
Other patients had 1 or more prior lines of therapy		Dose escalation Alectinib 20 to 300 mg twice dailyJapan15 (26)4 (7)
[43]Phase 2, multicentreAdults
n = 18		ALK-positive lung cancer with poor performance status72% had no previous systemic therapy
28% had chemotherapy, crizotinib or both		Alectinib 300 mg twice per dayJapan3 (17)0 (0)
[44]Phase 2, open-label, multicentreChildren and Adults
n = 10		ALK-positive anaplastic large T-cell lymphoma1 or 2 previous lines of systemic therapyAlectinib 600 mg twice per dayJapan2 (20)2 (20)
[13]Phase 2, multicentre, single-agent, open-labelAdults
n = 87		ALK-positive lung cancer, crizotinib-resistant74% of patients had previous chemotherapyAlectinib 600 mg twice per dayUSA and Canada4 (5)1 (1)
[4]Phase 3, multicentre, randomized, open-labelAdults
n = 70		ALK-positive lung cancer, crizotinib pretreated2 prior lines of systemic therapyAlectinib 600 mg twice per dayEurope and Asia2 (3)0 (0)
[45]Phase 3, multicentre, randomized, open-labelAdults
n = 303		ALK-positive lung cancerNo prior therapyAlectinib 600 mg twice per day or Crizotinib 250 mg twice per day NRAlectinib: 0 (0)
vs.
Crizotinib: 8 (5)
[17]Phase 3, multicentre, randomized, open-labelAdults
n = 207		ALK-positive lung cancer64% of patients had no prior systemic therapy
Other patients had 1 line of systemic therapy		Alectinib 600 mg twice per day or Crizotinib 250 mg twice per dayJapanAlectinib: 3 (3)
vs.
Crizotinib: 19 (18)		Alectinib: 2 (2)
vs.
Crizotinib: 14 (14)
[46]Phase 3, randomized, open-label, multicentreAdults
n = 187		ALK-positive lung cancerNo prior therapyAlectinib 600 mg twice per day or Crizotinib 250 mg twice per dayChina, South Korea, ThailandAlectinib: 4 (3)
vs.
Crizotinib: 12 (19)		Alectinib: 0 (0)
vs.
Crizotinib: 7 (11)
[47]Retrospective, multicentreAdults
n = 1221		ALK-positive lung cancer18% of patients had no prior therapy
81% had 1 or more prior lines of therapy		Alectinib 300 mg twice dailyJapan93 (8)14 (1)
[48]Phase 1, open-labelAdults
n = 246		ALK-positive lung cancer19% of patients had no previous treatment regimen
Other patients had 1–4 or more previous lines of treatment		Ceritinib 750 mg in dose escalationEurope and North America and Asia-PacificNR4 (2)
[49]Phase 1, multicentre, open-labelChildren
n = 83		ALK-positive malignancies55% of patients had 1–2 previous lines of therapy
25% of patients had 3 or more previous lines of therapy		Ceritinib dose escalation
500 mg/m2, 510 mg/m2		International9 (11)6 (7)
[50]Phase 1, multicentre, open-labelAdults
n = 20		ALK-positive lung cancer and inflammatory myofibroblastic tumours80% had prior ALK therapyDose escalationCeritinib 300 mg, 450 mg, 600 mg, and 750 mg per dayJapan4 (20)0 (0)
[51]Phase 3, multicentre, randomized, open-labelAdults
n = 76		ALK-positive lung cancerAll patients had no prior therapyCeritinib 750 mg per dayAsia8 (10)2 (3)
[6]Phase 3, randomized, controlled, open-labelAdults
n = 115		ALK-positive lung cancerAll patients had crizotinib and 1 or 2 lines of chemotherapyCeritinib 750 mg per dayInternational4 (3)1 (2)
[18]Phase 3, randomized, open-label, multicentreAdults
n = 189		ALK-positive lung cancerNo prior therapyCeritinib 750 mg per dayInternational9 (5)1 (1)
[10]Phase 3, randomized, open-label, multicentreAdults
n = 11		ALK-positive lung cancerAll patients had 1 prior line of chemotherapyCeritinib 750 mg per dayJapan1 (9)0 (0)
[52]Phase 3, multicentre, randomized, open-labelAdults
n = 275		ALK-positive lung cancerNo prior therapyBrigatinib 180 mg per day or Crizotinib 250 mg twice per dayInternationalBrigatinib: 3 (2)
vs.
Crizotinib: 13 (10)		Brigatinib: 3 (2)
vs.
Crizotinib: 11 (8)
[14]Phase 3, randomized, open-label, multicentreAdults
n = 296		ALK-positive lung cancerNo prior therapyLorlatinib 100 mg per day or Crizotinib 250 mg twice per dayInternationalLorlatinib: 10 (7)
vs.
Crizotinib: 21 (15)		Lorlatinib: 1 (1)
vs.
Crizotinib: 12 (8)
[53]Phase 3, randomized, open-label, multicentreAdults
n = 25		ALK-positive lung cancerNo prior therapyLorlatinib 100 mg per day or Crizotinib 250 mg twice per dayJapanLorlatinib: 0 (0)
vs.
Crizotinib: 4 (18)		Lorlatinib: 0 (0)
vs.
Crizotinib: 3 (14)
[54]Phase 1 and phase 2, single-arm, multicentreAdults
n = 193		NTRK tumours73% of patients had prior chemotherapyEntrectinib 600 mg/dayInternational11 (6)4 (2)
[55]Phase 1 and phase 2, single-arm, multicentreAdults
n = 224		ROS1-positive lung cancer63% of patients had prior systemic therapyEntrectinib 600 mg/dayInternational10 (4)5 (2)
[56]Phase 1/2, single-arm, multicentreChildren
n = 43		ALK, ROS1, NTRK solid tumours or primary CNS tumours77% of patients had prior chemotherapyDose escalationEntrectinib 250, 400, 550, 750 mg/m2North America, Europe, North Korea4 (9)3 (7)
[57]Phase 1, dose escalationAdults
n = 63		ALK- and ROS1- rearranged lung cancer25% of patients had prior ALK-TKI treatment
48% of patients had chemotherapy		TQ-B3139 50–800 mgChina8 (13)0 (0)
Abbreviations: CNS: central nervous system; TKI: tyrosine kinase inhibitor.
Table 2. ALK inhibitors induced febrile neutropenia.
Table 2. ALK inhibitors induced febrile neutropenia.
Ref.Study DesignPopulationCancer TypeTreatment and DoseFebrile Neutropenia (%)
[22]Phase 1, open-label, multicentreChildren
n = 79		ALK-positive solid tumours, lymphomas, CNS tumoursDose escalation
crizotinib 100, 130, 165, 215, 280, and 365 mg/m2 twice per day		10
[23]Phase 2, multicentre, single-armAdults
n = 1069		ALK-positive lung cancerCrizotinib 250 mg twice per day3
[25]Phase 2, multicentre, single-agent, open-labelAdults
n = 45		TFE3-rearranged alveolar soft part sarcomaCrizotinib 250 mg twice per day2
[44]Phase 2, open-label, multicentreChildren and Adults
n = 10		ALK-positive anaplastic large T-cell lymphomaAlectinib 600 mg twice per day10
[48]Phase 1, open-labelAdults
n = 255		ALK-positive lung cancerCeritinib 750 mg in dose escalation<1
[6]Phase 3, randomized, controlled, open-labelAdults
n = 231		ALK-positive lung cancerCeritinib 750 mg per day0
Abbreviations: CNS: central nervous system.
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Moinard-Butot, F.; Nannini, S.; Fischbach, C.; Abdallahoui, S.; Demarchi, M.; Petit, T.; Bender, L.; Schott, R. Anaplastic Lymphoma Kinase Inhibitor-Induced Neutropenia: A Systematic Review. Cancers 2023, 15, 4940. https://doi.org/10.3390/cancers15204940

AMA Style

Moinard-Butot F, Nannini S, Fischbach C, Abdallahoui S, Demarchi M, Petit T, Bender L, Schott R. Anaplastic Lymphoma Kinase Inhibitor-Induced Neutropenia: A Systematic Review. Cancers. 2023; 15(20):4940. https://doi.org/10.3390/cancers15204940

Chicago/Turabian Style

Moinard-Butot, Fabien, Simon Nannini, Cathie Fischbach, Safa Abdallahoui, Martin Demarchi, Thierry Petit, Laura Bender, and Roland Schott. 2023. "Anaplastic Lymphoma Kinase Inhibitor-Induced Neutropenia: A Systematic Review" Cancers 15, no. 20: 4940. https://doi.org/10.3390/cancers15204940

APA Style

Moinard-Butot, F., Nannini, S., Fischbach, C., Abdallahoui, S., Demarchi, M., Petit, T., Bender, L., & Schott, R. (2023). Anaplastic Lymphoma Kinase Inhibitor-Induced Neutropenia: A Systematic Review. Cancers, 15(20), 4940. https://doi.org/10.3390/cancers15204940

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