Pattern of failure analysis in ALK-positive non-small cell lung cancer patients treated with targeted therapy

doi:10.3877/cma.j.issn.1674-6902.2026.02.002

Abstract

Abstract:

Objective

To investigate the impact of distinct clinical progression patterns on progression-free survival (PFS) in patients with anaplastic lymphoma kinase (ALK) fusion gene-positive non-small cell lung cancer (NSCLC) following treatment with first-generation, first-line and sequential second-line second-generation ALK tyrosine kinase inhibitors (ALK-TKIs), to analyze whether baseline patient characteristics can predict progression patterns, and to evaluate survival differences among various treatment strategies after second-generation ALK-TKI resistance.

Methods

A retrospective analysis was conducted on ALK-positive advanced NSCLC patients who experienced disease progression after ALK-TKI therapy between January 1, 2017, and September 30, 2025, across four centers (Eastern Theater Command General Hospital, Hunan Cancer Hospital, Shanxi Bethune Hospital, and Nanjing Chest Hospital). Patients were divided into first-generation ALK-TKI resistance cohort and second-generation ALK-TKI resistance cohort based on the targeted agent and treatment line at the time of drug resistance. The second-generation ALK-TKI resistance cohort included two subgroups: patients progressed after first-line second-generation ALK-TKI treatment, and patients progressed after sequential second-generation ALK-TKI treatment (second-line) following first-generation ALK-TKI. Progression patterns (oligoprogression vs. systemic progression; primary site progression vs. distant site progression) were assessed according to RECIST 1.1 criteria. Kaplan-Meier method was used for PFS analysis, and Firth regression was applied to identify predictive factors for systemic progression after second-generation ALK-TKI resistance.

Results

The first- and second-generation TKI resistance cohorts included 53 and 56 patients, respectively. The median PFS for patients with oligoprogression after second-generation TKI resistance (17.7 months; 95%CI: 12.5~22.8 months) was significantly longer than for those with systemic progression (9.0 months; 95%CI: 4.5~13.5 months, P<0.001). Subgroup analysis showed that patients with oligoprogression had significantly better PFS than those with systemic progression, regardless of first-line or sequential second-line second-generation TKI treatment (all P<0.05). Patients presenting with oligometastatic disease before second-generation TKI treatment were less likely to develop systemic progression (OR=0.18, 95%CI: 0.03~0.87, P=0.033). After second-generation TKI resistance, no significant difference in PFS was observed among patients who continued the original drug, switched to another second-generation TKI, or initiated a third-generation TKI (P=0.979).

Conclusions

After second generation ALK-TKI resistance, oligoprogression pattern is associated with longer PFS regardless of treatment line, and pre-treatment metastatic status may serve as an independent predictor for the progression pattern. No significant difference in efficacy was found among different subsequent TKI strategies following second-generation TKI resistance, and this result is only an exploratory analysis, which needs to be further verified by prospective studies

Key words: Non-small cell lung cancer, Anaplastic lymphoma kinase, Tyrosine kinase inhibitor

Mengyi Shen, Jiayan Chen, Yueying Chen, Zhen Wang, Chunwei Xu, Dong Wang, Tangfeng Lyu. Pattern of failure analysis in ALK-positive non-small cell lung cancer patients treated with targeted therapy[J]. Chinese Journal of Lung Diseases(Electronic Edition), 2026, 19(02): 189-196.

/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: https://zhfbjbzz.cma-cmc.com.cn/EN/10.3877/cma.j.issn.1674-6902.2026.02.002

https://zhfbjbzz.cma-cmc.com.cn/EN/Y2026/V19/I02/189

Figures/Tables 5

References 35

1	Julia R, Trever GB. Understanding and targeting resistance mechanisms in NSCLC[J]. Nature Reviews Cancer, 2017, 17(11): 637-658.
2	Benjamin JS, Todd MB, Tony SKM, et al. Efficacy and safety of first-line lorlatinib versus crizotinib in patients with advanced, ALK-positive non-small-cell lung cancer: updated analysis of data from the phase 3, randomised, open-label CROWN study[J]. Lancet Respir Med, 2022, 11(4): 354-366.
3	Wang L, Wang W. Safety and efficacy of anaplastic lymphoma kinase tyrosine kinase inhibitors in non-small cell lung cancer (Review)[J]. Oncol Rep, 2021, 45(1): 13-28.
4	Lara C, Natasha BL, Mina T, et al. Trends in real-world clinical outcomes of patients with anaplastic lymphoma kinase (ALK) rearranged non-small cell lung cancer (NSCLC) receiving one or more ALK tyrosine kinase inhibitors (TKIs): a cohort study in ontario, canada[J]. Current Oncology, 2024, 32(1): 13.
5	Noriyuki M, Yuichiro O, Akihiko G, et al. Safety and effectiveness of alectinib in a real-world surveillance study in patients with ALK-positive non-small-cell lung cancer in Japan[J]. Cancer Sci, 2019, 110(4): 1401-1407.
6	Darin P, Sana A, Ye S, et al. ALK inhibitors in cancer: mechanisms of resistance and therapeutic management strategies[J]. Cancer Drug Resist, 2024, 7: 20.
7	Antoine B, Hubert C, Isabelle M, et al. Rebiopsy feasibility and clinical impact on metastatic non-small-cell lung cancer with EGFR/ALK/ROS oncogenic driver progression after optimal targeted therapy: a multicenter real-world analysis[J]. Clin Lung Cancer, 2025, 26(8): e724-e730.
8	徐天亮，程干思，吴亚平，等. 奥希替尼联合安罗替尼二线治疗转移性NSCLC的疗效分析[J/OL]. 中华肺部疾病杂志(电子版), 2023, 16(4): 520-522.
9	张剑，卢从华，李江华，等. 根据转录组学分析奥希替尼获得性耐药机制的研究[J/OL]. 中华肺部疾病杂志(电子版), 2024, 17(2): 195-200.
10	中国医师协会肿瘤医师分会，中国医疗保健国际交流促进会肿瘤内科学分会. 间变性淋巴瘤激酶酪氨酸激酶抑制剂治疗非小细胞肺癌指南(2025版)[J]. 中华肿瘤杂志，2025, 47(4): 283-297.
11	Taimei T, Yosuke M, Hironori N, et al. Optimal treatment strategy for oligo-recurrence lung cancer patients with driver mutations[J]. Cancers, 2024, 16(2): 464.
12	David Chun CT, Douglas EH, Tejas P, et al. The role of local therapy for oligo-progressive disease in oncogene-addicted non-small-cell lung cancer[J]. Adv Radiat Oncol, 2024, 9(7): 101516.
13	Li N, Xie MY, Zhou ZC, et al. Real-world treatment and prognostic factors for survival in ALK＋ non-small cell lung cancer (NSCLC) patients with brain metastases in China[J]. Thorac Cancer, 2023, 14(3): 237-245.
14	Eisenhauer EA, Therasse P, Bogaerts J, et al. New response evaluation criteria in solid tumours: revised RECIST guideline (version 1.1)[J]. Eur J Cancer, 2009, 45(2): 228-247.
15	Anne-Marie CD, Lizza ELH, Thierry B, et al. Definition of synchronous oligometastatic non-small cell lung cancer-a consensus report[J]. J Thorac Oncol, 2019, 14(12): 2109-2119.
16	Revathi R, Erin Jay GF, Edward CD, et al. Management of oligoprogressive and oligopersistent disease in advanced NSCLC[J]. Clin Adv Hematol Oncol, 2025, 23(1): 40-50.
17	Andrew JW, Benjamin S, Joseph MB, et al. Local ablative therapy of oligoprogressive disease prolongs disease control by tyrosine kinase inhibitors in oncogene-addicted non-small-cell lung cancer[J]. J Thorac Oncol, 2012, 7(12): 1807-1814.
18	Daijiro H, Nagio T. Oligoprogression in non-small cell lung cancer[J]. Cancers, 2021, 13(22): 5823.
19	Hani Al-Halabi, Karl S, Subba RD, et al. Pattern of failure analysis in metastatic EGFR-mutant lung cancer treated with tyrosine kinase inhibitors to identify candidates for consolidation stereotactic body radiation therapy[J]. J Thorac Oncol, 2015, 10(11): 1601-1607.
20	Mei E, Petros C. Therapeutic sequencing in ALK＋ NSCLC[J]. Pharmaceuticals (Basel, Switzerland), 2021, 14(2): 80.
21	Daniel BC, Susumu K, Shuchi SP, et al. CSF concentration of the anaplastic lymphoma kinase inhibitor crizotinib[J]. J Clin Oncol, 2011, 29(15): e443-e445.
22	Cole F, Nicholas M, Wei F, et al. Isolated progression of metastatic lung cancer: Clinical outcomes associated with definitive radiotherapy[J]. Cancer, 2020, 126(20): 4572-4583.
23	Wu LG, Zou ZH, Li Y, et al. Progression patterns, resistant mechanisms and subsequent therapy for ALK-positive NSCLC in the era of second-generation ALK-TKIs[J]. J Transl Med, 2024, 22(1): 585.
24	Gadgeel S, Peters S, Mok T, et al. Alectinib versus crizotinib in treatment-naive anaplastic lymphoma kinase-positive (ALK＋) non-small-cell lung cancer: CNS efficacy results from the ALEX study[J]. Ann Oncol, 2018, 29(11): 2214-2222.
25	Leora H, Wang ZP, Wu G, et al. Ensartinib vs crizotinib for patients with anaplastic lymphoma kinase-positive non-small cell lung cancer: a randomized clinical trial[J]. JAMA Oncol, 2021, 7(11): 1617-1625.
26	Takahiro U, Hayato M, Yosuke S, et al. AXL-mediated drug resistance in ALK-rearranged NSCLC enhanced by GAS6 from macrophages and MMP11 positive fibroblasts[J]. Cancer Sci, 2025, 116(4): 1034-1047.
27	Friedes C, Yegya-Raman N, Zhang SQ, et al. Patterns of failure in metastatic NSCLC treated with first line pembrolizumab and use of local therapy in patients with oligoprogression[J]. ClinLung Cancer, 2023, 25(1): 50-60.
28	Wei YQ, Shen KK, Lv TF, et al. Three new disease-progression modes in NSCLC patients after EGFR-TKI treatment by next-generation sequencing analysis[J]. Lung Cancer, 2018, 125: 43-50.
29	Ibiayi DJ, Marguerite R, Jessica JL, et al. Treatment with Next-generation ALK inhibitors fuels plasma ALK mutation diversity[J]. Clin Cancer Res, 2019, 25(22): 6662-6670.
30	Li YM, Hao ZP, Ma YY, et al. Alectinib continuation beyond progression in ALK-positive non-small cell lung cancer with alectinib-refractory[J]. Transl Lung Cancer Res, 2024, 13(1): 152-162.
31	Justin FG, Leila D, Satoshi Y, et al. Molecular mechanisms of resistance to first- and second-generation ALK inhibitors in ALK-rearranged lung cancer[J]. Cancer Discov, 2016, 6(10): 1118-1133.
32	Dagogo-Jack I, Brannon AR, Lorin AF, et al. Tracking the evolution of resistance to ALK tyrosine kinase inhibitors through longitudinal analysis of circulating tumor DNA[J]. JCO Precis Oncol, 2018, 2018: PO.17.00160.
33	Shiba-Ishii A, Johnson TW, Dagogo-Jack I, et al. Analysis of lorlatinib analogs reveals a roadmap for targeting diverse compound resistance mutations in ALK-positive lung cancer[J]. Nature Cancer, 2022, 3(6): 710-722.
34	Hu J, Ding N, Xu X, et al. MET and NF2 alterations confer primary and early resistance to first-line alectinib treatment in ALK-positive non-small-cell lung cancer[J]. Mol Oncol, 2025, 19(9): 2715-2729.
35	Xie Y, Zhang Y, Wu Y, et al. Analysis of the resistance profile of real-world alectinib first-line therapy in patients with ALK rearrangement-positive advanced non-small cell lung cancer using organoid technology in one case of lung cancer[J]. J Thorac Dis, 2024, 16(6): 3854-3863.

临床资料	一代耐药队列(n＝53)	二代耐药队列(n＝56)
性别
男	25(47.17)	30(53.57)
女	28(52.83)	26(46.43)
年龄	51.89±11.81	52.29±9.44
吸烟史
无	45(84.91)	45(80.36)
有	8(15.09)	11(19.64)
ECOG评分
0-1	52(98.11)	48(85.71)
≥2	1(1.87)	8(14.29)
临床分期
ⅢB、ⅢC	10(18.87)	3(5.38)
ⅣA	17(32.08)	19(33.93)
ⅣB	26(49.06)	34(60.71)
耐药时所使用的TKI
克唑替尼	53(100.00)	/
阿来替尼	/	36(64.29)
布加替尼	/	5(8.93)
恩沙替尼	/	4(7.14)
赛瑞替尼	/	11(19.64)
基线转移部位
肺	12(22.64)	9(16.07)
中枢神经系统	10(18.87)	17(30.36)
胸膜	22(41.51)	18(32.14)
骨	19(35.85)	25(44.64)
肾上腺	2(3.73)	5(8.93)
肝	5(9.43)	10(17.86)
腹腔	3(5.66)	4(7.14)

临床资料	一代耐药队列(n＝53)	二代耐药队列(n＝56)
性别
男	25(47.17)	30(53.57)
女	28(52.83)	26(46.43)
年龄	51.89±11.81	52.29±9.44
吸烟史
无	45(84.91)	45(80.36)
有	8(15.09)	11(19.64)
ECOG评分
0-1	52(98.11)	48(85.71)
≥2	1(1.87)	8(14.29)
临床分期
ⅢB、ⅢC	10(18.87)	3(5.38)
ⅣA	17(32.08)	19(33.93)
ⅣB	26(49.06)	34(60.71)
耐药时所使用的TKI
克唑替尼	53(100.00)	/
阿来替尼	/	36(64.29)
布加替尼	/	5(8.93)
恩沙替尼	/	4(7.14)
赛瑞替尼	/	11(19.64)
基线转移部位
肺	12(22.64)	9(16.07)
中枢神经系统	10(18.87)	17(30.36)
胸膜	22(41.51)	18(32.14)
骨	19(35.85)	25(44.64)
肾上腺	2(3.73)	5(8.93)
肝	5(9.43)	10(17.86)
腹腔	3(5.66)	4(7.14)

临床资料	一线二代耐药(n＝30)	一代序贯二代耐药(n＝26)	统计值(F/χ²)	P值
临床分期				0.828
ⅢB、ⅢC	1(3.33)	2(7.69)
ⅣA	10(33.33)	9(34.62)
ⅣB	19(63.34)	15(57.69)
耐药时所使用的TKI				0.577
克唑替尼	/	/
阿来替尼	20(66.67)	16(61.54)
布加替尼	2(6.67)	3(11.54)
恩沙替尼	1(3.33)	3(11.54)
赛瑞替尼	7(23.33)	4(15.38)
基线转移部位
肺	4(13.33)	5(19.23)		0.719
中枢神经系统	10(33.33)	7(26.92)	0.271	0.603
胸膜	6(20.00)	12(46.15)	4.368	0.037
骨	13(43.33)	12(44.15)	0.045	0.832
肾上腺	5(16.67)	0		0.055
肝	6(20.00)	4(15.38)		0.737
腹腔	3(10.00)	1(3.84)		0.615

临床资料	一线二代耐药(n＝30)	一代序贯二代耐药(n＝26)	统计值(F/χ²)	P值
临床分期				0.828
ⅢB、ⅢC	1(3.33)	2(7.69)
ⅣA	10(33.33)	9(34.62)
ⅣB	19(63.34)	15(57.69)
耐药时所使用的TKI				0.577
克唑替尼	/	/
阿来替尼	20(66.67)	16(61.54)
布加替尼	2(6.67)	3(11.54)
恩沙替尼	1(3.33)	3(11.54)
赛瑞替尼	7(23.33)	4(15.38)
基线转移部位
肺	4(13.33)	5(19.23)		0.719
中枢神经系统	10(33.33)	7(26.92)	0.271	0.603
胸膜	6(20.00)	12(46.15)	4.368	0.037
骨	13(43.33)	12(44.15)	0.045	0.832
肾上腺	5(16.67)	0		0.055
肝	6(20.00)	4(15.38)		0.737
腹腔	3(10.00)	1(3.84)		0.615

NSCLC转移器官及模式	一代耐药队列(n＝53)	二代耐药队列(n＝56)	统计值(χ²值)	P值
进展部位
肺	18(33.96)	12(21.43)	2.144	0.143
中枢神经系统	25(47.17)	22(39.29)	0.690	0.406
胸膜	6(11.32)	7(12.50)	0.036	0.849
骨	4(7.55)	6(10.71)		0.743
肾上腺	1(1.89)	1(1.78)		1.000
肝	2(3.87)	4(7.14)		0.679
腹腔	1(1.89)	2(3.57)		1.000
区域淋巴结	3(5.66)	2(3.57)		0.673
进展模式			0.056	0.813
寡进展	30(56.60)	34(60.71)
全身进展	23(43.40)	22(39.29)
进展模式			4.243	0.039
原发部位进展	12(22.64)	23(41.07)
远处部位进展	41(77.36)	33(58.93)

Please choose a citation manager

Content to export