放射性淋巴细胞减少对局限期小细胞肺癌患者预后的影响：一项队列研究

doi:10.19401/j.cnki.1007-3639.2025.09.007

摘要/Abstract

摘要：

背景与目的： 尽管放射性淋巴细胞减少与某些恶性肿瘤的不良生存结局相关，但是关于小细胞肺癌（small cell lung cancer，SCLC）的研究证据仍较少。本研究旨在探讨放疗前后淋巴细胞计数是否能预测局限期SCLC（limited-stage SCLC，LS-SCLC）患者的临床预后。方法： 本研究为一项单中心回顾性队列研究。回顾性分析2007年1月—2017年12月在复旦大学附属肿瘤医院接受根治性放化疗的LS-SCLC患者。纳入标准包括：⑴ 经病理学检查确认为SCLC；⑵ 通过正电子发射计算机体层成像（positron emission tomography and computed tomography，PET/CT）、脑增强磁共振成像（magnetic resonance imaging，MRI）诊断为局限期[美国癌症联合会（American Joint Committee on Cancer，AJCC）第8版TNM分期M0]；⑶ 接受了根治性放化疗；⑷ 具有放疗前、放疗期间及放疗后1个月的血常规数据；⑸ 可获得完整的生存、复发及末次随访信息。排除标准包括：⑴ 基线远处转移（AJCC第8版TNM分期M1，包括任何远处淋巴结、器官或骨髓转移）；⑵ 放疗剂量小于50 Gy[以等效生物剂量2 Gy/次计算，即生物有效剂量（biological effective dose，BED）<40 Gy]；⑶ 放疗前、放疗期间及放疗后的数据不完整；⑷ 无法获知生存、复发状态或末次随访记录不完整。本研究获得复旦大学附属肿瘤医院伦理委员会的批准（伦理编号：2303271-15），并豁免了患者的知情同意。采集的临床数据包括患者年龄、性别、美国东部肿瘤协作组体能状态（Eastern Cooperative Oncology Group performance status，ECOG PS）评分、吸烟史、肿瘤TNM分期、化疗方案与周期、放疗剂量与分割方式、是否同步放化疗、是否接受预防性颅脑照射（prophylactic cranial irradiation，PCI）；实验室检查数据包括LS-SCLC患者在放疗前、放疗期间及放疗后1个月的淋巴细胞计数，根据不良事件通用术语标准（Common Terminology Criteria for Adverse Events，CTCAE）4.0版对淋巴细胞减少进行分级。使用Kaplan-Meier方法估计无进展生存期（progression-free survival，PFS）和总生存期（overall survival，OS），并用log-rank检验进行比较。结果： 共纳入170例患者。患者的中位年龄为57岁，男性占77.6%。中位放疗剂量为60 Gy（范围：45~66 Gy)。整组人群的中位PFS为22.0个月，5年PFS率为31.3%，10年PFS率19.8%；中位OS为38.0个月，5年OS率为37.5%，10年OS率24.2%。放疗前，有14例（8.2%）患者出现1~2级淋巴细胞减少；在放疗期间，出现1、2、3、4级淋巴细胞减少的患者分别为7例（4.1%）、22例（12.9%）、111例（65.3%）、24例（14.1%）；在放疗后1个月，1级、2级、3级、4级淋巴细胞减少的患者分别有36例（21.2%）、36例（21.2%）、11例（6.5%）、1例（0.6%）。无论放疗前、中、后，各级淋巴细胞减少患者之间的PFS和OS均无显著差异。结论： 在免疫治疗前，放疗引起的淋巴细胞减少似乎不影响LS-SCLC患者的预后。

关键词: 局限期小细胞肺癌, 淋巴细胞减少, 放疗, 预后, 生存分析, 队列研究

Abstract:

Background and purpose: Despite Radiation-induced lymphopenia has been associated with poor survival outcomes in certain solid tumors, there is limited evidence for small cell lung cancer (SCLC). The purpose of this study was to investigate whether the absolute lymphocyte count before and after radiotherapy could predict the clinical outcomes for limited-stage SCLC (LS-SCLC) patients. Methods: This was a single-center, retrospective cohort study. A retrospective analysis of patients evaluated at Fudan University Shanghai Cancer Center from January 2007 to December 2017 was conducted. Inclusion criteria: ⑴ pathologically confirmed small-cell lung cancer; ⑵ limited-stage disease defined by positron emission tomography and computed tomography (PET/CT) and contrast-enhanced brain magnetic resonance imaging (MRI) [American Joint Committee on Cancer (AJCC) 8th edition TNM stage M0]; ⑶ receipt of definitive chemoradiotherapy; ⑷ availability of complete blood counts before, during and within 1 month after radiotherapy; ⑸ complete survival, relapse, and last-follow-up information retrievable. Exclusion criteria: ⑴ distant metastasis at baseline (AJCC 8th edition TNM stage M1, including any distant nodal, visceral, or bone-marrow involvement); ⑵ total radiotherapy dose<50 Gy [calculated as an equivalent biological dose at 2 Gy/fraction, i.e., a biological effective dose (BED)<40 Gy]; ⑶ incomplete laboratory data at any scheduled time point; ⑷ inability to ascertain survival or relapse status or insufficient follow-up records. The study protocol was approved by the ethics committee of Fudan University Shanghai Cancer Center (approval number: 2303271-15), and the requirement for informed consent was waived. Clinical data extracted comprised age, sex, Eastern Cooperative Oncology Group performance status (ECOG PS) score, smoking history, TNM stage, chemotherapy regimen and number of cycles, radiotherapy dose and fractionation schedule, use of concurrent chemoradiotherapy and administration of prophylactic cranial irradiation (PCI). Laboratory data comprised serial absolute lymphocyte counts obtained within 1 month before, during and after radiotherapy; lymphopenia was graded according to the Common Terminology Criteria for Adverse Events (CTCAE) version 4.0. Progression-free survival (PFS) and overall survival (OS) were estimated using the Kaplan-Meier method and compared with the log-rank test. Results: A total of 170 patients were included. The median age of the patients was 57 years, with 77.6% being male. The median radiation therapy dose was 60 Gy (range: 45-66 Gy). For the entire cohort, the median PFS was 22.0 months, the 5-year PFS rate was 31.3%, and the 10-year PFS rate was 19.8%. The median OS was 38.0 months, the 5-year OS rate was 37.5%, and the 10-year OS rate was 24.2%. Before radiation therapy, 14 patients (8.2%) had grade 1-2 lymphocytopenia. During radiation therapy, the number of patients with grade 1, 2, 3 and 4 lymphocytopenia was 7 (4.1%), 22 (12.9%), 111 (65.3%), and 24 (14.1%), respectively. One month after radiation therapy, the number of patients with grade 1, 2, 3 and 4 lymphocytopenia was 36 (21.2%), 36 (21.2%), 11 (6.5%) and 1 (0.6%), respectively. There were no significant differences in PFS and OS among patients with different grades of lymphocytopenia before, during, or after radiation therapy. Conclusion: Before immunotherapy, radiotherapy-induced lymphopenia did not appear to affect the prognosis of patients with LS-SCLC.

Key words: Limited-stage small cell lung cancer, Lymphopenia, Radiotherapy, Prognosis, Survival analysis, Cohort study

中图分类号:

R734.2

王艺华, 李雅琪, 裴玉蕾, 吴开良, 范兴文. 放射性淋巴细胞减少对局限期小细胞肺癌患者预后的影响：一项队列研究[J]. 中国癌症杂志, 2025, 35(9): 867-873.

WANG Yihua, LI Yaqi, PEI Yulei, WU Kailiang, FAN Xingwen. Impact of radiation-induced lymphopenia on prognosis in patients with limited-stage small cell lung cancer: a cohort study[J]. China Oncology, 2025, 35(9): 867-873.

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Characteristic	Number
Median age (range)/year	57 (31-76)
Age/year
≥60	70 (41.2)
<60	100 (58.8)
ECOG PS score
0-1	125 (73.5)
2	45 (26.5)
Gender
Male	132 (77.6)
Female	38 (22.4)
TNM stage
Ⅱ	69 (40.6)
Ⅲ	101 (59.4)
Smoking
Yes	105 (62.0)
No	65 (38.0)
Chemotherapy cycle
≤4	164 (96.5)
>4	6 (3.54)
Radiation dose/Gy
≥60	103 (60.6)
<60	67 (39.4)
Concurrent chemoradiotherapy
Yes	154 (90.6)
No	16 (9.4)
PCI
No	34 (20.0)
Yes	136 (80.0)

Factor	OS			PFS
Factor	HR	95% CI	P value	HR	95% CI	P value
Age (<60 years vs ≥60 years)	1.306	0.816-2.089	0.266	1.302	0.847-1.999	0.229
Gender (female vs male)	1.554	0.796-3.035	0.197	1.612	0.874-2.971	0.126
TNM stage (Ⅲ vs Ⅱ)	2.188	0.966-4.960	0.061	1.446	0.762-2.745	0.259
Concurrent chemoradiotherapy (yes vs no)	1.087	0.336-3.512	0.890	0.872	0.349-2.184	0.771
Smoker (yes vs no)	1.209	0.643-2.275	0.555	1.126	0.656-1.933	0.667
PCI (no vs yes)	0.801	0.357-1.797	0.590	1.630	0.905-2.938	0.104
Lymphopenia before radiotherapy (yes vs no)	1.115	0.599-2.075	0.731	1.025	0.578-1.818	0.654
Lymphopenia during radiotherapy (G3-4 vs G0-2)	0.931	0.572-1.514	0.772	1.084	0.638-1.843	0.720
Lymphopenia after radiotherapy (G3-4 vs G0-2)	1.117	0.587-2.125	0.736	1.109	0.624-1.970	0.663

Factor	OS			PFS
Factor	HR	95% CI	P value	HR	95% CI	P value
Lymphopenia before radiotherapy (yes vs no)	1.356	0.552-3.329	0.507	1.226	0.569-2.643	0.603
Lymphopenia during radiotherapy (G3-4 vs G0-2)	1.327	0.598-2.945	0.486	1.257	0.638-2.477	0.509
Lymphopenia after radiotherapy (G3-4 vs G0-2)	0.702	0.197-2.504	0.585	0.758	0.299-1.925	0.560
Age (<60 years vs ≥60 years)	1.417	0.741-2.708	0.292	1.472	0.843-2.569	0.174
Gender (female vs male)	0.637	0.215-1.883	0.414	0.434	0.175-1.075	0.071
TNM stage (Ⅲ vs Ⅱ)	2.307	0.989-5.382	0.053	1.260	0.639-2.489	0.505
Concurrent chemoradiotherapy (yes vs no)	0.797	0.237-2.683	0.714	0.780	0.299-2.031	0.780
Smoker (yes vs no)	1.185	0.536-2.619	0.676	0.989	0.515-1.900	0.974
PCI (no vs yes)	1.038	0.431-2.499	0.934	2.574	1.301-5.092	0.007