放疗中心脏照射剂量体积与自主神经功能紊乱关系的研究

doi:10.19401/j.cnki.1007-3639.2024.11.006

摘要/Abstract

摘要：

背景与目的：晚期癌症患者心脏自主神经功能紊乱（autonomic dysfunction，AD）的发生率为65%~80%，AD导致的头晕、心悸及疲乏等神经衰弱症状，即使充分休息也难以缓解，严重影响患者的生存质量。同时，心血管自主神经系统对心率、心肌功能和心肌血流具有重要调节作用，AD会增加患者心血管疾病的发病率和死亡风险。AD不仅是一种功能状态，而且可能是整体心肌病变的早期标志。研究显示，在调整年龄、性别和心血管危险因素后，先前的辐射暴露与静息心率增高及运动后心率恢复异常等AD表现相关，但是目前放疗对心脏自主神经功能影响的相关研究尚少，具体的损伤效应及损伤发生的剂量阈值尚不明确。本研究通过对比放疗前后的心率变异性（heart rate variability，HRV）分析参数差异，探讨胸部放疗对恶性肿瘤患者心脏自主神经功能的影响，通过对比病例组和对照组间的剂量学差异，探索发生AD的剂量学相关危险因素，为优化放疗方案的剂量分布提供理论依据，以期改善患者的预后和减少并发症的发生。方法：前瞻性收集2023年2月—2023年12月华北理工大学附属医院放疗科收治的行胸部放疗的恶性肿瘤患者。纳入标准：① 经病理学检查证实为恶性肿瘤（肺癌、乳腺癌或食管癌）患者；② 有放疗适应证；③ 美国东部肿瘤协作组（Eastern Cooperative Oncology Group，ECOG）评分0~1分；④ 心电图、心脏彩超等检查无明显异常；⑤ 患者知情同意并签署同意书。排除标准：① 曾接受过胸部放疗；② 治疗前自觉明显心悸、胸闷和胸痛的患者；③ 合并糖尿病、心脏病等严重基础疾病；④ 目前正在使用抗心律失常药物；⑤ 不能耐受放疗以及随访过程中失访或脱失者。采用HRV分析评估放疗后自主神经功能的变化情况，将出现AD的患者纳入病例组，其余患者纳入对照组，采用单因素和多因素logistic回归分析方法探索胸部放疗后发生AD的剂量学相关危险因素和心脏限量。本研究经华北理工大学附属医院伦理委员会批准（伦理编号：20230228020）。结果：本研究共收集到符合本研究条件的胸部肿瘤患者89例，其中有41例（46%）患者放疗后发生了心脏AD，病例组心脏最高受照剂量（D_max）（6 273.500 cGy vs 4 675.900 cGy，P<0.001）、心脏平均受照剂量（D_mean）（1 513.700 cGy vs 452.050 cGy，P<0.001）和心脏受到5 Gy以上剂量照射的体积占心脏总体积的百分比（V₅）（49.000% vs 21.250%，P<0.001）、V₂₀（30.500% vs 7.300%，P<0.001）、V₃₀（18.700% vs 3.600%，P<0.001）、V₄₀（10.900% vs 1.500%，P<0.001）明显高于对照组，多因素logistic回归分析结果显示，心脏V₃₀是心脏AD发生的独立危险因素[OR（95% CI）=1.583（1.093~2.291），P=0.015]，心脏V₃₀能预测放射性心脏损伤的发生，曲线下面积为0.788，且17.1%是心脏V₃₀预测心脏AD发生的最佳截断值。结论：胸部放疗后，心脏AD患者的心脏照射剂量体积明显高于对照组患者，当心脏V₃₀高于17.1%时，患者发生心脏AD的风险明显升高。

关键词: 胸部放疗, 恶性肿瘤, 心脏自主神经功能, 心率变异性, 心脏损伤

Abstract:

Background and purpose: The incidence of autonomic dysfunction (AD) in patients with advanced cancer is approximately 65%-80%. The neurasthenic symptoms such as dizziness, palpitations and fatigue caused by AD are difficult to alleviate even with sufficient rest, seriously affecting the patients’ quality of life. Meanwhile, the cardiovascular autonomic nervous system plays a significant regulatory role in heart rate, myocardial function and myocardial blood flow. AD increases the morbidity and mortality risk of cardiovascular diseases in patients. AD is not only a functional state but might also be an early sign of overall myocardial lesion. Research indicates that after adjusting for age, gender and cardiovascular risk factors, previous radiation exposure is associated with AD manifestations such as increased resting heart rate and abnormal heart rate recovery after exercise. However, there are currently few relevant studies on the effect of radiotherapy on cardiac autonomic function, and the specific injury effects and dose threshold of injury occurrence remain unclear. This study aimed to explore the impact of thoracic radiotherapy on the cardiac autonomic function of patients with malignant tumors by comparing the differences in heart rate variability (HRV) analysis parameters before and after radiotherapy, and to explore the dosimetric risk factors for the occurrence of AD by comparing the dosimetry between the case group and the control group, providing a theoretical basis for optimizing the dose distribution of radiotherapy regimens in order to improve patient prognosis and reduce the occurrence of complications. Methods: We prospectively collected data of patients with malignant tumors who underwent thoracic radiotherapy in the Radiotherapy Department of the Affiliated Hospital of North China University of Science and Technology from February 2023 to December 2023. Inclusion criteria: ① Patients who were pathologically confirmed to have malignant tumors (lung cancer breast cancer or esophageal cancer); ② patients with radiation therapy indications as recommended by the guidelines; ③ patients with an ECOG score of 0-1; ④ patients with no significant abnormalities in electrocardiogram and echocardiography results. Exclusion criteria: ① previously received chest radiotherapy; ② patients with obvious palpitation, chest tightness and chest pain before treatment; ③ diabetes, heart disease and other serious underlying diseases; ④ anti-arrhythmic drugs are currently being used; ⑤ patients who cannot tolerate radiotherapy and who were lost or lost during follow-up. HRV analysis was used to evaluate changes in autonomic nerve function after radiotherapy. Patients with AD were included in the case group, and the remaining patients were included in the control group. Univariate and multivariate logistic regression analysis methods were used to explore the dosimetric risk factors and cardiac dose limitations for the occurrence of AD after thoracic radiotherapy. This study was approved by the ethics committee of Affiliated Hospital of North China University of Science and Technology (ethics number: 20230228020). Results: A total of 89 patients with thoracic tumors meeting the study criteria were enrolled in the study. Among them, 41 (46%) patients experienced cardiac AD after radiotherapy. The cardiac D_max (6 273.500 cGy vs 4 675.900 cGy, P<0.001), cardiac D_mean (1513.700 cGy vs 452.050 cGy, P<0.001), cardiac V₅ (49.000% vs 21.250%, P<0.001), V₂₀ (30.500% vs 7.300%, P<0.001), V₃₀ (18.700% vs 3.600%, P<0.001) and V₄₀ (10.900% vs 1.500%, P<0.001) were significantly higher in the case group than in the control group. The results of multivariate logistic regression analysis showed that cardiac V₃₀ was an independent risk factor for the occurrence of cardiac AD[OR (95% CI)=1.583 (1.093-2.291), P=0.015]. Cardiac V₃₀ could predict the occurrence of radiation-induced cardiac injury with an area under the curve of 0.788, and 17.1% was the optimal cut-off value of cardiac V₃₀ for predicting the occurrence of cardiac AD. Conclusion: After thoracic radiotherapy, the cardiac irradiation dose-volume was significantly higher in patients with cardiac AD than in the control group. When cardiac V₃₀ was higher than 17.1%, the risk of cardiac AD in patients significantly increased.

Key words: Thoracic radiotherapy, Malignant tumor, Cardiac autonomic function, Heart rate variability, Heart injuries

中图分类号:

R730.55

陈虹宇, 苏鹏宇, 罗文姿, 庞得全, 王斐然. 放疗中心脏照射剂量体积与自主神经功能紊乱关系的研究[J]. 中国癌症杂志, 2024, 34(11): 1036-1044.

CHEN Hongyu, SU Pengyu, LUO Wenzi, PANG Dequan, WANG Feiran. A study of relationship between cardiac exposure dose-volume and cardiovascular autonomic dysfunction in radiotherapy[J]. China Oncology, 2024, 34(11): 1036-1044.

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参考文献 19

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Parameter	Unit	Normal reference value
TP $\bar{x}±s$	ms²	3 466±1 018
LF $\bar{x}±s$	ms²	1 170±416
HF $\bar{x}±s$	ms²	975±203
Lfnorm $\bar{x}±s$	nU	54±4
Hfnorm $\bar{x}±s$	nU	29±3
LF/HF range		1.5-2.0

Parameter	Case group	Control group	χ² value	P value
Age/year
≤60	21 (23.6)	25 (28.1)	0.007	0.935
>60	20 (22.5)	23 (25.8)
Gender
Male	21 (23.6)	25 (28.1)	1.210	0.271
Female	20 (22.5)	23 (25.8)
Smoking history
No	28 (31.5)	40 (44.9)	2.775	0.096
Yes	13 (14.6)	8 (9.0)
Drinking history
No	29 (32.6)	40 (44.9)	2.016	0.156
Yes	12 (13.5)	8 (9.0)
Surgical history
No	24 (27.0)	21 (23.6)	1.934	0.164
Yes	17 (19.1)	27 (30.3)
Chemotherapy history
No	17 (19.1)	17 (19.1)	0.342	0.558
Yes	24 (27.0)	31 (34.8)
Concurrent chemoradiotherapy
No	30 (33.7)	34 (38.2)	0.060	0.807
Yes	11 (12.4)	14 (15.7)
Pathological type
Lung cancer	14 (15.7)	17 (19.1)	1.489	0.475
Esophageal cancer	9 (10.1)	6 (6.7)
Breast cancer	18 (20.2)	25 (28.1)

Analysis indicator	Before radiotherapy	After radiotherapy	t value	P value
SDNN/ms²	55.921±6.992	45.994±4.729	8.148	<0.001
RMSSD/ms²	63.107±10.036	50.813±7.630	6.757	<0.001
TP/ms²	2 255.210±489.788	1 476.310±339.241	9.057	<0.001
LF/ms²	1 205.980±215.261	788.980±174.079	10.436	<0.001
HFms²)	933.100±303.403	607.380±170.103	6.488	<0.001
Lfnorm/nU	57.422±6.274	56.405±7.233	0.736	0.464
Hfnorm/nU	42.321±6.193	43.487±7.262	-0.847	0.399
LF/HF	1.440±0.346	1.375±0.371	0.881	0.381
SD1/ms²	44.744±7.114	36.085±5.464	6.687	<0.001
SD2/ms²	65.173±7.885	54.040±5.454	8.046	<0.001
SD2/SD1	1.473±0.150	1.518±0.202	-1.234	0.220

Analysis indicator	Before radiotherapy	After radiotherapy	t value	P value
SDNN/ms²	52.217±8.564	38.122±5.936	8.662	<0.001
RMSSD/ms²	57.178±13.105	44.717±8.551	5.099	<0.001
TP/ms²	1991.220±403.911	986.660±204.691	14.205	<0.001
LF/ms²	1123.850±216.738	486.070±106.244	16.919	<0.001
HF/ms²	739.000±221.210	434.630±148.136	7.320	<0.001
Lfnorm/nU	60.669±5.563	52.281±9.864	4.743	<0.001
Hfnorm/nU	39.120±5.480	46.078±9.710	-3.996	<0.001
LF/HF	1.607±0.406	1.220±0.462	4.035	<0.001
SD1/ms²	40.478±9.263	32.056±6.329	4.807	<0.001
SD2/ms²	61.598±8.795	45.515±8.610	8.368	<0.001
SD2/SD1	1.555±0.181	1.443±0.238	2.398	0.019

Parameter	Case group (n=41)	Control group (n=48)	Z value	P value
Total dose/Gy	54.000 (50.000, 60.000)	52.000 (50.000, 60.000)	－1.753	0.080
Single dose/Gy $\bar{x}±s$	2.051±0.264	2.122±0.320	2.914^*	0.091
Cardiac Dmin/Gy	0.491 (0.244, 1.285)	0.326 (0.215, 0.550)	－1.803	0.071
Cardiac Dmax/Gy	62.735 (52.635, 65.028)	46.759 (32.256, 58.447)	－4.079	<0.001
Cardiac Dmean/Gy	15.137 (5.334, 21.284)	4.521 (3.174, 7.871)	－4.400	<0.001
Cardiac V₅/%	49.000 (21.250, 82.000)	21.250 (15.775, 31.150)	－4.166	<0.001
Cardiac V₂₀/%	30.500 (8.550, 44.000)	7.300 (5.300, 12.750)	－4.331	<0.001
Cardiac V₃₀/%	18.700 (5.200, 29.800)	3.600 (1.900, 8.375)	－4.664	<0.001
Cardiac V₄₀/%	10.900 (1.550, 16.250)	1.500 (0.625, 3.875)	－3.632	<0.001