多模态超声影像组学特征对甲状腺乳头状癌患者淋巴血管浸润的预测价值

doi:10.3760/cma.j.cn371439-20250627-00012

摘要/Abstract

摘要：

目的探讨甲状腺乳头状癌（PTC）的多模态超声影像组学特征对淋巴血管浸润（LVI）的预测价值。方法回顾性收集2024年6月至2025年3月于新疆维吾尔自治区人民医院行多模态超声检查并经手术病理证实的PTC患者131例，按照7∶3比例随机分为训练集（n=92）和验证集（n=39），训练集根据患者是否伴有LVI，分为LVI组（n=23）和非LVI组（n=69）。采用多因素logistic回归分析影响患者LVI发生的因素，构建临床模型；采用最小绝对收缩和选择算子（LASSO）筛选不同模态超声影像组学特征并构建多模态超声影像组学评分（Radscore）模型。将筛选出的影像组学特征纳入4种机器学习算法构建4个深度学习模型。采用logistic回归分析构建融合模型。利用受试者操作特征（ROC）曲线评价模型效能，通过校准曲线及临床决策曲线对模型进行评价。结果 LVI组及非LVI组患者在肿瘤最大径（t=3.30，P=0.001）、肿瘤多灶性（χ²=17.97，P<0.001）、增强速度（χ²=5.69，P=0.017）、流入相灌注指数（WiPI）（t=2.69，P=0.009）方面的差异均有统计学意义。多因素分析结果表明，肿瘤最大径（OR=1.26，95%CI为1.09~1.47，P=0.002）、WiPI（OR=0.87，95%CI为0.78~0.97，P=0.009）、肿瘤多灶性（OR=6.05，95%CI为1.97~18.60，P=0.002）均为PTC患者LVI发生的独立影响因素。经LASSO回归进行降维后，得到常规超声影像组学特征6个，超声造影影像组学特征11个。基于上述特征构建多模态超声模型：logit（P）=-0.27+0.17×常规超声+0.30×超声造影。训练集和验证集LVI组患者的多模态超声Radscore（3.38±1.20、4.02±1.45）均明显高于非LVI患者（1.76±0.83、1.40±0.54），差异均有统计学意义（t=7.20，P<0.001；t=8.28，P<0.001）。构建的4个深度学习模型中支持向量机模型性能最优，可作为后续研究使用。ROC曲线分析显示，将临床模型、多模态超声影像组学模型、深度学习模型联合后构建的融合模型诊断LVI的曲线下面积为0.90（95%CI为0.81~0.95），诊断效能最优。校准曲线分析显示，融合模型预测概率与实际概率一致性较好，趋近于理想曲线。决策曲线分析显示，融合模型净效益最高。结论多模态超声影像组学模型对PTC患者LVI发生具有良好的预测效能。将多模态超声影像组学模型与临床模型及深度学习模型融合后能提高诊断效能，且该融合模型展现出较高的临床应用价值，同时具备一定的校准能力，有望为临床精准化个性治疗提供客观参考依据。

关键词: 甲状腺癌，乳头状, 淋巴血管浸润, 多模态超声影像组学

Abstract:

Objective To explore the predictive value of multimodal ultrasound radiomics features for lymphovascular invasion （LVI） in papillary thyroid cancer （PTC）. Methods A total of 131 patients with PTC who underwent multimodal ultrasound examination and were confirmed by surgical pathology at People's Hospital of Xinjiang Uygur Autonomous Region from June 2024 to March 2025 were retrospectively collected. Patients were randomly divided into a training set （n=92） and a validation set （n=39） at a ratio of 7∶3. The training set was further divided into an LVI group （n=23） and a non-LVI group （n=69） according to whether the patients had LVI. Multivariate logistic regression analysis was used to identify factors influencing LVI and construct a clinical model. The least absolute shrinkage and selection operator （LASSO） algorithm was applied to screen radiomics features from different ultrasound modalities and develop a multimodal ultrasound radiomics score （Radscore） model. Four deep learning models were constructed using four machine learning algorithms with the selected radiomics features. A fusion model was developed by integrating logistic regression analysis. Model performance was evaluated using receiver operator characteristic （ROC） curves， calibration curves， and clinical decision curve. Results Statistically significant differences were observed between LVI and non-LVI groups in maximum tumor diameter （t=3.30， P=0.001）， tumor multifocality （χ²=17.97， P<0.001）， enhancement rate （χ²=5.69， P=0.017）， and wash-in perfusion index （WiPI）（t=2.69， P=0.009）. The results of the multivariate analysis showed that， maximum tumor diameter （OR=1.26， 95%CI：1.09-1.47， P=0.002）， WiPI （OR=0.87， 95%CI：0.78-0.97， P=0.009） and tumor multifocality （OR=6.05， 95%CI：1.97-18.60， P=0.002） were all independent influencing factors for the occurrence of LVI in patients with PTC. After dimensionality reduction via LASSO regression， 6 radiomic features for conventional ultrasound and 11 radiomic features for contrast-enhanced ultrasound were obtained. A multimodal ultrasound model was constructed based on the aforementioned features：logit（P）=-0.27+0.17×conventional ultrasound+0.30×contrast-enhanced ultrasound. The multimodal ultrasound Radscores of the LVI group patients in the training set and validation set （3.38±1.20， 4.02±1.45） were significantly higher than those of the non-LVI patients （1.76±0.83， 1.40±0.54）， with statistically significant differences （t=7.20， P<0.001； t=8.28， P<0.001）. Among the 4 constructed deep learning models， the support vector machine model exhibited the best performance and could be used for subsequent studies. ROC curve analysis showed that the fusion model， which was constructed by combining the clinical model， multimodal ultrasound radiomics model， and deep learning model， had an area under the curve of 0.90 （95%CI：0.81-0.95） for diagnosing LVI， representing the optimal diagnostic performance. Calibration curve analysis indicated that the predictive probabilities of the fusion model showed good agreement with the actual probabilities and closely approached the ideal curve. Decision curve analysis showed that the fusion model had the highest net benefit. Conclusions Multimodal ultrasound radiomics models exhibit good predictive performance for LVI in PTC patients. The fusion model combining multimodal ultrasound radiomics， clinical features， and deep learning can improve diagnostic efficiency， demonstrating high clinical application value. This approach shows certain calibration abilities and is expected to provide an objective basis for precise and personalized clinical treatment.

Key words: Thyroid cancer， papillary, Lymphovascular invasion, Multimodal ultrasound radiomics

刘娟, 徐蕾, 万静, 吕娟, 张利. 多模态超声影像组学特征对甲状腺乳头状癌患者淋巴血管浸润的预测价值[J]. 国际肿瘤学杂志, 2026, 53(2): 79-86.

Liu Juan, Xu Lei, Wan Jing, Lyu Juan, Zhang Li. Predictive value of multimodal ultrasound radiomics features for lymphovascular invasion in patients with papillary thyroid cancer[J]. Journal of International Oncology, 2026, 53(2): 79-86.

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参考文献 21

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项目	训练集（n=92）	验证集（n=39）	χ²/t值	P值
性别[例（%）]
男	21（22.83）	7（17.95）	0.39	0.534
女	71（77.17）	32（82.05）	0.39	0.534
年龄（岁，$\bar{x}±s$）	47.14±8.93	47.18±9.82	0.02	0.982
肿瘤最大径（mm，$\bar{x}±s$）	9.42±3.92	9.97±4.07	0.73	0.469
TSH（μIU/ml，$\bar{x}±s$）	3.41±1.48	3.63±1.58	0.76	0.449
肿瘤边界[例（%）]
清晰	24（26.09）	9（23.08）	0.13	0.717
不清晰	68（73.91）	30（76.92）	0.13	0.717
回声情况[例（%）]
低回声	73（79.35）	31（79.49）	<0.01	0.986
极低回声	19（20.65）	8（20.51）	<0.01	0.986
肿瘤多灶性[例（%）]
单灶	59（64.13）	22（56.41）	0.69	0.406
多灶	33（35.87）	17（43.59）	0.69	0.406
造影剂分布[例（%）]
均匀	8（8.70）	2（5.13）	0.49	0.482
不均匀	84（91.30）	37（94.87）	0.49	0.482
增强速度[例（%）]
无-低增强	59（64.13）	22（56.41）	0.69	0.406
等-高增强	33（35.87）	17（43.59）	0.69	0.406
TTP（s，$\bar{x}±s$）	21.67±5.51	21.93±5.79	0.24	0.815
WiPI（a.u，$\bar{x}±s$）	1 104.18±573.79	1 086.87±555.30	0.19	0.851
WiWoAUC（a.u，$\bar{x}±s$）	33 764.95±15 830.13	32 332.28±15 595.88	0.48	0.635

项目	LVI组（n=23）	非LVI组（n=69）	χ²/t值	P值
性别[例（%）]
男	5（21.74）	19（27.54）	0.30	0.583
女	18（78.26）	50（72.46）	0.30	0.583
年龄（岁，$\bar{x}±s$）	48.13±9.75	46.81±8.69	0.58	0.568
肿瘤最大径（mm，$\bar{x}±s$）	12.04±3.14	9.06±3.93	3.30	0.001
TSH（μIU/ml，$\bar{x}±s$）	3.74±1.62	3.42±1.49	0.87	0.385
肿瘤边界[例（%）]
清晰	8（34.78）	15（21.74）	1.57	0.211
不清晰	15（65.22）	54（78.26）	1.57	0.211
回声情况[例（%）]
低回声	17（73.91）	46（66.67）	0.42	0.517
极低回声	6（26.09）	23（33.33）	0.42	0.517
肿瘤多灶性[例（%）]
单灶	4（17.39）	47（68.12）	17.97	<0.001
多灶	19（82.61）	22（31.88）	17.97	<0.001
造影剂分布[例（%）]
均匀	3（13.04）	7（10.14）	0.15	0.699
不均匀	20（86.96）	62（89.86）	0.15	0.699
增强速度[例（%）]
无-低增强	10（43.48）	49（71.01）	5.69	0.017
等-高增强	13（56.52）	20（28.99）	5.69	0.017
TTP（s，$\bar{x}±s$）	21.57±4.99	21.79±5.71	0.16	0.871
WiPI（a.u，$\bar{x}±s$）	808.32±467.71	1 161.43±568.07	2.69	0.009
WiWoAUC（a.u，$\bar{x}±s$）	33 034.15±9 513.24	33 403.37±9 364.52	0.16	0.871

因素	β值	SE值	Wald χ²值	OR值	95%CI	P值
肿瘤最大径	0.23	0.08	9.34	1.26	1.09~1.47	0.002
WiPI	-0.14	0.05	6.88	0.87	0.78~0.97	0.009
肿瘤多灶性	1.80	0.57	9.86	6.05	1.97~18.60	0.002
增强速度	0.59	0.57	1.09	1.81	0.60~5.46	0.296
常量	-3.99	1.11	12.98			<0.001

模型	AUC	95%CI	准确性	敏感性	特异性
KNN	0.76	0.59~0.81	0.78	0.75	0.70
RF	0.72	0.54~0.91	0.76	0.83	0.80
LR	0.84	0.75~0.92	0.79	0.85	0.76
SVM	0.89	0.76~0.99	0.92	0.89	0.90

模型	AUC	95%CI	准确性	敏感性	特异性
临床模型	0.63	0.53~0.70	0.67	0.71	0.54
多模态超声影像组学模型	0.72	0.66~0.78	0.82	0.89	0.67
深度学习模型	0.79	0.70~0.89	0.85	0.85	0.81
融合模型	0.90	0.81~0.95	0.96	0.97	0.93