Progress of postoperative adjuvant interventional-related therapy for hepatocellular carcinoma with microvascular invasion

doi:10.3877/cma.j.issn.1674-0793.2026.01.010

Abstract

Abstract:

Hepatocellular carcinoma (HCC) is one of the most common malignant tumors in the world, and surgical resection is its core treatment. However, the postoperative recurrence rate is high, and the prognosis is inferior in patients combined with microvascular invasion (MVI). And studies have shown that appropriate postoperative adjuvant therapy can delay the time to recurrence and improve overall survival in MVI-positive patients. Currently, there is no standardized postoperative adjuvant treatment for HCC with MVI, and treatment options include interventional therapy, targeted therapy, immunotherapy, radiation therapy, antiviral therapy, and the combination of the above treatments. Current evidence indicates that interventional therapies significantly improve survival outcomes in MVI-positive patients, while combination therapies involving interventional approaches demonstrate advantages in reducing early recurrence rates. However, the long-term survival benefits remain uncertain due to a lack of high-quality multicenter studies. Large-scale prospective clinical trials are required to further validate the efficacy and safety of interventional-based combination treatment strategies. In this article, we review the research progress of postoperative adjuvant interventional-related treatment for patients with MVI-positive HCC after surgery.

Key words: Carcinoma, hepatocellular, Microvascular invasion, Interventional therapy, Combination therapy

Yuhui Fang, Yuquan Chang, Kun He. Progress of postoperative adjuvant interventional-related therapy for hepatocellular carcinoma with microvascular invasion[J]. Chinese Archives of General Surgery(Electronic Edition), 2026, 20(01): 53-59.

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References 44

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作者	研究类型	例数	治疗方案	DFS 或 RFS (%)	OS (%)	PMID
Sun等^［19］	回顾性研究	137	TACE	5年RFS:35	5年:54	26 714 945
		185	N/A	5年RFS: 30.3	5年:43.2
Luo等^［22］	回顾性研究	782	TACE	3年DFS:48	3年:77	36 905 230
		723	N/A	3年DFS:27	3年:40
Xiang等^［20］	回顾性研究	109	TACE	5年RFS: 17.8	5年:26.1	37 812 183
		137	N/A	5年RFS: 8.7	5年:18.5
Ma等^［23］	随机对照研究	166	TACE	5年RFS: 60.6	5年:86.1	39 808 820
		166	N/A	5年RFS: 58.1	5年:85.2
Kumamoto等^［26］	回顾性研究	16	HAIC-5-FU+ IFN-α	2年RFS:26.8	5年:50.5	24 324 102
		17	N/A	2年RFS:28.2	5年:11
Nitta等^［27］	回顾性研究	38	HAIC-FP	5年DFS:33.1	5年:46.7	23 435 678
		35	N/A	5年DFS:11.8	5年:32.7
Nagano等^［28］	回顾性研究	30	HAIC-5-FU+ IFN	5年DFS:39	5年:44	23 251 233
		20	N/A	5年DFS:0	5年:5
Kim等^［29］	回顾性研究	31	HAIC-FP	2年RFS:9.1	3年:73.3	22 067 673
		62	N/A	2年RFS:4.2	3年:68.3
Li等^［31］	随机对照研究	157	HAIC-FOLFOXA	3年DFS:41.1	3年:80.4	36 525 610
		158	N/A	3年DFS:26.6	3年:74.9

作者	研究类型	例数	治疗方案	DFS 或 RFS (%)	OS (%)	PMID
Sun等^［19］	回顾性研究	137	TACE	5年RFS:35	5年:54	26 714 945
		185	N/A	5年RFS: 30.3	5年:43.2
Luo等^［22］	回顾性研究	782	TACE	3年DFS:48	3年:77	36 905 230
		723	N/A	3年DFS:27	3年:40
Xiang等^［20］	回顾性研究	109	TACE	5年RFS: 17.8	5年:26.1	37 812 183
		137	N/A	5年RFS: 8.7	5年:18.5
Ma等^［23］	随机对照研究	166	TACE	5年RFS: 60.6	5年:86.1	39 808 820
		166	N/A	5年RFS: 58.1	5年:85.2
Kumamoto等^［26］	回顾性研究	16	HAIC-5-FU+ IFN-α	2年RFS:26.8	5年:50.5	24 324 102
		17	N/A	2年RFS:28.2	5年:11
Nitta等^［27］	回顾性研究	38	HAIC-FP	5年DFS:33.1	5年:46.7	23 435 678
		35	N/A	5年DFS:11.8	5年:32.7
Nagano等^［28］	回顾性研究	30	HAIC-5-FU+ IFN	5年DFS:39	5年:44	23 251 233
		20	N/A	5年DFS:0	5年:5
Kim等^［29］	回顾性研究	31	HAIC-FP	2年RFS:9.1	3年:73.3	22 067 673
		62	N/A	2年RFS:4.2	3年:68.3
Li等^［31］	随机对照研究	157	HAIC-FOLFOXA	3年DFS:41.1	3年:80.4	36 525 610
		158	N/A	3年DFS:26.6	3年:74.9

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NCT04981665	一项评估 TACE 序贯替雷利珠单抗作为根治性切除术后高复发风险肝细胞癌患者辅助治疗的研究	50	药物：替雷利珠单抗方案：TACE	阶段：2期分配：N/A 干预模式：单组分配	2021年11月8日至2024年12月	招募
NCT02436902	肝细胞癌和MVI患者的辅助治疗 (A-TACE/S-HCC)	240	方案：TACE 药物：索拉非尼药物：TACE 联合索拉非尼	阶段：3期分配：随机化分配干预模式：平行分配	2019年2月1日至2022年8月30日	招募
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NCT05161143	多纳非尼联合TACE治疗肝细胞癌辅助治疗	30	药物：多纳非尼方案：TACE	阶段：2期分配：N/A 干预模式：单组分配	2021年12月至2024年12月	尚未招募
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