Imaging manifestations and pathological mechanism analysis of human infection with H10N3 avian influenza virus pneumonia: a report of two cases

doi:10.19871/j.cnki.xfcrbzz.2025.02.002

Abstract

Abstract: Human infection with H10N3 avian virus pneumonia is a rare respiratory infectious disease caused by H10N3 subtype avian influenza virus. While demonstrating low pathogenicity in avian populations, cross-species infection in humans may manifest as severe viral pneumonia, potentially progressing to life-threatening complications including acute respiratory distress syndrome (ARDS) and multi-organ failure. The first confirmed case of human infection with H10N3 avian influenza virus iwas reported in Jiangsu Province in 2021, followed by three more cases in China. This study conducted comprehensive analyses of imaging manifestations and underlying pathological mechanisms based on clinical data from confirmed cases in Yunnan and Guangxi regions, aiming to elucidate the characteristic imaging features of human H10N3 avian influenza virus pneumonia. The investigation revealed a triphasic temporal pattern in radiological evolution, demonstrating distinct stage-specific radiological characteristics that can be categorized into three progressive phases: ① Early stage (day 1-7 of disease progression): ground glass density with patchy consolidation appeared in both lungs. ② Progression period (day 8-20 of disease progression): enlargement and fusion of consolidation areas, thickening of interlobular septa, and air bronchogram sign. ③ Recovery period (day ≥ 21 of disease progression): tractional bronchiectasis and reticular fibrosis lesions. his study provides certain guiding significance for people in understanding the imaging manifestations, clinical diagnosis, differential diagnosis, efficacy evaluation, and prognosis judgment of human infection with H10N3 avian influenza virus pneumonia.

Key words: H10N3 avian influenza, Imaging characteristics, Pathological mechanisms, Imaging follow-up, Pulmonary fibrosis

CLC Number:

R511.7

Li Minyuan, Shan Qiulan, Zhang Le, Qin Chunle, Li Xiang, Lu Yibo. Imaging manifestations and pathological mechanism analysis of human infection with H10N3 avian influenza virus pneumonia: a report of two cases[J]. Electronic Journal of Emerging Infectious Diseases, 2025, 10(2): 7-13.

References

[1] JING J, WANG L, WANG G, et al.A human infection case with avian-origin H10N3 influenza virus[J]. Quant Imag Med Surg, 2021, 11(10): 4508-4510.
[2] WORLD HEALTH ORGANIZATION, REGIONAL OFFICE FOR THE WESTERN PACIFIC. Avian influenza weekly update2025[EB/OL].[2025-02-13]. https://iris.who.int/handle/10665/380024.
[3] ZHANG W, ZHANG Z, WANG M, et al.Second Identified Human Infection With the Avian Influenza Virus H10N3: A Case Report[J]. Ann Intern Med, 2023, 176(3): 429-431.
[4] ZHAO Z, LUO S, GAO Y, et al.A case report of human infection with avian influenza H10N3 with a complex respiratory disease history[J]. BMC Infect Dis, 2024, 24(1): 918.
[5] WU H, YANG F, LIU F, et al.Molecular characterization of H10 subtype avian influenza viruses isolated from poultry in Eastern China[J]. Arch Virol, 2019, 164(1): 159-179.
[6] HERFST S, ZHANG J, RICHARD M, et al. Hemagglutinin Traits Determine Transmission of Avian A/H10N7 Influenza Virus between Mammals[J]. Cell Host Microbe, 2020, 28(4): 602-613.e7.
[7] 袁悦, 田甜, 杨静茹, 等. 14株H10N3亚型禽流感病毒的遗传变异研究[J]. 病毒学报, 2023, 39(4): 949-961.
[8] ZHANG Y, SHI J, CUI P, et al.Genetic analysis and biological characterization of H10N3 influenza A viruses isolated in China from 2014 to 2021[J]. J Med Virol, 2023, 95(2): e28476.
[9] 杨灿, 沃恩康, 杨新燕, 等. 甲型流感病毒致肺损伤的机制分析[J]. 国际流行病学传染病学杂志, 2021, 48(1):27-32.
[10] 中国研究型医院学会感染与炎症放射学专业委员会, 中华医学会放射学分会传染病学组, 中国科技产业化促进会数字健康专业委员会, 等. 甲型H1N1流感重症肺炎影像诊断中国专家共识[J]. 中华医学杂志, 2023, 103(33): 2571-2578.
[11] 杜娟, 范学杰, 陈红梅, 等. 甲流H1N1流感病毒性肺炎临床特征及CT影像学表现分析[J/CD]. 中华肺部疾病杂志(电子版), 2019, 12(03): 296-300.
[12] YU M, ZHU Y, QU X, et al.Differences in clinical characteristics and chest CT findings between severe and critical H1N1 pneumonia[J]. Clin Respir J, 2023, 17(4): 277-285.
[13] TANG X, XU XL, WAN N, et al.Long-term outcomes of survivors with influenza A H1N1 virus-induced severe pneumonia and ARDS: a single-center prospective cohort study[J]. Front Cell Infect Microbiol, 2024, 14: 1378379.
[14] 杨晨, 程冰雪, 周莉, 等. 人感染H7N9禽流感与甲型H1N1肺炎的早期鉴别诊断[J]. 临床放射学杂志, 2018, 37(9): 1464-1468.
[15] 毕辉, 葛运起. H7N9、H1N1、H3亚型禽流感病毒肺炎的CT表现与生存预后因素分析[J]. 中国临床研究, 2020, 33(10): 1373-1376.
[16] LI H, WENG H, LAN C, et al.Comparison of patients with avian influenza A (H7N9) and influenza A (H1N1) complicated by acute respiratory distress syndrome[J]. Medicine, 2018, 97(12): e0194.
[17] 耿梦杰, 任翔, 彭质斌, 等. 2021年我国夏季重点传染病疫情形势分析[J]. 疾病监测, 2021, 36(8): 811-817.
[18] 崔鹏飞, 卢昆鹏, 陈思, 等. 两株H3N8亚型禽流感病毒(AIV)的生物学特性[J]. 农业生物技术学报, 2016, 24(7): 980-986.
[19] SHAPOURI-MOGHADDAM A, MOHAMMADIAN S, VAZINI H, et al.Macrophage plasticity, polarization, and function in health and disease[J]. J Cell Physiol, 2018, 233(9): 6425-6440.
[20] ELLIOTT MR, KOSTER KM, MURPHY PS.Efferocytosis Signaling in the Regulation of Macrophage Inflammatory Responses[J]. J Immunol, 2017, 198(4): 1387-1394.
[21] GORITZKA M, MAKRIS S, KAUSAR F, et al.Alveolar macrophage-derived type I interferons orchestrate innate immunity to RSV throμgh recruitment of antiviral monocytes[J]. J Exp Med, 2015, 212(5): 699-714.
[22] 吴炅, 孔俊沣, 何泽清, 等. 人感染H7N9禽流感病毒性肺炎的胸部X线与CT影像学表现及特征分析[J]. 医学影像学杂志, 2019, 29(5): 770-774.
[23] 陈平, 吴发银, 胡汉金, 等. 六例人感染H7N9禽流感伴肺部感染患者的影像学表现[J]. 海南医学, 2017, 28(23): 3890-3892.
[24] XING ZH, SUN X, XU L, et al.Thin-section computed tomography detects long-term pulmonary sequelae 3 years after novel influenza A virus-associated pneumonia[J]. Chin Med J (Engl), 2015, 128(7): 902-908.
[25] 郭元吉. 高致病性禽流感研究进展[J]. 中华实验和临床病毒学杂志, 2006, 20(2):90-93
[26] LEE KY.Pneumonia, Acute Respiratory Distress Syndrome, and Early Immune-Modulator Therapy[J]. Int J Mol Sci, 2017, 18(2):388.
[27] 韩朋, 王瑞兰. 甲型流感病毒对肺泡上皮细胞作用的研究进展[J]. 国际呼吸杂志, 2017, 37(13):1027-1030.
[28] ROJAS-QUINTERO J, WANG X, TIPPER J, et al.Matrix metalloproteinase-9 deficiency protects mice from severe influenza A viral infection[J]. JCI Insight, 2018, 3(24):e99022.
[29] LI Y, VOLLEMAN C, DUBELAAR DPC, et al.Exploring the Impact of Extracorporeal Membrane Oxygenation on the Endothelium: A Systematic Review[J]. Int J Mol Sci, 2024, 25(19):10680.
[30] LI G, ZHU S, ZENG J, et al.Arterial Pulsatility Aμgments Microcirculatory Perfusion and Maintains the Endothelial Integrity during Extracorporeal Membrane Oxygenation via hsa_circ_0007367 Upregulation in a Canine Model with Cardiac Arrest[J]. Oxid Med Cell Longev, 2022, 18:1630918.
[31] KEDIA-MEHTA N, TOBIN L, ZAIATZ-BITTENCOURT V, et al.Cytokine-induced natural killer cell training is dependent on cellular metabolism and is defective in obesity[J]. Blood Adv, 2021, 5(21):4447-4455.
[32] CONG J, WEI H.Natural Killer Cells in the Lungs[J]. Front Immunol, 2019, 25(10):1416.