曲妥珠单抗
乳腺癌
判别式
外体
微泡
计算机科学
机器学习
人工智能
液体活检
一致性
医学
生物标志物
精密医学
肿瘤科
活检
人表皮生长因子受体2
模式识别(心理学)
精确肿瘤学
诊断准确性
癌症
信号处理
支持向量机
数字信号处理
伴生诊断
传感器阵列
算法
作者
Tianyu Zeng,Zeying Li,Yanting Sun,Yincheng Liu,Jialin Xu,Xiang Huang,Yan Liang,Hai Shi,Shuai Wu,Genxi Li,Yongmei Yin
标识
DOI:10.1007/s42114-026-01638-5
摘要
Accurate and rapid diagnosis of human epidermal growth factor receptor-2 (HER2)-positive breast cancer, coupled with prediction of trastuzumab therapeutic efficacy, is critical for clinical decision-making to the patients with breast cancer. However, there is still no standard to be clinically used without suffering from inherent limitations. In this work, we propose a machine learning-assisted multifunctional biosensing platform utilizing enzyme-embedded hydrogen-bonded organic frameworks (HOFs). In this design, diverse HOFs@enzyme composites with distinct assembly configurations serve as sensitive array elements to interact with breast cancer-derived exosomes. Moreover, these interactions can modulate HOF-enzyme activity, generating diagnostic signal patterns that form unique exosomal molecular “fingerprint” profiles. Simultaneously, coordination with machine learning enables processing of complex sensor array-based data to amplify subtle differences of exosome between different subtypes of breast cancer, thereby enhancing the discriminatory capacity of this platform. By establishing reference fingerprints using exosomes from 96 training-set patients and validating classification accuracy against immunohistochemical in 76 test-set patients, the platform achieved 100% concordance in identifying the HER2-positive subtype, demonstrating exceptional discriminative capacity. Remarkably, the platform can also predict trastuzumab treatment response with 87.5% accuracy through clinical outcome correlation. So, by enabling precise exosome characterization from peripheral blood, this non-invasive liquid biopsy technology offers a transformative approach for precision oncology in HER2-positive breast cancer, overcoming critical limitations of current diagnostic paradigms.
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