循环细胞外囊泡作为心脏移植排斥反应的非侵入性生物标志物。
Circulating extracellular vesicles as non-invasive biomarker of rejection in heart transplant.
机构信息
Cardiovascular Pathology and Pathological Anatomy, Department of Cardiac, Thoracic, Vascular Sciences and Public Health, University of Padova, Padova, Italy.
Laboratory of Cellular and Molecular Cardiology and Laboratory for Cardiovascular Theranostics, Cardiocentro Ticino Foundation, Lugano, Switzerland.
出版信息
J Heart Lung Transplant. 2020 Oct;39(10):1136-1148. doi: 10.1016/j.healun.2020.06.011. Epub 2020 Jun 20.
BACKGROUND
Circulating extracellular vesicles (EVs) are raising considerable interest as a non-invasive diagnostic tool, as they are easily detectable in biologic fluids and contain a specific set of nucleic acids, proteins, and lipids reflecting pathophysiologic conditions. We aimed to investigate differences in plasma-derived EV surface protein profiles as a biomarker to be used in combination with endomyocardial biopsies (EMBs) for the diagnosis of allograft rejection.
METHODS
Plasma was collected from 90 patients (53 training cohort, 37 validation cohort) before EMB. EV concentration was assessed by nanoparticle tracking analysis. EV surface antigens were measured using a multiplex flow cytometry assay composed of 37 fluorescently labeled capture bead populations coated with specific antibodies directed against respective EV surface epitopes.
RESULTS
The concentration of EVs was significantly increased and their diameter decreased in patients undergoing rejection as compared with negative ones. The trend was highly significant for both antibody-mediated rejection and acute cellular rejection (p < 0.001). Among EV surface markers, CD3, CD2, ROR1, SSEA-4, human leukocyte antigen (HLA)-I, and CD41b were identified as discriminants between controls and acute cellular rejection, whereas HLA-II, CD326, CD19, CD25, CD20, ROR1, SSEA-4, HLA-I, and CD41b discriminated controls from patients with antibody-mediated rejection. Receiver operating characteristics curves confirmed a reliable diagnostic performance for each single marker (area under the curve range, 0.727-0.939). According to differential EV-marker expression, a diagnostic model was built and validated in an external cohort of patients. Our model was able to distinguish patients undergoing rejection from those without rejection. The accuracy at validation in an independent external cohort reached 86.5%. Its application for patient management has the potential to reduce the number of EMBs. Further studies in a higher number of patients are required to validate this approach for clinical purposes.
CONCLUSIONS
Circulating EVs are highly promising as a new tool to characterize cardiac allograft rejection and to be complementary to EMB monitoring.
背景
循环细胞外囊泡 (EVs) 作为一种非侵入性诊断工具引起了极大的关注,因为它们很容易在生物体液中检测到,并且包含反映病理生理状况的特定核酸、蛋白质和脂质。我们旨在研究血浆衍生 EV 表面蛋白谱的差异作为一种生物标志物,与心内膜活检 (EMB) 联合用于诊断移植物排斥。
方法
在 EMB 之前收集了 90 名患者(53 名训练队列,37 名验证队列)的血浆。通过纳米颗粒跟踪分析评估 EV 浓度。使用由 37 种荧光标记的捕获珠群体组成的多重流式细胞术检测 EV 表面抗原,这些珠群体涂有针对各自 EV 表面表位的特异性抗体。
结果
与阴性患者相比,接受排斥反应的患者的 EV 浓度显着增加,直径减小。这一趋势对于抗体介导的排斥反应和急性细胞性排斥反应都非常显著(p < 0.001)。在 EV 表面标志物中,CD3、CD2、ROR1、SSEA-4、人类白细胞抗原 (HLA)-I 和 CD41b 被鉴定为急性细胞性排斥反应与对照组之间的鉴别标志物,而 HLA-II、CD326、CD19、CD25、CD20、ROR1、SSEA-4、HLA-I 和 CD41b 则将对照组与抗体介导的排斥反应患者区分开来。受试者工作特征曲线证实了每个单一标志物的可靠诊断性能(曲线下面积范围,0.727-0.939)。根据差异 EV 标志物表达,建立并验证了一个外部患者队列的诊断模型。我们的模型能够区分正在接受排斥反应的患者和没有排斥反应的患者。在独立的外部队列中的验证准确性达到 86.5%。它在患者管理中的应用有可能减少 EMB 的数量。需要进一步在更多患者中进行研究,以验证该方法的临床应用。
结论
循环 EVs 作为一种新的工具来描述心脏移植物排斥反应具有很大的潜力,并与 EMB 监测互补。
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