Savvas Savvidis, Roberta Ragazzini, Valeria Conde de Rafael, J. Ciaran Hutchinson, Lorenzo Massimi, Fabio A. Vittoria, Sara Campinoti, Tom Partridge, Olumide K. Ogunbiyi, Alessia Atzeni, Neil J. Sebire, Paolo De Coppi, Alberto Mittone, Alberto Bravin, Paola Bonfanti, Alessandro Olivo
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引用次数: 0
Abstract
The thymus, responsible for T cell-mediated adaptive immune system, has a structural and functional complexity that is not yet fully understood. Until now, thymic anatomy has been studied using histological thin sections or confocal microscopy 3D reconstruction, necessarily for limited volumes. We used Phase Contrast X-Ray Computed Tomography to address the lack of whole-organ volumetric information on the microarchitecture of its structural components. We scanned 15 human thymi (9 foetal and 6 postnatal) with synchrotron radiation, and repeated scans using a conventional laboratory x-ray system. We used histology, immunofluorescence and flow cytometry to validate the x-ray findings. Application to human thymi at pre- and post-natal stages allowed reliable tracking and quantification of the evolution of parameters such as size and distribution of Hassall’s Bodies and medulla-to-cortex ratio, whose changes reflect adaptation of thymic activity. We show that Hassall’s bodies can occupy 25% of the medulla volume, indicating they should be considered a third thymic compartment with possible implications on their role. Moreover, we demonstrate compatible results can be obtained with standard laboratory-based x-ray equipment, making this research tool accessible to a wider community. Our study allows overcoming the resolution and/or volumetric limitations of existing approaches for the study of thymic disfunction in congenital and acquired disorders affecting the adaptive immune system. The thymus is the organ responsible for programming the immune system. It consists of two main compartments, named medulla and cortex. The medulla contains onion-shaped parts known as “Hassall’s bodies”. By imaging thymi at different stages of development with advanced x-ray methods, we gain understanding of changes that occur over time in 3D. We quantified how much of the thymus was occupied by these different components as they change with age, showing that Hassall’s bodies can take up 25% of the medulla, and should therefore be considered a proper part of the thymus with a purpose. Having a better understanding of the thymus can prove important in targeting conditions such as Down syndrome and thymic tumours, as well as provide information about structure. Savvidis et al. present x-ray 3D imaging visualizing the internal anatomy of the human thymus across developmental stages. Quantification and evolution of Hassall’s bodies and medulla-to-cortex ratio, indicate they should be considered a third compartment of the thymic anatomy.
背景:胸腺负责T细胞介导的适应性免疫系统,其结构和功能的复杂性尚未完全明了。迄今为止,对胸腺解剖结构的研究都是通过组织学薄切片或共聚焦显微镜三维重建来进行的,而且必须是在体积有限的情况下:方法:我们使用相位对比 X 射线计算机断层扫描来解决缺乏有关其结构成分微观架构的整个器官容积信息的问题。我们使用同步辐射扫描了 15 个人体胸腺(9 个胎儿胸腺和 6 个出生后胸腺),并使用传统的实验室 X 射线系统进行了重复扫描。我们使用组织学、免疫荧光和流式细胞术验证了 X 射线的研究结果:结果:应用于人类出生前和出生后阶段的胸腺,可对哈索尔体的大小和分布以及髓质与皮质的比例等参数的演变进行可靠的跟踪和量化,这些参数的变化反映了胸腺活动的适应性。我们的研究表明,哈索尔体可占据髓质体积的25%,这表明它们应被视为胸腺的第三区室,并可能对其作用产生影响。此外,我们还证明了使用标准实验室 X 射线设备可以获得兼容的结果,使更多人可以使用这一研究工具:我们的研究克服了现有方法在研究影响适应性免疫系统的先天性和后天性疾病的胸腺功能障碍时存在的分辨率和/或体积限制。