Jan Philipp Burchert, Jasper Frohn, Ulrike Rölleke, Hendrik Bruns, Boram Yu, Sophie Charlotte Gleber, Roland Stange, Madleen Busse, Markus Osterhoff, Tim Salditt, Sarah Köster
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引用次数: 0
Abstract
X-rays can penetrate deeply into biological cells and thus allow for examination of their internal structures with high spatial resolution. In this study, X-ray phase-contrast imaging and tomography is combined with an X-ray-compatible optical stretcher and microfluidic sample delivery. Using this setup, individual cells can be kept in suspension while they are examined with the X-ray beam at a synchrotron. From the recorded holograms, 2D phase shift images that are proportional to the projected local electron density of the investigated cell can be calculated. From the tomographic reconstruction of multiple such projections the 3D electron density can be obtained. The cells can thus be studied in a hydrated or even living state, thus avoiding artifacts from freezing, drying or embedding, and can in principle also be subjected to different sample environments or mechanical strains. This combination of techniques is applied to living as well as fixed and stained NIH3T3 mouse fibroblasts and the effect of the beam energy on the phase shifts is investigated. Furthermore, a 3D algebraic reconstruction scheme and a dedicated mathematical description is used to follow the motion of the trapped cells in the optical stretcher for multiple rotations.
X 射线可以深入生物细胞,因此可以对其内部结构进行高空间分辨率的检查。在这项研究中,X 射线相位对比成像和层析成像与兼容 X 射线的光学担架和微流体样品输送相结合。利用这种装置,可以将单个细胞保持在悬浮状态,同时用同步加速器的 X 射线光束对其进行检查。根据记录的全息图像,可以计算出与被检细胞的投影局部电子密度成正比的二维相移图像。通过对多个此类投影进行层析重建,可以获得三维电子密度。因此,细胞可以在水合状态甚至活体状态下进行研究,从而避免了冷冻、干燥或包埋造成的伪影,原则上也可以在不同的样品环境或机械应变下进行研究。这种技术组合适用于活体以及固定和染色的 NIH3T3 小鼠成纤维细胞,并研究了光束能量对相移的影响。此外,还使用了三维代数重建方案和专门的数学描述来跟踪被困细胞在光学担架中多次旋转时的运动情况。
期刊介绍:
Synchrotron radiation research is rapidly expanding with many new sources of radiation being created globally. Synchrotron radiation plays a leading role in pure science and in emerging technologies. The Journal of Synchrotron Radiation provides comprehensive coverage of the entire field of synchrotron radiation and free-electron laser research including instrumentation, theory, computing and scientific applications in areas such as biology, nanoscience and materials science. Rapid publication ensures an up-to-date information resource for scientists and engineers in the field.