In-line X-ray phase-contrast imaging of murine liver microvasculature ex vivo

SYNCHROTRON TECHNOLOGY AND APPLICATIONS

In-line X-ray phase-contrast imaging of murine liver microvasculature ex vivo

LI Beilei，

XU Min，

WU Weizhong，

PENG Guanyun，

ZHANG Xi，

PENG Yifeng，

SHI Hongcheng，

CHEN Shaoliang

Nuclear Science and Techniques

Vol.23, No.1

pp.10-14

Published in print 20 Feb 2012

DOI：10.13538/j.1001-8042/nst.23.10-14

47100

Imaging blood vessels is of importance for determining the vascular distribution of organs and tumors. Phase-contrast X-ray imaging can reveal the vessels in much more detail than conventional X-ray absorption method. Visualizing murine liver microvasculature ex vivo with phase-contrast X-ray imaging was performed at Shanghai Synchrotron Radiation Facility. Barium sulfate and physiological saline were used as contrast agents for the blood vessels. Blood vessels of <Φ20 μm could be detected by replacing resident blood with physiological saline or barium sulfate. An entire branch of the portal vein (from the main axial portal vein to the ninth generation of branching) could be captured in a single phase-contrast image. It is demonstrated that selective angiography based on phase contrast X-ray imaging, with a physiological material of low Z elements (such as saline) being the contrast agent, is a viable imaging strategy. Further efforts will be focused on using the technique to image tumor angiogenesis.

Synchrotron radiationX-rayPhase-contrast imagingMicrovascularLiver

References

[1]

Chen J G, Zhang S W. Semin Cancer Biol, 2011, 21: 59-69.

[2]

Eichhorn M E, Kleespies A, Angele M K, et al. Langenbecks Arch Surg, 2007, 392:371-379.

[3]

Chen J A, Shi M, Li J Q, et al. Hepatol Int, 2010, 4: 537-547.

[4]

Mori H, Hyodo K, Tobita K, Chujo M, et al. Circulation, 1994, 89: 863-871.

[5]

Gao D, Pogany A, Stevenson A W, et al. Radiographics, 1998, 18: 1257-1267.

[6]

Zhou S A, Brahme A. Phys Med, 2008, 24: 129-148.

[7]

Momose A, Takeda T, Itai Y. Radiology, 2000, 217: 593-596.

[8]

Takeda T, Momose A, Wu J, et al. Circulation, 2002, 105: 1708-1712.

[9]

Zhang L, Hu C, Zhao T, et al. Eur J Radiol, EURR-4925(2010)005.

[10]

Zhang X, Liu X S, Yang X R, et al. Phy Med Biol, 2008, 53: 535-543.

[11]

Kobayashi S, Hori M, Dono K, et al. J Hepatol, 2004, 40: 405-408.

[12]

Liu P, Sun J, Zhao J, et al. J Synchrotron Radiat, 2010, 17: 517-521.

[13]

Lu W, Dong Z, Liu Z, et al. J Surg Res, 2010, 164: e193-139.

[14]

Momose A, Takeda T, Itai Y. Acad Radiol, 1995, 2: 883-887.

[15]

Plouraboue F, Cloetens P, Fonta C, et al. J Microsc, 2004, 215:139-148.

[16]

Risser L, Plouraboué F, Steyer A, et al. J Cereb Blood Flow Metab, 2007, 27: 293-303.

[17]

Yamashita T. Invest Radiol, 2001, 36: 713-720.

[18]

Givvimani S, Sen U, Tyagi N, et al. Arch.Physiol Biochem,2011, 117: 1-7.

[19]

Xiao T Q, Bergamaschi A, Dreossi D, et al. Nucl Instru Meth.A, 2005, 548: 155-162.