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European Radiology
Published in: European Radiology 2/2013

01-02-2013 | Hepatobiliary-Pancreas

Visualising liver fibrosis by phase-contrast X-ray imaging in common bile duct ligated mice

Authors: Xi Zhang, Xin-Rong Yang, Yu Chen, Hai-Qing Li, Rui-Min Li, Qing-Xi Yuan, Pei-Ping Zhu, Wan-Xia Huang, Wei-jun Peng

Published in: European Radiology | Issue 2/2013

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Abstract

Objectives

To determine whether phase-contrast X-ray imaging can be used to visualise directly the accumulated extracellular matrix proteins associated with liver fibrosis in common bile duct ligated mice.

Methods

Twenty-six-week-old C57BL female mice were randomised into three groups. In groups 1 (n = 5) and 2 (n = 10), common bile duct ligation was conducted to produce secondary biliary cirrhosis. Mouse livers were then excised 15 (group 1) and 40 days (group 2) after the ligation of the common bile duct for imaging. In the control group, the livers of 5 mice were excised 40 days after the sham operation. Images were then acquired using the analyser crystal set at different positions of the rocking curve.

Results

The results show that the fibrotic septa and hepatic lobules enclosed by fibrotic septa can be visualised clearly at the whole organ level via phase-contrast X-ray imaging without any contrast agent.

Conclusion

These results suggest that phase-contrast X-ray imaging can easily reveal the accumulated extracellular matrix proteins associated with liver fibrosis without using any contrast agent and has great potential in the study of liver fibrosis.

Key Points

Phase-contrast X-ray imaging may aid the study of liver fibrosis.
It provides higher contrast and spatial resolution (ca. 10 μm) than conventional radiography.
It can reveal fibrotic septa, small ducts and vessels without using contrast agents.
Results in animals now need to be translated to human clinical practice.
Literature
1.
Bedossa P, Dargere D, Paradis V (2003) Sampling variability of liver fibrosis in chronic hepatitis C. Hepatology 38:1449–1457PubMed
2.
Cadranel JF, Rufat P, Degos F (2000) Practices of liver biopsy in France: results of a prospective nationwide survey. For the Group of Epidemiology of the French Association for the Study of the Liver (AFEF). Hepatology 32:477–481PubMedCrossRef
3.
Yoshioka K, Kawabe N, Hashimoto S (2008) Transient elastography: applications and limitations. Hepatol Res 38:1063–1068PubMedCrossRef
4.
Ogawa E, Furusyo N, Toyoda K, Takeoka H, Otaguro S, Hamada M et al (2007) Transient elastography for patients with chronic hepatitis B and C virus infection: Non-invasive, quantitative assessment of liver fibrosis. Hepatol Res 37:1002–1010PubMedCrossRef
5.
Sagir A, Erhardt A, Schmitt M, Haussinger D (2008) Transient elastography is unreliable for detection of cirrhosis in patients with acute liver damage. Hepatology 47:592–595PubMedCrossRef
6.
Arena U, Vizzutti F, Corti G, Ambu S, Stasi C, Bresci S et al (2008) Acute viral hepatitis increases liver stiffness values measured by transient elastography. Hepatology 47:380–384PubMedCrossRef
7.
Rau C, Robinson IK, Richter CP (2006) Visualizing soft tissue in the mammalian cochlea with coherent hard X-rays. Microsc Res Tech 69:660–665PubMedCrossRef
8.
Takeda T, Momose A, Itai Y, Wu J, Hirano K (1995) Phase-contrast imaging with synchrotron X-rays for detecting cancer lesions. Acad Radiol 2:799–803PubMedCrossRef
9.
Takeda T, Momose A, Hirano K, Haraoka S, Watanabe T, Itai Y (2000) Human carcinoma: early experience with phase-contrast X-ray CT with synchrotron radiation – comparative specimen study with optical microscopy. Radiology 214:298–301PubMed
10.
Momose A, Takeda T, Itai Y (2000) Blood vessels: depiction at phase-contrast X-ray imaging without contrast agents in the mouse and rat-feasibility study. Radiology 217:593–596PubMed
11.
Hwu Y, Tsai WL, Chang HM et al (2004) Imaging cells and tissues with refractive index radiology. Biophys J 87:4180–4187PubMedCrossRef
12.
Yoon CY, Sung DJ, Lee JH et al (2007) Imaging of renal and prostate carcinoma with refractive index radiology. Int J Urol 14:96–103PubMedCrossRef
13.
Arfelli F, Bonvicini V, Bravin A et al (1998) Mammography of a phantom and breast tissue with synchrotron radiation and a linear-array silicon detector. Radiology 208:709–715PubMed
14.
Arfelli F, Bonvicini V, Bravin A et al (2000) Mammography with synchrotron radiation: phase-detection techniques. Radiology 215:286–293PubMed
15.
Pisano ED, Johnston RE, Chapman D et al (2000) Human breast cancer specimens: diffraction-enhanced imaging with histologic correlation – improved conspicuity of lesion detail compared with digital radiography. Radiology 214:895–901PubMed
16.
Zhang X, Liu XS, Yang XR, Chen SL, Zhu PP, Yuan QX (2008) Mouse blood vessel imaging by in-line x-ray phase-contrast imaging. Phys Med Biol 53:5735–5743PubMedCrossRef
17.
Zhang X, Yang X-R et al (2010) Diffraction enhanced X-ray imaging of various mouse organs. AJR 195:545–549PubMedCrossRef
18.
Gao D, Pogany A, Stevenson AW, Wilkins SW (1998) Phase-contrast radiography. Radiographics 18:1257–1267PubMed
19.
Momose A, Takeda T, Itai Y, Hirano K (1996) Phase-contrast X-ray computed tomography for observing biological soft tissues. Nat Med 2:473–475PubMedCrossRef
20.
Li J, Williams JM, Zhong Z et al (2005) Reliability of diffraction enhanced imaging for assessment of cartilage lesions, ex vivo. Osteoarthritis Cartilage 13:187–197PubMedCrossRef
21.
Muehleman C, Li J, Zhong Z (2006) Preliminary study on diffraction enhanced radiographic imaging for a canine model of cartilage damage. Osteoarthritis Cartilage 14:882–888PubMedCrossRef
22.
Li J, Zhong Z, Lidtke R et al (2003) Radiography of soft tissue of the foot and ankle with diffraction enhanced imaging. J Anat 202:463–470PubMedCrossRef
23.
Beckmann F, Heise K, Kolsch B et al (1999) Three-dimensional imaging of nerve tissue by x-ray phase-contrast microtomography. Biophys J 76:98–102PubMedCrossRef
24.
Lewis RA, Yagi N, Kitchen MJ et al (2005) Dynamic imaging of the lungs using x-ray phase contrast. Phys Med Biol 50:5031–5040PubMedCrossRef
25.
Chapman D, Thomlinson W, Johnston RE et al (1997) Diffraction enhanced x-ray imaging. Phys Med Biol 42:2015–2025PubMedCrossRef
26.
Kiss MZ, Sayers DE, Zhong Z, Parham C, Pisano ED (2004) Improved image contrast of calcifications in breast tissue specimens using diffraction enhanced imaging. Phys Med Biol 49:3427–3439PubMedCrossRef
27.
Lewis RA, Hall CJ, Hufton AP et al (2003) X-ray refraction effects: application to the imaging of biological tissues. Br J Radiol 76:301–308PubMedCrossRef
28.
Abdel AG, Lebeau G, Rescan PY et al (1990) Reversibility of hepatic fibrosis in experimentally induced cholestasis in rat. Am J Pathol 137:1333–1342
29.
Alberto B, Stefan F, William CT (2002) Very-low-dose mammography: new perspectives in diffraction enhanced imaging (DEI) mammography. In: Larry EA, Martin JY (eds) SPIE 4682:167–173
30.
Connor DM, Zhong Z, Foda HD et al (2011) Diffraction enhanced imaging of a rat model of gastric acid aspiration pneumonitis. Acad Radiol 18:1515–1521PubMedCrossRef
31.
Brenner DJ, Hall EJ (2007) Computed tomography—an increasing source of radiation exposure. N Engl J Med 357:2277–2284PubMedCrossRef
32.
Chapman D, Pisano E, Thomlinson W et al (1998) Medical applications of diffraction enhanced imaging. Breast Dis 10:197–207PubMed
33.
Carroll FE, Waters JW, Traeger RH et al (1999) Production of tunable, monochromatic X-rays by the Vanderbilt free-electron laser. Free-Electron Laser Challenges 3614:139–146
34.
Otendal M, Tuohimaa T, Hemberg O, Hertz HM (2004) Status of the liquid-metal-jet-anode electron-impact x-ray source. In: MacDonald CA, Macrander AT, Ishikawa T, Morawe C, Wood JL (eds) Conference on X-ray sources and optics. SPIE Int Soc Optical Engineering, Denver, CO, pp 57–63
35.
Kleuker U, Suortti P, Weyrich W, Spanne P (1998) Feasibility study of x-ray diffraction computed tomography for medical imaging. Phys Med Biol 43:2911–2923PubMedCrossRef
36.
Bravin A, Keyrilainen J, Fernandez M et al (2007) High-resolution CT by diffraction-enhanced x-ray imaging: mapping of breast tissue samples and comparison with their histo-pathology. Phys Med Biol 52:2197–2211PubMedCrossRef
37.
Sera T, Yokota H, Fujisaki K et al (2008) Development of high-resolution 4D in vivo-CT for visualization of cardiac and respiratory deformations of small animals. Phys Med Biol 53:4258–4301CrossRef
38.
Castelli E, Tonutti M, Arfelli F et al (2011) Mammography with synchrotron radiation: first clinical experience with phase-detection technique. Radiology 259:684–694PubMedCrossRef
39.
Metadata
Title
Visualising liver fibrosis by phase-contrast X-ray imaging in common bile duct ligated mice
Authors
Xi Zhang
Xin-Rong Yang
Yu Chen
Hai-Qing Li
Rui-Min Li
Qing-Xi Yuan
Pei-Ping Zhu
Wan-Xia Huang
Wei-jun Peng
Publication date
01-02-2013
Publisher
Springer-Verlag
Published in
European Radiology / Issue 2/2013
Print ISSN: 0938-7994
Electronic ISSN: 1432-1084
DOI
https://doi.org/10.1007/s00330-012-2630-z

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