PLoS ONE (Jan 2016)

Multiparametric Functional MRI: Non-Invasive Imaging of Inflammation and Edema Formation after Kidney Transplantation in Mice.

  • Katja Hueper,
  • Marcel Gutberlet,
  • Jan Hinrich Bräsen,
  • Mi-Sun Jang,
  • Anja Thorenz,
  • Rongjun Chen,
  • Barbara Hertel,
  • Amelie Barrmeyer,
  • Martina Schmidbauer,
  • Martin Meier,
  • Sibylle von Vietinghoff,
  • Abedalrazag Khalifa,
  • Dagmar Hartung,
  • Hermann Haller,
  • Frank Wacker,
  • Song Rong,
  • Faikah Gueler

DOI
https://doi.org/10.1371/journal.pone.0162705
Journal volume & issue
Vol. 11, no. 9
p. e0162705

Abstract

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BACKGROUND:Kidney transplantation (ktx) in mice is used to learn about rejection and to develop new treatment strategies. Past studies have mainly been based on histological or molecular biological methods. Imaging techniques to monitor allograft pathology have rarely been used. METHODS:Here we investigated mice after isogenic and allogenic ktx over time with functional MRI with diffusion-weighted imaging (DWI) and mapping of T2-relaxation time (T2-mapping) to assess graft inflammation and edema formation. To characterize graft pathology, we used PAS-staining, counted CD3-positive T-lymphocytes, analyzed leukocytes by means flow cytometry. RESULTS:DWI revealed progressive restriction of diffusion of water molecules in allogenic kidney grafts. This was paralleled by enhanced infiltration of the kidney by inflammatory cells. Changes in tissue diffusion were not seen following isogenic ktx. T2-times in renal cortex were increased after both isogenic and allogenic transplantation, consistent with tissue edema due to ischemic injury following prolonged cold ischemia time of 60 minutes. Lack of T2 increase in the inner stripe of the inner medulla in allogenic kidney grafts matched loss of tubular autofluorescence and may result from rejection-driven reductions in tubular water content due to tubular dysfunction and renal functional impairment. CONCLUSIONS:Functional MRI is a valuable non-invasive technique for monitoring inflammation, tissue edema and tubular function. It permits on to differentiate between acute rejection and ischemic renal injury in a mouse model of ktx.