OBJECTIVES: The purpose of this study was to investigate the use of Gd-DTPA shortly before magnetic resonance guided high-intensity focused ultrasound MR-HIFU thermal ablation therapy with respect to dissociation, trapping, and long-term deposition of gadolinium (Gd) in the body. MATERIALS AND METHODS: Magnetic resonance-HIFU ablation treatment was conducted in vivo on both rat muscle and subcutaneous tumor (9L glioma) using a clinical 3T MR-HIFU system equipped with a small-animal coil setup. A human equivalent dose of gadopentetate dimeglumine (Gd-DTPA) (0.6 mmol/kg of body weight) was injected via a tail vein catheter just before ablation (≤5 minutes). Potential trapping of the contrast agent in the ablated area was visualized through the acquisition of R1 maps of the target location before and after therapy. The animals were sacrificed 2 hours or 14 days after the injection (n = 4 per group, a total of 40 animals). Subsequently, the Gd content in the tissue and carcass was determined using inductively coupled plasma techniques to investigate the biodistribution. RESULTS: Temporal trapping of Gd-DTPA in the coagulated tissue was observed on the R1 maps acquired within 2 hours after the ablation, an effect confirmed by the inductively coupled plasma analysis (3 times more Gd was found in the treated muscle volume than in the control muscle tissue). Two weeks after the therapy, the absolute amount of Gd present in the coagulated tissue was low compared with the amount present in the kidneys 14 days after the injection (ablated muscle, 0.009% ± 0.002% ID/g; kidney, 0.144% ± 0.165% ID/g). There was no significant increase in Gd content in the principal target organs for translocated Gdions (liver, spleen, and bone) or in the entire carcasses between the HIFU- and sham-treated animals. Finally, an in vivo relaxivity of 4.6 mmols was found in the HIFU-ablated volume, indicating intact Gd-DTPA. CONCLUSIONS: Magnetic resonance-HIFU treatment does not induce the dissociation of Gd-DTPA. In small-tissue volumes, no significant effect on the long-term in vivo Gd retention was found. However, care must be taken with the use of proton resonance frequency shift-based MR thermometry for HIFU guidance in combination with Gd because the susceptibility artifact induced by Gd can severely influence treatment outcome.
OBJECTIVES: The purpose of this study was to investigate the use of Gd-DTPA shortly before magnetic resonance guided high-intensity focused ultrasound MR-HIFU thermal ablation therapy with respect to dissociation, trapping, and long-term deposition of gadolinium (Gd) in the body. MATERIALS AND METHODS: Magnetic resonance-HIFU ablation treatment was conducted in vivo on both rat muscle and subcutaneous tumor (9L glioma) using a clinical 3T MR-HIFU system equipped with a small-animal coil setup. A human equivalent dose of gadopentetate dimeglumine (Gd-DTPA) (0.6 mmol/kg of body weight) was injected via a tail vein catheter just before ablation (≤5 minutes). Potential trapping of the contrast agent in the ablated area was visualized through the acquisition of R1 maps of the target location before and after therapy. The animals were sacrificed 2 hours or 14 days after the injection (n = 4 per group, a total of 40 animals). Subsequently, the Gd content in the tissue and carcass was determined using inductively coupled plasma techniques to investigate the biodistribution. RESULTS: Temporal trapping of Gd-DTPA in the coagulated tissue was observed on the R1 maps acquired within 2 hours after the ablation, an effect confirmed by the inductively coupled plasma analysis (3 times more Gd was found in the treated muscle volume than in the control muscle tissue). Two weeks after the therapy, the absolute amount of Gd present in the coagulated tissue was low compared with the amount present in the kidneys 14 days after the injection (ablated muscle, 0.009% ± 0.002% ID/g; kidney, 0.144% ± 0.165% ID/g). There was no significant increase in Gd content in the principal target organs for translocated Gdions (liver, spleen, and bone) or in the entire carcasses between the HIFU- and sham-treated animals. Finally, an in vivo relaxivity of 4.6 mmols was found in the HIFU-ablated volume, indicating intact Gd-DTPA. CONCLUSIONS: Magnetic resonance-HIFU treatment does not induce the dissociation of Gd-DTPA. In small-tissue volumes, no significant effect on the long-term in vivo Gd retention was found. However, care must be taken with the use of proton resonance frequency shift-based MR thermometry for HIFU guidance in combination with Gd because the susceptibility artifact induced by Gd can severely influence treatment outcome.
Authors: Hanke J Schalkx; Esben T Petersen; Nicky H G M Peters; Wouter B Veldhuis; Maarten S van Leeuwen; Josien P W Pluim; Maurice A A J van den Bosch; Marijn van Stralen Journal: Eur Radiol Date: 2015-03-22 Impact factor: 5.315
Authors: Marlijne E Ikink; Marianne J Voogt; Maurice A A J van den Bosch; Robbert J Nijenhuis; Bilgin Keserci; Young-sun Kim; Koen L Vincken; Lambertus W Bartels Journal: Eur Radiol Date: 2014-06-25 Impact factor: 5.315
Authors: Blake E Zimmerman; Sara Johnson; Henrik Odeen; Jill Shea; Markus D Foote; Nicole Winkler; Sarang C Joshi; Allison Payne Journal: IEEE Trans Biomed Eng Date: 2021-04-21 Impact factor: 4.538
Authors: Jessie E Lee; Chris J Diederich; Robert Bok; Renuka Sriram; Romelyn Delos Santos; Susan M Noworolski; Vasant A Salgaonkar; Matthew S Adams; Daniel B Vigneron; John Kurhanewicz Journal: NMR Biomed Date: 2018-07-18 Impact factor: 4.044