Preliminary Experience with Intraoperative Low-Field MRI in Pituitary Surgery

Background Intraoperative low field MRI (iMRI, 0.15 T) during transsphenoidal surgery on pituitary adenomas (PAs) may significantly improve tumor removal. However, extensive surgery can lead to pituitary hormone deficiency. Furthermore, introduction of iMRI will prolong duration of surgery, which may elevate risk of postoperative infections. Methods Overall, 180 transsphenoidal surgeries for PAs from 2007 to 2015 were included. IMRI was available from 2011 to 2015, during this period 67/78 (86%) surgeries were with iMRI (iMRI, n = 67). A total of 113 surgeries were performed without iMRI (controls). All surgical procedures were performed by microscopic technique. Tumor size, hormonal status and vision were assessed before surgery and 3–5 months postoperatively. Results Gross total resection (GTR), mean tumor remnant volume and ∆-volumes were comparable between iMRI and controls: 15% (10/66) vs 23% (26/109) (P = 0.17), 2.97 cm3 (0.9–5) vs 2.1 cm3 (1.6–2.6) (P = 0.3) and 4.5 cm3 (3.6–5.5) vs 5.1 cm3 (4.2–6) (P = 0.4), respectively. Duration of surgery was significantly longer during iMRI vs controls: 126 min (117–135) vs 98 min (92–103) (P < 0.001). New pituitary–adrenal deficiency in iMRI vs controls was seen in 35% (17/48) and 35% (23/66) of surgeries, respectively (P = 0.95). New thyroid deficiency was found in 33% (13/29) and 41% (28/69) and visual field deficiencies improved in 44% (19/43) and 38% (23/60) in iMRI vs controls, respectively (P > 0.1). Conclusion Tumor remnant after pituitary surgery was not significantly reduced using intraoperative low field MRI. Duration of surgery was increased in iMRI, but was not associated with increased infection rate. Pituitary hormonal function and vision were comparable between iMRI and controls.

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Improved Contrast in Ultra-Low-Field MRI with Time-Dependent Bipolar Prepolarizing Fields: Theory and NMR Demonstrations

Metrology and Measurement Systems ◽

10.2478/mms-2013-0028 ◽

2013 ◽

Vol 20 (3) ◽

pp. 327-336 ◽

Cited By ~ 3

Author(s):

Jaakko O. Nieminen ◽

Jens Voigt ◽

Stefan Hartwig ◽

Hans Jürgen Scheer ◽

Martin Burghoff ◽

...

Keyword(s):

Field Strength ◽

Time Course ◽

Signal Strength ◽

Relaxation Rates ◽

Resonance Imaging ◽

New Approach ◽

Spin Lattice ◽

Low Field ◽

Low Field Mri ◽

Magnetic Resonance Imaging Mri

Abstract The spin-lattice (T1) relaxation rates of materials depend on the strength of the external magnetic field in which the relaxation occurs. This T1 dispersion has been suggested to offer a means to discriminate between healthy and cancerous tissue by performing magnetic resonance imaging (MRI) at low magnetic fields. In prepolarized ultra-low-field (ULF) MRI, spin precession is detected in fields of the order of 10-100 μT. To increase the signal strength, the sample is first magnetized with a relatively strong polarizing field. Typically, the polarizing field is kept constant during the polarization period. However, in ULF MRI, the polarizing-field strength can be easily varied to produce a desired time course. This paper describes how a novel variation of the polarizing-field strength and duration can optimize the contrast between two types of tissue having different T1 relaxation dispersions. In addition, NMR experiments showing that the principle works in practice are presented. The described procedure may become a key component for a promising new approach of MRI at ultra-low fields

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