An MRI system for imaging neonates in the NICU: initial feasibility study.

BACKGROUND: Transporting premature infants from a neonatal intensive care unit (NICU) to a radiology department for MRI has medical risks and logistical challenges. OBJECTIVE: To develop a small 1.5-T MRI system for neonatal imaging that can be easily installed in the NICU and to evaluate its performance using a sheep model of human prematurity. MATERIALS AND METHODS: A 1.5-T MRI system designed for orthopedic use was adapted for neonatal imaging. The system was used for MRI examinations of the brain, chest and abdomen in 12 premature lambs during the first hours of life. Spin-echo, fast spin-echo and gradient-echo MR images were evaluated by two pediatric radiologists. RESULTS: All animals remained physiologically stable throughout the imaging sessions. Animals were imaged at two or three time points. Seven brain MRI examinations were performed in seven different animals, 23 chest examinations in 12 animals and 19 abdominal examinations in 11 animals. At each anatomical location, high-quality images demonstrating good spatial resolution, signal-to-noise ratio and tissue contrast were routinely obtained within 30 min using standard clinical protocols. CONCLUSION: Our preliminary experience demonstrates the feasibility and potential of the neonatal MRI system to provide state-of-the-art MRI capabilities within the NICU. Advantages include overall reduced cost and site demands, lower acoustic noise, improved ease of access and reduced medical risk to the neonate.

HIFU lesion volume as a function of sonication time, as determined by MRI, histology, and computations.

Characterization of high-intensity focused ultrasound (HIFU) systems using ex vivo tissues is an important part of the preclinical testing for new HIFU devices. In ex vivo characterization, the lesion volume produced by the absorption of HIFU energy is quantified as operational parameters are varied. This paper examines the three methods used for lesion-volume quantification: histology, magnetic resonance (MR) imaging, and numerical calculations. The methods were studied in the context of a clinically relevant problem for HIFU procedures--that of quantifying the change in the lesion volume with changing sonication time. The lesion volumes of sonicated samples of porcine liver were determined using the three methods, at focal intensities ranging from 800 W/cm(2) to 1700 W/cm(2) and sonication times between 20 s and 40 s. It was found that histology consistently yielded lower lesion volumes than the other two methods, and the calculated values were below magnetic resonance imaging (MRI) at high applied energies. Still, the three methods agreed with each other to within a +/-10% difference for all of the experiments. Increasing the sonication time produced much larger changes in the lesion volume than increasing the acoustic intensity, for the same total energy expenditure, at lower energy (less than 1000 J) levels. At higher energy levels, (around 1500 J), increasing the sonication time and increasing the intensity produced roughly the same change in the lesion volume for the same total energy expenditure.

Quantification of aortic compliance in mice using radial phase contrast MRI.

PURPOSE: To investigate the feasibility of radial phase contrast MR imaging to measure in vivo pulse wave velocity (PWV) and wall shear stress (WSS) in small animals on a 7 Tesla scanner. MATERIALS AND METHODS: The aortic compliance of 9-month-old ApoE deficient (ApoE-KO) mice (n = 10) on a normal diet was studied in comparison to that of wild-type (WT) mice (n = 10). An undersampled, asymmetric echo radial phase contrast MR technique was developed to measure through plane blood flow velocity at axial slices along the descending aorta. The PWV and the time averaged WSS was calculated from the spatiotemporal flow data. The reproducibility of PWV and WSS was evaluated by taking multiple measures on a separate cohort of WT (n = 4) mice. RESULTS: The mean percentage standard deviation among repeated measures was 10.1% for PWV and 24.8% for WSS. The PWV of ApoE-KO mice (5.84 +/- 2.15 m/s) was significantly higher (p = 0.02) than that of WT (3.55 +/- 0.97 m/s), whereas WSS was lower in ApoE-KO mice (1.44 +/- 0.31Pa) compared with WT (1.55 +/- 0.36Pa). CONCLUSION: This study demonstrates that in vivo PWV derived from radial phase contrast MR imaging can be potentially used as a surrogate marker for impaired vascular function in mice.