Fitzgerald Tamara N, Muto Akihito, Fancher Tiffany T, Brown Peter B, Martin Karen A, Muhs Bart E, Rothman Douglas L, Constable R Todd, Sampath Smita, Dardik Alan
Department of Surgery, Yale University School of Medicine, New Haven, CT, USA.
Ann Vasc Surg. 2010 Feb;24(2):242-53. doi: 10.1016/j.avsg.2009.10.006. Epub 2009 Dec 29.
Magnetic resonance angiography (MRA) is clinically useful but of limited applicability to small animal models due to poor signal resolution, with typical voxel sizes of 1 mm(3) that are insufficient to analyze vessels of diameter <1 mm. We determined whether surgically implantable, extravascular MRA coils increase signal resolution adequately to examine blood flow dynamics
A custom MRA coil was surgically implanted near the carotid artery of a New Zealand White rabbit. A stenosis was created in the carotid artery to induce complicated, non-laminar flow. Phase contrast images were obtained on multiple axial planes with 3T MRA and through-plane velocity profiles were calculated under laminar and complicated flow conditions. These velocity profiles were fit to a laminar flow model using ordinary least squares in order to quantify the degree of flow complication (Matlab). Flow was also measured with a Doppler flow probe; vessel diameters and flow velocities were compared with duplex ultrasound
Carotid artery blood flow was 24.7 +/- 2.6 ml/min prior to stenosis creation and reduced to 12.0 +/- 1.7 ml/min following injury (n=3). An MRA voxel size of 0.1 x 0.1 x 5 mm was achieved. The control carotid artery diameter was 1.9 +/- 0.1 mm, and cross-sectional images containing 318 +/- 22 voxels were acquired (n=26). Velocity profiles resembled laminar flow proximal to the stenosis, and then became more complicated just proximal and distal to the stenosis. Laminar flow conditions returned downstream of the stenosis
Implantable, extra-vascular coils enable small MRA voxel sizes to reproducibly calculate complex velocity profiles under both laminar and complicated flow in a small animal model. This technique may be applied to study blood flow dynamics of vessel remodeling and atherogenesis.
磁共振血管造影(MRA)在临床上很有用,但由于信号分辨率差,在小动物模型中的适用性有限,典型的体素大小为1立方毫米,不足以分析直径小于1毫米的血管。我们确定了手术植入的血管外MRA线圈是否能充分提高信号分辨率以检查血流动力学。
将定制的MRA线圈手术植入新西兰白兔的颈动脉附近。在颈动脉中制造狭窄以诱导复杂的非层流。使用3T MRA在多个轴向平面上获取相位对比图像,并在层流和复杂流动条件下计算平面内速度分布。使用普通最小二乘法将这些速度分布拟合到层流模型中,以量化流动复杂性的程度(Matlab)。还使用多普勒血流探头测量血流;将血管直径和流速与双功超声进行比较。
在制造狭窄之前,颈动脉血流量为24.7±2.6毫升/分钟,损伤后降至12.0±1.7毫升/分钟(n = 3)。实现了0.1×0.1×5毫米的MRA体素大小。对照颈动脉直径为1.9±0.1毫米,并获取了包含318±22个体素的横截面图像(n = 26)。狭窄近端的速度分布类似于层流,然后在狭窄近端和远端变得更加复杂。层流条件在狭窄下游恢复。
可植入的血管外线圈能够在小动物模型中,在层流和复杂流动条件下,以较小的MRA体素大小可重复地计算复杂的速度分布。该技术可用于研究血管重塑和动脉粥样硬化形成的血流动力学。
