Betrouni N, Lopes R, Makni N, Dewalle A S, Vermandel M, Rousseau J
INSERM U703, Pavillon Vancostanobel, University Hospital of Lille (CHRU), Lille 59037, France.
Ultrasonics. 2009 Dec;49(8):646-52. doi: 10.1016/j.ultras.2009.03.008. Epub 2009 Apr 7.
Many algorithms exist for 3D reconstruction of data from freehand 2D ultrasound slices. These methods are based on interpolation techniques to fill the voxels from the pixels. For quantification purposes, segmentation is involved to delineate the structure of interest. However, speckle and partial volume effect errors can affect quantification.
This study aimed to assess the effect of the combination of a fuzzy model and 3D reconstruction algorithms of freehand ultrasound images on these errors.
We introduced a fuzzification step to correct the initial segmentation, by weighting the pixels by a distribution function, taking into account the local gray levels, the orientation of the local gradient, and the local contrast-to-noise ratio. We then used two of the most wide-spread reconstruction algorithms (pixel nearest neighbour (PNN) and voxel nearest neighbour (VNN)) to interpolate and create the volume of the structure. Finally, defuzzification was used to estimate the optimal volume.
B-scans were acquired using 5 MHz and 8 MHz ultrasound probes on ultrasound tissue-mimicking phantoms. Quantitative evaluation of the reconstructed structures was done by comparing the method output to the real volumes. Comparison was also done with classical PNN and VNN algorithms.
With the fuzzy model quantification errors were less than 4.3%, whereas with classical algorithms, errors were larger (10.3% using PNN, 17.2% using VNN). Furthermore, for very small structures (0.5 cm(3)), errors reached 24.3% using the classical VNN algorithm, while they were about 9.6% with the fuzzy VNN model.
These experiments prove that the fuzzy model allows volumes to be determined with better accuracy and reproducibility, especially for small structures (<3 cm(3)).
存在许多用于从徒手二维超声切片进行数据三维重建的算法。这些方法基于插值技术,通过像素来填充体素。出于量化目的,需要进行分割以勾勒出感兴趣的结构。然而,斑点和部分容积效应误差会影响量化。
本研究旨在评估模糊模型与徒手超声图像三维重建算法相结合对这些误差的影响。
我们引入了一个模糊化步骤来校正初始分割,通过一个分布函数对像素进行加权,同时考虑局部灰度级、局部梯度方向和局部对比噪声比。然后我们使用两种应用最广泛的重建算法(像素最近邻(PNN)和体素最近邻(VNN))进行插值并创建结构的体积。最后,使用去模糊化来估计最佳体积。
使用5兆赫和8兆赫超声探头在超声组织模拟体模上采集B超扫描图像。通过将方法输出与实际体积进行比较,对重建结构进行定量评估。还与经典的PNN和VNN算法进行了比较。
使用模糊模型时,量化误差小于4.3%,而使用经典算法时,误差更大(使用PNN时为10.3%,使用VNN时为17.2%)。此外,对于非常小的结构(0.5立方厘米),使用经典VNN算法时误差达到24.3%,而使用模糊VNN模型时误差约为9.6%。
这些实验证明,模糊模型能够以更高的准确性和可重复性确定体积,特别是对于小结构(<3立方厘米)。
