Fractal analysis of dendrites morphology using modified Richardson's and box counting method.

Pub Date : 2013-01-01 DOI:10.1400/215773
D. Ristanovic, B. Stefanovic, N. Puškaš
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引用次数: 7

Abstract

Fractal analysis has proven to be a useful tool in analysis of various phenomena in numerous naturel sciences including biology and medicine. It has been widely used in quantitative morphologic studies mainly in calculating the fractal dimension of objects. The fractal dimension describes an object's complexity: it is higher if the object is more complex, that is, its border more rugged, its linear structure more winding, or its space more filled. We use a manual version of Richardson's (ruler-based) method and a most popular computer-based box-counting method applying to the problem of measuring the fractal dimension of dendritic arborization in neurons. We also compare how these methods work with skeletonized vs. unskeletonized binary images. We show that for dendrite arborization, the mean box dimension of unskeletonized images is significantly larger than that of skeletonized images. We also show that the box-counting method is sensitive to an object's orientation, whereas the ruler-based dimension is unaffected by skeletonizing and orientation. We show that the mean fractal dimension measured using the ruler-based method is significantly smaller than that measured using the box-counting method. Whereas the box-counting method requires defined usage that limits its utility for analyzing dendritic arborization, the ruler-based method based on Richardson's model presented here can be used more liberally. Although this method is rather tedious to use manually, an accessible computer-based implementation for the neuroscientist has not yet been made available.
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用改进的理查德森和箱形计数法进行枝晶形态的分形分析。
分形分析已被证明是分析包括生物学和医学在内的许多自然科学中各种现象的有用工具。它在定量形态学研究中得到了广泛的应用,主要是计算物体的分形维数。分形维数描述了物体的复杂程度:物体越复杂,也就是说,它的边界越崎岖,它的线性结构越蜿蜒,或者它的空间越填充,分形维数就越高。我们使用Richardson(基于尺子的)方法的手动版本和最流行的基于计算机的盒计数方法,应用于测量神经元树突树杈的分形维数问题。我们还比较了这些方法如何处理骨架化与非骨架化的二值图像。我们表明,对于树突树突化,非骨架化图像的平均盒维数明显大于骨架化图像的平均盒维数。我们还表明,盒计数方法对对象的方向很敏感,而基于尺子的维度不受骨架化和方向的影响。我们表明,使用基于尺子的方法测量的平均分形维数明显小于使用盒计数方法测量的平均分形维数。盒计数方法需要明确的用法,这限制了它在分析树突树杈化方面的效用,而基于Richardson模型的基于尺子的方法可以更自由地使用。尽管手工使用这种方法相当繁琐,但神经科学家还没有一种可访问的基于计算机的实现方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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