Three-dimensional tumor perfusion reconstruction using fractal interpolation functions

Three-dimensional tumor perfusion reconstruction using fractal interpolation functions

It has been shown that the perfusion of blood in tumor tissue can be approximated using the relative perfusion index determined from dynamic contrast-enhanced magnetic resonance imaging (DE-MRI) of the tumor blood pool. Also, it was concluded in a previous report that the blood perfusion in a two-di...

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Bibliographic Details
Published in:IEEE transactions on biomedical engineering Vol. 48; no. 4; pp. 462 - 473
Main Authors: Craciunescu, O.I., Das, S.K., Poulson, J.M., Samulski, T.V.
Format: Journal Article
Language:English
Published: New York, NY IEEE 01-04-2001
Institute of Electrical and Electronics Engineers
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Animals
Biological and medical sciences
Blood
Contrast Media
Dogs
Equations
Fibrosarcoma - blood supply
Forelimb
Fractals
General aspects
Image Processing, Computer-Assisted - methods
Image reconstruction
Interpolation
Magnetic Resonance Imaging
Medical sciences
Models, Cardiovascular
Neoplasms
Polynomials
Spline
Tumors
Two dimensional displays
Fissipedia
Carnivora
Tumoral tissue
Fractal system
Metabolism
Nuclear magnetic resonance imaging
Modeling
Image reconstruction
Interpolation
Vertebrata
Mammalia
Three dimensional representation
Perfusion
Animal
Medical imagery
Circulatory system
Hemodynamics
Dog
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Summary:It has been shown that the perfusion of blood in tumor tissue can be approximated using the relative perfusion index determined from dynamic contrast-enhanced magnetic resonance imaging (DE-MRI) of the tumor blood pool. Also, it was concluded in a previous report that the blood perfusion in a two-dimensional (2-D) tumor vessel network has a fractal structure and that the evolution of the perfusion front can be characterized using invasion percolation. Here, the three-dimensional (3-D) tumor perfusion is reconstructed from the 2-D slices using the method of fractal interpolation functions (FIF), i.e., the piecewise self-affine fractal interpolation model (PSAFIM) and the piecewise hidden variable fractal interpolation model (PHVFIM). The fractal models are compared to classical interpolatlon techniques (linear, spline, polynomial) by means of determining the 2-D fractal dimension of the reconstructed slices. Using FIFs instead of classical interpolation techniques better conserves the fractal-like structure of the perfusion data. Among the two FIF methods, PHVFIM conserves the 3-D fractality better due to the cross correlation that exists between the data in the 2-D slices and the data along the reconstructed direction. The 3-D structures resulting from PHVFIM have a fractal dimension within 3%-5% of the one reported in literature for 3-D percolation. It is, thus, concluded that the reconstructed 3-D perfusion has a percolation-like scaling. As the perfusion term from bio-heat equation is possibly better described by reconstruction via fractal interpolation, a more suitable computation of the temperature field induced during hyperthermia treatments is expected.
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ISSN:0018-9294
1558-2531
DOI:10.1109/10.915713