The present invention relates to a method for the characterization of connectivity within complex data and more particularly to a method for identifying neural pathways within DW-MRI data.
Magnetic Resonance Imaging (MRI), or nuclear magnetic resonance imaging, is commonly used to visualize detailed internal structures in the body. MRI provides superior contrast between the different soft tissues of the body when compared to x-ray computed tomography (CT). Unlike CT, MRI involves no ionizing radiation because it uses a powerful magnetic field to align protons, most commonly those of the hydrogen atoms of the water present in tissue. A radio frequency electromagnetic field is then briefly turned on, causing the protons to alter their alignment relative to the field. When this field is turned off the protons return to their original magnetization alignment. These alignment changes create signals that are detected by a scanner. Images can be created because the protons in different tissues return to their equilibrium state at different rates. By altering the parameters on the scanner this effect can be used to create contrast between different types of body tissue. MRI may be used to image every part of the body, and is particularly useful for neurological conditions, for disorders of the muscles and joints, for evaluating tumors, and for showing abnormalities in the heart and blood vessels. Magnetic resonance imaging (MRI) methods provide several tissue contrast mechanisms that can be used to assess the micro- and macrostructure of living tissue in both health and disease. Diffusion MRI is a method that produces in vivo images of biological tissues weighted with the local microstructural characteristics of water diffusion. There are two distinct forms of diffusion MRI, diffusion weighted MRI and diffusion tensor MRI. In diffusion weighted imaging (DWI), each image voxel (three-dimensional pixel) has an image intensity that reflects a single best measurement of the rate of water diffusion at that location. This measurement is more sensitive to early changes such as occur after a stroke than more traditional MRI measurements such as T1 or T2 relaxation rates. DWI is most applicable when the tissue of interest is dominated by isotropic water movement, e.g., grey matter in the cerebral cortex and major brain nuclei—where the diffusion rate appears to be the same when measured along any axis. Traditionally, in diffusion-weighted imaging (DWI), three gradient-directions are applied, sufficient to estimate the trace of the diffusion tensor or ‘average diffusivity’, a putative measure of edema. Clinically, trace-weighted images have proven to be very useful to diagnose vascular strokes in the brain, by early detection (within a couple of minutes) of the hypoxic edema.
Diffusion tensor imaging (DTI) is a technique that enables the measurement of the restricted diffusion of water in tissue in order to produce neural tract images instead of using this data solely for the purpose of assigning contrast or colors to pixels in a cross sectional image. It also provides useful structural information about muscle—including heart muscle, as well as other tissues such as the prostate. DTI is important when a tissue—such as the neural axons of white matter in the brain or muscle fibers in the heart—has an internal fibrous structure analogous to the anisotropy of some crystals. Water tends to diffuse more rapidly in the direction aligned with the internal structure, and more slowly as it moves transverse to the preferred direction. This also means that the measured rate of diffusion will differ depending on the position of the observer. In DTI, each voxel can have one or more pairs of parameters: a rate of diffusion and a preferred direction of diffusion, described in terms of three dimensional space, for which that parameter is valid. The properties of each voxel of a single DTI image may be calculated by vector or tensor math from six or more different diffusion weighted acquisitions, each obtained with a different orientation of the diffusion sensitizing gradients. In some methods, hundreds of measurements—each making up a complete image—can be used to generate a single resulting calculated image data set. The higher information content of a DTI voxel makes it extremely sensitive to subtle pathology in the brain. In addition, the directional information can be exploited at a higher level of structure to select and follow neural tracts through the brain—a process called tractography.
Tractography is the only available tool for identifying and measuring pathways in the brain (neural tracts) non-invasively and in-vivo. By comparison with invasive techniques, tractography measurements are indirect, difficult to interpret quantitatively, and error-prone. However, their non-invasive nature and ease of measurement mean that tractography studies can address scientific questions that cannot be answered by any other means. In particular, brain connections can be measured in living human subjects, and measurements can be made simultaneously across the entire brain. Hence, areal connections may be compared in humans across many cortical and sub-cortical sites. Furthermore, connections can be compared with other in-vivo measures such as functional connectivity and behavior across individuals.
More extended diffusion tensor imaging (DTI) scans derive neural tract directional information from the data using 3D or multidimensional vector algorithms based on three, six, or more gradient directions, sufficient to compute the diffusion tensor. The diffusion model is a rather simple model of the diffusion process, assuming homogeneity and linearity of the diffusion within each image voxel. From the diffusion tensor, diffusion anisotropy measures such as the fractional anisotropy (FA) can be computed. The principal direction of the diffusion tensor can be used to infer the white-matter connectivity of the brain. Recently, more advanced models of the diffusion process have been proposed to overcome the weaknesses of the diffusion tensor model. Amongst others, these include q-space imaging and generalized diffusion tensor imaging.
Reconstruction of tissue fiber pathways from volumetric diffusion weighted magnetic resonance imaging (DW-MRI) data is an inherently ill-posed problem because the local (voxel) diffusion measurements are noisy and made on a scale significantly greater than the underlying fibers and, thus, there are a multitude of possible neural pathways between any two given points in the imaging volume that might be consistent with the experimental data. The question then is to find the paths that are most probable. Current fiber tractography methods generally fall into two categories: 1) deterministic methods, typically based on some form of streamline construction, probabilistic methods, also generally based on streamline construction, but with the most likely principal diffusion direction determined from a posterior distribution of principal diffusion directions. These algorithms are “local” in the sense that the computations are done at each voxel and some small neighborhood around it and thus are not informed by the final path that is created, and thus are not capable of assessing the probability of the final path amongst all possible paths. In most cases, these algorithms are inherently based upon some underlying relation to a random walk which guides the evolution of the trajectories.
Recently, interest has grown in more “global” methods that take into account the probabilities of the final paths by incorporating the path probabilities into the estimation process. These methods are typically based upon parameterizations of the diffusion field, or the anatomical connections they imply, that extend spatially beyond the voxel dimensions and subsequently take the form of either improving the local computations by the incorporation of more spatially extended path lengths or on the extremization of a cost function over a multitude of possible paths. These global methods usually (with some exceptions do not take the random walk viewpoint but rather view the entire system as possessing some underlying structure, characterized by local interactions or potentials, that can be elucidated by optimizing some cost function (e.g., energy) over multiple configurations of that system.
The original diffusion tensor imaging (DTI) model assumes that the measurements in each voxel provide an estimate of a single real, 3×3 symmetric diffusion tensor D from whose eigenstructure can be derived both a meaningful measure of the anisotropy (here characterized by the fractional anisotropy FA and a principal eigenvector that can be used as a proxy for the fiber orientation. Then DTI is the simplest underlying model for diffusion tensor data, is predicated on a single fiber model for the voxel content, and is equivalent to a Gaussian model for diffusion. However, the DTI model is not sufficient to capture more realistic possibilities of complex fiber crossings needed for clinical applications. To estimate local diffusion directions in each voxel (streamline directions) several high angular resolution diffusion imaging (HARDI) methods are typically used. These methods represent an extension of the original DTI method to higher angular resolutions appropriate not only for detection of main fiber orientation, but also for attempting to resolve more complex intravoxel fiber architecture such as multiple crossing fibers.
In recent years, there has been significant interest in developing DW-MRI methods capable not only of estimating angular fiber distributions from multidirectional diffusion imaging (multiple q-angles), but also find spatial scales with multiple diffusion weightings (multiple b-shells). While it has long been recognized that the most general nonparametric (model-free) approach is to measure the displacement probability density function or diffusion propagator directly, the natural extension of this to imaging wherein 3D Cartesian sampling of q-space is used to obtain the 3D displacement probability density function (dPDF) at each voxel, is prohibitively expensive from the standpoint of data acquisition. This recognition has recently spawned more practical methods for obtaining an estimate of the dPDF, often called the ensemble average propagator (EAP), from more practical multi-shell, multi-directional acquisitions. See, e.g., Merlet, et al., “TRactography via the Ensemble Average Propagator in diffusion MRI”
Despite these advances, a critical simplification that is made in all current methods used to estimate either the intravoxel diffusion characteristics (via the EAP, for example) or to estimate the underlying global structure (tractography) is the assumption that these two estimation procedures are independent. Thus, one must first estimate the intravoxel diffusion, then apply a tractography algorithm. For example, multiple b-shell effects, used in obtaining the EAP, are used only to infer directional multiple fiber information for input into streamline tractography algorithms. However, this distinction between local and global estimation is artificial and limiting, since both the local (voxel EAP) information and the global structure (tracts) are from the same tissue, just seen at different scales.
In an embodiment of the invention, a method and system are provided for characterization of connectivity within complex data. The inventive method may be used for a wide range of applications in which connectivity needs to be inferred from complex multi-dimensional data, such as magnetic resonance imaging (MRI) of the human brain using diffusion tensor magnetic resonance imaging (DT-MRI) for characterization of neuronal fibers and brain connectivity, or in the analysis of networks in the human brain using functional MRI (fMRI).
Characterization of connectivity with data is a complex procedure that is often approached with ad-hoc methods. The inventive method provides a solution to the problem of assessing global connectivity within complex data sets. The method, referred to as “Entropy Spectrum Pathways”, or “ESP”, is based on the description of pathways according to their entropy, and provides a method for ranking the significance of the pathways. The method is a generalization of the maximum entropy random walk (“MERW”), which appears in the literature as a description of a diffusion process that possesses localization of probabilities. The inventive approach expands the use of MERW beyond diffusion, and applies it as a measure of information. Additional applications include network analysis.
A computer-implemented method for fiber tractography based on Entropy Spectrum Pathways includes instructions fixed in a computer-readable medium that cause a computer processor to solve an eigenvector problem for the probability distribution and use it for an integration of the probability conservation through ray tracing of the convective modes guided by a global structure of the entropy spectrum coupled with a small scale local diffusion. The intervoxel diffusion is sampled by multi b-shell multi q-angle DWI data expanded in spherical harmonics and spherical Bessel series.
In some embodiments, a method for fiber tractography processes multi-shell diffusion weighted MRI data to identify fiber tracts by calculating intravoxel diffusion characteristics from the MRI data. A transition probability is calculated for each possible path on the lattice, with the transition probability weighted according the intravoxel characteristics. Entropy is calculated for each path and the paths are ranked according to entropy. A geometrical optics algorithm is applied to the entropy data to define pathways, which are ranked according to their significance to generate a map of the pathways.
In one aspect, the inventive method includes acquiring, via an imaging system, diffusion weighted MRI data comprising a plurality of voxels, wherein the plurality of voxels defines a lattice, each voxel connected by a path; inputting the MRI data into a computer processor data having instructions stored therein for causing the computer processor to execute the steps of: calculating intravoxel diffusion characteristics from the MRI data; calculating a transition probability for each path on the lattice, wherein the transition probability is weighted according the intravoxel characteristics; calculating an entropy for each path; ranking the paths between two voxels according to entropy to determine a maximum entropy; calculating a connection between a global structure of the probability with a local structure of the lattice by applying the Fokker-Planck equation to one or more highest ranked paths, wherein potential equals entropy; calculating a location and direction of one or more fiber tracts by applying geometric optics algorithms to the results of the Fokker-Planck equation; and generating an output comprising a display corresponding to the one or more fiber tracts. In an embodiment of the method, the Fokker-Planck equation is ∂tP+∇·(LP∇S)=∇·D∇P, where P is the probability, S is the entropy, and L is a local diffusion tensor, where L=κD, where κ is the Onsager coefficient. In another embodiment, the geometric optics algorithms comprise
where r is the location, R is displacement, k is the direction, t is time, X=∇P0(2+ln P0)+∇(P0(1+ln P0)), Y=P0(1+ln P0), and Z=∇·∇P0(2+ln P0).
In another aspect of the invention, a method for fiber tractography comprises acquiring, via an imaging system, diffusion weighted MRI data comprising a plurality of voxels, wherein the plurality of voxels defines a lattice, each voxel connected by a path; inputting the MRI data into a computer processor data having instructions stored therein for causing the computer processor to execute the steps of: calculating intravoxel diffusion characteristics from the MRI data; calculating a transition probability for each path on the lattice, wherein the transition probability is weighted according the intravoxel characteristics; calculating an entropy for each path; ranking the paths between two voxels according to entropy to determine a maximum entropy; calculating a connection between a global structure of the probability with a local structure of the lattice for one or more highest ranked paths; determining one or more fiber tracts corresponding to the highest ranked paths using ray tracing, wherein potential equals entropy; and generating an output comprising a display corresponding to the one or more fiber tracts. In one embodiment, calculating a connection comprises applying the relationship ∂tP+∇·(LP∇S)=∇·D∇P to the one or more highest ranked paths, where P is probability=P0+P1, S is the entropy, D is a diffusion coefficient, and L is a local diffusion tensor, where L=κD, where κ is the Onsager coefficient. In another embodiment, ray tracing comprises applying geometric optics algorithms to the highest ranked paths according to the relationships
where r is the location, R is the displacement, k is the direction, t is time, X=∇P0(2+ln P0)+∇(P0(1+ln P0)), Y=P0(1+ln P0), and Z=∇·∇P0(2+ln P0).
In still another aspect of the invention, a method for fiber tractography comprises acquiring, via an imaging system, multi-shell diffusion weighted MRI data comprising a plurality of voxels, wherein the plurality of voxels define locations on a lattice, each location connected by a path; and in a computing device, executing the steps of: performing a spherical wave decomposition on the data to define a set of spherical wave decomposition coefficients; using the spherical wave decomposition coefficients, generating a coupling matrix for diffusion connectivity at multiple scales, wherein the coupling matrix defines interactions between locations on the lattice; using the coupling matrix, computing transition probabilities and equilibrium probabilities for a plurality of interactions between locations on the lattice; using the computed transition probabilities to represent angular and scale distributions of potential paths between locations on the lattice; applying a geometric optics tractography algorithm to the transition probabilities to construct possible pathways, each possible pathway having an eigenvector and an eigenvalue; calculating eigenmodes for the possible pathways; ranking the possible pathways according to their eigenmode; defining a preselected number of pathways from the ranked pathways; and displaying the preselected number of pathways on a visual display.
Applications of the ESP method include any commercial neuroscience application involved in the quantification of connectivity, including neural fiber connectivity using diffusion tensor imaging, functional connectivity using functional MRI, or anatomical connectivity using segmentation analysis. The ESP method may also be used as a tool for characterization of connectivity in networks, examples of which include the internet and communications systems.
The present invention provides a method for the simultaneous estimation of local diffusion and global fiber tracts. The ESP method can be further enhanced by introducing a new approach to include multi-scale and multi-modal diffusion field into a scalar information entropy flow.
For the first time in neuroscience, the ESP method provides for the application of probability conservation to obtain fiber tracts through ray tracing of the convective modes guided by a global structure of the entropy spectrum coupled with small scale local diffusion. The method uses a novel approach to incorporate global information about multiple fiber crossings in each individual voxel and rank it in a scientifically rigorous manner. The method exploits six dimensional space for tracking neurofibers, providing a significant improvement over the three-dimensional positional tracking methods currently in use. The method avoids the need for an expensive front evolution step, which is common in the majority of current approaches. Instead, it is able to derive more complete and accurate path information more efficiently from the global entropy spectrum.
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A computer 226 of the imaging system 200 comprises a processor 202 and storage 212. Suitable processors include, for example, general-purpose processors, digital signal processors, and microcontrollers. Processor architectures generally include execution units (e.g., fixed point, floating point, integer, etc.), storage (e.g., registers, memory, etc.), instruction decoding, peripherals (e.g., interrupt controllers, timers, direct memory access controllers, etc.), input/output systems (e.g., serial ports, parallel ports, etc.) and various other components and sub-systems. The storage 212 includes a computer-readable storage medium.
Software programming executable by the processor 202 may be stored in the storage 212. More specifically, the storage 212 contains software instructions that, when executed by the processor 202, causes the processor 202 to acquire multi-shell diffusion weighted magnetic resonance (MRI) data in the region of interest (“ROI”) and process it using a spherical wave decomposition (SWD) module (SWD module 214); compute entropy spectrum pathways (ESP) (ESP module 216); perform ray tracing using a geometric optics tractography algorithm (GO module 218) to generate graphical images of fiber tracts for display (e.g., on display device 210, which may be any device suitable for displaying graphic data) the microstructural integrity and/or connectivity of ROI based on the computed MD and FA (microstructural integrity/connectivity module 224). More particularly, the software instructions stored in the storage 212 cause the processor 202 to display the microstructural integrity and/or connectivity of ROI based on the SWD, ESP and GO computations.
Additionally, the software instructions stored in the storage 212 may cause the processor 202 to perform various other operations described herein. In some cases, one or more of the modules may be executed using a second computer of the imaging system. (Even if the second computer is not originally or initially part of the imaging system 200, it is considered in the context of this disclosure as part of the imaging system 200.) In this disclosure, the computers of the imaging system 200 are interconnected and are capable of communicating with one another and performing tasks in an integrated manner. For example, each computer is able to access the other's storage.
In other cases, a computer system (similar to the computer 226), whether being a part of the imaging system 200 or not, is used for post-processing of diffusion MRI data that have been acquired. In this disclosure, such a computer system comprise one or more computers and the computers are interconnected and are capable of communicating with one another and performing tasks in an integrated manner. For example, each computer is able to access another's storage. Such a computer system comprises a processor and a computer-readable storage medium (CRSM). The CRSM contains software that, when executed by the processor, causes the processor to obtain diffusion magnetic resonance (MRI) data in region of interest (ROI) in a patient and process the data by performing spherical wave decomposition (SWD), entropy spectrum pathway (ESP) analysis and applying geometric optics algorithms to execute ray tracing operations to define fiber tracts for display on a display device.
The inventive method provides a solution to the problem of assessing global connectivity within complex data sets. The method, referred to as “Entropy Spectrum Pathways”, or “ESP”, described below, is based on the description of pathways according to their entropy, and provides a method for ranking the significance of the pathways. The method is a generalization of the maximum entropy random walk (“MERW”), which appears in the literature as a description of a diffusion process that possesses localization of probabilities. The inventive approach expands the use of MERW beyond diffusion, and applies it as a measure of information. Additional applications include network analysis.
According to the ESP method, the MERW solution can be viewed as a specific manifestation of a more general result concerning inference on a lattice which has nothing necessarily to do with diffusion, or any other physical process. The general approach results in a new theoretical framework suitable for application to a wide range of problems involved with analysis of disordered lattice systems. As a byproduct, we show that the previous interpretation of the localization phenomenon by the Lifshitz sphere argument is not true in general. Moreover, the correct general solution we derive elucidates the source of the localization phenomenon, demonstrates that it actually occurs on multiple scales, and paves the way for the classification of optimal pathways of information in a lattice.
Consider the random walk on a two-dimensional lattice—a random walk is defined by the simple rule that at each time step a particle at location (i, j) can move one step in either the i or j direction. In a standard, or generic, random walk (GRW), all lattice sites are accessible, as illustrated in
Consider a 2D Cartesian grid of equally spaced points at R spatial locations (xl, . . . , xR) where each point can take on any one of s available values {vl, . . . , vs}. To simplify the notation, we will equate the spatial path with the sequence of values and speak of the trajectory as the sequence of values along the spatial path: γban={vx
The logical procedure for determining the path probabilities is the principle of maximum entropy in which the Shannon information entropy
is maximized subject to the constraints imposed by the basic rules of probability theory and by the s data points uk for k=1, . . . , s:
where the Uk are the expected values of the data along the set of all possible paths {γ}. This is a variational problem solved by the method of Lagrange multipliers and has the general solution:
p(γ)=Z−1 exp[−Λ(γ)], (3)
where
and the partition function is
The Lagrange multipliers {λk} are determined from the data by
for k=1, . . . , s, and the fluctuations are determined from
The entropy Eq. 1 of the maximum entropy distribution Eq. 3 is
The reformulation of the path probabilities in terms of the maximum entropy formalism, as expressed by Eqs. 3-8, allows the construction of path probabilities consistent with given prior information. We now consider two different sets of prior information and show how these lead to the GRW and MERW, respectively. We stress here the fact that the dependence of the derived distribution p(γ) on the prior information means that it is an expression of our processing of information, rather than of a physical effect. Moreover, while the specific examples described herein are confined to prior information about nearest neighbor coupling, the formalism is very general and can incorporate prior information about more complex couplings.
Suppose that the known values vi represent the node degrees d and that the prior information consists of the frequency fi with which each value di occurs. If Ni=number of times di appears along γ, and fi=expected frequencies of di, then
where N=Σi Ni is the total number of sites visited. The path probability p(γ) is then found by maximizing Eq. 1 subject to Eq. 2a, Eq. 2b, and Eq. 2c (in the form of Eq. 9). The solution is then:
where the partition function is
and
From Eq. 6 and Eq. 9
λi=−ln(zfi),1≦i≦s, (13)
which, when substituted into Eq. 3 and properly normalized, gives the multinomial distribution
For 2D Cartesian lattice s=4. The number of different paths for specified Ni is N!/(N1! . . . Ns!). Eq. 14 says that the probability of any path only depends on how many times the values {vi} appear along the path, but not on the order in which they appear. Thus the GRW can be viewed as the maximum entropy solution when the prior information is limited to the frequency of occurrences of the defects.
Supposing that the prior information consists of the frequency fij with which the pairs of value vivj occur together. At the end, we will consider the special case in which this information is reduced to whether or not location i and j are connected, on that the prior information is just the adjacency matrix. Now we consider the more general case where Nij=number of times vivj appears along γ, and fij=expected frequencies of the pairs vivj, and the fij are known (they are again the prior information), then
where n=Σij Nij is the total number of jumps between sites, and thus the trajectory length, and again {γ} denotes the set of all possible paths γ. In the path γ the number of times the pair xixj appears is
where δ represents the Dirac delta function: δi,j=1 if i=j and δi,j=0 for i≠j.
The problem is logically identical to the problem of diagram frequencies in communication theory addressed by Jaynes. The path probability p(ry) that has maximum entropy subject to the constraint Eq. 15 has the solution
where the partition function is
This complicated sum over all the different paths γ is simplified by noting that this partition function can be rewritten in terms of a matrix product
where the matrix Q is defined as
Qij=e−λ
Thus, each transition probability is associated with a standard eigenvalue equation
This matrix defines the interactions between locations on the lattice and so will be called the “coupling matrix.” As we show later, the Lagrange multiplier λij that define the interactions can be seen as local potentials that depend on some function of the spatial locations on the lattice. We will suppress the more complete notation λij (xij), and thus Q (xij), for clarity.
A useful trick to simplify the computation of the partition function is to add the step (xn, xl) to the pathway, which adds another exp(−λij) to the partition function Eq. 18 and creates periodic boundary conditions. This modifies Eq. 19 to
where {qk} are the roots of |Qij−qδij|. This trick is justified in the limit of long trajectories n>∞. The probability of the entire path, Eq. 17 can be written using Eq. 16 and Eq. 20
p(γab|I)=Z−1Qx
where the periodic boundary conditions trick has been invoked.
While Eq. 17 is formally the solution of the path probability, we would like to determine the transition probability. In order to do this, we can consider the problem of how our estimates change as we move along a path. In other words, if we have moved part way along a path, what does this tell us about the remainder of the path? This is analogous to the partial message problem. To address this question, imagine that we break the path yab from an initial point a to a final point b into two segments (
γac(m−1)=vx
γcb(n−m+1)=vx
The probability of the entire path is just the joint probability of the two path segments {γac, γcb} and from the basic rules of probability theory is equal to Eq. 17:
p(γab|I)=p(γabγcb|I)=p(γcb|γac,I)p(γac|I) (24)
so the conditional probability of γcb, given γac, is
The marginal distribution of initial part of the path, p(γac|I), is
which, from Eq. 22, is
where
R=Z−1Qx
Define the transition point from the initial path as ij where i=xm−1 is the last point in the first path and j=xm is the first point in the second path. Just as in the step from Eq. 18 to Eq. 19, the sum over paths in Eq. 27 can be written as a matrix product:
where
The conditional probability distribution of the second part of the path, given the first part (Eq. 25) is then, from Eq. 22 and Eq. 29,
since the common factor R cancels. This distribution represents a Markov chain because the probability for the second path {xm . . . xn} depends only on the previous location xm−1 and not on any of the details of the path the particle took to get to that point. From Eq. 31 we can determine the probability that the path switches from the first path at i=xm−1 to the second path at j=xm. This is called the “transition probability” and is found from the basic rules of probability by summing Eq. 31 over the locations that are not of interest:
where the term in parentheses is just Tj of Eq. 30. Thus, the transition probability is
where the superscript notation is to remind us of the dependency on both n and m. This result was previously derived in the context of communication theory. This represents the maximum entropy transition probability between location i=xm−1 and location j=xm for a path of length n.
Having derived the general case Eq. 34, the limiting case for n→∞ can be determined. The term both containing m and n is Tk (Eq. 30), so we look at that first. The matrix Q can be reduced to block diagonal Q form as there exists a non-singular matrix B for which
Qn=B
so as n→∞ the element(s) q1n of Qn dominate all others. In general, the roots {q1, q2, . . . , qr} (assumed to be arranged in the order |q1|≧|q2|≧ . . . ≧|qr|) of the characteristic equation D(q)=det(Qij−qôij) can be degenerate and complex. However, if q1 is non-degenerate and real, then from Eq. 30 and Eq. 35
ψ1≡B1 is an eigenvector of Q (the one with the largest eigenvalue) and ψ1i is the ith component of ψ1. The denominator of Eq. 34 then contains a term
Using this and canceling common factors, the transition probability Eq. 34 in the limit of large n becomes:
where q1 is the maximum eigenvalue of Q and ψ1i is the ith element of the eigenvector ψ1 associated with the maximum eigenvalue.
It is useful at this point to recall the parameter dependencies in Eq. 38. As noted above, the coupling matrix depends on the spatial locations Q(x) through the Lagrange multipliers. Thus, so do the eigenvectors: ψ=ψ(x) and the associated eigenvalues q(x). In the examples shown below, the spatial dependence of these quantities is what produces the distribution maps directly from the eigenstructure of the lattice.
Eq. 38 appears similar to the expression for the transition matrix a priori introduced in (Eq. 5) but with several important differences. First of all, rather than being postulated it was obtained as a limit n→∞ from a more general expression Eq. 34. The derivation of Eq. 34 itself is general and depends on the sequence length n and the transition point xm, both of which may be of arbitrary length (provided m<n). Further, it is not required that Q represent an adjacency matrix. If the Lagrange multipliers take the form
then Q becomes an adjacency matrix and Eq. 38 is identical to the expression (Eq. 5). Taking the Lagrange multipliers as “potentials”, Eq. 39 can be viewed as representing local potentials that are either completely attractive (λ=0) or completely repulsive (λ=∞).
The entropy of the maximum entropy distribution Eq. 8, in the limit n→∞ can be obtained using the expression for the partition function
{where qk} are the roots of |Qij−qδij|. Taking limn→∞Z=q1n and using Eq. 15, the entropy per step becomes, from Eq. 8,
From Eq. 39, for the connected components λij=0, in which case Eq. 41 becomes S/n=ln q1, which is the same as the limit given by Burda, et. al. (Phys. Rev. Lett. 103, 160602 (2009).
In the special case that Q reduces to the adjacency matrix A (Eq. 39), an interesting property of the transition probability pij(∞)(γ) in the limit n→∞ (the equilibrium transition probability) noted by Burda is that it localizes in what appears to be the largest accessible region of a defective lattice. They explained this effect by reformulating the problem in terms of a Hamiltonian equation, then making the analogy with Lifshitz spheres, defined as the largest spherical region of the lattice that is free of defects. We show here that this view is not correct in general.
It has been noted that the spatial distribution of the equilibrium probability density is described by the eigenvector ψ(1) associated with the maximum eigenvalue q1 and thus localization can be investigated by looking at the structure of ψ(1). While it is possible to work directly in the eigen coordinates of the adjacency matrix Aψ(k)=qkψ(k), it is useful and common to recast this in the form of a differential equation by noting that the adjacency matrix is related to the graph Laplacian by L=D−A. The elements of the diagonal degree matrix are dii=di, where di is the vertex degree, and thus
Lψ
(k)
−Dψ
(k)
=−q
kψ(k) (42)
In an undirected graph where edges have no orientation (which is all we will consider here), the degree is the number of edges incident to the vertex. For graphs that in the absence of defects are regular, every vertex has the same degree dmax. Then, vertices with defects have d=0 and those with d<dmax are adjacent to defects. Adding dmaxψ(k) to each side of Eq. 42 and noting that the graph Laplacian is the negative of the Laplacian operator Δ for the Dirichlet boundary conditions considered here, yields the differential equation
−Δψ+Vψ=Ekψ (43)
where Vj=dmax−dj is the “potential” and Ek=dmax−qk is the “energy”. The potential V is a vector of length n=length(ψ) and Vψ in Eq. 43 is an n-dimensional vector whose jth element is Vjψj. Spatial variations in the potential are thus encoded through the components Vj. Eq. 43 has the familiar form of a Hamiltonian equation ψ=Ekψ where =Δ+V. The addition of dmaxψ to both sides of Eq. 42 allows the interpretation of ψ(1) of Eq. 43 as the ground state wavefunction, since E1=dmax−q1 is the lowest energy because q1 is the largest eigenvalue.
While the spatial distribution of the equilibrium MERW probability is encoded in ψ1 the higher order MERW eigenfunction convey important information, as we shall demonstrate. Thus, while it is possible to examine Eq. 43 in the context of Lifshitz potentials, it is perhaps more illuminating to recognize that this equation expresses the fact that the eigenvectors of the adjacency matrix are the different energy modes of the Laplacian with boundary conditions determined by the potentials. This viewpoint permits a clear understanding of the localization phenomenon, and will further inform our understanding of the dynamics.
To illustrate this view, we consider localization examples of the disk and the ellipse, shown in
Thus there are in fact multiple localization regions within the lattice, ranked according to the corresponding eigenvalues. It is therefore the spectrum of the maximum entropy eigenvectors, in descending order of the associated eigenvalues, which describes the information flow in the lattice. This flow occurs via a multitude of paths over multiple spatial scales of the lattice, hence the name “entropy spectrum pathways”, or “ESP.” In practical applications, the lattice can be described in terms of in pathways constructed from the first in eigenvectors of the adjacency matrix (in decreasing order of the eigenvalues which, from Eq. 38, is
where
For each transition matrix Eq. 44b there is a unique stationary distribution associated with each path k:
μ(k)=[ψ(k)]2 (45)
that satisfies
the first of which μi(1) corresponds to the to the maximum entropy stationary distribution.
The localization phenomenon in a random lattice can now be made clear by combining a random lattice with the perfect disk and ellipse of
pt+1=pijpt (47)
In the lattice
While Eq. 47 provides a method to compute the information flow in the lattice, it provides little insight into how the macroscopic structure of the pathways is related to the microscopic dynamics of the information flow. One possibility to introduce this relation (due to Jaynes (Complex Systems—Operational Approaches in Neurobiology, Physics, and Computers, edited by H. Haken (Springer-Verlag, Berlin, 1985) pp. 254-269), albeit in a highly abbreviated form) is “bubble dynamics”, in which the spatial-temporal characteristics of a probability density P(x l . . . xm; t) of a set of macroscopic variables X i, i=1, . . . , m, is characterized by the conservation of probability
∂tP+∇JI=0 (48)
where the information flux JI is the sum of a diffusive component Jd=−D∇P and a convective component Jc=−LP∇S:
J
I
=J
d
+J
c (49)
and S(x)=k In W(x) is the entropy in which W(x) is the density of states, D is the diffusion coefficient (or, more generally, the diffusion tensor), and L=κD (where κ≡k−1 is the Onsager coefficient). Here x refers to spatial coordinates, on k, which is Boltzmann's constant in thermodynamics, just scales the entropy to the macroscopic variable space. Onsager coefficients are thus diffusion coefficients scaled to the spatial coordinates. Substitution of Eq. 49 into Eq. 48 gives
∂tP+L∇·(P∇S)=D∇2P (50)
This is the Fokker-Planck equation with the potential equal to the entropy: V=S, and connects the global structure of the probability with the local structure of the lattice through the local structure of the entropy. Eq. 50 was previously derived (in a slightly different form) by Grabert and Green, (Physical Review A 19, 1747 (1979). It can be shown that Eq. 50 accurately describes the dynamics of the ESP, such as that illustrated in
In order to investigate the dynamics via Eq. 50 we need to construct the entropy S. Having determined the maximum entropy transition matrix Pij∞ (Eq. 38) between an initial point i and a final point j on the lattice, we want to construct the entropy map by calculating the entropy for every path xij between these two points. This amounts to calculating the matrix
We then utilize a theorem by Ekroot and Cover (IEEE Trans. on Inform. Theory 39, 1418 (1993)) to construct the entropy map for all paths between a specified initial and final lattice locations. This theorem demonstrates that the matrix Eq. 51 can be computed directly from the transition matrix pij and the equilibrium distribution μ from the expression
S=K−{tilde over (K)}+S
Δ (52)
where K=(I−P+B)−1 (S*−SΔ) in which I is the identity matrix, P is the transition matrix, and {tilde over (K)}ij=Kjj, Bij=μj, S*ij=S(pij) and
where h is the entropy per step in the limit n→∞:
and S(pi) is the entropy of the first step of a trajectory initially at location i, given by
The columns of S correspond to spatial maps of maximal entropy pathways from each point in the image to the target points and thus reveal preferred pathways throughout the image volume. This procedure can be done for any other of the k modes using pijk∞ (Eq. 44b).
Using this construction, the path entropy S(x,y) (Eq. 51) from the initial distribution location
The time-varying distribution P(x,y,t) for the path entropy
The presented formalism can be used for finding static relations and for assessing dynamical information flow in many real world situations. With the ever-increasing number of applications in which connectivity plays a critical role (social networks, brain function and structure, etc.), methods for quantitative assessment of connectivity measures will play an increasingly significant role in a wide range of applications.
As an illustration of possible applications, we have included one practical example of ESP processing of magnetic resonance diffusion tensor imaging (MR-DTI) data, DTI data is often used for neural fiber tractography in the studies of brain connectivity. This is a complex and severely ill-posed problem. Within an imaging volume, local (voxel) DTI data measurements are used to reconstruct a (possibly high dimensional) tensor in each voxel that is able to capture some broad aspects of the underlying tissue microstructure, but on a scale much greater than the fibers themselves. From these tensor estimates are reconstructed the proported pathways of neural fiber bundles throughout the brain that produced the underlying variations in the diffusion signal. Imaging resolution is never (currently) fine enough to resolve individual fibers and thus individual voxel measurements are degraded by averaging over fiber bundles, possibly at different orientations, and other tissue compartments. Given the great complexity of the neural structure of the human brain, reconstruction of the macroscopic neural pathways from large volumes of noisy, highly multidimensional tensors derived from measurements of microscopic signal variations poses a significant theoretical and computational challenge.
The reconstruction of the macroscopic neural fiber pathways from the microscopic measurements of the local diffusion from DTI data is precisely the type of problem suited for the ESP formalism. The goal is to determine the most probable global pathways (neural fibers) consistent with measured values (diffusion tensors) based upon the available prior information. The ESP formalism provides a general method for the incorporation of prior information regarding the relationship between voxels. While the current description is limited to the nearest neighborhood coupling discussed in detail above, those of skill in the art will recognize that this is but one possible realization of the method. For the nearest neighbor coupling, the local potential can be derived from the interaction of the tensors, which is chosen here to be their inner product.
The presented example clearly shows a “global” nature of the ESP method, in the sense that it probes the most probable of all possible paths between the two points and the optimization is based on the entropy of the entire path, which depends upon all of the possible connections in all of the possible paths. One important advantage as demonstrated here is that the neighborhood of the path is explicitly taken into account. Different coupling schemes can produce different trajectory calibers. The method is quite general and can incorporate more sophisticated models of both intervoxel diffusion anisotropy, such as high angular resolution reconstruction, and intravoxel coupling schemes, such as long range correlations.
A critical simplification that is made in all current methods used to estimate either the intravoxel diffusion characteristics (via the EAP, for example) or to estimate the underlying global structure (tractography) is the assumption that these two estimation procedures are independent. Thus, one first estimates the intravoxel diffusion, then applies a tractography algorithms. For example multiple b-shell effects, used in obtaining the EAP, are used only to infer directional multiple fiber information for input into streamline tractography algorithms. However, this distinction between local and global estimation is artificial and limiting, since both the local (voxel EAP) information and the global structure (tracts) are from the same tissue, just seen at different scales.
The problem of local diffusion estimation and fiber tractography is revisited with the specific goal to include multiple spatial and temporal scales that can be deduced from multiple b-shell DW-MRI measurements in addition to just angular (multi-)fiber orientation. In many practical applications, either one or two spatial locations (or regions) are known a priori. In neuroscience applications, for example, two regions may be functionally connected (as measured, perhaps, by FMRI) and the diffusion weighted MRI data is being used to assess the degree (if any) of the structural connectivity between two functionally connected regions. We therefore reconsider two common formulations of fiber tractography: (1)—initial value, i.e., finding fibers that start at some chosen area of the brain; and (2)—boundary value, i.e., finding fibers that connect two preselected brain regions. Thus, we recast the fiber tractography algorithm as the determination of the most probable path either starting at a selected location or connecting two spatial locations, and seek a general probabilistic framework that can accommodate various local diffusion models and yet can incorporate the structure of extended pathways into the inference process. In this case, the problem of tractography from DWI data can be reformulated as the determination of the probability of paths on a 3D lattice between two given points where the probability of a path passing through any particular point is not equiprobable, but is weighted according to the locally measured diffusion characteristics.
The essential problem at the core of the tractography problem is the estimation of macroscopic structure from microscopic measurements. In this example, we present a formulation of the tractography problem based upon entropy spectrum pathways (ESP). The ESP method is generalized to utilize multi-scale diffusion information that is available in multi-shell DWI datasets by extending the mechanism of streamlines generation using a Hamiltonian formalism and a diffusion-convection (Fokker-Plank) description of signal propagation though multiple scales.
The ESP framework allows for the incorporation of both measured data and prior information into the estimation procedure. It is therefore essential that the description of the data be as general and complete as possible. A general description of the measured DW-MRI data is provided by the EAP formalism. (See, e.g., M. Descoteaux, et al., “Multiple q-shell diffusion propagator imaging,” Med. Image Anal., vol. 15, no. 4, pp. 603-621, August 2011.) In this example, we reformulate the problem in order to provide a general characterization amenable to numerical implementation, and to bring out some of the essential spatial scales that inform the application of ESP.
The basic process for application of the inventive approach to fiber tractography are illustrated in the block diagram 1100 of
In step 1102, the DW-MRI signal W(r, q) measured in both r and q space can be expressed in terms of both the spin density p(r) and the average propagator pΔ(r, R) using the narrow pulse approximation as
W(r,q)=∫Q(r,R)e−iq·RdR (56)
where r is the voxel coordinate, q=γGδ/2π, with G and δ being the strength and duration of the diffusion-encoding gradient and γ the gyromagnetic ratio of protons and the function W(r, q) is the Fourier transform (in the diffusion displacement coordinate R, defined as a change in particle position over time t, R=r(t0+t)−r(t0)) of the weighted spin density function
Q(r,R)=ρ(r)pΔ(r,R) (57)
that scales (or weights) the spin density with the average propagator pΔ(r, R) at each observed voxel.
In step 1104, to find an expression for the spin density function Q(r, R) we will use the plane wave expansion in spherical coordinates with q=q{circumflex over (q)} and R=R{circumflex over (R)}, where q=∥Q∥ and R=∥R∥,
where jl(qR) is the spherical Bessel function of order l and Ylm({acute over (q)})=Ylm(Ω{acute over (q)})=Ylm(θq,φq) is the spherical harmonic with θq and φq being the polar and azimuthal angles of the vector q, and similarly for the vector R.
The product ql(qx)Ylm({circumflex over (x)}) represents the basis function for the spherical wave expansion. These basis functions can be obtained as solutions of Helmholtz's wave equation:
∇2f+q2f=0, (59)
This representation suggests an interesting possibility of treating the problem of fiber tractography for diffusion weighted MRI data using the techniques of geometrical optics in inhomogeneous media.
The above basis functions are composed of radial (spherical Bessel jl) and angular (spherical harmonic Ylm) parts, where the spherical harmonics Ylm ({circumflex over (x)}) are the eigensolution of the angular part of the Laplacian with the eigenvalues λl=−l(l+1):
∇Ω2Ylm=λlYlm. (60)
The spherical harmonic Ylm of degree l and order m allows separation of the θ and φ variables when expressed using associated Legendre polynomials Plm of order m as
Y
l
m(θ,φ)=cl,mPlm(cos θ)e−imφ (61)
where cl,m is the normalization constant
chosen to guarantee the orthonormality condition
∫0π∫02πYlmYl′m′*sin θdθdφ=δll′,δmm′.
The radial component jl(qx) of Eq. 58 is obtained as the eigenfunction of the radial Laplacian
with the orthonormality conditions
This allows us to reconstruct the spin density function (r, R) using the spherical wave decomposition as
where
s
lm(r,R)=∫W(r,q)jl(qR)Ylm*({circumflex over (q)})dq. (64)
This representation offers a concise and intuitively clear quantitative description of the local diffusion in terms of a clearly defined expansion order on which can be based decisions of optimal fitting. It may be noted that finding the best representation of q-signal on partially acquired grid was not an intent of the above exercise, and that existing fast and robust algorithms previously disclosed by the inventors in International Publication No. WO02015/039054 A1 (incorporated herein by reference) were used for this computation. This implementation is flexible and provides a choice of several filters that can significantly reduce ringing artifacts.
It should be kept in mind that the typical scales for the voxel coordinate r and for the dynamic displacement R in current diffusion weighted MR experiments are vastly different. For the time scale over which the individual measurements in DWI are typically made (≈50 ms), the free diffusion root mean squared distance is x21/2≈20μ and thus much smaller than typical voxel dimensions (≈1 mm3, at best). Hence, with high degree of accuracy it can be assumed that the average propagator in the spin density function Q(r, R) only influences the nearest neighbor voxels through the dynamic displacement R dependence. The entropy spectrum pathway (ESP) formalism presented herein is well suited for taking nearest neighbors into account.
As previously described, the ESP method is an extension of the maximum entropy random walk and concerns the very general problem of random walks on a defective or disordered lattice. ESP provides several key findings: first, the pathways of the random walk are determined by prior information concerning the structure and relationships of the lattice points, and therefore the ESP represents a flow of information, rather than representing an actual physical process. This view facilitates the use of ESP within a wide range of practical problems related to connectivity. Second, it is possible to characterize multiple pathways, ranked according to their entropy, all of which contribute to the flow of information on the lattice. Thirdly, the interesting localization phenomenon previously noted can be understood in terms of the eigenstructure of the lattice. Fourthly, the local interactions that inform the generation of global structure can be based upon whatever coupling information the user has available. This coupling can take on a general form, and it was shown that this property can be understood in terms of potential theory. In the case of nearest neighbor coupling with a “binary” potential (on or off), the problem reduces to the computation of the eigenstructure of the adjacency matrix of accessible (non-defective) lattice locations. But the more general formulation of ESP facilitates the use in practical applications.
In the context of the tractography problem, the objective is to calculate the probability that a spin, or “particle”, starting from an initial spatial location x(t0) at initial time t0=0 diffuses to a second location x(t) at a later time t. While the underlying structure we wish to estimate is assumed continuous (being comprised of tissue fibers), the spatial locations x at which the measurements are acquired are assumed to be from DWI images and thus discretized to a 3D Cartesian spatial grid. However, the temporal discretization to be employed is a fictitious construct used to implement a random walk model, due to the above mentioned difference in scales of the voxel coordinates and the dynamic displacement. Our space-time points are defined on the true voxel spatial grid but on a diffusion pseudo-time grid whose increments are much larger than the experimental time scale. Simulating diffusion in this way lends itself to two different interpretations. One view of this process is to see it as diffusion that is allowed to take place for much longer than the measurement time, or, equivalently, that the process is in equilibrium and thus long time behavior is well-represented by the snapshots in time provided by the experimental data. However, another viewpoint, that of ESP, and the one we adopt, is that the simulation is of the flow of information constrained by the physical measurements. The entire process is one of estimating macroscopic phenomena from local measurements, using prior information.
Application of the ESP theory to the present problem lies in its ability to rank multiple paths, and that these paths can be constructed from arbitrary coupling schemes through Qij. For each of the stationary distributions is associated a path related to the localization of information related to the eigenstructure of the disordered lattice (see Eq. 45). The key feature is that the local transition probabilities between nodes depend on the global structure of the graph through the eigenvectors ψ(k). In practical applications, the lattice can be described in terms of n pathways constructed from the first n eigenvectors of the potential matrix in decreasing order of the eigenvalues).
We do not presume to be explicitly modeling the diffusion over the paths, since we know that the diffusion length over the typical time-scale of a DWI experiment is typically far smaller than a voxel dimension. Rather, this procedure is viewed as one of estimation and thus the construction of the ranked maximum entropy paths—those that are most unbiased with respect to the measured data and the prior information (the lattice couplings) while satisfying the initial and/or final conditions. In this view, the problem is one of estimating the global connectivity from the local diffusion characteristics.
The estimation of the local and global tissue structure over multiple scales using DW-MRI data can be investigated within the ESP framework by viewing the data as measurements on a 3D lattice in which each voxel is ascribed a “potential” that is related to its coupling with neighboring voxels. An important feature of the ESP approach is that this potential is very general in form. This is critical to its application in the current problem. While it was shown for a binary coupling (i.e., wherein the coupling matrix reduced to the adjacency matrix with 0/1 elements), in the current problem we will incorporate a strength of coupling that reflects the local interaction of voxel data. In order to do this we first symmetrize the spin density function
Q
ij(ri,l)=Qji(rj,l)=½[Q(ri,(ri−rj)l)+Q(rj,(rj−ri)l)], (65)
where l represents the dimensionless ratio of scales of dynamic displacement R to the spatial (voxel) scales r, and, then sum all relevant scales included in the spin density function Q(r, R) by the dependence on the dynamic displacement R:
ij
=
ji=∫lminlmaxQij(ri,l)dl. (66)
Here, we used a symmetric input from voxels i and j by taking the line integral of the spin density function Q(r, Ri) along the direction Rl=ri−rj between those voxels and take into account only a subset of spatial scales that can contribute to this interaction (from lmin to lmax). Since the typical scales for the voxel coordinate r in current diffusion weighted MR experiments are much larger than the scales for the dynamic displacement R (20μ vs 1 mm), the coupling can be limited to nearest neighbor effects taking lmin=0 and lmax=∞ to calculate a coupling potential
In step 1106 of
which will be equal to the total transition probability Pij when integrated over all scales l. As those probabilities only describe transitions between nearest neighbors they can be expressed as a scale dependent function l(r, R). We will also generate the equilibrium probabilities μ(k)=[ψ(k)]2.
To reiterate, the general problem of tractography is necessarily one of multiple scales because the local diffusion occurs on the microscale and the tracts are on a macroscale. The entire point of the ESP approach is that it enables a characterization of the problem in terms of information at these multiple scales.
The present goal is either to construct a pathway between an initial spatial location a and a final spatial location b or to trace a pathway incrementally starting from an initial location a. In both cases we are interested in “the most probable” pathways, i.e., we would like to constrain our local search by the global entropy structure. Therefore, our interest is not in the final equilibrium distribution μ* but in the pathway to it. We are therefore interested in the dynamics of the probability and want to compute the path that maximizes the entropy at each step, and thus results in the final (equilibrium) distribution μ* at time τ. The scale dependent transition and equilibrium probabilities obtained in the previous section can naturally define the global entropy field that shapes the flow of information and allow optimal paths to be found. In the limit of long pathway lengths (or large time τ) and under the Markovian assumption, the rate of entropy change Sl(ri) can be expressed at each location ri as
The most straightforward way to include this multiscale structure of the global entropy field is by taking into account that the conservation of probability in general includes not only the diffusive component (as for example used by Callaghan (Principles of nuclear magnetic resonance miscroscopy, Oxford Univer. Press, 1993) for obtaining the expression of EAP in single mode homogeneous self-diffusion), but also has the convective part
∂tP+∇·(LP∇S)=∇·D∇P, (70)
where P is the probability, S is the entropy, and L and D are coefficients (in general, either tensors or functions of the coordinates) that characterize local convective and diffusive scales (L=κD). This Fokker-Planck equation (also provided as Eq. 50), with the potential equal to the entropy, connects the global structure of the probability with the local structure of the lattice through the local structure of the entropy.
The current state-of-the-art approaches used for fiber tractography in DTI/DWI data require splitting this problem into two parts: first, obtain the EAP from the diffusion only subsystem,
∂tP=∇R·D∇RP, (71)
and second, solve the convective part (averaged over all the dynamic displacement scales R)
∫[∂tP+∇r·(LP∇rS)]dR=0, (72)
by simple local tracing of one (DTI) or several (DWI) principal fiber directions. Unfortunately, this decoupling results in only the local diffusion information derived from EAP being used at the fiber tracking stage.
To illustrate this point, we will first assume the entropy gradient fixed and will show how it leads to the current tractography. In this case, the convective part of Eq. 70 in the eikonal approximation provides a simple expression for the Hamiltonian (w, k, r)—the function of canonical coordinates that defines the dynamics. (For mechanical systems this function is simply the total energy, which is conserved in motion. For more complex systems it does not necessarily correspond to energy, but still describes conservation laws of the system).
where an input from all dynamic displacement scales is included, as formally both L and S may depend on both R and r. Finding the characteristics (or rays) of Eq. 70 will describe how the signals propagate and can be accomplished by integrating a set of ordinary differential equations of the Hamilton-Jacobi type:
The current fiber tractography methods in general do not emphasize or discuss the notion of global entropy, but implicitly assume the local behavior of the entropy gradient, directing it along some of the major axes of the local diffusion/convection tensor L=κD, i.e., ∇V=ψ, where ψ is the eigenvector of L·ψ=λψ. Under the assumption of scale independent diffusion (i.e., D(r, R)≡D(r)) the Hamiltonian Eq. 73 then becomes
(ω,k,r)=−ω2+λ2(k·ψ)2, (75)
and the ray tracing equation simplifies to the following form
Ignoring the spatial dependence of the diffusion propagator (i.e., C=const) this equation is exactly in the form of Frenet equation commonly used for fiber tracking. Thus, the current fiber tractography can be regarded as a fixed scale and spatially homogeneous limit of the more general Fokker-Plank formalism—Eqs. 50 and 70.
To develop a more general entropy-based tractography, several assumptions will be made. First, only solutions with the high enough probability will be considered, i.e., it will be assumed that in the region of interest the probabilities are sufficiently close to 1, so that it is possible to linearize both the probability and the entropy as
P=P
0
+P
1
,S=S
0
+S
1
=S
0−(1+ln P0)P1, (77)
where S0=−P0 ln P0 and the scale dependent transition probability l(r, R) (Eq. 68) can be substituted for P0. It is assumed that P1 is a small correction to the equilibrium probability (i.e., P1<<P0). The linearized convective part of Eq. 70 can then be written
∂tP1=∇·(P1∇P0(2+ln P0))+∇·(P0(1+ln P0)∇P1). (78)
Use of the scale dependent transition probability l(r, R) for P0 allows us to omit L in these expressions, as the diffusion anisotropy is already included in ESP calculations of l(r, R) from the spin density function Q(r, R) obtained with the spherical wave decomposition using Eqs. 63 and 64. No time dependence is assumed to be present in P0 as it is time stationary, hence ∂tP0≡0. We have also omitted the last term ∇·D∇P1 from the Eq. 70 as it will not appear in eikonal approximation used for obtaining the ray tracing equations.
Eq. 78 is a linear inhomogeneous hyperbolic equation, hence it has traveling wave solutions propagating along the characteristics. In order to formally find those characteristics we will assume a plane wave solution for P1 in the form
P
1(r,R,t)=A(r,R,t)eiψ(r,t), ψ(r,t)=k·r−ωt, (79)
and then obtain a more general expression for the Hamiltonian as
where X=∇P0(2+In P0)+∇(P0(1+ln P0)), Y=P0(1+In P0), Z=∇·∇P0(2+In P0), and again, again we averaged over all dynamic displacement scales.
Hence, in step 1108, taking into account the global entropy gradient as well as the scale dependence of the diffusion coefficient, the fiber tracking in the geometrical optics limit can be represented in more general form, using Eqs. 74 and 80, as
The first equation (Eq. 81) traces the characteristics (rays) of the convective part of the original Fokker-Plank equation (Eq. 70) under the influence of a local diffusion coupled with a global entropy gradient. This coupling is locally described by a vector X. A second term (with 2kY) provides some smoothing by adding “a push” in the direction of the wave vector k. It also ensures that in voxels with isotropic diffusion (or with many fibers of different directions crossing) and without a global entropy gradient, the ray will continue following this k direction. In the second equation (Eq. 82), the spatial gradients are responsible for a change of the wave vector k direction and magnitude.
The traditional approach defines tracts by integration of position-only function V, which assigns the tangential direction of tracts to each location r. For the geometrical optics approach, the integration takes into account both the orientation and multiple scales, through the dependence of ψ on directional angle k/|k| and magnitude |k|.
To evaluate practical aspects and performance of ESP-guided fiber tractography, we conducted several simulations of multiple shell multiple angle diffusion weighted MRI datasets acquired using either realistic MR phantom or real brain samples.
The first dataset is of the well-known “fiber cup” MR phantom extensively used for testing and performance evaluation of various fiber tractography approaches. The phantom consists of seven fiber bundles confined in a single plane by squeezing them in between two solid disks. Diffusion-weighted image data of the phantom was acquired on the 3T Tim Trio MRI system with 3 mm isotropic resolution on 64×64×3 spatial grid. Three diffusion sensitizations (at b-values b=650/1500/2000 s/mm2) were collected two times for 64 different diffusion gradients uniformly distributed over a unit sphere. Several baseline (b=0) images were also recorded.
Our initial stage of processing includes restoration of the spin density function Q(r, R) using Eqs. 63 and 64. The spin density function is then used to generate symmetric scale integrated input to the coupling potential with Eqs. 65 and 66. Eigenvectors and eigenvalues of the coupling potential then used for obtaining the transition probabilities using Eq. 44b.
We included one of the baseline images of the fiber cup phantom in
Current standard analyses that are based on the maps of the apparent diffusion coefficient (ADC) and the fractional anisotropy (FA) also favor those regions by assigning higher anisotropy and diffusion values. As a result, many of the current streamline tracing tractography approaches do not see the actual ends of the fiber bundles and continue tracts through the circular disks interfaces.
The local samples of multiple scales of the transition probabilities calculated by the ESP method are presented in
To stress two important aspects of our method, first,
Second, the use of multiple scales enables the geometrical optics-like approach presented here to find the correct path even when the angular resolution is relatively low. To illustrate this fact, two possible tracking scenarios are shown:
Utilization of high angular resolution locally (in an isolated voxel) and without the incorporation of multiple scales and global connectivity does not necessarily guarantee detection of crossing fibers. For example, it is not possible to detect the second direction of fibers in an EAP-like function (
A direct comparison with the Fiber Cup results (from the 2009 Medical Image Computing and Computer Assisted Intervention (MICCAI 2009)) is illustrated in
To generate fiber tracts we selected seed points, illustrated by blue dots in
For human brain ESP tractography we collected multi b-shell multi q-angle DWI dataset on the GE MR750 3T scanner at the UCSD Center for FMRI using a multi-band blipped-CAIPI EPI method with a GRAPPA reconstruction. Each data set was collected with both forward and reversed phase encoding polarity in order to perform a “topup” distortion and eddy current correction using FSL. The dataset contains three shells at b=1000, 2000 and 3000 s/mm2. Each b-shell uses different number of q-values, with 30 angles for b=1000 s/mm2, 45 angles for b=2000 s/mm2 , and the largest at 60 angles for b=3000 s/mm2.
Several slices of three dimensional eigenvector map obtained by the ESP solution are shown in
To illustrate the practical ability of geometrical optics-like tracking of fibers though those “difficult” areas of multiple fibers with different orientations we generated fiber tracts for several sets of seed points located in the areas of corpus callosum and longitudinal fasciculus that are known to have multiple overlaps in both inferior and fronto-occipital regions.
In the fasciculus region two sets of seeds were selected in left and right hemispheres with 30 seeds each again grouped in blocks by three consecutive voxels vertically and five consecutive voxels coronally. The total number of seeds were 195 voxels resulting in 195 distinct fiber tracts.
The seeds were selected primarily in the regions with predominantly single fiber orientation. Using the multiscale ESP-guided geometrical optics-like approach, the tracking algorithm is able to continue tracts across voxels with a mixture of fibers of different orientations and select the correct path based on the combination of local and global parameters.
For a more “difficult” starting point, we first chose several seed voxels in the area around the splenium of the corpus callosum and up to the internal capsule. The five fiber tracts, shown in
To study behavior of our approach in even more difficult conditions, we selected a single seed voxel that is located into a region where the corticospinal tract crosses the corpus callosum. This is a region that is well known for crossing fiber problems, and appears often in the DTI literature. Even starting with just a single voxel seed in the “difficult” area, the multiscale multi-modal approach is able to find and distinguish several fibers that go into different regions of brain shown in
Using several seeds in the small vicinity of the single seed voxel used in
The inventive approach is a novel diffusion estimation and fiber tractography method that is based on simultaneous estimation of global and local parameters of neural tracts from maximum entropy principles and sorting them into a series of entropy spectral pathways (ESP). The method uses local coupling between sub-scale diffusion parameters to compute the structure of the equilibrium probabilities that define the global information entropy field and uses this global entropy to update the local properties of neural fiber tracts.
In some embodiments, the method provides an efficient way to trace individual tracts using the multi-scale and multi-modal structure of the local diffusion-convection propagation by means of an approach reminiscent of the geometrical optics ray tracing in dispersive media (either elastic or viscoelastic). This geometrical optics-like approach naturally includes multiple scales that allow fiber tracing to continue fibers through voxels with complex local diffusion properties where multiple fiber directions are unable to be adequately resolved.
One of the most important aspects of the inventive method is that it is “global” in the sense that data from spatially extended brain structures are being used to inform both the local diffusion and generation of tracts. The typical workflow of the majority of other global algorithms used in tractography, including algorithms based on the well-known shortest-path algorithm on graphs by Dijkstra, represent the brain as a graph, where each voxel is a node, in which they have a local estimation of the diffusion process that they use as a speed function to guide a front evolution evolving from a seed point. Then, the geodesic or shortest-path between this point and any other location in the brain can be easily computed with backtracking While there might appear to be similarities with the inventive method, we point out that both the theoretical foundations and the numerical implementation for our approach are quite different from these schemes. Our method does not represent the brain as a graph it only uses nearest neighbors input in the coupling. The local estimation of the diffusion process is not used as a speed function. Rather, the prior coupling is used to find the global eigenvalues/vectors, rank those information pathways based on a maximum entropy, and spread this global information about pathways to every voxel. The global information used in every voxel is more than an analog of a locally inferred speed function—it is more akin to a dispersion of fibers. For each voxel this function includes both angular and radial (scale) distributions obtained as a collective effect of all fibers that cross in a single voxel.
The disclosed tracking process, although it might appear to be a front evolution, is not. The inventive approach does not need an explicit front evolution step at all. The eigensystem calculation of the connectivity matrix provides more complete and accurate path information than is available from the typical front evolution methods, and does it more efficiently. The inventive tracking is performed in 6-dimensional coordinate and momentum space. Not only is the position of each fiber updated on each step, but a momentum equation is used to update the local fiber orientation as well as a rate of orientation change based on a globally constructed distribution/dispersion of fibers. All the current tracking algorithms, including the shortest-path algorithms, only update a position of fiber assuming its orientation defined by static (fixed at each voxel position) speed function.
It is important to reiterate that the inventive method formulates the analysis problem as one of inference where the goal is to make the most accurate estimates of both the local diffusion and the extended fiber tracts based only upon the available data and any relevant prior information. This approach is based on the logic of probability theory: the theoretical basis for the method is a probabilistic analysis of information flow in a lattice.
A key conclusion that can be drawn using the methods disclosed herein is that local coupling information provides significant information about global pathways, which thus forms the important connection between local phenomena (diffusion) and global structures (fiber tracts). In addition, the dynamics of how local effects inform global structures can be characterized by a Fokker-Planck equation with a potential equal to the entropy, a formulation that had previously been put forth in a general theoretical framework, but here finds a very practical manifestation, as it facilitates a geometric-optics tractography scheme where the relationship between the local diffusion measurements and the global fiber tract structure is made explicit.
An important point demonstrated by the inventive method is that the connection between the local and the global properties of the diffusion field are mediated by the transition probability, which emerges as a more fundamental quantity than the traditional diffusion PDF (probability density function). In effect, the inventive approach makes explicit a fact that is often implicitly assumed in diffusion analysis papers but rarely explicitly addressed: There is a fundamental logical flaw in estimating the local diffusion as if it were taking place in independent, isolated voxels, but then using it to generate connections between voxels based on their assumed dependence. Our formulation naturally incorporates the continuum of spatial scales, from local to global, and avoids unnecessary arguments related to the fact that the actual diffusion is occurring on a scale much smaller than the measurement process, and thus far smaller than the scale of the fiber structures, since we are only requiring that our macroscopic predictions from microscopic phenomena are consistent with our data and prior information.
The computer-implemented method for fiber tractography based on Entropy Spectrum Pathways includes instructions fixed in a computer-readable medium that cause a computer processor to solve an eigenvector problem for the probability distribution and use it for an integration of the probability conservation through ray tracing of the convective modes guided by a global structure of the entropy spectrum coupled with a small scale local diffusion. The intervoxel diffusion is sample by multi b-shell multi q-angle DWI data expanded in spherical harmonics and spherical Bessel series.
According to embodiments of the invention, the problem of local diffusion estimation and fiber tractography is addressed with the specific goal of including multiple spatial and temporal scales that can be deduced from multiple b-shell DW-MRI measurements in addition to just angular (multi-)fiber orientation. In many practical applications, either one or two spatial locations (or regions) are known a priori. In neuroscience applications, for example, two regions may be functionally connected (as measured, perhaps, by FMRI) and the diffusion weighted MRI data is being used to assess the degree (if any) of the structural connectivity between two functionally connected regions. We therefore reconsider two common formulations of fiber tractography: (1)—initial value, i.e. finding fibers that start at some chosen area of the brain, (2)—boundary value, i.e. finding fibers that connect two preselected brain regions. Thus we recast the fiber tractography algorithm as the determination of the most probable path either starting at a selected location or connecting two spatial locations, and seek a general probabilistic framework that can accommodate various local diffusion models and yet can incorporate the structure of extended pathways into the inference process. In this case, the problem of tractography from DWI data can be reformulated as the determination of the probability of paths on a 3D lattice between two given points where the probability of a path passing through any particular point is not equiprobable, but is weighted according to the locally measured diffusion characteristics.
Applications of the ESP method include any commercial neuroscience application involved in the quantification of connectivity, including neural fiber connectivity using diffusion tensor imaging, functional connectivity using functional MRI, or anatomical connectivity using segmentation analysis. The ESP method may also be used as a tool for characterization of connectivity in networks, examples of which include the internet and communications systems.
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This claims the benefit of the priority of Provisional Application No. 62/066,780, filed Oct. 21, 2014, which is incorporated herein by reference in its entirety.
This invention was made with government support under Grant MH096100 awarded by the National Institutes of Health and Grant DBI-1147260 awarded by the National Science Foundation. The government has certain rights in the invention.
Number | Date | Country | |
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62066780 | Oct 2014 | US |