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Bioinformatics of the Brain
the difference in these values between two regions is used to determine the
edge weight of the edge between them to construct the overall graph.
• Effective Brain Networks (EBN): This type of connectivity shows the casual
interactions between brain regions by considering the influence of one brain
region to another.
We will focus on the construction of FBNs here and the analysis of these
networks throughout this review as this type of brain network is the subject of
various research studies to analyze brain functions. The main steps of building
such a network are as follows: [2]:
1.
Defining the nodes: Dividing the brain into large-scale homogeneous
and non-overlapping regions is performed to define the nodes of
the network. Selection of these regions is called parcellation which
is the process of dividing the brain into distinct regions based on
anatomical, morphological or topological criteria.
2.
Computation of Connection Matrix: Estimating the network con-
nectivity is commonly employed by correlation and partial correla-
tion to quantify brain activity between the ROIs. These methods
provide similarity information between the time series or frequency
spectra of nodes which can be used to construct the connectivity
matrix C. The wiring diagram of the brain regions obtained in this
manner is commonly called the connectome which is formed by the
matrix representation of all pairwise connections between ROIs.
3.
Thresholding: This is the process of filtering the connectivity ma-
trix C such that connectivity values below a certain parameter are
deleted from this matrix. As a result, the connectivity matrix C
is processed to yield a binary matrix A such that entry aij = 1 if
node i is connected to node j. A fixed threshold or a fixed threshold
node degree or a fixed edge density value may be used to filter the
connection matrix [2].
The processing of these steps that results in the connectome of the brain is
depicted in Figure 9.1. The connection matrix C provides the representation
of an edge weighted graph G = (V, E, w) where V is the set of nodes, E is
the set of edges and function f : E →R provides the weights associated with
edges which can be directed or undirected, depending on the interpretations of
interactions between the nodes. This graph may be considered as a complete
graph by associating a null value for an edge between two nodes that are not
related. The binary adjacency matrix A can be used to build an unweighted,
undirected graph G = (V, E) over which various analysis methods may be
applied.