This study assessed five different methods for aligning microscope images of Nissl-stained sections of mouse brain to form three-dimensional image volumes. Methods exploiting both image content and information from un-sectioned tissue were investigated. The accuracy of reconstruction was estimated using fiducials with known physical properties, demonstrating that methods exploiting tissue content produced distorted image volumes while a method using artificial fiducials produced the most accurate and unbiased alignment. Methodological issues relating to methods of volume reconstruction are discussed and it is recommended that methods using information from un-sectioned tissue be used wherever possible
Ex vivo 2-photon fluorescence microscopy (2PFM) with optical clearing enables vascular imaging deep ...
Much insight into metabolic interactions, tissue growth, and tissue organization can be gained by an...
BACKGROUND:Brain mapping research in most neuroanatomical laboratories relies on conventional proces...
This thesis describes an investigation into digital techniques for image alignment and deformation c...
1 ABSTRACT Many variants of microscopic techniques are the key methods for tissue structure examinat...
Building and studying 3D representations of anatomical structures, such as the brain, plays an impor...
Optical microscopy exhibits many challenges for digital image analysis. In general, microscopy volum...
Analysis of brain ultrastructure is needed to understand how neurons communicate with one another vi...
3D volume reconstruction of a mouse brain from histological sections using warp filterin
Structural abnormalities of the microvasculature can impair perfusion and function. Conventional his...
The presence of microtomy induced distortion in paraffin sections is a significant hindrance to the ...
We present a method for reconstruction of macroscopic optical images of post-mortem brain slices to ...
We present a method for reconstruction of macroscopic optical images of post-mortem brain slices t...
Biological matter may change shape via water absorption or loss. For example, brain tissue shows non...
Context: Three dimensional (3D) tissue reconstructions from the histology images with different stai...
Ex vivo 2-photon fluorescence microscopy (2PFM) with optical clearing enables vascular imaging deep ...
Much insight into metabolic interactions, tissue growth, and tissue organization can be gained by an...
BACKGROUND:Brain mapping research in most neuroanatomical laboratories relies on conventional proces...
This thesis describes an investigation into digital techniques for image alignment and deformation c...
1 ABSTRACT Many variants of microscopic techniques are the key methods for tissue structure examinat...
Building and studying 3D representations of anatomical structures, such as the brain, plays an impor...
Optical microscopy exhibits many challenges for digital image analysis. In general, microscopy volum...
Analysis of brain ultrastructure is needed to understand how neurons communicate with one another vi...
3D volume reconstruction of a mouse brain from histological sections using warp filterin
Structural abnormalities of the microvasculature can impair perfusion and function. Conventional his...
The presence of microtomy induced distortion in paraffin sections is a significant hindrance to the ...
We present a method for reconstruction of macroscopic optical images of post-mortem brain slices to ...
We present a method for reconstruction of macroscopic optical images of post-mortem brain slices t...
Biological matter may change shape via water absorption or loss. For example, brain tissue shows non...
Context: Three dimensional (3D) tissue reconstructions from the histology images with different stai...
Ex vivo 2-photon fluorescence microscopy (2PFM) with optical clearing enables vascular imaging deep ...
Much insight into metabolic interactions, tissue growth, and tissue organization can be gained by an...
BACKGROUND:Brain mapping research in most neuroanatomical laboratories relies on conventional proces...