Normalized accurate measurement of longitudinal brain change

Stephen M. Smith; Nicola De Stefano; Mark Jenkinson; Paul M. Matthews

doi:10.1097/00004728-200105000-00022

Normalized accurate measurement of longitudinal brain change

Stephen M. Smith, Nicola De Stefano, Mark Jenkinson, Paul M. Matthews

Research output: Contribution to journal › Article › peer-review

446 Citations (Scopus)

Abstract

Purpose: Quantitative measurement of change in brain size and shape (e.g., to estimate atrophy) is an important current area of research. New methods of change analysis attempt to improve robustness, accuracy, and extent of automation. A fully automated method has been developed that achieves high estimation accuracy. Method: A fully automated method of longitudinal change analysis is presented here, which automatically segments brain from nonbrain in each image, registers the two brain images while using estimated skull images to constrain scaling and skew, and finally estimates brain surface motion by tracking surface points to subvoxel accuracy. Results and Conclusion: The method described has been shown to be accurate (≈0.2% brain volume change error) and to achieve high robustness (no failures in several hundred analyses over a range of different data sets).

Original language	English
Pages (from-to)	466-475
Number of pages	10
Journal	Journal of Computer Assisted Tomography
Volume	25
Issue number	3
DOIs	https://doi.org/10.1097/00004728-200105000-00022
Publication status	Published or Issued - 2001
Externally published	Yes

Keywords

Atrophy measurement
Normalized registration

ASJC Scopus subject areas

Radiology Nuclear Medicine and imaging

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10.1097/00004728-200105000-00022

Cite this

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title = "Normalized accurate measurement of longitudinal brain change",

abstract = "Purpose: Quantitative measurement of change in brain size and shape (e.g., to estimate atrophy) is an important current area of research. New methods of change analysis attempt to improve robustness, accuracy, and extent of automation. A fully automated method has been developed that achieves high estimation accuracy. Method: A fully automated method of longitudinal change analysis is presented here, which automatically segments brain from nonbrain in each image, registers the two brain images while using estimated skull images to constrain scaling and skew, and finally estimates brain surface motion by tracking surface points to subvoxel accuracy. Results and Conclusion: The method described has been shown to be accurate (≈0.2% brain volume change error) and to achieve high robustness (no failures in several hundred analyses over a range of different data sets).",

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T1 - Normalized accurate measurement of longitudinal brain change

AU - Smith, Stephen M.

AU - De Stefano, Nicola

AU - Jenkinson, Mark

AU - Matthews, Paul M.

PY - 2001

Y1 - 2001

N2 - Purpose: Quantitative measurement of change in brain size and shape (e.g., to estimate atrophy) is an important current area of research. New methods of change analysis attempt to improve robustness, accuracy, and extent of automation. A fully automated method has been developed that achieves high estimation accuracy. Method: A fully automated method of longitudinal change analysis is presented here, which automatically segments brain from nonbrain in each image, registers the two brain images while using estimated skull images to constrain scaling and skew, and finally estimates brain surface motion by tracking surface points to subvoxel accuracy. Results and Conclusion: The method described has been shown to be accurate (≈0.2% brain volume change error) and to achieve high robustness (no failures in several hundred analyses over a range of different data sets).

AB - Purpose: Quantitative measurement of change in brain size and shape (e.g., to estimate atrophy) is an important current area of research. New methods of change analysis attempt to improve robustness, accuracy, and extent of automation. A fully automated method has been developed that achieves high estimation accuracy. Method: A fully automated method of longitudinal change analysis is presented here, which automatically segments brain from nonbrain in each image, registers the two brain images while using estimated skull images to constrain scaling and skew, and finally estimates brain surface motion by tracking surface points to subvoxel accuracy. Results and Conclusion: The method described has been shown to be accurate (≈0.2% brain volume change error) and to achieve high robustness (no failures in several hundred analyses over a range of different data sets).

KW - Atrophy measurement

KW - Normalized registration

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DO - 10.1097/00004728-200105000-00022

M3 - Article

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AN - SCOPUS:0035006178

SN - 0363-8715

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EP - 475

JO - Journal of Computer Assisted Tomography

JF - Journal of Computer Assisted Tomography

IS - 3

ER -

Normalized accurate measurement of longitudinal brain change

Abstract

Keywords

ASJC Scopus subject areas

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