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Machine learning of dissection photographs and surface scanning for quantitative 3D neuropathology.
Gazula, Harshvardhan; Tregidgo, Henry F J; Billot, Benjamin; Balbastre, Yael; Williams-Ramirez, Jonathan; Herisse, Rogeny; Deden-Binder, Lucas J; Casamitjana, Adria; Melief, Erica J; Latimer, Caitlin S; Kilgore, Mitchell D; Montine, Mark; Robinson, Eleanor; Blackburn, Emily; Marshall, Michael S; Connors, Theresa R; Oakley, Derek H; Frosch, Matthew P; Young, Sean I; Van Leemput, Koen; Dalca, Adrian V; Fischl, Bruce; MacDonald, Christine L; Keene, C Dirk; Hyman, Bradley T; Iglesias, Juan E.
Afiliación
  • Gazula H; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Tregidgo HFJ; Centre for Medical Image Computing, University College London, London, United Kingdom.
  • Billot B; Computer Science and Artificial Intelligence Laboratory, MIT, Cambridge, United States.
  • Balbastre Y; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Williams-Ramirez J; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Herisse R; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Deden-Binder LJ; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Casamitjana A; Centre for Medical Image Computing, University College London, London, United Kingdom.
  • Melief EJ; Biomedical Imaging Group, Universitat Politècnica de Catalunya, Barcelona, Spain.
  • Latimer CS; BioRepository and Integrated Neuropathology (BRaIN) Laboratory and Precision Neuropathology Core, UW School of Medicine, Seattle, United States.
  • Kilgore MD; BioRepository and Integrated Neuropathology (BRaIN) Laboratory and Precision Neuropathology Core, UW School of Medicine, Seattle, United States.
  • Montine M; BioRepository and Integrated Neuropathology (BRaIN) Laboratory and Precision Neuropathology Core, UW School of Medicine, Seattle, United States.
  • Robinson E; BioRepository and Integrated Neuropathology (BRaIN) Laboratory and Precision Neuropathology Core, UW School of Medicine, Seattle, United States.
  • Blackburn E; Centre for Medical Image Computing, University College London, London, United Kingdom.
  • Marshall MS; Centre for Medical Image Computing, University College London, London, United Kingdom.
  • Connors TR; Massachusetts Alzheimer Disease Research Center, MGH and Harvard Medical School, Charlestown, United States.
  • Oakley DH; Massachusetts Alzheimer Disease Research Center, MGH and Harvard Medical School, Charlestown, United States.
  • Frosch MP; Massachusetts Alzheimer Disease Research Center, MGH and Harvard Medical School, Charlestown, United States.
  • Young SI; Massachusetts Alzheimer Disease Research Center, MGH and Harvard Medical School, Charlestown, United States.
  • Van Leemput K; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Dalca AV; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Fischl B; Neuroscience and Biomedical Engineering, Aalto University, Espoo, Finland.
  • MacDonald CL; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Keene CD; Computer Science and Artificial Intelligence Laboratory, MIT, Cambridge, United States.
  • Hyman BT; Martinos Center for Biomedical Imaging, MGH and Harvard Medical School, Charlestown, United States.
  • Iglesias JE; Department of Neurological Surgery, UW School of Medicine, Seattle, United States.
Elife ; 122024 Jun 19.
Article en En | MEDLINE | ID: mdl-38896568
ABSTRACT
We present open-source tools for three-dimensional (3D) analysis of photographs of dissected slices of human brains, which are routinely acquired in brain banks but seldom used for quantitative analysis. Our tools can (1) 3D reconstruct a volume from the photographs and, optionally, a surface scan; and (2) produce a high-resolution 3D segmentation into 11 brain regions per hemisphere (22 in total), independently of the slice thickness. Our tools can be used as a substitute for ex vivo magnetic resonance imaging (MRI), which requires access to an MRI scanner, ex vivo scanning expertise, and considerable financial resources. We tested our tools on synthetic and real data from two NIH Alzheimer's Disease Research Centers. The results show that our methodology yields accurate 3D reconstructions, segmentations, and volumetric measurements that are highly correlated to those from MRI. Our method also detects expected differences between post mortem confirmed Alzheimer's disease cases and controls. The tools are available in our widespread neuroimaging suite 'FreeSurfer' (https//surfer.nmr.mgh.harvard.edu/fswiki/PhotoTools).
Every year, thousands of human brains are donated to science. These brains are used to study normal aging, as well as neurological diseases like Alzheimer's or Parkinson's. Donated brains usually go to 'brain banks', institutions where the brains are dissected to extract tissues relevant to different diseases. During this process, it is routine to take photographs of brain slices for archiving purposes. Often, studies of dead brains rely on qualitative observations, such as 'the hippocampus displays some atrophy', rather than concrete 'numerical' measurements. This is because the gold standard to take three-dimensional measurements of the brain is magnetic resonance imaging (MRI), which is an expensive technique that requires high expertise ­ especially with dead brains. The lack of quantitative data means it is not always straightforward to study certain conditions. To bridge this gap, Gazula et al. have developed an openly available software that can build three-dimensional reconstructions of dead brains based on photographs of brain slices. The software can also use machine learning methods to automatically extract different brain regions from the three-dimensional reconstructions and measure their size. These data can be used to take precise quantitative measurements that can be used to better describe how different conditions lead to changes in the brain, such as atrophy (reduced volume of one or more brain regions). The researchers assessed the accuracy of the method in two ways. First, they digitally sliced MRI-scanned brains and used the software to compute the sizes of different structures based on these synthetic data, comparing the results to the known sizes. Second, they used brains for which both MRI data and dissection photographs existed and compared the measurements taken by the software to the measurements obtained with MRI images. Gazula et al. show that, as long as the photographs satisfy some basic conditions, they can provide good estimates of the sizes of many brain structures. The tools developed by Gazula et al. are publicly available as part of FreeSurfer, a widespread neuroimaging software that can be used by any researcher working at a brain bank. This will allow brain banks to obtain accurate measurements of dead brains, allowing them to cheaply perform quantitative studies of brain structures, which could lead to new findings relating to neurodegenerative diseases.
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Texto completo: 1 Banco de datos: MEDLINE Asunto principal: Encéfalo / Imagenología Tridimensional / Enfermedad de Alzheimer / Aprendizaje Automático Límite: Humans Idioma: En Revista: Elife Año: 2024 Tipo del documento: Article País de afiliación: Estados Unidos

Texto completo: 1 Banco de datos: MEDLINE Asunto principal: Encéfalo / Imagenología Tridimensional / Enfermedad de Alzheimer / Aprendizaje Automático Límite: Humans Idioma: En Revista: Elife Año: 2024 Tipo del documento: Article País de afiliación: Estados Unidos