Skip to main content
eScholarship
Open Access Publications from the University of California

Machine Learning for Large-Scale Quality Control of 3D Shape Models in Neuroimaging.

  • Author(s): Petrov, Dmitry
  • Gutman, Boris A
  • Yu, Shih-Hua Julie
  • van Erp, Theo GM
  • Turner, Jessica A
  • Schmaal, Lianne
  • Veltman, Dick
  • Wang, Lei
  • Alpert, Kathryn
  • Isaev, Dmitry
  • Zavaliangos-Petropulu, Artemis
  • Ching, Christopher RK
  • Calhoun, Vince
  • Glahn, David
  • Satterthwaite, Theodore D
  • Andreasen, Ole Andreas
  • Borgwardt, Stefan
  • Howells, Fleur
  • Groenewold, Nynke
  • Voineskos, Aristotle
  • Radua, Joaquim
  • Potkin, Steven G
  • Crespo-Facorro, Benedicto
  • Tordesillas-Gutiérrez, Diana
  • Shen, Li
  • Lebedeva, Irina
  • Spalletta, Gianfranco
  • Donohoe, Gary
  • Kochunov, Peter
  • Rosa, Pedro GP
  • James, Anthony
  • Dannlowski, Udo
  • Baune, Bernhard T
  • Aleman, André
  • Gotlib, Ian H
  • Walter, Henrik
  • Walter, Martin
  • Soares, Jair C
  • Ehrlich, Stefan
  • Gur, Ruben C
  • Doan, N Trung
  • Agartz, Ingrid
  • Westlye, Lars T
  • Harrisberger, Fabienne
  • Riecher-Rössler, Anita
  • Uhlmann, Anne
  • Stein, Dan J
  • Dickie, Erin W
  • Pomarol-Clotet, Edith
  • Fuentes-Claramonte, Paola
  • Canales-Rodríguez, Erick Jorge
  • Salvador, Raymond
  • Huang, Alexander J
  • Roiz-Santiañez, Roberto
  • Cong, Shan
  • Tomyshev, Alexander
  • Piras, Fabrizio
  • Vecchio, Daniela
  • Banaj, Nerisa
  • Ciullo, Valentina
  • Hong, Elliot
  • Busatto, Geraldo
  • Zanetti, Marcus V
  • Serpa, Mauricio H
  • Cervenka, Simon
  • Kelly, Sinead
  • Grotegerd, Dominik
  • Sacchet, Matthew D
  • Veer, Ilya M
  • Li, Meng
  • Wu, Mon-Ju
  • Irungu, Benson
  • Walton, Esther
  • Thompson, Paul M
  • et al.
Abstract

As very large studies of complex neuroimaging phenotypes become more common, human quality assessment of MRI-derived data remains one of the last major bottlenecks. Few attempts have so far been made to address this issue with machine learning. In this work, we optimize predictive models of quality for meshes representing deep brain structure shapes. We use standard vertex-wise and global shape features computed homologously across 19 cohorts and over 7500 human-rated subjects, training kernelized Support Vector Machine and Gradient Boosted Decision Trees classifiers to detect meshes of failing quality. Our models generalize across datasets and diseases, reducing human workload by 30-70%, or equivalently hundreds of human rater hours for datasets of comparable size, with recall rates approaching inter-rater reliability.

Many UC-authored scholarly publications are freely available on this site because of the UC Academic Senate's Open Access Policy. Let us know how this access is important for you.

Main Content
Current View