Scientific Data (Mar 2025)

Multimodal precision MRI of the individual human brain at ultra-high fields

  • Donna Gift Cabalo,
  • Ilana Ruth Leppert,
  • Risavarshni Thevakumaran,
  • Jordan DeKraker,
  • Youngeun Hwang,
  • Jessica Royer,
  • Valeria Kebets,
  • Shahin Tavakol,
  • Yezhou Wang,
  • Yigu Zhou,
  • Oualid Benkarim,
  • Nicole Eichert,
  • Casey Paquola,
  • Julien Doyon,
  • Christine Lucas Tardif,
  • David Rudko,
  • Jonathan Smallwood,
  • Raul Rodriguez-Cruces,
  • Boris C. Bernhardt

DOI
https://doi.org/10.1038/s41597-025-04863-7
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 11

Abstract

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Abstract Multimodal neuroimaging, in particular magnetic resonance imaging (MRI), allows for non-invasive examination of human brain structure and function across multiple scales. Precision neuroimaging builds upon this foundation, enabling the mapping of brain structure, function, and connectivity patterns with high fidelity in single individuals. Highfield MRI, operating at magnetic field strengths of 7 Tesla (T) or higher, increases signal-to-noise ratio and opens up possibilities for gains spatial resolution. Here, we share a multimodal Precision Neuroimaging and Connectomics (PNI) 7 T MRI dataset. Ten healthy individuals underwent a comprehensive MRI protocol, including T1 relaxometry, magnetization transfer imaging, T2*-weighted imaging, diffusion MRI, and multi-state functional MRI paradigms, aggregated across three imaging sessions. Alongside anonymized raw MRI data, we release cortex-wide connectomes from different modalities across multiple parcellation scales, and supply “gradients” that compactly characterize spatial patterning of cortical organization. Our precision MRI dataset will advance our understanding of structure-function relationships in the individual human brain and is publicly available via the Open Science Framework.