Back to Search
Start Over
Sensitivity and specificity considerations for fMRI encoding, decoding, and mapping of auditory cortex at ultra-high field
- Source :
- Neuroimage, 164, 18-31. Elsevier Science
- Publication Year :
- 2018
- Publisher :
- Elsevier Science, 2018.
-
Abstract
- Following rapid technological advances, ultra-high field functional MRI (fMRI) enables exploring correlates of neuronal population activity at an increasing spatial resolution. However, as the fMRI blood-oxygenation-level-dependent (BOLD) contrast is a vascular signal, the spatial specificity of fMRI data is ultimately determined by the characteristics of the underlying vasculature. At 7T, fMRI measurement parameters determine the relative contribution of the macro- and microvasculature to the acquired signal. Here we investigate how these parameters affect relevant high-end fMRI analyses such as encoding, decoding, and submillimeter mapping of voxel preferences in the human auditory cortex. Specifically, we compare a T2* weighted fMRI dataset, obtained with 2D gradient echo (GE) EPI, to a predominantly T2 weighted dataset obtained with 3D GRASE. We first investigated the decoding accuracy based on two encoding models that represented different hypotheses about auditory cortical processing. This encoding/decoding analysis profited from the large spatial coverage and sensitivity of the T2* weighted acquisitions, as evidenced by a significantly higher prediction accuracy in the GE-EPI dataset compared to the 3D GRASE dataset for both encoding models. The main disadvantage of the T2* weighted GE-EPI dataset for encoding/decoding analyses was that the prediction accuracy exhibited cortical depth dependent vascular biases. However, we propose that the comparison of prediction accuracy across the different encoding models may be used as a post processing technique to salvage the spatial interpretability of the GE-EPI cortical depth-dependent prediction accuracy. Second, we explored the mapping of voxel preferences. Large-scale maps of frequency preference (i.e., tonotopy) were similar across datasets, yet the GE-EPI dataset was preferable due to its larger spatial coverage and sensitivity. However, submillimeter tonotopy maps revealed biases in assigned frequency preference and selectivity for the GE-EPI dataset, but not for the 3D GRASE dataset. Thus, a T2 weighted acquisition is recommended if high specificity in tonotopic maps is required. In conclusion, different fMRI acquisitions were better suited for different analyses. It is therefore critical that any sequence parameter optimization considers the eventual intended fMRI analyses and the nature of the neuroscience questions being asked.
- Subjects :
- 0301 basic medicine
Auditory Cortex/diagnostic imaging
Image Processing, Computer-Assisted/methods
Computer science
Cognitive Neuroscience
Speech recognition
Image Processing
Auditory cortex
computer.software_genre
Sensitivity and Specificity
Article
Magnetic Resonance Imaging/methods
03 medical and health sciences
0302 clinical medicine
Voxel
Encoding (memory)
Brain Mapping/methods
Image Processing, Computer-Assisted
Computer-Assisted/methods
Humans
Sensitivity (control systems)
Auditory Cortex
Brain Mapping
Contrast (statistics)
Magnetic Resonance Imaging
030104 developmental biology
Neurology
Tonotopy
computer
030217 neurology & neurosurgery
Decoding methods
Algorithms
Subjects
Details
- Language :
- English
- ISSN :
- 10959572 and 10538119
- Volume :
- 164
- Database :
- OpenAIRE
- Journal :
- Neuroimage
- Accession number :
- edsair.doi.dedup.....93f2d1ab9f62a84c44782f75f09cc3bb