Projekt per år
Sammanfattning
Purpose
To map T1 and the local flip angle (B1+) in human brain using a single MP3RAGE sequence with 3 rapid acquisitions of gradient echoes (RAGEs).
Theory and methods
A third RAGE with a relatively high flip angle was appended to an MP2RAGE sequence. Through curve fitting and a rational approximation for small flip angles and short TR, closed form solutions for T1 and B1+ were derived. The influence of different k-space encoding schemes on precision and whether edge enhancement artifacts could be reduced with a saturation pulse applied prior to the third RAGE were explored. Validation of T1 estimates was performed using single-slice inversion recovery (IR) and a subsequent region-of-interest–based comparison, whereas validation of B1+ was performed using a whole brain pixelwise comparison to a DREAM flip angle mapping protocol. Lastly, MP3RAGE was compared to T1-mapping by MP2RAGE with separate B1+ correction.
Results
Whole brain maps of T1 and B1+ at 1 mm isotropic resolution were obtained with MP3RAGE in 06:37 min. A linear–reverse centric–reverse centric phase-encoding order of the 3 RAGEs improved precision, and artifacts were successfully reduced with the saturation pulse. Estimations of T1 and B1+ deviated +2.5 ± 3.1% and −1.7 ± 8.6% from their respective references.
Conclusion
T1 and B1+ can be mapped simultaneously using MP3RAGE. The approach can be thought of as combining MP2RAGE with a dual flip angle T1-mapping protocol. Both maps can be solved for analytically and will be inherently co-registered at the high resolution associated with MPRAGE.
To map T1 and the local flip angle (B1+) in human brain using a single MP3RAGE sequence with 3 rapid acquisitions of gradient echoes (RAGEs).
Theory and methods
A third RAGE with a relatively high flip angle was appended to an MP2RAGE sequence. Through curve fitting and a rational approximation for small flip angles and short TR, closed form solutions for T1 and B1+ were derived. The influence of different k-space encoding schemes on precision and whether edge enhancement artifacts could be reduced with a saturation pulse applied prior to the third RAGE were explored. Validation of T1 estimates was performed using single-slice inversion recovery (IR) and a subsequent region-of-interest–based comparison, whereas validation of B1+ was performed using a whole brain pixelwise comparison to a DREAM flip angle mapping protocol. Lastly, MP3RAGE was compared to T1-mapping by MP2RAGE with separate B1+ correction.
Results
Whole brain maps of T1 and B1+ at 1 mm isotropic resolution were obtained with MP3RAGE in 06:37 min. A linear–reverse centric–reverse centric phase-encoding order of the 3 RAGEs improved precision, and artifacts were successfully reduced with the saturation pulse. Estimations of T1 and B1+ deviated +2.5 ± 3.1% and −1.7 ± 8.6% from their respective references.
Conclusion
T1 and B1+ can be mapped simultaneously using MP3RAGE. The approach can be thought of as combining MP2RAGE with a dual flip angle T1-mapping protocol. Both maps can be solved for analytically and will be inherently co-registered at the high resolution associated with MPRAGE.
Originalspråk | engelska |
---|---|
Sidor (från-till) | 2637-2649 |
Tidskrift | Magnetic Resonance in Medicine |
Volym | 87 |
Nummer | 6 |
Tidigt onlinedatum | 2022 |
DOI | |
Status | Published - 2022 |
Ämnesklassifikation (UKÄ)
- Radiologi och bildbehandling
- Annan fysik
Fingeravtryck
Utforska forskningsämnen för ”Simultaneous mapping of T1and B1+ in human brain at 7T”. Tillsammans bildar de ett unikt fingeravtryck.Projekt
- 2 Avslutade
-
Högupplöst T1 kartering av hjärnan med MP2RAGE
Kadhim, M. (Forskarstuderande), Olsson, H. (Forskare) & Helms, G. (PI)
2020/08/31 → 2021/01/29
Projekt: Forskning
Fil -
Gradient echo-based quantitative MRI of human brain at 7T
Olsson, H. (Forskare), Andersen, M. (Biträdande handledare), Wirestam, R. (Biträdande handledare) & Helms, G. (Handledare)
2016/11/01 → 2021/10/29
Projekt: Avhandling
Utrustning
-
Lund University Bioimaging Centre
Westergren-Thorsson, G. (Manager)
Medicinska fakultetenInfrastruktur