MR imaging with B1 mapping
US-9977106-B2 · May 22, 2018 · US
Systems and methods for designing magnetic resonance imaging radio frequency pulses that are robust against physiological motion errors
US10247803B2 · US · B2
| Field | Value |
|---|---|
| Publication number | US-10247803-B2 |
| Application number | US-201514696099-A |
| Country | US |
| Kind code | B2 |
| Filing date | Apr 24, 2015 |
| Priority date | Apr 25, 2014 |
| Publication date | Apr 2, 2019 |
| Grant date | Apr 2, 2019 |
How to read this patent
A practical reading order for non-experts. Skip the full description unless you need deep technical detail.
- Title
What the patent document calls the invention.
- Abstract
A short plain-language summary of the technical disclosure.
- Assignees and inventors
Who owns or filed the patent and who is credited as inventor.
- Key dates
Filing, priority, publication, and grant dates set the timeline.
- First independent claim
The legal scope of protection — read this for what is actually claimed.
- CPC / IPC classifications
Technology tags used to group this patent with similar filings.
- Citations and related patents
Prior art links and similar publications in this corpus.
Abstract
Official abstract text for this publication.
Systems and methods for designing and/or using radio frequency (“RF”) pulses for in-vivo MRI applications, where the RF pulses are robust against errors due to physiological motion of organs during the respiratory cycle. For example, RF pulses are designed based on multi-channel B1+ maps correlated to different positions of the respiratory cycle.
First claim
Opening claim text (preview).
The invention claimed is: 1. A magnetic resonance imaging (MRI) system comprising: a magnet system configured to generate a polarizing magnetic field about at least a region of interest (ROI) of a subject arranged in the MRI system, the ROI being subject to cyclical physiological motion including a plurality of different states of physiological motion; a plurality of gradient coils configured to apply a gradient field with respect to the polarizing magnetic field; a radio frequency (RF) system configured to apply RF excitation fields to the subject and acquire MR image data therefrom; and a computer programmed to: acquire a B 1 + calibration map for each of a plurality of selected ones of the plurality of different states of physiological motion in the subject, wherein each B 1 + calibration map is correlated with a state of the physiological motion in the subject during acquisition of the B 1 + calibration map; using the B 1 + calibration maps and correlated state of the physiological motion in the subject, design an RF pulse waveform that reduces B1+ inhomogeneity at each correlated state of physiological motion; control the plurality of gradient coils and the RF system to produce an RF field based on a portion of the RF pulse waveform to acquire the image data from the subject, wherein the portion of the RF pulse waveform is correlated with a state of physiological motion of the subject during acquisition of the image data; and reconstruct an image of the subject from the image data. 2. The MRI system of claim 1 , wherein the computer is further programmed to track a state of the physiological motion in the subject without performing a navigator pulse sequence. 3. The MRI system of claim 1 , wherein the computer is further programmed to assemble the B 1 + calibration maps into groups of virtual slices within the ROI and, to design the RF pulse waveform, the computer is further programmed to simultaneously design the RF pulse waveform using the groups of virtual slices to reduce errors induced by the physiological motion in the ROI. 4. The MRI system of claim 3 , wherein the computer is further programmed to simultaneously optimize the RF pulse waveform using the groups of virtual slices to minimize errors induced by the physiological motion in the ROI. 5. The MRI system of claim 1 , wherein the computer is further programmed to design the RF pulse waveform as a parallel transmission RF pulse waveform. 6. The MRI system of claim 1 , wherein the computer is further programmed to acquire B 0 calibration maps for each of a plurality of different states of physiological motion in a subject and use the B 0 calibration maps to design the RF pulse waveform. 7. The MRI system of claim 1 , wherein the physiological motion is respiratory motion.
Assignees
Inventors
Classifications
involving electronic [EMR] or nuclear [NMR] magnetic resonance, e.g. magnetic resonance imaging · CPC title
Cine imaging · CPC title
Assessment of an electric or a magnetic field, e.g. spatial mapping, determination of a B0 drift or dosimetry · CPC title
caused by a distortion of the RF magnetic field, e.g. spatial inhomogeneities of the RF magnetic field (G01R33/56509, G01R33/56518, G01R33/56536 take precedence) · CPC title
Spatial mapping of the RF magnetic field B1 · CPC title
Patent family
Related publications grouped by family.
External sources
Frequently asked questions
Answers are generated from the same data shown on this page.
- What does patent US10247803B2 cover?
- Systems and methods for designing and/or using radio frequency (“RF”) pulses for in-vivo MRI applications, where the RF pulses are robust against errors due to physiological motion of organs during the respiratory cycle. For example, RF pulses are designed based on multi-channel B1+ maps correlated to different positions of the respiratory cycle.
- Who is the assignee on this patent?
- Univ Minnesota
- What technology area does this patent fall under?
- Primary CPC classification G01R33/567. Mapped technology areas include Physics.
- When was this patent published?
- Publication date Tue Apr 02 2019 00:00:00 GMT+0000 (Coordinated Universal Time) (B2). Legal status and post-grant events are not shown on this page.
- What related patents are in patentsdb?
- We list 4 related publications on this page (citations in our corpus or others sharing the same primary CPC).