MRI CLINICAL APPLICATIONS

The Neuro fMRI/DTI Combi Package is a bundle of:
- Inline BOLD Imaging :Performing a Motor Cortex Functional Exam
- 3D PACE syngo : Prospective Acquisition CorrEction
- BOLD 3D Evaluation syngo
- fMRI Trigger Converter
- Diffusion Tensor Imaging
- DTI Evaluation
- DTI Tractography syngo

The bundle comprehends all acquisition and postprocessing tools for comprehensive BOLD fMRI and DTI exams. BOLD fMRI experiments can be displayed fused with DTI data and anatomy. The package is particularly valuable for presurgical planning. The 3D display of anatomical images, functional brain mapping results and DTI allows a better understanding of the spatial relationship between eloquent cortices, cortical landmarks, brain lesions and tract shifts of white matter.

Inline BOLD Imaging
The BOLD imaging package allows the user to define protocols which, apart from the measurement, configure automatic evaluation of the measured data during the scan. With Inline Technology it is thus possible to generate statistical images (t-value) based on 3D motion corrected and spatially filtered data automatically in real time without any further user interaction. The Inline display of activation cards allows the user to decide during the scan whether enough statistical power has built up for his brain mapping task or if the examination is corrupted by motion. As a result examinations will be shorter with a higher success rate. Functional brain mapping can be easily integrated into the clinical routine e.g. prior to neurosurgical interventions.

Additional Features:
- Inline retrospective 3D motion detection and correction in 3 rotational and 3 translational directions
- Inline t-statistics calculation for variable paradigms and display of t-value images
- Statistical evaluation by means of “General Linear Model (GLM)”:
- Paradigms can be configured
- Transitions between passive and active states can be modeled by the hemodynamic response function
- Correction of low-frequency trends
- Allows for time delays due to the BOLD-EPI slice order during a measurement
- Display of GLM design matrix
- Display of a continuously updated t-value card during measurement
- Display of colored activation cards continuously updated during measurement, overlaid over the respective BOLD images using Inline technology
- MOSAIC image mode for accelerating display, processing and storage of images

3D PACE syngo
By tracking the patients head 3D PACE reduces motion resulting in increased data quality beyond what can be achieved with a retrospective motion correction. As a result the sensitivity and specificity of BOLD experiments are increased.
Features:
- Real time prospective motion correction: Highest accuracy real time motion detection algorithm feeding a real time feed back loop to the acquisition system with updated positioning information
- 3D motion correction for 6 degrees of freedom (3 translation and 3 rotation)
- Motion related artifacts are avoided in first place instead of correcting for them retrospectively
- Significant reduction of motion-related artifacts in statistical evaluations
- Increased sensitivity and specificity of BOLD experiments

BOLD 3D Evaluation syngo

syngo BOLD 3D Evaluation is a comprehensive processing and visualization package for BOLD fMRI.

Features

•This package provides statistical map calculations from BOLD datasets and enables the visualization of task-related areas of activation with 2D or 3D anatomical data. This allows the visualization of the spatial relation of eloquent cortices with cortical landmarks or brain lesions
•On the syngo Acquisition Workplace the unique Inline function of syngo BOLD 3D Evaluation merges, in real time, the results of ongoing BOLD imaging measurements with 3D anatomical data
•Additionally, evolving signal time courses in task-related areas of activation can be displayed and monitored
•Functional and anatomical image data can be exported for surgical planning as DICOM datasets, additionally all color fused images and results can be stored or printed
•Statistical map generation: paradigm definition, calculation of t-value map with General Linear Model or t-test
•3D Visualization: fused display of fMRI results,
color t-value maps on anatomical datasets
•Inline 3D real time monitoring of the fMRI acquisition
•On-the-Fly adjustment for t-value thresholding, 3D clustering, and opacity control
•Data export to neurosurgical planning software

Clinical Applications

•Neurosurgical planning
•Assess the effects of neurodegenerative diseases, trauma or stroke on brain function
•Brain mapping


BOLD evaluation task card	BOLD evaluation task card

Step by step:
1. Load the ep2d_bold_moco series into the BOLD Evaluation Task card. From the patient browser, select this series and go to Applications and choose BOLD Evaluation.
2. Choose the moco filter 3D evaluation program. Automatically the evaluation controller dialog box will appear, when post processing BOLD data it is freely selectable to choose filters or motion
3. Adjust the simple clustering to remove noise from BOLD data. Increasing this value will remove any colored clustered pixels lower than this number. For example when setting this value to 10 any value of activated (colored) adjacent pixels less than 10 will be hidden from view.
4. Load the t1_se_tra sequence into segment
1. From the patient browser select this sequence and drag and drop into the upper left segment. This will fuse the BOLD data with anatomic data
5. Scroll thru the images using the "dog ear tab" of segment one. This will also move the fused anatomic and functional slices.
6. Set the transparency of the functional data. Reducing the Alpha Value will make the functional data more transparent.
7. Save the fused results. Go to patient, and select Save All Alpha As... This will save all slice positions and allow naming of the sequence, for easy access in the patient browser.
This series can now be viewed in the viewing card or sent via PACs for reading.

All tasks from statistical evaluation of the fMRI datasets to reading and exporting results are supported by BOLD 3D Evaluation syngo:

Generation of statistical maps:
- In cases an inline calculated statistical map is not available a statistical map can be generated easily using processing protocols. An intuitive editor UI allows the paradigm definition and offers the selection of head motion correction, image filters and statistical evaluation.
- Predefined processing protocols and paradigms are available, which can be edited if required.

Statistical evaluation using General Linear Model (GLM)
- Transitions between passive and active states modeled by the hemodynamic response function.
- Correction of low-frequency trends.
- Corrects for time delays due to the BOLD-EPI slice order during a measurement.
- Output of a t-value map and the GLM design matrix

Inline monitoring of the fMRI exam
- During an ongoing BOLD imaging exam results are calculated (by Inline BOLD imaging) and displayed in real time.
- The results are displayed and continuously updated as an overlay on online adjustable, free angulated cut planes through the anatomical 3D data set.
- The evolving signal time courses in task-related areas of activation can be displayed and monitored.

Visualization of fMRI Results
- Visualization with 3D volume rendering.
- Superimposing on cut planes through the volume.
- Interactive Navigation: Zoom, pan and rotate in 3D without noticeable delay. Free double oblique angulation of up to 6 cut planes.
- Cine display of the BOLD time series and of EPI volumes in 3 orthogonal cuts for evaluation of non-corrected head motion.

Data Quality Monitoring
- Based on the B0 field map, loaded automatically with the fMRI data, areas with less reliable results are indicated.

fMRI Trigger Converter
An optical trigger signal is available to trigger external stimulation devices in fMRI experiments.
With the "fMRI Trigger Converter" this signal can be converted to an electrical signal (TTL/BNC and RS 232 interface for PC; modes: toggle or impulse).

Diffusion Tensor Imaging
Diffusion Tensor Imaging allows for a complete description of the diffusion properties of the brain within the scope of the tensor diffusion model, both for anisotropic and isotropic diffusion. Efficient diffusion direction schemes are pre-defined to allow for optimal diffusion directional resolution. Schemes with up to 256 directions can be selected.
Inline technology enables automatic and immediate calculation of the diffusion tensor, including grey-scale and colored “fractional anisotropy" (FA) map derived from it.

Details:
- Measurements with up to 256 different directions and with up to 16 different b-values
- Inline calculation of tensor, grey-scale and colored FA map, ADC map and trace-weighted image
- Support of parallel imaging (iPAT)
- Clinical protocols with full head coverage, incl. inline calculation of tensor, FA, ADC and trace-weighted images in 4 minutes.

DTI Tractography syngo
syngo DTI Tractography is optimized for the clinical use by providing advanced 3D visualization of white matter tracts in the context of 2D or 3D anatomical datasets and DTI datasets. DTI data sets can be explored fast and intuitively using the interactive QuickTracking. QuickTracking instantaneously displays the tract originating from the mouse pointer position while moving over the DTI data set. This also allows identifying qualified regions to place seeding ROIs. Seed points can be set to assess connectivity by tracking with single ROI and with multiple ROIs. Furthermore they can be placed in fused views displaying the anatomical reference and e.g. the colored FA map simultaneously.
Texture Diffusion, a highly versatile in-plane visualization of white matter tracts, allows to display and read DTI Tractography results on PACS reading stations and in the OR.
At the same time the package provides the scientific user with the flexibility to configure the tracking algorithm and to change display settings for the tracts. Tract and seeding ROI statistics are included to support publications (e.g. mean/max FA value, min/mean/max ADC value).
All views can be exported as DICOM images or bitmaps. Tract and seeding ROI statistics can be exported as html files.

DTI Evaluation
Clinical applications are supported by a dedicated DTI evaluation mode to support diagnostics of white matter diseases (e.g. multiple sclerosis and brain maturation disorders). Based on the tensor, in addition to the already inline-calculated parameter maps, further maps characterizing the anisotropy of diffusion properties can be calculated and stored. Multiple diffusion parameter maps (e.g. Fractional Anisotropy, ADC, b=0) and an anatomical image are displayed next to each other in the same slice position for comparison. The images can be evaluated together based on ROIs and the results can be documented in a table. The display options include 2D and 3D tensor graphics, colour-coded images and overlay images on the anatomical images.

In addition, the package offers the scientific user full flexibility of 2- and 3-dimensional visualization of the diffusion tensor with measures of isotropic and anisotropic (fractional and relative) diffusion, Eigen vectors (E1, E2, E3) of the diffusion tensor and shape-descriptive measures of the diffusion tensor (linear, planar, spherical).

Prostate Package #T+D

The prostate spectroscopy package is an comprehensive software package which bundles:
- Single Voxel Spectroscopy
- 2D Chemical shift Imaging
- 3D Chemical Shift Imaging
- Spectroscopy Evaluation syngo
- syngo Tissue 4D Evaluation
Sequences and protocols for proton spectroscopy, 2D and 3D proton chemical shift imaging (2D CSI and 3D CSI) to examine metabolic changes in the prostate are included. Furthermore included is the comprehensive Spectroscopy evaluation software which enables fast evaluation of spectroscopy data on the syngo Acquisition Workplace.
Tissue 4D is an application for visualizing and post-processing dynamic contrast-enhanced 3D datasets.
Tissue 4D provides two evaluation options:
- Standard curve evaluation
- Curve evaluation according to a pharmacokinetic model.

The spectroscopy evaluation software is fully integrated in syngo MR.
Evaluation protocols adapted to the scan protocols carry out a complete and automatic evaluation of the measured data.
Optimized protocols for 3D CSI in the prostate are included.

The following functions are included:
- Subsequent water suppression with optional phase correction
- Apodization
- Zero filling
- Fourier transformation
- Base line correction
- Automatic or manual phase correction
- Curve fitting and peak labeling
- Summaries in tabular form of the essential results specifying the metabolites, their position, integrals and signal ratios in relation to a selectable reference.

Tissue 4D provides the tissue visualization features:
- 4D visualization (3D and over time)
- Color display of parametric cards (Ktrans, Kep, Ve, Vp, iAUC)
- Additional visualization of 2D or 3D morphological dataset

Post-processing features:
- Elastic 3D motion correction
- Fully automatic calculation of subtracted images

Standard curve evaluation:
- Calculation and display of enrichment curves

Pharmacokinetic model:
- Pharmacokinetic calculation on a pixel-by-pixel basis using a 2-compartment model
- Calculation is based on the Toft model. Various model functions are available.
- Manual segmentation and calculation on the result images.

The following result images can be saved as DICOM images:
- 3D motion-corrected, dynamic images
- Colored images
- Possibility for exporting results in the relevant layout format.

Cardiac examinations used to be the most complex exams in MR. Now Cardiac Dot Engine supports the user in many ways. Using anatomical landmarks, standard views of the heart, such as dedicated long axis and short-axis views, are easily generated and can easily be reproduced using different scanning techniques. Scan parameters are adjusted to the patient’s heart rate and automatic voice commands are given. All of this takes most of the complexity out of a cardiac exam and supports customized workflows that are easy to repeat. Every time.

Guidance View
- Step-by-step user guidance is seamlessly integrated.
- Example images and guidance text are displayed for the individual steps of the scanning workflow.
- Both images and text are easily configurable by the user

Patient View
- Within the Patient View the user can easily tailor the exam to each individual patient (e.g. patient with arrhythmia, breath hold capability).
- Pre-defined Dot Exam Strategies are integrated. The user just selects the appropriate strategy with one click and the queue and the complete scan set-up are automatically updated

AutoFoV (automatic Field of View calculation)
- Based on the localizer images the optimal FoV is automatically estimated.
- In case the patient moves during the examination, this step can be repeated at any time

Automated parameter adaptation
- Scan parameters are automatically adapted to the patient’s condition (e.g. heart rate)

Novel heart localization method
- On-board guidance visually facilitates anatomic landmark settings which are used for calculation
- Automated localization
- Automated localization of short-axis views

Guided slice positioning
- Easy way to match slice positions (short-axis) between cine, dynamic imaging, tissue characterization

Cardiac Views
- Easy selection of cardiac views (e.g. 3 chamber view) during scan planning

Inline Ventricular Function Evaluation
- syngo Inline VF performs volumetric evaluation of cardiac cine data fully automatically right after image reconstruction.
- No user input necessary. If desired, inline calculated segmentation results can be loaded to 4D Ventricular Function Analysis for further review or processing

Inline Time Course Evaluation
- Automatic, real-time and motion corrected calculation of parametric maps with inline technology

Cardiac specific layout for the Exam task
- Automatically chosen layouts show the new physio display and are configured for every step of the exam
- Automatic display of images
- Automatic display of images in dedicated cardiac image orientations in contrast to standard DICOM orientations

Adaptive triggering
- Acquisition adapts in realtime to heart rate variations for non cine applications

Automated Naming
- Automated naming of series depending on cardiac views and contrast

Auto Voice Commands
- Auto Voice Commands are seamlessly integrated into the scanning workflow. The system plays them automatically at the right time point. This ensures optimal timing of scanning, breathing and contrast media. The user can monitor which breath-hold or pauses are actually played, and could add pauses between the automatic breath hold commands if necessary

Dot Exam Strategies
The workflow can be personalized to the individual patient condition and clinical need. The following predefined strategies are included. They can be changed at any time during the workflow:
- Standard: Segmented acquisition techniques
- Limited patient capabilities: switch to realtime and single shot imaging if breath-hold is not possible or arrhythmias occur

Customization
Existing Dot Engines can be modified by the user to their individual standard of care.
- Add/remove protocol steps
- Change guidance content (images and text)
- Change or add Dot Exam Strategies and Decision Points
- Modify the Parameter View

This application provides a dedicated evaluation software for colored, volume rendered (VRT) visualization of MR and CT data as a complement to traditional MIP display.
The combination of automated segmentation and easy-to-use editing tools, provides users with a rapid way to visualize MRA and VIBE studies in their 3D context in a clear and precise manner.
3D VRT includes tools for:
Direct Volume Rendering Technique (VRT) for viewing 3D volumes
- Projection of volume information onto an arbitrarily orientation plane.
- For each projection ray the density, opacity, and refraction of the penetrated volume is evaluated and the resulting intensity/color is recorded.
- Independent control of color, opacity and shading of up to 4 tissue classes.
- Selection of predefined color VRT settings via an image gallery
- User selectable visualization filters for MPR, MIP, SSD or VRT
- Storage and filming of reconstructed images or ranges

Editing Functions to create and modify segmented objects
- Segmentation of 3D datasets either with manual contour creation, by thresholding, or by volume growing operations.
- Volume measurements

This package includes:
- 2D TSE protocols for PD, T1 and T2-weighted contrast with high in-plane resolution and thin slices
- 3D MEDIC, 3D TrueFISP protocols with water excitation for T2-weighted imaging with high in-plane resolution and thin slices
- High resolution 3D VIBE protocol for MR arthrography (knee, shoulder and hip)
- 3D MEDIC, 3D TrueFISP, 3D VIBE protocols with water excitation having high isotropic resolution, optimized for 3D post-processing
- PD SPACE with fat saturation and T2 SPACE with high isotropic resolution optimized for 3D post-processing
- Whole spine single-step or multi-step protocols
- Excellent fat suppression in off-center positions, e.g. in the shoulder due to high magnet homogeneity
- Dynamic TMJ and ilio-sacral joint protocol
- Susceptibility-insensitive protocols for imaging in the presence of a prosthesis
- Multi-Echo SE sequence with up to 32 echoes for the calculation of T2 time maps (calculation included in the Scientific Suite)
- High resolution 3D DESS (Double Echo Steady State): T2 / T1-weighted imaging for excellent fluid-cartilage differentiation

The real power of MR imaging lies in the wide range of applications for which it can be used. Current applications include soft-tissue delineation, determining extent of disease, tumor staging, functional and metabolic information, and monitoring response to treatment. Some of these newer applications are outlined herein.

T1- and T2-weighted Imaging

T1- and T2-weighted imaging are the most widely used sequences for soft-tissue delineation of anatomic structures and related pathologic conditions. For example, in the brain, T2-and T1-weighted imaging with or without contrast material can be used to see changes in white or gray matter. In other body organs, such as the breast, extremities, and liver, and in uterine lesions, imaging has been performed by using T2- and T1-weighted MR imaging.

Diffusion-weighted and Perfusion-weighted Imaging

Diffusion-weighted imaging (DWI) and perfusion-weighted imaging (PWI) are used in neurologic applications, such as brain tumor imaging and cerebral ischemia. The use of perfusion and diffusion MR imaging techniques can identify regions of abnormal brain tissue after cerebral ischemia. PWI readily depicts areas of brain with a compromised cerebral blood flow, whereas DWI can depict regions of ischemic tissue that may or may not recover, depending on the duration of reduced blood flow. By combining PWI and DWI methods, three scenarios can be observed: PWI > DWI (mismatch), PWI = DWI (match), or DWI > PWI (reverse mismatch). For example, if PWI is larger than DWI, then the area depicted may represent “at risk” or penumbral tissue. Evaluation of these tissue characteristics is important for the targeting of therapeutic measures to maximize clinical outcomes.

DWI has been used in other organs of the body, for example, in the liver for demonstration of metastatic disease and response to treatment, in the uterus for monitoring treatment response from interventional procedures such as uterine arterial embolization and high-intensity focused ultrasound surgery, and for classification of breast lesions. Still larger studies are needed to fully understand the impact that DWI will have in these applications.

Spectroscopy

Proton spectroscopy has been used primarily for brain applications and recently for other organs, such as the liver, breast, prostate, and soft tissue. The use of spectroscopy expands the repertoire of clinical information by providing information on intracellular metabolites, such as choline (3.2 ppm), creatine (3.0 ppm), citrate (2.6 ppm), N-acetyl aspartate (2.02 ppm), and lactate (1.4 ppm). (The unit “ppm” is defined as “parts per million” and is independent of the strength of the imaging unit.)

These metabolites are known to change in different pathologic conditions; for example, in brain tumors, N-acetyl aspartate (2.02 ppm) decreases with a subsequent increase in choline. In the breast, the presence of a choline peak (3.2 ppm) is suggestive of malignancy. In the prostate, MR spectroscopy is being increasingly used in conjunction with MR imaging to provide information on the presence or absence of citrate (2.6 ppm) and/or choline (3.2 ppm). These applications will become routine procedures in the near future.

²³Na (Sodium) MR Imaging

Sodium is abundant in most tissues and is actively pumped out of healthy cells by the Na+/H+-ATPase pump, which maintains a large concentration difference across the cell membrane at the cost of energy-rich adenosine triphosphate. Thus, an increase in intracellular sodium concentration can be a good indicator of compromised cellular membrane integrity or impaired energy metabolism. In the presence of tissue perfusion, the intracellular changes and concurrent increase in vascular or interstitial volume appear to be an equally good indicator of cellular membrane integrity and energy metabolism.

The intracellular sodium cannot be imaged separately from the extracellular sodium concentration without toxic shift reagents or special MR methods that cause a significant reduction in SNR and resolution. However, the total sodium concentration in tissue can be resolved by using MR imaging, and there has been increased interest in the application of sodium MR. In particular, sodium imaging has been performed in the brain, breast, heart, kidney, and uterus. In recent reports, sodium MR imaging has shown promise in monitoring therapeutic response.

Beyond 3 T: Emerging High-Field-Strength MR Imaging (7 T and Greater)

Although there have been vast technological advances in MR imaging over the past 40 years, the central principle for advancing MR imaging technology has been based on finding ways to increase SNR in the MR image. The most fundamental approach to increasing SNR has been to increase the field strength of the MR imaging magnets. As a result, the impetus for improved MR imaging has driven progressive increases in its magnetic field strengths from fractions of a tesla to fields of 1.5 T in the 1980s then to fields of 3 T by the mid-1990s. The next push for increasing MR imaging field strength was possible with the advancement of superconducting technology. In the late 1990s and early 2000s, the development of a human MR imaging unit above 4.1 T, in this case 8 T, was achieved.

As a result of its tremendous potential, human MR imaging is currently performed at field strengths reaching 7 T, 8 T, and 9.4 T. The three major MR imaging vendors—GE Healthcare, Siemens Medical Solutions, and Philips Medical Systems—are developing 7-T whole-body human imaging units. However, as with many scientific breakthroughs, the potential of ultrahigh-field-strength imaging can be achieved only if other challenges are overcome. The most significant of these challenges include (a) safety concerns regarding exceeding RF power deposition in tissue and (b) noninherent inhomogeneity of MR imaging signal detection across the human head.

Conclusions

MR imaging provides a powerful tool for diagnosis and excellent soft-tissue contrast because the image contrast can be finely optimized for specific clinical questions. Moreover, novel pulse sequence techniques allow image contrast to be based on tissue physiology or even cellular metabolism in a noninvasive manner. In addition, with ever-increasing improvement in both hardware and software, MR imaging may one day be used for screening of different pathologic conditions and provide a window into cellular metabolism and tissue physiology.