The connectome concept was introduced in 2005 (1) to refer to a network inventory of the human brain that accounts for the totality of neural elements—neurons and synapses—as well as the axonal interconnections, which can be intrinsic to gray matter (GM) or extrinsic traversing white matter (WM) (2, 3). From the onset (1), connectome realizations were conceptualized at three progressively coarser neuro-structural scales, from the microscale of individual neurons and synapses, to the mesoscale of mini columns of neurons and their connection patterns, to the macroscale of brain regions and pathways.
A microscopic rendition of the human brain connectome through imaging would entail creating a comprehensive three-dimensional map of its neural connection matrix as sampled at sub-cellular spatial resolution of a voxel ≤(1 μm)3. The creation of such microscopic connectomes in vivo, not currently possible, would have profound implications for understanding normal neurological function as well as for deciphering the complexities of neurologic disorders. Similarly, noninvasive in vivo connectome rendering at the mesoscale using voxel ≤(50 μm)3 is also currently out of reach.
The more modest goal of creating in vivo macroscopic connectome renditions (4) at the coarser spatial resolution possible with current magnetic resonance imaging (MRI) technologies voxel ≥(500 μm)3 could have far-reaching research and clinical implications provided that such connectome renditions are spatially accurate, reproducible, obtained with the short scan times needed for routine clinical workflow, and generated with standard configuration clinical equipment.
Diffusion MRI (dMRI) white matter tractography (WMT) is currently the only imaging technique described in the scientific literature for in vivo macroscopic connectomics. It has been adopted by large scale research initiatives such as the human connectome project (5, 6), which employs unique ultra-powerful imaging hardware (7). The defining technical feature of dMRI pulse sequences is the use of pulsed-field-gradient (PFG) technique for diffusion encoding (8-11). PFG diffusion encoding pulses are typically applied along numerous spatial directions—typically greater than 16—in order to generate sufficient experimental data as needed for modeling the geometrically intricate fiber orientation distribution functions (ODF) at each point. ODFs are intermediate mathematical objects used for tracing the streamlines—also known as estimated fascicles (12)—that are ultimately inferred as physical WM fibertracts.
There is a need in the art for alternative methods of making connectomes. This disclosure meets this and other needs.
This disclosure provides a conceptually different and likely complementary magnetic resonance imaging (MRI) technique for in vivo connectomics, referred to as white matter fibrography (WMF) in order to distinguish it from dMRI-WMT (
At the image acquisition frontend, WMF is an application of multispectral quantitative MRI (MS-qMRI) scanning, which can use any of several MRI pulse sequences including mixed-TSE, multi-echo turbo spin echo with magnetization recovery (meTSEmr,
Post image acquisition WMF has at its core an MRI Synthesis mathematical algorithm (13) that is used for enhancing the subtle WM texture observed in maps of the longitudinal magnetization relaxation rate R1=1/T1 (see
Alternatively, WMF can use an analogous qMRI parameter, specifically pseudoR1=1/pseudoT1, which can be mapped with a faster MRI scan; dual echo turbo spin echo (DE-TSE).
WMF uses model-free direct and deterministic image processing techniques at the backend; the image processing chain may include MS-qMRI algorithms for mapping R1, R2 and PD, an image synthesis engine for R1-weighting, a brain segmentation algorithm, as well as standard image sharpening filters, 3D-to-2D projection and 3D rendering techniques.
In the absence of a definite reference technique for in vivo connectomics (2, 14-16), this disclosure validates WMF by illustrating the defining organizational features and symmetry properties of normal connectomes, and by illustrating connectome alterations in the context of self-evident and independently confirmed pathology (acute ischemia), as well as more subtle organizational disorder possibly associated with impaired cognition. Accordingly, this disclosure demonstrates: 1) that WMF can be used to create realistic and symmetric connectome renditions using two MRI scanners of different manufacturers; 2) that WMF connectome development proceeds in a predictable pattern as a function of increasing age—range: 0.6-to-34 years—consistent with known developmental trajectory and patterns; 3) structural connectome alterations in areas of WM lesions following ischemic stroke detected by concurrent dMRI, and 4) diminished connectome order and/or symmetry in a prospectively studied cohort of adolescents born extremely preterm who have subnormal cognition.
The following abbreviations and terminology are used herein. “Mixed-TSE” refers to mixed turbo spin echo, which is a multislice four time points multispectral quantitative MRI (MS-qMRI) scan. “TSE” and “FSE” stand for turbo spin echo or fast spin echo. “meTSEmr” stands for multi-echo turbo spin echo with magnetization recovery. “DE-TSE” stands for dual echo turbo spin echo. “Tri-TSE” stands for concatenation of a single echo TSE and a dual echo TSE sequences that are run consecutively without delay and with identical geometrical settings (voxel dimensions, field of view, and slice specifications: slice thickness and gap).
Thus, in an aspect this disclosure provides methods of making a white matter fibrogram representing the connectome of the brain of a subject. In some embodiments the methods comprise (a) performing a multispectral multislice magnetic resonance scan on the brain of a subject, (b) storing image data indicative of a plurality of magnetic resonance weightings of each of a plurality of slices of the brain of the subject to provide directly acquired images, (c) processing the directly acquired images to generate a plurality of quantitative maps of the brain indicative of a plurality of qMRI parameters of the subject, (d) constructing a plurality of magnetic resonance images indicative of white matter structure from the quantitative maps, and (e) rendering a white matter fibrogram of the brain of the subject from the plurality of magnetic resonance images.
In some embodiments the multispectral multislice magnetic resonance scan of (a) comprises performing a 2D scan. In some embodiments the 2D scan is a multispectral 2D scan. In some embodiments the multispectral 2D scan is selected from the group consisting of a 2D mixed-TSE scan, a 2D meTSEmr scan, 2D DE-TSE scan, and a 2D Tri-TSE scan.
In some embodiments the multispectral multislice magnetic resonance scan of (a) comprises performing a 3D scan. In some embodiments the 3D scan is a multispectral 3D scan. In some embodiments the multispectral 3D scan is selected from the group consisting of a 3D mixed-TSE scan, a 3D meTSEmr scan, a 3D DE-TSE scan, and a 3D Tri-TSE scan.
In some embodiments of the methods, (b) comprises storing the directly acquired images. In some embodiments the directly acquired images are stored in a location selected from a remote computer, a dedicated workstation, a smart device (phone or tablet), and a computer cloud.
In some embodiments of the methods (c) comprises processing the directly acquired images in an MRI scanner console, and/or (d) comprises processing the magnetic resonance images in an MRI scanner console, and/or (e) comprises processing the magnetic resonance images in an MRI scanner console.
In some embodiments of the methods (c) comprises processing the directly acquired images in a remote computer or dedicated workstation, and/or (d) comprises processing the magnetic resonance images in a remote computer or dedicated workstation, and/or (e) comprises processing the magnetic resonance images in a remote computer or dedicated workstation.
In some embodiments of the methods (c) comprises processing the directly acquired images in a smart device (phone or tablet), and/or (d) comprises processing the magnetic resonance images in a smart device (phone or tablet), and/or (e) comprises processing the magnetic resonance images in a smart device (phone or tablet).
In some embodiments of the methods (c) comprises processing the directly acquired images in a server in a computer cloud, and/or (d) comprises processing the magnetic resonance images in a server in a computer cloud, and/or (e) comprises processing the magnetic resonance images in a server in a computer cloud.
In some embodiments of the methods (d) comprises performing a synthetic MRI scan. In some embodiments of the synthetic MRI scan of (d) is selected from a synthetic MRI scan with quantitative R1 weighting, a synthetic MRI scan with quantitative pseudoR1 weighting, and a synthetic MRI scan with qualitative R1 weighting.
In some embodiments of the methods (c) comprises processing the directly acquired images with an image sharpening filter, and/or (d) comprises processing the magnetic resonance images with an image sharpening filter, and/or (e) comprises processing the magnetic resonance images with an image sharpening filter. In some embodiments the image sharpening filter is an unsharp mask filter or a deconvolution filter.
In some embodiments of the methods (e) comprises performing a 3D to 2D projection algorithm and the white matter fibrogram of (e) is a 3D to 2D projection image.
In some embodiments of the methods (e) comprises performing a 3D to 2D maximum intensity algorithm and the white matter fibrogram of (e) is a 3D to 2D maximum intensity projection.
In some embodiments of the methods comprises performing an algorithm selected from the group consisting of a volume rendering algorithm and a tractography algorithm.
In some embodiments of the methods (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying at least one of the T1, T2, and PD distributions at the native spatial resolution of the directly acquired images.
In some embodiments of the methods (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying at least one of the R1, R2, and PD distributions at the native spatial resolution of the directly acquired images.
In some embodiments of the methods (c) comprises processing a plurality of directly acquired images to generate synthetic MR images weighted by R1. In some embodiments the directly acquired images are processed with an algorithm comprising a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz. In some embodiments the algorithm comprises a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz, or from 10 Hz to 50 Hz, or from 15 Hz to 25 Hz, or from 5 Hz to 10 Hz, or from 10 Hz to 15 Hz, or from 15 Hz to 20 Hz, or from 20 Hz to 25 Hz, or from 4 Hz to 15 Hz.
In some embodiments of the methods (c) comprises processing a plurality of directly acquired images to generate synthetic MR images weighted by pseudoR1. In some embodiments the directly acquired images are processed with an algorithm comprising a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz. In some embodiments the algorithm comprises a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz, or from 10 Hz to 50 Hz, or from 15 Hz to 25 Hz, or from 5 Hz to 10 Hz, or from 10 Hz to 15 Hz, or from 15 Hz to 20 Hz, or from 20 Hz to 25 Hz, or from 4 Hz to 15 Hz.
Also provided are systems configured for making a white matter fibrogram representing the connectome of the brain of a subject. The methods may comprise: i) a magnetic resonance imaging machine configured to apply an external magnetic field and a plurality of excitation pulses to a subject in the magnetic resonance imaging machine; ii) a control system connected to the magnetic resonance imaging machine and configured to perform the method of claim 1; and iii) a computer processor configured to receive magnetic resonance image data and render a connectome from the data.
To provide a general understanding of the systems and methods described herein, certain illustrative embodiments will now be described. However, it will be understood that the systems and methods described herein may be adapted and modified as is appropriate for the application being addressed and that the systems and methods described herein may be employed in other suitable applications, and that such other additions and modifications will not depart from the scope thereof. In particular, a computerized control system, computer, processor, smartphone, tablet, or server in a cloud as used in this description may be a single computing device or multiple computing devices working collectively and in which the storage of data and the execution of functions are spread out amongst the various computing devices.
Diffusion-MRI white matter tractography (dMRI-WMT) is currently the only technique available for in vivo mapping the neural connections of the human brain. This disclosure provides a fundamentally different technique for MRI based connectomics that is referred to herein as white matter fibrography (WMF). WMF is a direct connectome rendering technique which is an application of multispectral quantitative MRI (MS-qMRI) and Synthetic-MRI (
In the absence of definite reference standard for in vivo connectomics, this disclosure validates WMF by illustrating the defining organizational features and symmetry properties of normal connectomes as a function of age, and by demonstrating connectome alterations in the context of self-evident and independently confirmed pathology—acute ischemic stroke—, as well as less obvious organizational connectome disorder, possibly associated with impaired cognition.
The data presented in the Examples demonstrates that WMF is a promising complementary alternative to dMRI-WMT for in vivo connectomics, which can generate undistorted high spatial resolution connectomes in clinically feasible scan times (<10 min) using standard clinical MRI hardware. The examples demonstrate the utility of the invention for the assessment of WM disease and for improving preoperative surgical planning, and building ultrahigh spatial resolution connectomes.
Creating in vivo connectome renditions routinely in the clinic can have far-reaching medical and scientific implications. The described WMF technique bridges a technological gap because the maximum spatial resolution achievable is not hampered by the mathematical and technical requirements associated with diffusion encoded MRI. WMF is promising because it is clinically practical, direct, geometrically accurate, and self-evident.
Aspects of the methods described herein comprise use of two dimensional (2D-) MRI pulse sequences capable of generating coregistered PD and R1 maps, with either partial magnetization recovery (multislice multi-echo MS-meTSEmr in
Aspects of the methods described herein comprise use of three dimensional (3D-) MRI pulse sequences capable of generating coregistered PD and R1 maps, with either partial magnetization recovery (multi-echo MS-meTSEmr in
The timing diagram core module of the meTSEmr pulse sequence is as follows (see
The timing diagram of the Tri-TSE pulse sequence (see
In certain embodiments the simplest and/or fastest pulse sequence that can be used for WMF as pertaining to this invention is the DE-TSE pulse sequence (see
In these equations A and B are parameters that depend on the main magnetic field strength B0. These can be fitted from the experimental data of Fatouros and Marmarou paper to give: A==−0.002*B02−0.023*B0+0.96 and B=−0.004*B02+0.106*B0+0.173
The magnetic resonance images used for WMF processing may be directly acquired images or quantitative maps and in addition may be multispectral—that is, more than one magnetic resonance image parameter may be mapped from a single pulse sequence. One or more of the tissue parameters influence the contrasts of these magnetic resonance images. Such parameters include any of the following: the longitudinal magnetization relaxation time T1, the longitudinal magnetization relaxation rate R1, the transverse magnetization relaxation time T2, the transverse magnetization relaxation rate R2, the reduced transverse magnetization relaxation time T2*, the proton density (PD), and the diffusion coefficient.
The longitudinal magnetization relaxation rate R1 (=1/T1) of brain tissue includes three distinct physical phenomena depending on the location and microscopic environment of the 1H-protons (
In a first embodiment, a general white matter fibrogram (WMF) generating algorithm is used to generate a connectome for the brain of a subject. A flow chart representative of the embodiment is shown in
In a second embodiment an exponential white matter fibrogram (WMF) generating algorithm is used to generate a connectome for the brain of a subject. A flow chart representative of the embodiment is shown in
In a third embodiment a fully quantitative as well as exponential white matter fibrogram (WMF) generating algorithm is used to generate a connectome for the brain of a subject. A flow chart representative of the embodiment is shown in
In a fourth embodiment of the invention (
The WM texture enhancement effects obtained with R1-weighted synthetic MRI increase as a function of increasing the value of the weighting parameter omega (a). This effect is illustrated in
The WM texture enhancement effects are studied systematically (
Using a Ω value of 10 Hz, the full image processing pipeline is shown graphically in
1. Ethics and Subjects: Boston University Medical Center
This data was acquired as part of a prospective study protocol that was approved by the Institutional Review Board (IRB) of Boston University Medical Center. All subjects provided written consent.
For the aging study, 12 subjects were selected from our brain qMRI database. For data consistency only subjects scanned at 1.5 T using the same MS-qMRI pulse sequence (mixed-TSE) (15) and who had a normal by Mill clinical report were chosen. Subjects who received intravenous contrast administration were not included. In addition, two healthy volunteer subjects were scanned at 3.0 T using this same IRB approved protocol.
2. Ethics and Subjects: ELGAN Study
The Extremely Low Gestational Age Newborn (ELGAN) study is prospective observational study that was approved by the Institutional Review Boards of the 12 participating institutions (42). Participating institutions of the ELGAN study are from three geographic hubs: 1) The New England Hub (Baystate Children's Hospital, Springfield, Mass., Children's Hospital of Boston, Boston, Mass., Tufts Medical Center, Boston, Mass., UMass Memorial Hospital, Boston, Mass., Yale-New Haven Children's Hospital, New Haven, Conn.). 2) The North Carolina Hub (East Carolina University, Greenville, N.C., North Carolina Children's Hospital, Chapel Hill, N.C., Wake Forest School of Medicine, Winston-Salem, N.C.). 3) The Lake Michigan Hub (Michigan State University, East Lansing, Mich., Helen DeVos Children's Hospital, Grand Rapids, MR, University of Chicago Medical Center, Chicago, Ill., William Beaumont Hospital, Royal Oak, Mich.).
3. Measures of Cognition
General cognitive ability (or IQ) was assessed with the School-Age Differential Ability Scales-II (DAS-II) Verbal and Nonverbal Reasoning scales (43) as reviewed in detail elsewhere (44). Two 15 year-old females were chosen for this paper to illustrate the marked connectome differences.
4. MS-qMRI at BMC (1.5 T and 3.0 T)
Mixed-TSE is a multislice four time points MS-qMRI pulse sequence that has been described in the literature (15). It combines in a single acquisition the principles of T1-weighting by inversion recovery and of T2-weighting by dual-echo sampling. The mixed-TSE pulse sequence begins with a slice selective inversion pulse and acquires dual TSE data, i.e., two effective echo times TE1eff and TE2eff at two different inversion times TI1 and TI2. In this way, four self-coregistered images per slice are generated, each with different levels of T1- and T2-weightings: the first two correspond to the two echoes acquired at inversion time TI1, and, analogously, the second two correspond with the echoes at the second inversion time TI2. The mixed-TSE pulse sequence interrogates two interleaved packages of slices sequentially acquired in the same acquisition. The inter-slice gap of each package is chosen equal to the slice thickness, resulting in a contiguous image dataset with negligible inter-slice cross talk artifacts. The directly acquired images can be processed to generate qMRI maps portraying the T1 (and R1), T2, and PD distributions simultaneously and with the native spatial resolution and anatomic coverage of the directly acquired mixed-TSE scan.
The second MS-qMRI pulse sequence tri-TSE was implemented in the two 3.0 T MRI scanners of our hospital; this is a three time points MS-qMRI pulse sequence that achieves T1-weighting by magnetization saturation and PD- and T2-weightings via a dual-echo (DE) TSE imaging. As such Tri-TSE consists of a single echo-TSE scan that is run in temporal concatenation, and with the same pre-scan settings, with a DE-TSE scan; all together it generates T1-, T2, and PD-weighted directly acquired images, which can be qMRI processed to generate coregistered maps of T1, T2, and PD. Tri-TSE was implemented at 3.0 T at high spatial resolution on the two clinical scanners of our institution (Discovery MR750w, GE Healthcare, Waukesha, Wis. and Achieva, Philips Healthcare, Cleveland, Ohio).
5. MS-qMRI for the ELGAN Study (1.5 T and 3.0 T)
Tri-TSE images were acquired with MRI scanners built by three manufacturers: General Electric Healthcare (n=3), Philips Healthcare (n=2), and Siemens Healthcare (n=7) with magnetic field strengths of 3.0 T (11 sites) and 1.5 T (one site). In all cases, the body quadrature coil and the head phased array coil were used for RF transmission and signal reception respectively.
6. Image Processing
The multiple directly-acquired images per slice of the mixed-TSE or tri-TSE or DE-TSE acquisitions were used to create maps of the relaxation times, the relaxation rates, and the normalized proton density using qMRI algorithms programmed in Mathcad (PTC, Needham, Mass.) and Python 3.5, using the Canopy integrated development environment (Enthought, Austin, Tex.). The skull and extracranial tissues were removed using a dual clustering segmentation algorithm (45). Longitudinal magnetization relaxation rate (R1) heavily images of the intracranium were then generated with a synthetic MRI engine. The skull stripped R1-weighted synthetic images, which show well-defined white matter structure, were processed with Fiji (48): first sharpened with the “Unsharp mask” filter (radius=1 and mask weight=0.6), orange colorized, and then 3D-to-2D projected using the Volume Viewer plugin of Fiji (https://imagej.nih.gov/ij/plugins/volume-viewer.html). This procedure results in connectome renditions as presented in the various figures of this disclosure.
7. Synthetic MRI and R1 Contrast Optimization
An exponential R1-weighting image synthesis algorithm was implemented with a simple exponential R1 weighting function:
I
synth(n)=PD exp(−Ω/R1) [1].
In this formula, PD is the proton density and Ω is the relaxation rate weighting factor, which has a practical range of Ω∈(0, ˜25 Hz) with the maximum value being a function of the signal-to-noise ratio available in the PD and R1 maps (see
The imaging effects resulting from progressively increasing the level of synthetic R1 weighting, as imparted by increasing the value of the parameter Ω in Eq. 1, are demonstrated in
Assuming typical image noise levels in the 5%-10% range, the curve in
As a first step for validating WMF, Mill scanning platform independency was shown by analyzing imaging data at a medium-high spatial resolution (voxel=0.5×0.5×2 mm3). Comparable quality imaging data generated with two 3.0 T Mill scanners of different manufacturers was processed in under 8 min of scan time each. The resulting connectome renditions of the two healthy volunteers shown in
A second WMF validation step illustrates the normal brain age-related changes: whole brain axial connectome renditions as a function of increasing age are shown in
A third WMF technique validation step assesses WM integrity under the stress of ischemia. Two acute ischemic stroke lesions (arrow) in a 48 yo female are shown in
A fourth step towards WMF technique validation exemplifies the technique's potential for characterizing the level of connectome fiber organizational order or disorder in the context of neurocognitive impairment. The full brain connectomes shown in
The qMRI maps (qPD, R1, and R2) are further processed with a heavily R1-weighted synthetic pulse sequence embodied in the formula Isynth(Ω)=PD exp(−Ω/R1) in order to generate images that reveal the finer structure of white matter (
White matter fibrograms of eight prematurely born adolescents of the ELGAN study as a function of increasing intelligence quotient (IQ), from left to right and top to bottom as labelled in
1. WMF: summary of findings.
The examples herein demonstrate development and testing of a new and fundamentally different Mill based technique for in vivo brain connectomics termed WFM. The data show that the WMF connectome renditions are anatomically realistic and similar from subject to subject, change with age in a manner consistent with known patterns of normal brain development, can demonstrate major WM injury (ischemia) as well as reveal fiber disorganization anomalies. Such WM fiber disorder is likely associated with low measures of cognition sequelae of extreme preterm birth of the studied adolescent subject. In addition, WMF connectomes can be generated with clinically compatible scan-times using commercial configuration MRI scanners of three prominent Mill manufacturers.
WMF does not use the PFG diffusion encoding technique of Stejskal-Tanner (8) and is therefore different from dMRI-WMT at the image acquisition frontend as well as at the image processing backend. In certain embodiments of the invention, at the image acquisition frontend, the best suited pulse sequences for WMF are generally MS-qMRI variants of the fast (turbo) spin echo pulse sequence which are scan-time efficient and can achieve arguably the finest MR image quality in terms of high SNR, geometric accuracy, and high spatial resolution. Furthermore, these MS-qMRI pulse sequences are highly resilient to artifacts from magnetic field inhomogeneity and motion. These advantageous technical qualities can translate into directly acquired images of high geometrical accuracy and detail that are therefore particularly useful for unravelling the finer structural features of the connectome. At the image processing backend, WMF uses qMRI mapping algorithms and image synthesis programs that are direct and deterministic, and therefore WM fibers are observed- or detected-as opposed to created- or inferred-via mathematical modeling.
2. Validation Considerations
The data do not attempt validating WMF against dMRI-WMT because the highest quality dMRI-WMT connectome renditions may not be achievable with the commercial configuration MRI scanners and dMRI-WMT is still works-in-progress. The technical difficulties of dMRI-WMT connectomics have been analyzed in several comprehensive modern reviews (18, 20-22) and this is an active research area with continuous and encouraging improvements particularly with regards to finding an optimum balance between spatial encoding (k-space sampling) vs. diffusion encoding (q-space sampling), the so-called k-q tradeoff of dMRI-WMT (23).
The NMR origins of dMRI-WMT date back to the papers by Torrey (24) and Stejskal (25) that laid down the theoretical physics foundations and the diffusion tensor (DT) mathematical framework for the NMR description of diffusional anisotropy in complex materials and biological tissue. dMRI-WMT was made possible by incorporating diffusion encoding gradient pulses into imaging pulse sequencesthus paving the road for in vivo connectomics, starting with DT imaging (26-31) WM tractography (32). The bare DT model is however rudimentary for describing the organizational complexities of WM thus stimulating the development of the so-called “higher-order” models (35-37) for dMRI-WMT connectomics. Although much progress has been made at the image processing backend of dMRI-WMT, fundamental limitations may not be solved in the near future. Thomas et al. (16) report that even with exceptional quality images generated ex vivo under ideal experimental conditions—absence of motion artifacts—and processed with the most sophisticated tractography algorithms currently available, dMRI-WMT alone is unlikely to provide an anatomically accurate rendering of the brain connectome. This work's main finding is “that a tractography technique that shows high sensitivity (a high rate of true positives) most likely will show low specificity (a high rate of false positives). In addition, the anatomical accuracy of tractography techniques was found to be highly dependent on a number of technical parameters, such as the type of diffusion model, the angular threshold, and the composition of the seed ROI” (16). It would seem therefore that the main difficulty of dMRI-WMT connectomics ultimately is to the ill-posed nature of the mathematical problem (38) in addition to the steep but conceivably surmountable technological challenges at image acquisition (7).
3. Scientific and Clinical Applications
The spectra of scientific and clinical applications of WMF and dMRI-WMT connectomics likely overlap and at the most fundamental level begin with deriving an understanding of normal brain architecture, normal brain development, and implications on cognition and behavior. WMF could be instrumental for the assessment of numerous neuropsychiatric diagnoses including Schizophrenia, Alzheimer's disease, depression, and many other conditions (see reference (12) for a more exhaustive list). The list of possible clinical applications further includes, cancer, pre-surgical planning, stroke, WM diseases, and traumatic brain injury. Perhaps the most beneficial WMF assets relate to its potential as a routine clinical tool, the full potential of which may not be estimated at this early stage of implementation and development.
The maximum spatial resolution of the directly acquired images and therefore of the connectome renditions of this report could be improved without significantly increasing scan-time by using acceleration imaging techniques such as compressed sense (39), simultaneous multislice imaging(40, 41), as well as more powerful MRI hardware (7).
4. R1-Weighted Synthetic MRI and Myelin Water
WMF technique uses R1-weighting (Eq. 1) for attenuating the intravoxel MR signals stemming from 1H-protonic species with lower R1 values. In all likelihood the residual high-R1 (i.e. short-T1) signals observed via WMF stem from 1H-protons of water or lipids of the myelin sheaths environment. Experimental evidence supporting the existence of such short-T1 protonic species in WM has been reported recently in the context of myelin water imaging (40, 41) and therefore, WMF by R1-weighted Synthetic MRI could be a viable technique for myelin water imaging.
Notably, the possibility of generating heavily R1-weighted images, which is straightforward with Synthetic MRI, may difficult to replicate with actual Physical MRI; physical pulse sequence cannot generate contrast weighting according to Eq. 1. It thus seem that Synthetic MRI can extend the capabilities of Physical MRI. This further highlights the need for, and the benefits of developing more efficient and powerful MS-qMRI pulse sequences as well as more sophisticated qMRI algorithms for generating accurate renditions of the “virtual patient” at the highest possible spatial resolution and image fidelity.
The following exemplary embodiments are provided for illustration only and are not intended to be limiting.
A method of making a white matter fibrogram representing the connectome of the brain of a subject, comprising: (a) performing a multispectral multislice magnetic resonance scan on the brain of a subject, (b) storing image data indicative of a plurality of magnetic resonance weightings of each of a plurality of slices of the brain of the subject to provide directly acquired images, (c) processing the directly acquired images to generate a plurality of quantitative maps of the brain indicative of a plurality of qMRI parameters of the subject, (d) constructing a plurality of magnetic resonance images indicative of white matter structure from the quantitative maps, and (e) rendering a white matter fibrogram of the brain of the subject from the plurality of magnetic resonance images.
The method of Embodiment 1, wherein the multispectral multislice magnetic resonance scan of (a) comprises performing a 2D scan.
The method of Embodiment 2, wherein the 2D scan is a multispectral 2D scan.
The method of Embodiment 3, wherein the multispectral 2D scan is selected from the group consisting of a 2D mixed-TSE scan, a 2D meTSEmr scan, 2D DE-TSE scan, and a 2D Tri-TSE scan.
The method of Embodiment 1, wherein the multispectral multislice magnetic resonance scan of (a) comprises performing a 3D scan.
The method of Embodiment 5, wherein the 3D scan is a multispectral 3D scan.
The method of Embodiment 6, wherein the multispectral 3D scan is selected from the group consisting of a 3D mixed-TSE scan, a 3D meTSEmr scan, a 3D DE-TSE scan, and a 3D Tri-TSE scan.
The method of any one of Embodiments 1 to 7, wherein (b) comprises storing the directly acquired images.
The method of Embodiment 8, wherein the directly acquired images are stored in a location selected from a remote computer, a dedicated workstation, a smart device (phone or tablet), and a computer cloud.
The method of any one of Embodiments 1 to 9, wherein (c) comprises processing the directly acquired images in an MRI scanner console, and/or (d) comprises processing the magnetic resonance images in an MRI scanner console, and/or (e) comprises processing the magnetic resonance images in an MRI scanner console.
The method of any one of Embodiments 1 to 9, wherein (c) comprises processing the directly acquired images in a remote computer or dedicated workstation, and/or (d) comprises processing the magnetic resonance images in a remote computer or dedicated workstation, and/or (e) comprises processing the magnetic resonance images in a remote computer or dedicated workstation.
The method of any one of Embodiments 1 to 9, wherein (c) comprises processing the directly acquired images in a smart device (phone or tablet), and/or (d) comprises processing the magnetic resonance images in a smart device (phone or tablet), and/or (e) comprises processing the magnetic resonance images in a smart device (phone or tablet).
The method of any one of Embodiments 1 to 9, wherein (c) comprises processing the directly acquired images in a server in a computer cloud, and/or (d) comprises processing the magnetic resonance images in a server in a computer cloud, and/or (e) comprises processing the magnetic resonance images in a server in a computer cloud.
The method of any one of Embodiments 1 to 13, wherein (d) comprises performing a synthetic MRI scan
The method of Embodiment 14, wherein the synthetic MRI scan of (d) is selected from a synthetic MRI scan with quantitative R1 weighting, a synthetic MRI scan with quantitative pseudoR1 weighting, and a synthetic MRI scan with qualitative R1 weighting.
The method of any one of Embodiments 1 to 15, wherein (c) comprises processing the directly acquired images with an image sharpening filter, and/or (d) comprises processing the magnetic resonance images with an image sharpening filter, and/or (e) comprises processing the magnetic resonance images with an image sharpening filter.
The method of Embodiment 16, wherein the image sharpening filter is an unsharp mask filter or a deconvolution filter.
The method of any one of Embodiments 1 to 17, wherein (e) comprises performing a 3D to 2D projection algorithm and the white matter fibrogram of (e) is a 3D to 2D projection image.
The method of any one of Embodiments 1 to 17, wherein (e) comprises performing a 3D to 2D maximum intensity algorithm and the white matter fibrogram of (e) is a 3D to 2D maximum intensity projection.
The method of any one of Embodiments 1 to 17, wherein (e) comprises performing an algorithm selected from the group consisting of a volume rendering algorithm and a tractography algorithm.
The method of any one of Embodiments 1 to 20, wherein (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying at least one of the T1, T2, and PD distributions at the native spatial resolution of the directly acquired images.
The method of any one of Embodiments 1 to 20, wherein (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying at least one of the R1, R2, and PD distributions at the native spatial resolution of the directly acquired images.
The method of any one of Embodiments 1 to 20, wherein (c) comprises processing a plurality of directly acquired images to generate synthetic MR images weighted by R1.
The method of Embodiment 23, wherein the directly acquired images are processed with an algorithm comprising a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz.
The method of any one of Embodiments 1 to 20, wherein (c) comprises processing a plurality of directly acquired images to generate synthetic MR images weighted by pseudoR1.
The method of Embodiment 25, wherein the directly acquired images are processed with an algorithm comprising a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz.
A system configured for making a white matter fibrogram representing the connectome of the brain of a subject, comprising: i) a magnetic resonance imaging machine configured to apply an external magnetic field and a plurality of excitation pulses to a subject in the magnetic resonance imaging machine; ii) a control system connected to the magnetic resonance imaging machine and configured to perform the method of any one of Embodiments 1 to 26; and iii) a computer processor configured to receive magnetic resonance image data and render a connectome from the data.
The following exemplary alternative embodiments are provided for illustration only and are not intended to be limiting.
A method of making a white matter fibrogram representing the connectome of the brain of a subject, comprising: (a) performing a multi-slice magnetic resonance scan on the brain of a subject, (b) storing image data indicative of a plurality of magnetic resonance weightings of each of a plurality of slices of the brain of the subject to provide directly acquired images, (c) constructing a plurality of magnetic resonance images indicative of white matter structure from the data, and (d) rendering a white matter fibrogram of the brain of the subject from the plurality of magnetic resonance images.
The method of Alternative Embodiment 1, wherein (c) comprises performing a synthetic MRI scan.
The method of Alternative Embodiment 1, wherein (c) comprises performing a synthetic MRI scan with quantitative R1 weighting.
The method of any one of Alternative Embodiments 1 to 3, wherein (c) comprises processing images with an image sharpening filter.
The method of Alternative Embodiment 4, wherein the image sharpening filter is selected from an unsharp mask filter and a convolution filter.
The method of any one of Alternative Embodiments 1 to 5, wherein (d) comprises performing a 3D to 2D projection algorithm and the white matter fibrogram of (d) is a 3D to 2D projection image.
The method of any one of Alternative Embodiments 1 to 5, wherein (d) comprises performing a 3D to 2D maximum intensity algorithm and the white matter fibrogram of (d) is a 3D to 2D maximum intensity projection.
The method of any one of Alternative Embodiments 1 to 5, wherein (d) comprises performing a volume rendering algorithm
The method of any one of Alternative Embodiments 1 to 5, wherein (d) comprises performing a tractography algorithm.
The method of any one of Alternative Embodiments 1 to 9, wherein the multi-slice magnetic resonance scan of (a) is performed by a method comprising: (i) applying a first excitation pulse to a first slice of the subject; (ii) detecting a first plurality of echo signals emitted by the first slice after the first excitation pulse; (iii) waiting a first period of time; (iv) applying a second excitation pulse to the first slice during partial recovery of a longitudinal magnetization of the first slice; and (v) detecting a second plurality of echo signals emitted by the first slice after the second excitation pulse.
The method of Alternative Embodiment 10, wherein detecting the first plurality of echo signals comprises obtaining an electrical response from each echo signal in the first plurality of echo signals.
The method of Alternative Embodiment 10, wherein the detected first plurality of echo signals are spin echoes, gradient echoes, or a combination of spin echoes and gradient echoes.
The method of Alternative Embodiment 10, wherein a first echo signal in the first plurality of echo signals and a first echo signal in the second plurality of echo signals are combined to form a plurality of fast spin echo readouts, a plurality of turbo spin echo readouts, or a plurality of gradient and spin echo readouts.
The method of Alternative Embodiment 10, wherein steps (i)-(iii) are applied to one or more additional slices of the subject during the first period of time.
The method of Alternative Embodiment 10, the method further comprising: (vi) waiting a second period of time; and (vii) repeating steps (i)-(v) a predetermined number of times.
The method of Alternative Embodiment 15, wherein steps (iv)-(vi) are applied to one or more additional slices of the subject during the second period of time.
The method of Alternative Embodiment 10, wherein the first excitation pulse is applied when the longitudinal magnetization of the first slice is equal to a net magnetization Mo.
The method of Alternative Embodiment 1, wherein the multi-slice magnetic resonance scan of (a) is performed by a method comprising use of a mixed turbo spin echo (TSE) pulse sequence.
The method of Alternative Embodiment 1, wherein the multi-slice magnetic resonance scan of (a) is performed by a method comprising use of a tri-TSE pulse sequence.
The method of any one of Alternative Embodiments 1 to 9, wherein the multi-slice magnetic resonance scan of (A) is performed by a method comprising: (i) applying a first excitation pulse to a first slice of the subject; (ii) detecting a first set of at least three echo signals emitted by the first slice after the first excitation pulse; (iii) waiting a first period of time; (iv) repeating steps (a) through (iii) a first predetermined number of times; (v) applying a second excitation pulse to the first slice; (vi) detecting a second set of at least three echo signals emitted by the first slice after the second excitation pulse; (vii) waiting a second period of time; and (viii) repeating steps (v) through (vii) a second predetermined number of times.
The method of Alternative Embodiment 20, wherein detecting the first plurality of echo signals comprises obtaining an electrical response from each echo signal in the first plurality of echo signals.
The method of Alternative Embodiment 20, wherein the detected first plurality of echo signals are spin echoes, gradient echoes, or a combination of spin echoes and gradient echoes.
The method of Alternative Embodiment 20, wherein a first echo signal in the first plurality of echo signals and a first echo signal in the second plurality of echo signals are combined to form a plurality of fast spin echo readouts, a plurality of turbo spin echo readouts, or a plurality of gradient and spin echo readouts.
The method of Alternative Embodiment 20, wherein steps (i)-(iii) are applied to one or more additional slices of the subject during the first period of time.
The method of Alternative Embodiment 20, wherein steps (v)-(vii) are applied to one or more additional slices of the subject during the second period of time.
The method of Alternative Embodiment 20, wherein the first excitation pulse is applied when the longitudinal magnetization of the first slice is equal to a net magnetization Mo.
The method of any one of Alternative Embodiments 1 to 26, wherein (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying at least one of the T1, T2, and PD distributions simultaneously and with a native spatial resolution.
The method of any one of Alternative Embodiments 1 to 26, wherein (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying the relaxation rates R1, R2, and PD distributions simultaneously and with a at least the native spatial resolution of the directly acquired images.
The method of any one of Alternative Embodiments 1 to 26, wherein (c) comprises processing a plurality of directly acquired images to generate qMRI maps portraying the relaxation times T1, T2, and PD distributions simultaneously and with a at least the native spatial resolution of the directly acquired images.
The method of any one of Alternative Embodiments 1 to 29, wherein (c) comprises processing a plurality of directly acquired images to generate synthetic MR images weighted by R1.
The method of any one of Alternative Embodiments 1 to 29, wherein (c) comprises processing images with an exponential R1-weighting image synthesis algorithm.
The method of Alternative Embodiment 30 or 31, wherein the algorithm comprises a relaxation rate weighting factor (Ω) of from 0 Hz to 25 Hz.
The method of any one of Alternative Embodiments 1 to 32, wherein parts (c) and (d) are implemented in the control console of an MRI scanner.
The method of any one of Alternative Embodiments 1 to 32, wherein parts (c) and (d) are implemented in a remote workstation.
The method of any one of Alternative Embodiments 1 to 32, wherein methods in parts (c) and (d) are run in a server remotely operated by a computer.
The method of any one of Alternative Embodiments 1 to 32, wherein parts (c) and (d) are implemented in a cloud.
A system configured for making a white matter fibrogram representing the connectome of the brain of a subject, comprising: a magnetic resonance imaging machine configured to apply an external magnetic field and a plurality of excitation pulses to a subject in the magnetic resonance imaging machine; a control system connected to the magnetic resonance imaging machine and configured to perform any of the methods of any of Alternative Embodiments 1 to 36; and a computer processor configured to receive magnetic resonance image data and render a connectome from the data.
WMF is a promising complementary alternative to dMRI-WMT for studying the microarchitecture of white matter, which can generate undistorted high spatial resolution connectomes in clinically feasible (<10 min) scan times using standard clinical MRI hardware. This work could have implications for the assessment of WM disease, traumatic brain injury, and for improving preoperative surgical planning, and building ultrahigh spatial resolution connectomes.
It is to be understood that while various illustrative implementations have been described, the forgoing description is merely illustrative and does not limit the scope of the invention. While several examples have been provided in the present disclosure, it should be understood that the disclosed systems, components and methods may be embodied in many other specific forms without departing from the scope of the present disclosure.
The examples disclosed can be implemented in combinations or sub-combinations with one or more other features described herein. A variety of apparatus, systems and methods may be implemented based on the disclosure and still fall within the scope of the invention. Also, the various features described or illustrated above may be combined or integrated in other systems or certain features may be omitted, or not implemented.
While various embodiments and alternative embodiments of the present disclosure have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the disclosure. It should be understood that various alternatives to the embodiments of the disclosure described herein may be employed in practicing the disclosure.
This invention was made with Government support under Contract No. OD023348 awarded by the National Institutes of Health. The Government has certain rights in the invention.
Number | Date | Country | |
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62678725 | May 2018 | US |