SBIR-STTR Award

This project will provide the first ground truth connection anisotropic diffusion phantom to reproduce human white matter using axon scale diffusion tubes and track 250 micron scale fascicle (bundles of axons) with a common path. The phantom will advance MR diffusion imaging, providing accurate calibration, quality assurance, and research advancement. It utilizes innovations in textile engineering, 3D printing, and computer controlled connection routing to reproduce human brain scale white matter tissue, allowing for the reproduction of actual connective networks using millions of filled 5-12 micron scale textile tubes. It will quantify the accuracy of connectome anatomical mapping, drive technical advancement of diffusion MRI acquisition and fiber tracking, and provide ground truth measurement for clinical and research MRI centers, as well as quality assurance for anatomical connectome based brain scientific and clinical imaging. We will quantify the accuracy of following a set of neural fasciculi within tracts and through crossings in complex brain mapping paths over long distance (relative) and across a series of test MRI reference object phantoms representative of human tissue to calibrate measurement. The Phase I effort will be a demonstration of feasibility of research and calibration utility, creating a series of novel anisotropic diffusion phantoms to quantify connection routing accuracy. We will use hollow textiles called Taxons (manufactured textile, axon-shaped, micron scale hollow tubes) reproducing biologically known routes of long distance axonal anatomy. This will provide the first quantitative reference standard for intra-axonal water. These phantoms will include water/D2O, Mn+ doped, or fluorescent dye filled Taxons providing 1,000 point-to-point manufactured fasciculi scale tracts of 64,000 filled Taxons. The phantoms will provide manufactured reproduction of connectivity geometry comparable to the mesoscale of the human visual system (eye to LGN, to V1, to V2, V4) with spatial topology matching animal scale tracer studies. This will quantify how well advanced diffusion imaging sequences can follow the connectivity patterns as a function of tract size, crossing, spread, number and diameter distribution of Taxons. The Specific Aims are: 1) Develop a prototype multiscale manufactured standard reference taxon phantom for brain networks to demonstrate technical and economic feasibility to calibrate and advance MRI research; 2) Create a calibration brain tract/crossing MRI anisotropic phantom, and 3) Create a human scale connective phantom mapping the complexity in the visual system eye to layers of LGN. These will be tested with MRI (3T) and non-MRI methods (light and electron microscope, Micro CT, and textile industrial measurement). Testing will occur on 3T and 7T MRI (Siemens, GE, and Philips) magnets.

Public Health Relevance Statement:
Project Narrative With no standard for accuracy, the field of MRI imaging has serious concerns about the accuracy of diffusion imaging precision to produce anatomically correct maps of known anatomy. This project will advance the quality and speed of MRI diffusion imaging to provide an anatomically accurate map of brain connectivity, providing quantitative calibration of MRI scans for white matter pathology impacting over 10 million US residents annually for disorders including brain trauma, tumors, developmental disorders, and neurodegenerative disorders at an economic cost of over $80 billion. It will also provide the first viable ground truth calibration of anisotropic diffusion to calibrate US connectome-based imaging with over $316 million dollars of research effort supported by current NIH and Department of Defense research programs.

Project Terms:
Anatomy; Animals; Axon; base; Base of the Brain; Biological; Brain; Brain imaging; Brain Mapping; brain tract; Caliber; Calibration; Clinical; clinical Diagnosis; clinical imaging; Clinical Research; Complex; Computers; connectome; cost; density; Department of Defense; Deuterium; developmental disease/disorder; Diffusion; Diffusion Magnetic Resonance Imaging; Disease; economic cost; Economics; Electron Microscope; Electrons; Engineering; Eye; Fascicle; Fiber; Fluorescent Dyes; Genetic Crossing Over; Geometry; Goals; Hospitals; Hour; Human; human tissue; Image; imaging modality; imaging program; Industrialization; innovation; Investments; Language; Lateral Geniculate Body; Light Microscope; Liquid substance; Magnetic Resonance Imaging; Maps; Measurement; Measures; Methods; microCT; Modeling; MRI Scans; Neurodegenerative Disorders; novel; Optic Chiasm; Optic Nerve; Optic tract structure; Optics; Outcome; Pathology; Pattern; Phase; Photography; Printing; Procedures; Process; Production; programs; prototype; Publishing; quality assurance; Quality Control; Reference Standards; relating to nervous system; Reporting; Reproduction; Research; Research Project Grants; Route; Running; Science; Series; Speed; System; Taxon; Technology; Testing; Textiles; Tissues; Tracer; Translations; Traumatic Brain Injury; Tube; Tubular formation; tumor; Unit of Measure; United States National Institutes of Health; Validation; Variant; Vendor; Visual; visual motor; Visual system structure; Water; white matter

There is a critical gap in the reliability of anisotropic diffusion magnetic resonance imaging (AdMRI). This gap can be filled by using a ground truth measurement capability that allows for the necessary parametric control of water filled geometries of tubes at the micron scale that can produce paths representative of the millions of axons across centimeters in brain tract trajectories. Diffusion Tensor Imaging (DTI) publications report clinically significant systematic error that confounds accurate quantitative assessments across instruments and time. Reference phantoms that provide exact error metrics will advance MRI biophysics science and clinical quantitative accuracy. Correction algorithms using reference data can reduce systematic measurement error, enabling accurate reproducible measurement and provide cross scanner norms for AdMRI pathology. This project will deliver the first viable AdMRI phantom “ground truth” using ‘Taxons™’ (textile axon shaped nanotubes), invented by this team, and apply advanced bi-component polymer nanoscale production methods to create structures matched to human tissue histology. In doing this we will deliver axon scale taxons at 800 nanometer diameter, with a packing density of one million taxons per mm2, matched to actual human corpus callosum axon measurements. In Phase I we proposed and delivered taxons with 12 micron inner diameter tubes with a packing density of 1241 per mm2 that could be filled with water and produce FA measurement in the human tissue range. We actually “over- delivered”, exceeding a packing density of 1,000,000 per mm2 covering the human axonal tissue range. We can now precisely parametrically control the diameters, packing density, restricted/hindered, and isotropic water fractions to test and improve leading compartmental models of diffusion. We created a fasciculus routing machine that can, at viable cost, create human scale fasciculus routes matched to human tissue, such as the optic system eye to LGN, of 20 million routed taxons. The 1 to 1 scale taxonal network phantoms quantify dMRI measurement accuracy for each taxon path with 100 micron path precision along the trajectory. We scanned the phase I phantoms at ten sites. We established in empirical studies that there is substantial systematic, cross instrument and measurement error (e.g., 5x the TBI effect size), that the error is stable, and can be corrected for (removed 94% of systematic error). Phase II of this project will: 1) provide the first AdMRI phantom for ground truth measurement to quantify dMRI biophysics, spatial homogeneity, and routing precision; 2) provide fully automated quantification of accuracy and repeatability of measurement; 3) assess AdMRI precision of 20+ sites, quantifying measurement error at 1.5, 3, 7, 9.4 and 14T field strength; and4) develop a set of routing phantoms (Eye>LGN> V1, spinal cord and cortical tracts). These phantoms and/or subcomponents will be measured with non-MRI methods (confocal & electron microscope) using NIST traceable measurements. Researchers and center directors involved in Phase I scanning and reviewing of the results were very positive, with 30+ sites offering free scanning time to use the phantom, and to utilize the resulting quality assurance reports. Radiology has had phantom based pivotal successes (i.e., CT Hounsfield phantoms in the 1990s). This project will deliver a quantitative AdMRI phantom, enabling MRI metrics to become accurate across vendors and time implementing quantitative quality assurance (QQA).

Public Health Relevance Statement:
With no standard for accuracy, the field of MRI imaging has serious concerns about the accuracy of diffusion imaging precision to produce anatomically correct maps of known anatomy. This project will advance the quality and speed of MRI diffusion imaging to provide an anatomically accurate map of brain connectivity, providing quantitative calibration of MRI scans for white matter pathology impacting over 10 million US residents annually for disorders including brain trauma, tumors, developmental disorders, and neurodegenerative disorders at an economic cost of over $80 billion. It will also provide the first viable ground truth calibration of anisotropic diffusion to calibrate US connectome-based imaging with over $316 million dollars of research effort supported by current NIH and Department of Defense research programs.

Project Terms:
3-Dimensional; Algorithms; Anatomy; Animals; Axon; base; Biophysics; Brain; Brain imaging; brain tract; Caliber; Calibration; Clinical; clinically significant; Communities; Computer software; connectome; Corpus Callosum; cost; Data; Data Set; density; Department of Defense; developmental disease; Diffuse; Diffusion; Diffusion Magnetic Resonance Imaging; Dimensions; Disease; economic cost; Electron Microscope; Equipment; Eye; Fiber; Geometry; Goals; Government; Heating; Histology; Human; human tissue; Image; Imaging Phantoms; improved; Industrialization; instrument; Laboratories; Light Microscope; Liquid substance; Magnetic Resonance Imaging; Maps; Measurement; Measures; Methods; microCT; millimeter; Modeling; Monitor; MRI Scans; nanometer; nanoscale; Nanotubes; network models; Neurodegenerative Disorders; open data; Optics; Oxygen; Pathology; pathology imaging; Phase; Physiologic pulse; Polymers; Printing; Production; programs; Publications; Publishing; quality assurance; Quality Control; Radiology Specialty; Reporting; Reproducibility; Research; Research Personnel; Route; Running; Sampling; Scanning; Scoring Method; Ships; Site; Speed; Spinal Cord; Structure; success; System; Taxon; Technology; Temperature; Testing; Textiles; Time; Time Series Analysis; Tissues; Tracer; tractography; Traumatic Brain Injury; Tube; tumor; United States National Institutes of Health; Variant; Vendor; Water; white matter