grant

Label-free optical imaging for human mesoscale connectivity with a focus on deep brain stimulation targets

Organization UNIVERSITY OF MINNESOTALocation MINNEAPOLIS, UNITED STATESPosted 7 Mar 2022Deadline 31 Jan 2027
NIHUS FederalResearch GrantFY20253-D3-Dimensional3DAlgorithmsAnatomic SitesAnatomic structuresAnatomyAnimal ModelAnimal Models and Related StudiesArchitectureAtlasesAxonBirefractionBirefringenceBody TissuesBrainBrain DiseasesBrain DisordersBrain MappingBrain Nervous SystemBrain imagingCell BodyCellsCommon Rat StrainsDWI (diffusion weighted imaging)DWI-MRIDeep Brain StimulationDevelopmentDiffusion MRIDiffusion Magnetic Resonance ImagingDiffusion Weighted MRIDiffusion weighted imagingDiffusion-weighted Magnetic Resonance ImagingDiseaseDisorderDissectionDoppler OCTDouble RefractionEEGElectroencephalogramElectroencephalographyElectron MicroscopyEncephalonEncephalon DiseasesEngineering / ArchitectureFaceFascicleFiberFoundationsFunctional MRIFunctional Magnetic Resonance ImagingFutureGenerationsGoalsHistologicHistologicallyHumanImageImaging technologyInjectionsInternal CapsuleIntracranial CNS DisordersIntracranial Central Nervous System DisordersLabelLaser ElectromagneticLaser RadiationLasersLateralLocationM mulattaM. mulattaMacaca mulattaMacaca rhesusMapsMental disordersMental health disordersMethodsMicroscopicModern ManMotorMotor CortexNerve CellsNerve UnitNervous System DiseasesNervous System DisorderNeural CellNeurocyteNeurologic DisordersNeurological DisordersNeuronsNucleus SubthalamicusOCT TomographyOptical Coherence TomographyOpticsPathway interactionsPatternPerformancePhasePopulationPsychiatric DiseasePsychiatric DisorderRatRats MammalsRattusResolutionRhesus MacaqueRhesus MonkeySamplingStructureStructure of subthalamic nucleusSubthalamic NucleusSynapsesSynapticSystemTechniquesTechnologyThalamic structureThalamusTissuesTracerVisible LightVisible Light RadiationVisible RadiationVisualizationWorkanalytical toolattenuationbrain circuitrybrain tissuebrain visualizationcingulate cortexconnectomedMRIdensitydevelopmentaldiffusion tensor imagingfMRIfacesfacialgray matterhuman imagingimage processingimage-based methodimagingimaging methodimaging modalityimprovedin vivomental illnessmetermodel of animalmultiparametric imagingnano meter scalenano meter sizednanometer scalenanometer sizednanoscaleneural imagingneural tractneuro-imagingneuroimagingneurological diseaseneurological imagingneuronalneurosurgerynon-human primatenonhuman primatenoveloptic imagingopticaloptical Doppler tomographyoptical coherence Doppler tomographyoptical imagingpathwaypolarized lightpsychiatric illnesspsychological disorderquantitative imagingreconstructionresolutionssubstantia albasubstantia griseasynapsetargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmentthalamicthree dimensionaltractographywhite matter
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Full Description

PROJECT SUMMARY AND ABSTRACT
Many neurological and psychiatric disorders are essentially connectionist disorders: certain sets of neurons
have abnormally increased or decreased connectivity with other sets of neurons. Deep brain stimulation
(DBS) therapies target small, unique populations of axons and/or cell bodies in order to treat brain disorders
and normalize connectivity. Thus, mapping the wiring diagram of the brain is an important goal. Macroscale
connectivity has been studied indirectly in humans using noninvasive neuroimaging. In order to develop a
much higher resolution connectivity map of the brain, this project will develop depth-resolved polarized light
imaging to visualize axons and fiber tracts. Since brain imaging and mapping at microscopic resolution is
feasible with intrinsic optical contrasts (e.g. polarization-based) and depth-resolved block-face imaging is
desired before histological processing, we have developed the serial optical coherence scanner (SOCS) for
large-scale or whole brain imaging with microscopic resolution. SOCS combines a polarization-maintaining
fiber based polarization-sensitive optical coherence tomography and a tissue slicer. This project will create a
novel SOCS system that can image axonal tracts at the micron scale spatial resolution using unbiased optical
contrasts (Aim 1). The approach will be evaluated, refined, and compared in the same brain tissue to neural
tract-tracer labeling of tracts associated with DBS targets for brain disorders, in nonhuman animal models
(Aim 2). The approach will then be applied to DBS targets in the human brain (Aim 3). The physical scales at
which this project investigates the brain microstructure are unique (1-10 μm resolution across centimeters of
tissue). This project will pave the way for the foundation of a future human connectome at the micron scale,
which is the highest resolution achievable with current optical technology for imaging an entire human brain.

Grant Number: 5R01MH126923-04
NIH Institute/Center: NIH
Principal Investigator: TANER AKKIN

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