grant

Step 1 in Designing Appropriate Shams and Controls in Human TUS

Organization STANFORD UNIVERSITYLocation STANFORD, UNITED STATESPosted 14 Aug 2023Deadline 31 May 2027
NIHUS FederalResearch GrantFY2025Acoustic Evoked Brain Stem PotentialsAcoustic Evoked Brainstem PotentialsAcoustic StimulationAcousticsAffectAirAnimal ModelAnimal Models and Related StudiesAttentionAuditoryAuditory Brain Stem ResponsesAuditory StimulationAuditory systemBasicraniumBasis craniiBehavioralBrainBrain Nervous SystemBrain regionCell Communication and SignalingCell SignalingCephalicClinical TrialsCochleaCochlear OrganCodeCoding SystemCranialCranial BaseDataData SetDiagnostic ImagingDiseaseDisorderDoseEarplugEncephalonEnvironmentEpilepsyEpileptic SeizuresEpilepticsFrequenciesHearingHumanImageIndividualInternal EarInterventionIntracellular Communication and SignalingInvestigationInvestigatorsLabyrinthLocationLoudnessMR ImagingMR TomographyMRIMRIsMagnetic Resonance ImagingMasksMeasurementMeasuresMedical Imaging, Magnetic Resonance / Nuclear Magnetic ResonanceMental DepressionMental HealthMental HygieneMethodsModern ManMonitorMorphologyNMR ImagingNMR TomographyNervous System DiseasesNervous System DisorderNeurologicNeurologic DisordersNeurologicalNeurological DisordersNoiseNuclear Magnetic Resonance ImagingNucleus AccumbensOutcomePersonsPhasePhysiologicPhysiologic pulsePhysiologicalPlacebo EffectPlacebosPorosityPreclinical dataPredispositionPreparationProceduresPsychological HealthPsychophysicsPulseQualifyingRadiationResearchResearch PersonnelResearchersResolutionRodentRodentiaRodents MammalsSafetyScienceSeizure DisorderSham TreatmentSignal TransductionSignal Transduction SystemsSignalingSiteSkullSliceSonicationSubstance Use DisorderSubstance abuse problemSusceptibilitySystemTechnologyTemporal BoneTemporal bone structureTestingThickThicknessTimeTremorWorkZeugmatographyabuse of substancesagedbehavior measurementbehavior responsebehavioral measurebehavioral measurementbehavioral responsebiological signal transductionbonebone visualizationbrain stem auditory evoked potentialsbrain tissuebrainstem auditory evoked potentialscraniumdepressiondesigndesigningepilepsiaepileptogenicexpectancy effectexpectation effectexperimentexperimental researchexperimental studyexperimentsflexibilityflexibleimagingimaging studyimprovedinner earinnovateinnovationinnovativemodel of animalneural controlneural regulationneurological diseaseneuromodulationneuromodulatoryneuroregulationnocebonon-invasive brain stimulationopen sourceplacebo responsepreclinical findingspreclinical informationpreparationspressureprospectivepsychophysicalresolutionsresponsesham therapyskeletal visualizationskull basesoundsubstance abusesubstance use and disordersubstance use treatmentsuccessultrasoundvibrationviscoelasticity
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Full Description

Project Abstract
The nucleus accumbens (NAc) is a target for non-invasive brain stimulation for the treatment of substance use
disorders (SUDs). Due to its location deep in the brain, transcranial ultrasound stimulation (TUS) is unique
among non-invasive brain stimulation methods to be able to focus on the NAc with high spatial resolution. TUS
has been shown to be safe and effective in animal models. It is currently under active investigation in humans.
However, a major concern in the use of TUS in human studies is the potential for an off-target auditory
stimulation by bone-conducted sound, making the study susceptible to placebo and attention effects, which are
relevant in most studies of neurological disorder interventions. The purpose of this proposed research is to
increase the rigor and safety, and therefore success, of TUS in the treatment of SUDs, and TUS more
generally, thereby enabling truly innovative science. We will do this by accurately quantitating the hearing
response from TUS waveforms in humans, including correlation to skull morphology, and designing and testing
a framework for creating waveforms that reduce audibility while improving masking, all while still providing the
flexibility needed by TUS researchers. We will do this for stimulation waveforms and for MR-ARFI waveforms,
which we show in preclinical data provide a measure of the dose-response to the ultrasound stimulation.

Grant Number: 5R01MH131684-03
NIH Institute/Center: NIH
Principal Investigator: Kim Butts Pauly

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