2024
Androgen deprivation increases frontopolar cortical thickness in prostate cancer patients: an effect of early neurodegeneration?
Chaudhary S, Roy A, Summers C, Ahles T, Li C, Chao H. Androgen deprivation increases frontopolar cortical thickness in prostate cancer patients: an effect of early neurodegeneration? American Journal Of Cancer Research 2024, 14: 3652-3664. PMID: 39113873, PMCID: PMC11301281, DOI: 10.62347/wola8904.Peer-Reviewed Original ResearchFrontopolar cortexCortical thicknessWorking memoryAndrogen deprivation therapyN-back performanceN-back taskProstate cancer patientsYears of educationPublished routinesNeural consequencesBrain changesBrain morphologyMediation analysisCT changesConsequences of androgen deprivation therapyMonths of androgen deprivation therapyTestosterone level changesImpact of androgen deprivation therapyCancer patientsNon-metastatic prostate cancerTestosterone levelsResponse to androgen deprivationLong duration of treatmentBrain imagingNeurodegenerative changes
2016
Central nervous system regulation of eating: Insights from human brain imaging
Farr OM, Li CS, Mantzoros CS. Central nervous system regulation of eating: Insights from human brain imaging. Metabolism 2016, 65: 699-713. PMID: 27085777, PMCID: PMC4834455, DOI: 10.1016/j.metabol.2016.02.002.Peer-Reviewed Original ResearchConceptsCentral nervous systemCentral nervous system regulationOvereating/obesityBody weight regulationNervous system regulationWeight regulationNervous systemEnergy homeostasisObesity researchAvailable evidenceBrain imagingRespective underlying mechanismsAppetiteHomeostatic controlClinical researchersUnderlying mechanismHuman brain imagingSystem regulationHuman brainExact relative contributionObesityHumansHypothalamusPathogenesisCentral role
2015
Response Inhibition
Li C. Response Inhibition. 2015, 303-317. DOI: 10.1016/b978-0-12-397025-1.00248-7.Peer-Reviewed Original ResearchResponse inhibitionRight inferior frontal cortexStimulus-driven processesMotor response inhibitionInferior frontal cortexPresupplementary motor areaFunctional brain imagingIndividual brain regionsPsychological constructsNeural substratesComponent processesBehavioral paradigmsReactive controlMotor areaBrain regionsFrontal cortexBrain imagingConceptual frameworkCortexConstructsParadigmDistinctionMonkeys
2013
Neural bases of individual variation in decision time
Hu S, Tseng Y, Winkler AD, Li C. Neural bases of individual variation in decision time. Human Brain Mapping 2013, 35: 2531-2542. PMID: 24027122, PMCID: PMC4511156, DOI: 10.1002/hbm.22347.Peer-Reviewed Original ResearchConceptsStop-signal reaction timeSupplementary motor areaNeural basisSignal taskMovement timeTrial reaction timeStop-signal taskSignal reaction timeCaudate headReaction timeCognitive controlResponse inhibitionResponse selectionIndividual variationAccumulator modelBehavioral performanceComponent processesDecision timeLonger movement timesHuman behaviorMotor areaSimple taskBrain imagingSuccessful goTask
2009
A neural measure of behavioral engagement: Task-residual low-frequency blood oxygenation level-dependent activity in the precuneus
Zhang S, Li CS. A neural measure of behavioral engagement: Task-residual low-frequency blood oxygenation level-dependent activity in the precuneus. NeuroImage 2009, 49: 1911-1918. PMID: 19761851, PMCID: PMC2791356, DOI: 10.1016/j.neuroimage.2009.09.004.Peer-Reviewed Original ResearchConceptsBlood oxygenation level-dependent activityRegional brain activationLevel-dependent activityTask engagementNeural measuresNeural processesBrain activationPosterior cingulate cortexAttentional monitoringResponse inhibitionHuman cognitionPrefrontal activationSignal taskGreater activationBOLD activityBehavioral engagementCingulate cortexPrecuneusBrain regionsLow-frequency fluctuationsFractional amplitudeBrain imagingSeed regionIndependent component analysisEngagement