2024
Researching COVID to enhance recovery (RECOVER) pediatric study protocol: Rationale, objectives and design
Gross R, Thaweethai T, Rosenzweig E, Chan J, Chibnik L, Cicek M, Elliott A, Flaherman V, Foulkes A, Witvliet M, Gallagher R, Gennaro M, Jernigan T, Karlson E, Katz S, Kinser P, Kleinman L, Lamendola-Essel M, Milner J, Mohandas S, Mudumbi P, Newburger J, Rhee K, Salisbury A, Snowden J, Stein C, Stockwell M, Tantisira K, Thomason M, Truong D, Warburton D, Wood J, Ahmed S, Akerlundh A, Alshawabkeh A, Anderson B, Aschner J, Atz A, Aupperle R, Baker F, Balaraman V, Banerjee D, Barch D, Baskin-Sommers A, Bhuiyan, Bind M, Bogie A, Bradford T, Buchbinder N, Bueler E, Bükülmez H, Casey B, Chang L, Chrisant M, Clark D, Clifton R, Clouser K, Cottrell L, Cowan K, D’Sa V, Dapretto M, Dasgupta S, Dehority W, Dionne A, Dummer K, Elias M, Esquenazi-Karonika S, Evans D, Faustino E, Fiks A, Forsha D, Foxe J, Friedman N, Fry G, Gaur S, Gee D, Gray K, Handler S, Harahsheh A, Hasbani K, Heath A, Hebson C, Heitzeg M, Hester C, Hill S, Hobart-Porter L, Hong T, Horowitz C, Hsia D, Huentelman M, Hummel K, Irby K, Jacobus J, Jacoby V, Jone P, Kaelber D, Kasmarcak T, Kluko M, Kosut J, Laird A, Landeo-Gutierrez J, Lang S, Larson C, Lim P, Lisdahl K, McCrindle B, McCulloh R, McHugh K, Mendelsohn A, Metz T, Miller J, Mitchell E, Morgan L, Müller-Oehring E, Nahin E, Neale M, Ness-Cochinwala M, Nolan S, Oliveira C, Osakwe O, Oster M, Payne R, Portman M, Raissy H, Randall I, Rao S, Reeder H, Rosas J, Russell M, Sabati A, Sanil Y, Sato A, Schechter M, Selvarangan R, Tejtel S, Shakti D, Sharma K, Squeglia L, Srivastava S, Stevenson M, Szmuszkovicz J, Talavera-Barber M, Teufel R, Thacker D, Trachtenberg F, Udosen M, Warner M, Watson S, Werzberger A, Weyer J, Wood M, Yin H, Zempsky W, Zimmerman E, Dreyer B, Consortium O. Researching COVID to enhance recovery (RECOVER) pediatric study protocol: Rationale, objectives and design. PLOS ONE 2024, 19: e0285635. PMID: 38713673, PMCID: PMC11075869, DOI: 10.1371/journal.pone.0285635.Peer-Reviewed Original ResearchConceptsYoung adultsClinical courseAdolescent Brain Cognitive DevelopmentCaregiver-child pairsLong-term outcomesObservational cohort studyOutcomes of COVID-19De novo cohortAdolescent Brain Cognitive Development StudySociodemographic correlatesCommunity partnersBaseline assessmentLongitudinal follow-upPotential therapeutic interventionsPediatric protocolsCohort studyCollaborative partnershipsProspective cohortFollow-upStudy protocolFederal partnersNIH Researching COVIDLong-term outcomes of COVID-19Enhanced recoveryData collection
2021
Parental Buffering of Stress in the Time of COVID-19: Family-Level Factors May Moderate the Association Between Pandemic-Related Stress and Youth Symptomatology
Cohodes EM, McCauley S, Gee DG. Parental Buffering of Stress in the Time of COVID-19: Family-Level Factors May Moderate the Association Between Pandemic-Related Stress and Youth Symptomatology. Research On Child And Adolescent Psychopathology 2021, 49: 935-948. PMID: 33591457, PMCID: PMC7885749, DOI: 10.1007/s10802-020-00732-6.Peer-Reviewed Original ResearchConceptsPandemic-related stressChild symptomatologyAnxiety-related symptomatologyYouth symptomatologyFamily-level factorsCross-sectional study designCOVID-19-related stressYouth mental healthEffects of exposureParental bufferingStudy designSymptomatologyMental healthChildren's exposureParental reportsHigh levelsCOVID-19COVID-19 pandemicNegative emotionsGlobal pandemicDegree of stressExposureLight of evidenceHome routinesParenting stress
2016
Stimulus-Elicited Connectivity Influences Resting-State Connectivity Years Later in Human Development: A Prospective Study
Gabard-Durnam LJ, Gee DG, Goff B, Flannery J, Telzer E, Humphreys KL, Lumian DS, Fareri DS, Caldera C, Tottenham N. Stimulus-Elicited Connectivity Influences Resting-State Connectivity Years Later in Human Development: A Prospective Study. Journal Of Neuroscience 2016, 36: 4771-4784. PMID: 27122035, PMCID: PMC4846673, DOI: 10.1523/jneurosci.0598-16.2016.Peer-Reviewed Original ResearchConceptsMedial prefrontal cortexFunctional connectivityAmygdala-medial prefrontal cortex circuitInferior frontal gyrusResting-state functional networksFunctional architectureResting-state connectivityAmygdala functional connectivityFunctional network architecturePrefrontal cortex circuitAmygdala-mPFC circuitResting-state networksFunctional connectionsEmotional stimuliCourse of developmentFrontal gyrusAge-related changesPrefrontal cortexMotivate future investigationsCortex circuitPredictive associationsSensitive periodFunctional networksDevelopmental periodBrain functionIndividual differences in frontolimbic circuitry and anxiety emerge with adolescent changes in endocannabinoid signaling across species
Gee DG, Fetcho RN, Jing D, Li A, Glatt CE, Drysdale AT, Cohen AO, Dellarco DV, Yang RR, Dale AM, Jernigan TL, Lee FS, Casey BJ, Jernigan T, San Diego U, McCabe C, San Diego U, Chang L, Hawaii U, Akshoomoff N, San Diego U, Newman E, San Diego U, Dale A, San Diego U, Core M, Ernst T, Hawaii U, Dale A, San Diego U, Van Zijl P, Kuperman J, San Diego U, Murray S, Bloss C, Schork N, Appelbaum M, San Diego U, Gamst A, San Diego U, Thompson W, San Diego U, Bartsch H, San Diego U, Jernigan T, Dale A, Akshoomoff N, Chang L, Ernst T, Keating B, Amaral D, Sowell E, Kaufmann W, Van Zijl P, Mostofsky S, Casey B, Ruberry E, Powers A, Rosen B, Kenet T, Frazier J, Kennedy D, University Y, Gruen J. Individual differences in frontolimbic circuitry and anxiety emerge with adolescent changes in endocannabinoid signaling across species. Proceedings Of The National Academy Of Sciences Of The United States Of America 2016, 113: 4500-4505. PMID: 27001846, PMCID: PMC4843434, DOI: 10.1073/pnas.1600013113.Peer-Reviewed Original ResearchConceptsFatty acid amide hydrolaseAnxiety-related behaviorGene expressionFrontolimbic circuitryEndocannabinoid signalingAnxiety disordersNeural circuit maturationPostnatal day 45Phenotypic differencesFrontoamygdala circuitryAnandamide levelsGenetic effectsAEA levelsBiological stateIndividual differencesCircuit maturationGenetic alterationsFAAH genotypeMouse modelDevelopmental neurobiologyLevels of analysisAdolescent changesDevelopmental windowAmide hydrolaseBrain circuitry
2014
Maternal Buffering of Human Amygdala-Prefrontal Circuitry During Childhood but Not During Adolescence
Gee DG, Gabard-Durnam L, Telzer EH, Humphreys KL, Goff B, Shapiro M, Flannery J, Lumian DS, Fareri DS, Caldera C, Tottenham N. Maternal Buffering of Human Amygdala-Prefrontal Circuitry During Childhood but Not During Adolescence. Psychological Science 2014, 25: 2067-2078. PMID: 25280904, PMCID: PMC4377225, DOI: 10.1177/0956797614550878.Peer-Reviewed Original ResearchConceptsAmygdala-prefrontal circuitryMaternal bufferingMaternal stimuliAmygdala-prefrontal connectivityMature connectivityAmygdala reactivityPotential mechanismsMaternal modulationChildhoodMother-child relationshipNeural mechanismsSensitive periodChildrenCaregiversMaternal influenceRegulatory influenceAdolescenceStimuliBehavioral regulationNeurocircuitryCircuitry
2013
Early developmental emergence of human amygdala–prefrontal connectivity after maternal deprivation
Gee DG, Gabard-Durnam LJ, Flannery J, Goff B, Humphreys KL, Telzer EH, Hare TA, Bookheimer SY, Tottenham N. Early developmental emergence of human amygdala–prefrontal connectivity after maternal deprivation. Proceedings Of The National Academy Of Sciences Of The United States Of America 2013, 110: 15638-15643. PMID: 24019460, PMCID: PMC3785723, DOI: 10.1073/pnas.1307893110.Peer-Reviewed Original ResearchConceptsMaternal deprivationAmygdala-mPFC connectivityEarly adversityEarly maternal deprivationAmygdala-prefrontal connectivityMature connectivityRodent modelsReduced anxietyAdolescent phenotypeHormone cortisolEarly developmental emergenceStress-induced modificationsDeprivationComparison childrenConnectivity patternsChildrenDevelopmental emergenceAnxietyPhenotypeInstitutionalized youthAmygdalaAdversityCortisolOntogenetic adaptationA Developmental Shift from Positive to Negative Connectivity in Human Amygdala–Prefrontal Circuitry
Gee DG, Humphreys KL, Flannery J, Goff B, Telzer EH, Shapiro M, Hare TA, Bookheimer SY, Tottenham N. A Developmental Shift from Positive to Negative Connectivity in Human Amygdala–Prefrontal Circuitry. Journal Of Neuroscience 2013, 33: 4584-4593. PMID: 23467374, PMCID: PMC3670947, DOI: 10.1523/jneurosci.3446-12.2013.Peer-Reviewed Original ResearchConceptsAmygdala-prefrontal circuitryFunctional connectivityNegative connectivityAmygdala reactivityRecent human imagingParticipants 10 yearsTask-based functional magnetic resonance imagingNegative functional connectivityFunctional magnetic resonance imagingMagnetic resonance imagingAmygdala-prefrontal connectivityAmygdala-cortical connectivityAnxiety-related disordersFrontoamygdala circuitryAnimal studiesReciprocal connectionsResonance imagingTracing studyPositive connectivityAdolescent periodEarly childhoodNeurobiological basisEmotional behaviorPresent studyDevelopmental changes