{"corpus_id":36145263,"paper_sha":"7b972367c2998043fefd6c0c17b1f15d79b8be37","doi":"10.1002/hbm.24348","arxiv_id":null,"pmid":30120846,"pmcid":"PMC6866502","mag_id":2593653380,"dblp_id":null,"acl_id":null,"title":"The Neural Basis of Motivational Influences on Cognitive Control","year":2017,"publication_date":"2017-03-02","venue":"bioRxiv","journal":{"name":"bioRxiv","pages":null,"volume":null},"journal_issn":null,"journal_title":null,"publication_types":["JournalArticle"],"pubmed_pub_types":["Journal Article","Meta-Analysis"],"s2_fields_of_study":["Biology","Medicine","Psychology"],"reference_count":231,"citation_count":68,"influential_citation_count":6,"is_open_access":true,"arxiv_categories":null,"arxiv_license":null,"arxiv_journal_ref":null,"mesh_headings":[{"d":"Brain","mj":false,"qs":[{"q":"diagnostic imaging","mj":false,"ui":"Q000000981"},{"q":"physiology","mj":true,"ui":"Q000502"}],"ui":"D001921"},{"d":"Executive Function","mj":false,"qs":[{"q":"physiology","mj":true,"ui":"Q000502"}],"ui":"D056344"},{"d":"Functional Neuroimaging","mj":false,"qs":[{"q":"methods","mj":true,"ui":"Q000379"}],"ui":"D059907"},{"d":"Humans","mj":false,"ui":"D006801"},{"d":"Motivation","mj":false,"qs":[{"q":"physiology","mj":true,"ui":"Q000502"}],"ui":"D009042"},{"d":"Nerve Net","mj":false,"qs":[{"q":"diagnostic imaging","mj":false,"ui":"Q000000981"},{"q":"physiology","mj":true,"ui":"Q000502"}],"ui":"D009415"},{"d":"Reward","mj":true,"ui":"D012201"}],"chemicals":null,"comments_corrections":null,"source_flags":5,"s2_open_access_pdf_url":"https://onlinelibrary.wiley.com/doi/pdfdirect/10.1002/hbm.24348","s2_open_access_landing_url":"https://www.semanticscholar.org/paper/7b972367c2998043fefd6c0c17b1f15d79b8be37","s2_open_access_license":null,"s2_open_access_status":"BRONZE","pmc_open_access_pdf_url":null,"pmc_open_access_landing_url":null,"pmc_open_access_license":null,"pmc_open_access_status":null,"unpaywall_open_access_pdf_url":null,"unpaywall_open_access_landing_url":null,"unpaywall_open_access_license":null,"unpaywall_open_access_status":null,"abstract":"Cognitive control mechanisms support the deliberate regulation of thought and behavior based on current goals. Recent work suggests that motivational incentives improve cognitive control, and has begun to elucidate the brain regions that may support this effect. Here, we conducted a quantitative meta-analysis of neuroimaging studies of motivated cognitive control using activation likelihood estimation (ALE) and Neurosynth in order to delineate the brain regions that are consistently activated across studies. The analysis included functional neuroimaging studies that investigated changes in brain activation during cognitive control tasks when reward incentives were present versus absent. The ALE analysis revealed consistent recruitment in regions associated with the frontoparietal control network including the inferior frontal sulcus (IFS) and intraparietal sulcus (IPS), as well as consistent recruitment in regions associated with the salience network including the anterior insula and anterior mid-cingulate cortex (aMCC). A large-scale exploratory meta-analysis using Neurosynth replicated the ALE results, and also identified the caudate nucleus, nucleus accumbens, medial thalamus, inferior frontal junction/premotor cortex (IFJ/PMC), and hippocampus. Finally, we conducted separate ALE analyses to compare recruitment during cue and target periods, which tap into proactive engagement of rule-outcome associations, and the mobilization of appropriate viscero-motor states to execute a response, respectively. We found that largely distinct sets of brain regions are recruited during cue and target periods. Altogether, these findings suggest that flexible interactions between frontoparietal, salience, and dopaminergic midbrain-striatal networks may allow control demands to be precisely tailored based on expected value.","claims":[{"public_id":"cl_23dce1b56e2c848d7c6503338cc259d1","status":"active","text":"Activation likelihood estimation identified the inferior frontal sulcus, intraparietal sulcus, anterior insula, and anterior mid-cingulate cortex as consistently activated across the analyzed studies.","confidence":0.97,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous (12632b8b5f)","roles":["extraction"],"url":"https://sah.borca.ai/u/12632b8b5f"}],"url":"https://sah.borca.ai/claims/cl_23dce1b56e2c848d7c6503338cc259d1"},{"public_id":"cl_d15e65a2f8b11086a40f3da0b9030975","status":"active","text":"Cue and target periods recruit largely distinct sets of brain regions during motivated cognitive control.","confidence":0.94,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous (12632b8b5f)","roles":["extraction"],"url":"https://sah.borca.ai/u/12632b8b5f"}],"url":"https://sah.borca.ai/claims/cl_d15e65a2f8b11086a40f3da0b9030975"},{"public_id":"cl_47b4b37be1a3fb17b9aa0612564a8c00","status":"active","text":"Flexible interactions between frontoparietal, salience, and dopaminergic midbrain-striatal networks may allow control demands to be tailored to expected value.","confidence":0.88,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous (12632b8b5f)","roles":["extraction"],"url":"https://sah.borca.ai/u/12632b8b5f"}],"url":"https://sah.borca.ai/claims/cl_47b4b37be1a3fb17b9aa0612564a8c00"},{"public_id":"cl_f0b8f02139eaf242e1204651dd1deda0","status":"active","text":"Motivational incentives during cognitive control tasks consistently recruit regions in the frontoparietal control network and the salience network.","confidence":0.98,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous (12632b8b5f)","roles":["extraction"],"url":"https://sah.borca.ai/u/12632b8b5f"}],"url":"https://sah.borca.ai/claims/cl_f0b8f02139eaf242e1204651dd1deda0"},{"public_id":"cl_a135ce3b08026a93b4a5ca5340109288","status":"active","text":"Neurosynth replicated the ALE results and additionally identified the caudate nucleus, nucleus accumbens, medial thalamus, inferior frontal junction/premotor cortex, and hippocampus.","confidence":0.96,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous (12632b8b5f)","roles":["extraction"],"url":"https://sah.borca.ai/u/12632b8b5f"}],"url":"https://sah.borca.ai/claims/cl_a135ce3b08026a93b4a5ca5340109288"}],"concepts":[{"public_id":"co_01b538307ef00d16d3da1ebb91e8487c","status":"active","name":"dopaminergic midbrain-striatal networks","description":"Dopamine-related circuits linking midbrain and striatal structures.","types":["brain 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