At the core of reasoning: Dissociating deductive and non‐deductive load

Coetzee, John P.; Monti, Martin M.

doi:10.1002/hbm.23979

Cited by 33 publications

(65 citation statements)

References 73 publications

(180 reference statements)

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“…Rather than recruiting perisylvian fronto-temporal areas, mathematics and logic recruit a frontoparietal network, including the dorsolateral prefrontal cortex and the intraparietal sulcus (IPS) as well as putative symbol representations (i.e. numberform area) in inferior temporal cortex (Amalric & Dehaene, 2016;Coetzee & Monti, 2018;Goel et al, 2007;Monti, Parsons, & Osherson, 2009). This fronto-parietal network overlaps partially with the so called central executive/working memory system, which is implicated in a variety of cognitive tasks that involve maintaining and manipulating information in working memory, processes that are part and parcel of understanding and writing code (Brooks, 1977;Duncan, 2010;Letovsky, 1987;Miller & Cohen, 2001;Soloway & Ehrlich, 1984;Weinberg, 1971;Zanto & Gazzaley, 2013)(for a review of the cognitive models of code comprehension, see (Von Mayrhauser & Vans, 1995)).…”

Section: Introductionmentioning

confidence: 99%

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Computer code comprehension shares neural resources with formal logical inference in the fronto-parietal network

Liu

Kim

Wilson

et al. 2020

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Despite the importance of programming to modern society, the cognitive and neural bases of code comprehension are largely unknown. Programming languages might 'recycle' neurocognitive mechanisms originally used for natural languages. Alternatively, comprehension of code could depend on fronto-parietal networks shared with other culturally derived symbol systems, such as formal logic and math. Expert programmers (average 11 years of programming experience) performed code comprehension and memory control tasks while undergoing fMRI. The same participants also performed language, math, formal logic, and executive control localizer tasks. A left-lateralized fronto-parietal network was recruited for code comprehension. Patterns of activity within this network distinguish between "for" loops and "if" conditional code functions. Code comprehension overlapped extensively with neural basis of formal logic and to a lesser degree math. Overlap with simpler executive processes and language was low, but laterality of language and code covaried across individuals. Cultural symbol systems, including code, depend on a distinctive fronto-parietal cortical network.

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Section: Introductionmentioning

confidence: 99%

“…Logic and math activate a similar network but also have unique neural signatures. Within the prefrontal cortex, logic recruits more anterior regions associated with more advanced forms of reasoning and symbol manipulation (Coetzee & Monti, 2018;Ramnani & Owen, 2004).…”

Section: Introductionmentioning

confidence: 99%

Computer code comprehension shares neural resources with formal logical inference in the fronto-parietal network

Liu

Kim

Wilson

et al. 2020

Preprint

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“…This should have been perhaps 157 expected, given the general understanding that deduction might well rely on the 158 "concerted operation of several, functionally distinct, brain areas" [43], thus making it a 159 harder process to disrupt with single-location stimulation. Consistent with this 160 understanding, we have previously voiced the view that "core" deductive processes 161 might be implemented in multiple brain areas, including both the mesial BA8 target as 162 well as left rostrolateral prefrontal cortex, in BA10 [28,33]. 163 The lack of a cTBS effect on three versus four variable items is relevant to two 164 ongoing debates.…”

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confidence: 87%

“…??a). Given the randomized task order, a small "M" or "G" 283 block letter at the top left of the screen served as a reminder of which tasks participants 284 were expected to perform at each trial (as we have done in previous work [28]).…”

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confidence: 99%

“…The trial terminated upon button-press or 291 upon the elapsing of the allotted 15 For each participant, the FMIRB Software Library (FSL) [49] was used to transform the 295 individual T1-weighted structural MRI -which had been obtained, with consent, from 296 previous studies they had taken part in -into standard space (MNI template space). [25,28], and a control site in the LTOS (x = -25, 301 y = -85, z = 25) [32]. Two additional targets were used for the active motor 302 thresholding (AMT) procedure.…”

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confidence: 99%

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Dissociating language and thought in human reasoning

Coetzee

Johnson

et al. 2018

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What is the relationship between natural language and complex thought? In the context of complex reasoning, there are two main views on this question. Under the first, language sits at the center of the ability to process the syntax-like combinatorial operations necessary for various forms of complex reasoning, such as deductive reasoning. Under the second, these operations are independent of the mechanisms of natural language. We used noninvasive brain stimulation to assess the effects of transient inhibition of neural activity in targeted neural systems. If language and deductive reasoning can be shown to be dissociable with this approach, then the hypothesis that language is crucial to deductive reasoning can be ruled out. We inhibited Broca's area, a region associated in prior research with parsing the syntactic relations of natural language, and dorsomesial frontal cortex, a region previously described as core for logic reasoning. We tested the effects of perturbing activity in these areas on processing the syntactic operations of natural language and the syntax-like operations of deductive logic. The dissociative hypothesis of language and deductive reasoning predicts an interaction between stimulated areas and tested functions, which we observed. This interaction demonstrates that the effects of brain perturbation are reliably different at the two stimulated sites (Broca's area and dorsomesial prefrontal cortex) and for the two functional processes (language and thought). Transient inhibition of Broca's area disrupted linguistic processing without affecting deductive reasoning, whereas transient inhibition of dorsomesial frontal cortex exhibited the reverse pattern, albeit to a lesser degree. These results are evidence for the independence of abstract complex reasoning from natural language, at least in the adult brain. (236 words) Whether complex cognition is enabled by or founded upon the mechanisms of natural language has long been debated in many fields, including philosophy, psychology, and, more recently, neuroscience. In the context of human reasoning, some view language as central to inference-making, while others view this ability as independent of the mechanisms of natural language. Using a neuromodulatory approach, we show that it is possible to disrupt the neural mechanisms of natural language without affecting reasoning and vice versa. This result provides the first causal evidence that in the adult brain logic reasoning is independent of the mechanisms of natural language.Introduction 1 Does language shape human cognition [1][2][3][4][5]? This question is generally framed within 2 two opposite positions: the communicative conception of language, in which language is 3 viewed primarily as an inert means of communicating preexisting (i.e., non-linguistic) 4 mental representations from one mind to another through a mutually intelligible code, 5 and the cognitive conception of language, in which language is viewed as constitutively 6 involved in human cognition and the medium of thought [6]. 7A u...

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