International Journal of Yoga

: 2022  |  Volume : 15  |  Issue : 3  |  Page : 187--194

Functional connectivity of prefrontal cortex in various meditation techniques – A mini-review

Mrithunjay Rathore1, Meghnath Verma2, Mohit Nirwan2, Soumitra Trivedi1, Vikram Pai3,  
1 Department of Anatomy, AIIMS, Raipur, Chhattisgarh, India
2 Department of AYUSH, CCRYN-CMBIY, AIIMS, Raipur, Chhattisgarh, India
3 Department of Yoga and Naturopathy, AIIMS, Raipur, Chhattisgarh, India

Correspondence Address:
Meghnath Verma
CCRYN-CMBIY, AIIMS Raipur, Chhattisgarh


Meditation is a practice of concentration and relaxation. In philosophical terms, it is a process of gaining self-consciousness. Although there is diversity in meditation (Mindfulness, compassion, transcendental, and focused attention meditation), interventions show that meditation practices improve prefrontal cortex (PFC) functions like cognition, self-awareness, attention, and memory and reduce psychological symptoms. These results are thought to be due to meditation increasing functional connections of different brain regions. We reviewed to show the functional connectivity of the prefrontal cortex in various meditation practices. We were viewed various neuroimaging interventions of functional connectivity associated with the prefrontal cortex and different brain areas during meditation techniques on healthy meditators compared with non-meditators. fMRI findings show that meditation practices are associated with increased neural function and processing, default mode network, gray matter volume, and functional coupling in the brain area related to different parts of PFC. PFC's functional connectivity is associated with increased attention, working memory, cognitive control, executive control, emotion regulation, counteracting adverse effects, self-perception, and self-compassion. Furthermore, PFC's functional connectivity decreases anxiety, depression, perceived stress, negative emotion, and hyperarousal symptoms. In this review, we outlined the published effect of meditation on the function and structure of the different parts of the prefrontal cortex. We suggest a positive theoretical correlation between meditation and the functional connectivity of the prefrontal cortex. Altered prefrontal connectivity is seen in some neurological and psychosocial disorders. Therefore meditation can also play an influential role in treating these disorders.

How to cite this article:
Rathore M, Verma M, Nirwan M, Trivedi S, Pai V. Functional connectivity of prefrontal cortex in various meditation techniques – A mini-review.Int J Yoga 2022;15:187-194

How to cite this URL:
Rathore M, Verma M, Nirwan M, Trivedi S, Pai V. Functional connectivity of prefrontal cortex in various meditation techniques – A mini-review. Int J Yoga [serial online] 2022 [cited 2023 Apr 1 ];15:187-194
Available from:

Full Text


The human brain is a distributed network, but similar functional areas belong together by constantly sharing information. The prefrontal cortex (PFC) is the central structural region that contains executive functions such as planning, solving, working memory, cognition, and social control. It collects information from the environment and uses it intelligently to support thought processes, actions, and decisions. It manages emotions by inhibiting impaired thoughts, actions, and feelings.

In most cases of mental illness, PFC dysfunction is observed in cognitive and executive functions, including anxiety disorders, depression, schizophrenia, and addictive behaviors.[1] Disrupted connectivity is believed to be related to the spread of side effects and could also cause pathological diseases.[2]

Functional connectivity is characterized by the temporal dependence of neural activation schemes of different brain regions.[3] Improved brain connectivity, with all variations, is considered an evolutionary advantage mediated through complex sensorimotor functioning and complex cognitive abilities.[4]

Meditation is a mind–body practice that involves breath awareness, chanting mantras, and controlling thought processes. Meditation leads to a level of inner awareness and stillness.[5] Its philosophy and benefits are described in the oldest Indian texts, such as the Vedas, the Upanishads, the Bhagavad Gita (400600 BC), and the Yoga Sutras (900 BC).[6] In the Patanjali yoga sutra, two stages of meditation are explained, namely Dharana and Dhyana in Sanskrit “desabandhacittasya dharana” (Dharma PYS, Ch. 03, Verse 1), and “tatrapratyayaikatanata dhyanam” (Dhyana in Sanskrit; PYS, Ch. 03, Verse 2.[7] Dharna has focused attention meditation (FAM), and dhyana is effortless mental calmness or open monitoring meditation (OMM).

Different types of meditation affect different parts of the brain.[8] Zeidan et al. showed that mindfulness-mediated pain management was associated with greater activation in brain areas connected to pain's cognitive control, including the dorsolateral PFC (dlPFC), anterior cingulate cortex (ACC), and anterior insular cortex (AIC).[9] Dodich et al. found increased gray matter density due to 4-week Sahaj yoga meditation (SYM) and changes in the consistency of intrinsic cerebral activity in the right inferior frontal gyrus implying the dlPFC, posterolateral parietal areas.[10]

Independent of various meditations, little neuroimaging research has been done on meditation in the context of prefrontal activation and functional connectivity. The review presented helps describe PFC activation and functional connectivity in different types of meditation. In addition, this could be beneficial in generating the hypothesis for future meditation studies in clinical practice.


The data were independently collected from two authors' articles available in PubMed from 2015. The search keywords were “mindfulness Meditation” AND “Open monitoring” AND “Compassion “AND “Prefrontal cortex.” The research was limited to human studies and articles published in English. Conference proceedings, editorials, comments, case reports, and books/chapters were not included. The results obtained were consolidated, and the duplicates were deleted [Figure 1]. The studies were then reviewed by reading the full texts of free available manuscripts, titles, and abstracts of paid articles. Studies that did not stratify the inclusion criteria were excluded [summary of Scientific studies presented in [Table 1]].{Figure 1}{Table 1}

We included studies of changes in brain structure and function observed through meditation. Studies must have meditation or aspects of the program as the intervention and functional and structural magnetic resonance imaging (MRI) as the imaging modality. There was no age range, health status, or ethnicity restrictions. Our main goal is to examine studies that report an activation, deactivation or functional connectivity, or structural changes of PFC due to meditation. Since the spatial resolution of electroencephalography is lower, we have limited the imaging method to functional MRI (FMRI). Unpublished dissertations and conference papers were not considered.


The initial database (PubMed) search indicated 66 potentially eligible articles [Figure 1]. Of these, 43 articles were excluded as they did not meet our review objective.

Activation of the lateral region of prefrontal cortex in different styles of meditation

The PFC is the part of the cerebral cortex overlying the anterior frontal lobe. It is divided into lateral, medial, and inferior regions. The lateral area of the PFC is further divided into dlPFC and ventrolateral (vlPFC). dlPFC extends between the brain's upward longitudinal cleft and downward lateral cleft on the lateral side of the brain and also collects input from the motor cortex, from the temporoparietal junction. The dlPFC and vlPFC are involved in the functioning of attention, decision-making, working memory, and cognitive control.[34] The orbitofrontal cortex (OFC) comprises the inferior surface of the PFC. The functional anatomy of the prefrontal cortex is presented in [Figure 2] and functional connectivity of the prefrontal cortex is presented in [Figure 3].{Figure 2}{Figure 3}

A randomized controlled trial (RCT) performed by Kwak et al. was conducted to assess the effect of a 4-day meditation on the attentional network. Twenty-three experimental groups in meditation practice and 14 control groups in a relaxing retreat group will undergo attention network testing while fMRI imaging is performed before and after the intervention. The experimental group found activation in dlPFC and the ACC.[11] In another study of cognitive, affective neural plasticity conducted by Allen et al., there is greater activation in dlPFC.[12] Tang et al. investigated that meditation might reduce smoking, and fMRI scans increased activity in dlPFC and ACC, brain areas associated with self-control in the meditation group.[13] Taren et al. illustrate the increased functional connectivity of the left dlPFC with the right inferior frontal gyrus, right middle frontal gyrus, right supplementary eye field, right parietal cortex, and left middle temporal gyrus after meditation, brain areas associated with relaxation control.[14]

Similarly, researchers reported increased functional connectivity with the left dlPFC and the posterior cingulate gyrus.[15] King et al. concluded that mindfulness meditation could improve the ability to shift attention. Results showed increased functional connectivity between the default mode and executive network posts. It has also been associated with reducing symptoms of posttraumatic disorders supporting the adjuvant therapeutic use of mindfulness-based therapies.[16] Mahone et al. found that blood flow patterns in the ACC and dlPFC were significantly increased and decreased in the pons and cerebellum while performing transcendental meditation.[17] Weng et al. showed that compassion meditation (CM) is associated with altered activation in the lower parietal cortex and dlPFC. CM increases dlPFC connectivity with the nucleus accumbens.[18] Weng et al. showed that CM was connected with altered activation in brain regions associated with social cognition and emotion regulation, including functional connectivity of dlPFC with the nucleus accumbens; this suggests that the idea of compassion might be generated through meditation training.[18] Another study showed that top-down attentional control activates bilateral dlPFC, increasing meditators' working memory capacity.[21] Mascaro et al. conducted a RCT in which they found increased neural activity in the inferior frontal gyrus and dlPFC after meditation.[23] Yang et al. observed mindfulness meditation-induced neuroplasticity of affective disorders such as depression after 40 days.[22] Mahone et al. found that blood flow patterns during transcendental meditation were higher in the ACC and dlPFC.[17]

Activation of the medial region of prefrontal cortex in different styles of meditation

The medial region of the PFC is divided into dorsomedial (dmPFC) and ventromedial (vmPFC). The dorsomedial component of the PFC lies within an arc that extends downward from the supplementary motor area to the orbital component of the PFC. It is thought that the role of dmPFC is to engage in introspections. It is active in reflecting on the intentions and consequences of actions and in forgiving the transgressions of others.[35] It is speculated that this activity could also modulate stimulus-driven amygdala activity.[36] The dmPFC also responds to interoceptive and exteroceptive stimuli, particularly those encountered in social situations. The dmPFC is activated during the perception of pain in oneself and others. Doll et al. studied the effects of mindfulness on breathing in 26 healthy volunteers for 2 weeks and proposed that dmPFC activations are associated with mindfulness meditation. Furthermore, they found that emotional and functional connectivity between the amygdala and the left dmPFC was increased during mindfulness-on-breath meditation.[24] Laneri D results show increased activations of the anterior insula and cingulate gyrus as well as the dmPFC and temporal pole after long-term mindfulness training.[25] The result of Farb et al. showed the decreased recruitment of the dmPFC during interactive attention in mindfulness meditation.[26] Lutz et al. observed activation in the dmPFC after mindfulness meditation compared to control participants, along with increased functional connectivity to the posterior midline and parietal areas.[31]

vmPFC is located below dmPFC. A key difference to the dmPFC is that the vmPFC receives input from all sensory modalities. It has connections with the ACC, AIC, amygdala, and nucleus accumbens. These structures identify the valence and emotional tone of interoceptive and exteroceptive stimuli. Based on the nature of vmPFC's connections, it modulates social and personal decision-making. Kral et al. Observed short-term meditation practice results in increased functional connectivity between the amygdala and vmPFC during affective imagery, lowering amygdala reactivity to positive imagery than control.[27] Gray matter volume increased significantly in older experienced mediators in the bilateral vmPFC and ACC, insula, temporoparietal junction, and posterior cingulate cortex (PCC) compared to controls.[29] Gray matter volume in vmPFC, including rostral ACC, was increased after SYM. They further demonstrated increased functional connectivity between this area and putamen and decreased functional connectivity with the right thalamus/parahippocampal gyrus while performing the meditation.[30] Lenhart et al. showed reduced gray matter in the right dmPFC.[28]

Activation of the lower region of the orbitofrontal cortex in different meditation

The OFC is defined as the ventral surface of the frontal lobe from the rectus gyrus on the ventral surface to the ventrolateral convexity lateral and from the limen of the insula posterior to the frontal pole. The OFC receives input from the temporal association cortex, the amygdala, and the hypothalamus, making it the highest integration center for emotional processing. It is involved in processing visceromotor states and calculating expected value, reward outcome, and subjectively experienced pleasure.[33] Zeidan observed that mindfulness-based pain relief was associated with greater activation in brain regions associated with cognitive alteration of pain, including OFC and AIC.[9] An fMRI study demonstrated the effect of meditation on relaxing the mind in major depressive disorders, showing increased functional connectivity from the right dl to the left OFC.[37] Meditators who practiced mindfulness of their bodily sensations and emotions showed increased connectivity with the OFC/vmPFC as controls. This area of the brain is strongly connected to limbic regions.

Sevinc et al. observed neural activity after mindfulness meditation. The results showed increased functional connectivity of the right inferior frontal gyrus, a key hub of intentional inhibition and control – with additional motor areas. Mindfulness meditation was associated with a significant increase in right anterior insula functional connectivity – an important hub of sensory perception and emphasis compared to control.[32] An RCT showed improved competency-related behavior and performance on attentional tasks in focused-attention meditators. After the affective image task, the activated regions in meditators were consistent with attention-related processing.

In contrast, control responses were more consistent with the distinction between emotional contagion and compassion/emotional regulation processes.[19] Leung et al. found significantly increased gray matter volume in the right angle and the posterior hippocampal gyri in loving-kindness meditators.[20] The mediators demonstrated superior functional connectivity between the posterior cingulate and left inferior frontal gyrus while performing loving-kindness meditation. These results demonstrate that loving-kindness meditation is associated with a present-centered, selfless focus.

The studies informing functional connectivity and any other effect of PFC following meditation are summarized in [Table 2].{Table 2}


In this review, we have outlined the published effect of meditation on the function and structure of the various parts of the PFC and its connection. The recent trend evident among the research studies reviewed was in favor of various meditations associated with the functional connectivity and activity of the PFC.

The circuits involved in the different styles of meditation are the default mode network (DMN), the salience network (SN), and the central executive network (CEN). The DMN refers to an interconnected group of brain structures, including the vmPFC, PCC, and precuneus.[33] The important connection of the DMN is the hippocampus and the amygdala. Increased activity of the DMN can be observed in mind wandering state.[16] Our finding showed that FAM activates the dlPFC and deactivates the vmPFC. The SN, which has hub nodes in the ACC and anterior insula, responds to socially salient events, integrates autonomic and emotional information, and aids in reward processing.[38] Centered in the dlPFC and the posterior parietal cortex, CEN deals with cognitively demanding mental activity and working memory.[39] FAM activates connectivity between the dlPFC and the posterior parietal cortex.

Instead of drawing attention to objects, just keep your mind open and observe all aspects of our experience (albeit emotions and body awareness) without judgment or attachment, called OMM. Our analysis showed that the neuronal activity of PFC in OMM differs from FAM. FAM is associated with increased dlPFC activity and connectivity in the ACC and right insula compared to OMM. ACC is known as the primary limbic cortex and the cingulate cortex's affective or emotional division. It monitors amygdala sensory stimuli and plays an essential role in the network related to alternation, orientation, and execution function.[40] Coactivator of frontal and parietal and ACC in response to tasks known to activate the cingulate-frontal-parietal network that supports motivation, attention, motor control, and reward processes in healthy individuals. The insular cortex lies deep in the lateral cleft of the cerebral cortex and, together with ACC, is responsible for switching between DMN and SN. Various studies suggest that the maladaptive functional connectivity of the cingulate frontal-parietal network triggers the pathophysiology of psychiatric disorders, for example, altered functional connectivity in the dlPFC, PFC hippocampus, and amygdala pathways in patients with schizophrenia, bipolar disorder, and depression.[41],[42] Many studies have shown that patients with psychiatric disorders have cognitive dysfunctions such as cognitive flexibility[43] and working memory,[44] due to PFC functional connectivity malfunctions. FAM can also be an effective treatment for these disorders. FAM increases functional connectivity and activation of PFC regions and heightens alertness,[45] visuospatial processing,[9] and working memory,[46] and cognitive flexibility.[47] Therefore, considering the recent evidence that increased DMN activity is associated with negative psychological consequences, regular practice of FMA will be the meditation of choice for psychiatric disorders.

Autographic memory is a memory system consisting of episodes retrieved from a person's life based on a combination of episodic or event experiences. The neural core network consists of the left vmPFC and vlPFC, the temporoparietal junction, and the PCC cortex.[48] Our result showed that OMM improved the ability to detach from experiences such as autobiographical memories compared to FAM. The PCC is the part of the brain involved in referential processing, including past and future thinking.[49] Therefore, given recent evidence, regular practice of OMM will disable the neural network of autograph memory.

CM involves cultivating positive emotions such as joy and compassion. FAM showed less emotional reactivity and more activity in the left insula when seeing a happy image and more activity in the inferior and superior frontal gyrus when seeing a sad image. At the same time, CM increased activity in the left ACC and right inferior frontal gyrus in a happy image and higher activity in the left caudate nucleus and medial frontal gyrus. CM experts linking the negative/sad image showed brain activity associated with heightened emotional reactivity and more voluntary emotion regulation. Future studies should focus on meditation training interventions and standard treatments for integration.

Neurobiological improvements are associated with cognition and increased gray matter volume in expert meditation professionals.[29] Therefore, meditation can be an adjunctive treatment to improve gray matter volume and counteract cognitive dysfunction. Impaired cognitive function in individuals affected by Parkinson's disease can be attributed to a reduced hippocampus volume.[50] Meditation practice can play a therapeutic role alongside standard therapy in treating Parkinson's disease, as meditation improves bilateral hippocampal volume.


The different styles of meditation can alter the functional activity and connectivity of the PFC region, which is associated with increased attentional function, working memory, cognitive control, executive control, emotion regulation, countering negative effects, self-awareness, and compassion. The overall increase in functional connectivity and activity of the PFC may explain the decrease in anxiety, depression, perceived stress, negative emotions, and hyperarousal symptoms in meditators. An increase in mindfulness, alertness, and awareness has been demonstrated following meditation training programs, and this positive result can be extrapolated to a clinical population.

Financial support and sponsorship


Conflicts of interest

There are no conflicts of interest.


1Negrón-Oyarzo I, Aboitiz F, Fuentealba P. Impaired functional connectivity in the prefrontal cortex: A mechanism for chronic stress-induced neuropsychiatric disorders. Neural Plast 2016;2016:21–4.
2Pievani M, Filippini N, van den M, Cappa SF, Frisoni GB. Brain Connectivity in neurodegenerative diseases - from phenotype to proteinopathy. Nature Rev Neurol 2014;10:620-33.
3Bijsterbosch JD, Woolrich MW, Glasser MF, Robinson EC, Beckmann CF, Van Essen DC, et al. The relationship between spatial configuration and functional connectivity of brain regions. eLife 2018;7:1–27.
4Iturria-Medina Y, Evans AC. On the central role of brain connectivity in neurodegenerative disease progression. Front Aging Neurosci 2015;7:1–10.
5Canter PH. The therapeutic effects of meditation. BMJ 2003;326:1049-50.
6Sedlmeier P, Eberth J, Schwarz M, Zimmermann D, Haarig F, Jaeger S, et al. The psychological effects of meditation: A meta-analysis. Psychol Bull 2012;138:1139-71.
7EF Bryant. The Yoga Sutras of Patanjali. New York: North Point Press;2009. p. 377-9.
8Manocha R. Why meditation? Aust Fam Physician 2000;29:1135–8.
9Zeidan F, Gordon NS, Merchant J, Goolkasian P. The Effects of Brief Mindfulness Meditation Training on Experimentally Induced Pain. J Pain 2010;11:199–209.
10Dodich A, Zollo M, Crespi C, Cappa SF, Laureiro Martinez D, Falini A, et al. Short-term Sahaja Yoga meditation training modulates brain structure and spontaneous activity in the executive control network. Brain Behav 2019;9:1–11.
11Kwak S, Kim SY, Bae D, Hwang WJ, Cho KIK, Lim KO, et al. Enhanced Attentional Network by Short-Term Intensive Meditation. Front Psychol 2020;10.
12Allen M, Dietz M, Blair KS, van Beek M, Rees G, Vestergaard-Poulsen P, et al. Cognitive-affective neural plasticity following active-controlled mindfulness intervention. J Neurosci 2012;32:15601–10.
13Tang YY, Tang R, Posner MI. Brief meditation training induces smoking reduction. Proc Natl Acad Sci U S A 2013;110:13971–5.
14Taren AA, Gianaros PJ, Greco CM, Lindsay EK, Fairgrieve A, Brown KW, et al. Mindfulness Meditation Training and Executive Control Network Resting State Functional Connectivity: A Randomized Controlled Trial. Psychosom Med 2017;79:674–83.
15Creswell JD, Taren AA, Lindsay EK, Greco CM, Gianaros PJ, Fairgrieve A, et al. Alterations in resting-state functional connectivity link mindfulness meditation with reduced interleukin-6: A randomized controlled trial. Biol Psychiatry 2016;80:53–61.
16King AP, Block SR, Sripada RK, Rauch S, Giardino N, Favorite T, et al. Altered default mode network (dmn) resting state functional connectivity following a mindfulness-based exposure therapy for posttraumatic stress disorder (ptsd) in combat veterans of Afghanistan and Iraq. Depress Anxiety 2016;33:289–99.
17Mahone MC, Travis F, Gevirtz R, Hubbard D. fMRI during Transcendental Meditation practice. Brain Cogn 2018;123:30–3.
18Weng HY, Fox AS, Shackman AJ, Stodola DE, Caldwell JZK, Olson MC, et al. Compassion Training Alters Altruism and Neural Responses to Suffering. Psychol Sci 2013;24:1171–80.
19Lee TMC, Leung MK, Hou WK, Tang JCY, Yin J, So KF, et al. Distinct neural activity associated with focused-attention meditation and loving-kindness meditation. PLoS one 2012;7.
20Leung MK, Chan CCH, Yin J, Lee CF, So KF, Lee TMC. Increased gray matter volume in the right angular and posterior parahippocampal gyri in loving-kindness meditators. Soc Cogn Affect Neurosci 2013;8:34–9.
21Yamaya N, Tsuchiya K, Takizawa I, Shimoda K, Kitazawa K, Tozato F. Effect of one-session focused attention meditation on the working memory capacity of meditation novices: A functional near-infrared spectroscopy study. Brain Behav 2021;11:1–11.
22Yang CC, Barrós-Loscertales A, Pinazo D, Ventura-Campos N, Borchardt V, Bustamante JC, et al. State and training effects of mindfulness meditation on brain networks reflect neuronal mechanisms of its antidepressant effect. Neural Plast 2016;2016.
23Mascaro JS, Rilling JK, Tenzin Negi L, Raison CL. Compassion meditation enhances empathic accuracy and related neural activity. Soc Cogn Affect Neurosci 2013;8:48–55.
24Doll A, Hölzel BK, Mulej Bratec S, Boucard CC, Xie X, Wohlschläger AM, et al. Mindful attention to breath regulates emotions via increased amygdala-prefrontal cortex connectivity. Neuroimage 2016;134:305–13.
25Laneri D, Krach S, Paulus FM, Kanske P, Schuster V, Sommer J, et al. Mindfulness meditation regulates anterior insula activity during empathy for social pain. Hum Brain Mapp 2017;38:4034-46.
26Farb NAS, Segal Z V., Anderson AK. Mindfulness meditation training alters cortical representations of interoceptive attention. Soc Cogn Affect Neurosci 2013;8:15–26.
27Kral TRA, Schuyler BS, Mumford JA, Rosenkranz MA, Lutz A, Davidson RJ. Impact of short- and long-term mindfulness meditation training on amygdala reactivity to emotional stimuli. Neuroimage 2018;181:301–13.
28Lenhart L, Steiger R, Waibel M, Mangesius S, Grams AE, Singewald N, et al. Cortical reorganization processes in meditation naïve participants induced by 7 weeks focused attention meditation training. Behav Brain Res 2020;395:112828.
29Chételat G, Mézenge F, Tomadesso C, Landeau B, Arenaza-Urquijo E, Rauchs G, et al. Reduced age-associated brain changes in expert meditators: A multimodal neuroimaging pilot study. Sci Rep 2017;7:1–11.
30Hernández SE, Barros-Loscertales A, Xiao Y, González-Mora JL, Rubia K. Gray Matter and Functional Connectivity in Anterior Cingulate Cortex are Associated with the State of Mental Silence During Sahaja Yoga Meditation. Neuroscience 2018;371:395–406.
31Lutz J, Brühl AB, Doerig N, Scheerer H, Achermann R, Weibel A, et al. Altered processing of self-related emotional stimuli in mindfulness meditators. Neuroimage 2016;124:958-67.
32Sevinc G, Hölzel BK, Hashmi J, Greenberg J, McCallister A, Treadway M, et al. Common and dissociable neural activity after mindfulness-based stress reduction and relaxation response programs. Psychosom Med 2018;80:439–51.
33Jang JH, Jung WH, Kang DH, Byun MS, Kwon SJ, Choi CH, et al. Increased default mode network connectivity associated with meditation. Neurosci Lett 2011;487:358–62.
34Goldman-Rakic PS. Architecture of the Prefrontal Cortex and the Central executive. Ann N Y Acad Sci 1995;769:71-83.
35Gallagher HL, Frith CD. Functional imaging of theory of mind. Trends Cogn Sci 2003;7:77–83.
36Moreira JFG, Mclaughlin KA, Silvers JA. Characterizing the Network Architecture of Emotion Regulation Neurodevelopment. Cereb Cortex 2021;31:4140–50.
37Chen F, Lv X, Fang J, Yu S, Sui J, Fan L, et al. The effect of body-mind relaxation meditation induction on major depressive disorder: A resting-state fMRI study. J Affect Disord 2015;183:75–82.
38Seeley WW. The salience network: A neural system for perceiving and responding to homeostatic demands. J Neurosci 2019;39:9878–82.
39Heinonen J, Numminen J, Hlushchuk Y, Antell H, Taatila V, Suomala J. Default Mode and Executive Networks Areas: Association with the Serial Order in Divergent Thinking. PLoS One 2016;11:162234.
40Medford N, Critchley HD. Conjoint activity of anterior insular and anterior cingulate cortex: awareness and response. Brain Struct Funct 2010;214:535–49.
41Yu Y, Shen H, Zeng LL, Ma Q, Hu D. Convergent and Divergent Functional Connectivity Patterns in Schizophrenia and Depression. PLoS One 2013;8.
42Ye T, Peng J, Nie B, Gao J, Liu J, Li Y, et al. Altered functional connectivity of the dorsolateral prefrontal cortex in first-episode patients with major depressive disorder. Eur J Radiol 2012;81:4035-40.
43Austin MP, Mitchell P, Goodwin GM. Cognitive deficits in depression: Possible implications for functional neuropathology. Br J Psychiatry 2001;178:200–6.
44Park S, Holzman PS. Schizophrenics Show Spatial Working Memory Deficits. Arch Gen Psychiatry 1992;49:975–82.
45Malinowski P. Neural mechanisms of attentional control in mindfulness meditation. Front Neurosci 2013;7:1–11.
46Quach D, Jastrowski Mano KE, Alexander K. A Randomized Controlled Trial Examining the Effect of Mindfulness Meditation on Working Memory Capacity in Adolescents. J Adolesc Health 2016;58:489–96.
47Marciniak R, Sheardova K, Čermáková P, Hudeček D, Šumec R, Hort J. Effect of meditation on cognitive functions in context of aging and neurodegenerative diseases. Front Behav Neurosci 2014;8:1–9.
48Inman CS, James GA, Vytal K, Hamann S. Dynamic changes in large-scale functional network organization during autobiographical memory retrieval. Neuropsychologia 2018;110:208–24.
49Brewer JA, Garrison KA, Whitfield-Gabrieli S. What about the “Self” is Processed in the Posterior Cingulate Cortex? Front Hum Neurosci 2013;7.
50Lehrner J, Kogler S, Lamm C, Moser D, Klug S, Pusswald G, et al. Awareness of memory deficits in subjective cognitive decline, mild cognitive impairment, Alzheimer's disease and Parkinson's disease. Int Psychogeriatr 2014;27:357–66.