User:Dmodi6/Neural Mechanisms of Mindfulness Meditation

Mindfulness Meditation

Introduction

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Mindfulness is simply paying attention to thoughts, emotions, and body sensations in response to a conflicting stimulus and reacting in a non-judgmental manner. Meditation is a platform used to achieve mindfulness. This practice originated from the idea of mindfulness in Buddhism and has been widely promoted by Jon Kabat-Zinn. It has been shown to have a positive impact on several psychiatric problems such as depression and therefore has been adopted in mindfulness programs.[1] Examples of these programs include mindfulness-based cognitive therapy and mindfulness-based stress reduction. The applications of mindfulness meditation are well established and several attempts have been made to break down the components of mindfulness meditation. However, the mechanisms that underlie this practice remain relatively unexplored.

Components of Mindfulness Meditation

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Although several components for mindfulness meditation have been proposed, four components have found to be common among most: attention regulation, body awareness, emotion regulation, and change in perspective on the self.[2] All of the components described above are connected to each other. For example, when a person is triggered by an external stimuli, the executive attention system attempts to maintain a mindful state. There is also a heightened body awareness such as a rapid heartbeat which triggers an emotional response. The response is then regulated so that it does not become habitual, but constantly changes from moment to moment experience. This eventually leads to a change in the perspective of the self.

Attention Regulation

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Anterior cingulate cortex

Attention regulation is the task of focusing attention on an object, acknowledging any distractions, and then returning your focus back to the object. Some evidence for mechanisms responsible for attention regulation during mindfulness meditation are shown below.

  • Mindfulness meditators showed greater activation of rostral ACC and dorsal medial-prefrontal cortex (MPFC). [3] This suggests that meditators have a stronger processing of conflict/distraction and are more engaged in emotional regulation. However as the meditators become more efficient at focused attention, regulation becomes unnecessary and consequentially decreases activation of ACC in the long term. [4]
  • The cortical thickness in the dorsal ACC was also found to be greater in the of gray matter of experienced meditators. [5]
  • There is an increased frontal midline theta rhythm, which is related to attention demanding tasks and is believed to be indicative of ACC activation. [6]

The anterior cingulate cortex (ACC) detects conflicting information coming from distractions. When a person is presented with conflicting stimulus, the brain initially processes the stimulus incorrectly. This is known as error-related negativity (ERN). Before the ERN reaches a threshold, the correct conflict is detected by the frontocentral N2. After the correction, the rostral ACC is activated and allows for executive attention to the correct stimulus. [7] Therefore, mindfulness meditation could potentially be a method for treating attention related disorders such as ADHD and bipolar disorder.

Body Awareness

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Gray matter & Insula

Body awareness refers to focusing on an object/task within the body such as breathing. From a qualitative interview with ten mindfulness meditators, some of the following responses were observed: "When I'm walking, I deliberately notice the sensations of my body moving" and "I notice how foods and drinks affect my thoughts, bodily sensations, and emotions”. [8] The two possible mechanisms by which a mindfulness meditator can experience body awareness are discussed below.

  • Meditators showed a greater cortical thicknesss [9] and greater gray matter concentration in the right anterior insula. [10]
  • On the contrary, subjects who had undergone 8 weeks of mindfulness training showed no signficant change in gray matter concentration of the insula, but rather an increase gray matter concentration of the temporo-parietal junction. [11]

The insula is responsible for awareness to stimuli and the thickness of its gray matter correlates to the accuracy and detection of the stimuli by the nervous system. [12] [13] Since there is no quantitative evidence suggesting that mindfulness meditation impacts body awareness, this component is not well understood.

Emotion Regulation

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Emotions can be regulated cognitively or behaviorally. Cognitive regulation (in terms of mindfulness meditation) means having control over giving attention to a particular stimuli or by changing the response to that stimuli.The cognitive change is achieved through reappraisal (interpreting the stimulus in a more positive manner) and extinction (reversing the response to the stimulus). Behavioral regulation refers to inhibiting the expression of certain behaviors in response to a stimuli. Research suggests two main mechanisms for how mindfulness meditation influences the emotional response to a stimuli.

  • Increased activation of the ventrolateral PFC can regulate emotion by decreasing the activity of the amygdala. [15] [16] [17] This was also predicted by a study in which they observed the effect of a person's mood/attitude during mindfulness on brain activation. [18]

Lateral prefrontal cortex (lPFC) is important for selective attention while ventral prefrontal cortex (vPFC) is involved in inhibiting a response. As noted before, anterior cingulate cortex (ACC) has been noted for maintaining attention to a stimulus. The amygdala is responsible for generating emotions. Mindfulness meditation is believed to be able to regulate negative thoughts and decrease emotional reactivity through these regions of the brain. Some of the emotion regulation deficits have been noted in disorders such as borderline personality disorder [19] and depression [20] Many of these have been associated with reduced prefrontal activation and increased amygdala activity, which mindfulness meditation might be able to attenuate.

Change in perspective of the self

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The concept behind this component is that a person is capable of changing their response and therefore moving away from the idea that the self is static. A person's response to a stimulus depends on moment to moment experience. The posterior cingulate cortex (PCC), medial prefrontal cortex, and inferior parietal lobule make up a "default network" involved in self-reference processing. This default network is highly active during rest.

  • Meditators practicing mindfulness showed a decrease in the activity of the default network. [21]
  • A better connection of the PCC with the ACC and dorso-lateral PFC in experienced meditators. This indicates that cognitive regulation takes on a greater role than the default network. [22]

Applications of Mindfulness Meditation

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Pain-Relief

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Pain is known to activate the following regions of the brain: the anterior cingulate cortex, anterior/posterior insula, primary/secondary somatosensory cortices, and the thalamus. [23]. Mindfulness meditation may provide several methods by which a person can consciously regulate pain. [24].

  • Brown and Jones found that mindfulness meditation decreased pain anticipation in the right parietal cortex and mid-cingulate cortex. Mindfulness meditation also increased the activity of the anterior cingulate cortex (ACC) and ventromedial-prefrontal cortex (vm-PFC). Since the vm-PFC is involved in inhibiting emotional responses to stimuli, anticipation to pain was concluded to be reduced by cognitive and emotional control. [25]
  • Another study by Grant revealed that meditators showed greater activation of insula, thalamus, and mid-cingulate cortex while a lower activation of the regions responsible for emotion control (medial-PFC, OFC, and amygdala). Meditators were believed to be in a mental state that allowed them to pay close attention to the sensory input from the stimuli and simultaneously inhibit any appraisal or emotional reactivity. [26]

Brown and Jones found that meditators showed no difference in pain sensitivity but rather the anticipation in pain. However, Grant's research showed that meditators experienced lower sensitivity to pain. These conflicting studies illustrate that the exact mechanism may vary with the expertise level or meditation technique. [27].

Immune Response

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It has been shown that greater left-sided anterior activation might correlate with better immune function measured by NK activity. [28] There is also some evidence showing that a stressful life has a negative impact on these antibody titers. [29] Antibody titers are a way to measure the antibody level in the body as a response to foreign substances. Since several meditation programs are aimed at reducing stress, the impact of mindfulness meditation on an immune response was considered.

  • When comparing the immune function of patients who had participated in an 8 week mindfulness meditation program to those who did not, it was found that meditators had greater antibody titers in response to an influenza vaccine. Since a larger role of left-sided anterior activation was observed, it may have been responsible for greater antibody titers.[30]

References

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  1. ^ Holzel, B. K., Lazar, S. W., Gard, T., Schuman-Olivier, Z., Vago, D. R., & Ott, U. (2011). How Does Mindfulness Meditation Work? Proposing Mechanisms of Action From a Conceptual and Neural Perspective.Perspectives on Psychological Science, 6(6), 537-559. doi: 10.1177/1745691611419671
  2. ^ Holzel, B. K., Lazar, S. W., Gard, T., Schuman-Olivier, Z., Vago, D. R., & Ott, U. (2011). How Does Mindfulness Meditation Work? Proposing Mechanisms of Action From a Conceptual and Neural Perspective.Perspectives on Psychological Science, 6(6), 537-559. doi: 10.1177/1745691611419671
  3. ^ Hölzel, B.K., Ott, U., Hempel, H., Hackl, A., Wolf, K., Stark, R.,& Vaitl, D. (2007). Differential engagement of anterior cingulate cortex and adjacent medial frontal cortex in adept meditators and nonmeditators. Neuroscience Letters, 421, 16–21
  4. ^ Brefczynski-Lewis, J.A., Lutz, A., Schaefer, H.S., Levinson, D.B.,& Davidson, R.J. (2007). Neural correlates of attentional expertise in long-term meditation practitioners. Proceedings of the National Academy of Sciences of the United States of America,104, 11483–11488.
  5. ^ Grant, J.A., Courtemanche, J., Duerden, E.G., Duncan, G.H., & Rainville, P. (2010). Cortical thickness and pain sensitivity in Zen meditators. Emotion, 10, 43–53.
  6. ^ Asada, H., Fukuda, Y., Tsunoda, S., Yamaguchi, M., & Tonoike, M.(1999). Frontal midline theta rhythms reflect alternative activation of prefrontal cortex and anterior cingulate cortex in humans.Neuroscience Letters, 274, 29–32.
  7. ^ van Veen, V., & Carter, C.S. (2002). The anterior cingulate as a conflict monitor: FMRI and ERP studies. Physiology & Behavior,77, 477–482
  8. ^ Hölzel, B.K., Ott, U., Hempel, H., & Stark, R. (2006, May). Wie wirkt Achtsamkeit? Eine Interviewstudie mit erfahrenen Meditierenden(How does mindfulness work? An interview study with experienced meditators). Paper presented at the 24th Symposium of the Section for Clinical Psychology and Psychotherapy of the German Society for Psychology, Würzburg, Germany.
  9. ^ Lazar, S.W., Kerr, C.E., Wasserman, R.H., Gray, J.R., Greve, D.N.,Treadway, M.T., . . . Fischl, B. (2005). Meditation experience is associated with increased cortical thickness. NeuroReport, 16, 1893–1897.
  10. ^ Hölzel, B.K., Ott, U., Gard, T., Hempel, H., Weygandt, M., Morgen, K., & Vaitl, D. (2008). Investigation of mindfulness meditation practitioners with voxel-based morphometry. Social Cognitive and Affective Neuroscience, 3, 55–61.
  11. ^ Hölzel, B.K., Carmody, J., Vangel, M., Congleton, C., Yerramsetti,S.M., Gard, T., & Lazar, S.W. (2011). Mindfulness practice leads to increases in regional brain gray matter density. Psychiatry Research, 191, 36–43.
  12. ^ Craig, A.D. (2003). Interoception: The sense of the physiological condition of the body. Current Opinion in Neurobiology, 13, 500–505.
  13. ^ Critchley, H.D., Wiens, S., Rotshtein, P., Ohman, A., & Dolan, R.J.(2004). Neural systems supporting interoceptive awareness. Nature Neuroscience, 7, 189–195.
  14. ^ Hölzel, B.K., Ott, U., Hempel, H., Hackl, A., Wolf, K., Stark, R.,& Vaitl, D. (2007). Differential engagement of anterior cingulate and adjacent medial frontal cortex in adept meditators and nonmeditators. Neuroscience Letters, 421, 16–21.
  15. ^ Harenski, C.L., & Hamann, S. (2006). Neural correlates of regulating negative emotions related to moral violations. NeuroImage, 30,313–324.
  16. ^ Beauregard, M., Levesque, J., & Bourgouin, P. (2001). Neural correlates of conscious self-regulation of emotion. Journal of Neuroscience, 21, RC165.
  17. ^ Schaefer, S.M., Jackson, D.C., Davidson, R.J., Aguirre, G.K., Kimberg,D.Y., & Thompson-Schill, S.L. (2002). Modulation of amygdalar activity by the conscious regulation of negative emotion. Journal of Cognitive Neuroscience, 14, 913–921.
  18. ^ Creswell, J.D., Way, B.M., Eisenberger, N.I., & Lieberman, M.D.(2007). Neural correlates of dispositional mindfulness during affect labeling. Psychosomatic Medicine, 69, 560–565.
  19. ^ Silbersweig, D., Clarkin, J.F., Goldstein, M., Kernberg, O.F., Tuescher, O., Levy, K.N., . . . Rauch, S.L. (2007). Failure of frontolimbic inhibitory function in the context of negative emotion in borderline personality disorder. American Journal of Psychiatry, 164, 1832–1841.
  20. ^ Abercrombie, H.C., Schaefer, S.M., Larson, C.L., Oakes, T.R., Lindgren,K.A., Holden, J.E., . . . Davidson, R.J. (1998). Metabolic rate in the right amygdala predicts negative affect in depressed patients. NeuroReport, 9, 3301–3307.
  21. ^ Ott, U., Walter, B., Gebhardt, H., Stark, R., & Vaitl, D. (2010, June 6–10). Inhibition of default mode network activity during mindfulness meditation. Paper presented at the 16th Annual Meeting of the Organization for Human Brain Mapping, Barcelona,Spain
  22. ^ Brewer, J.A., Kober, H., Worhunsky, P.D., Tang, Y.-Y., Gray, J.R., & Weber, J. (2011). Mental training reveals differences in default mode network activation and functional connectivity. Manuscript submitted for publication.
  23. ^ Zeidan, F., Grant, J. A., Brown, C. A., McHaffie, J. G., & Coghill, R. C. (2012). Mindfulness meditation-related pain relief: Evidence for unique brain mechanisms in the regulation of pain. Neuroscience Letters, 520(2), 165-173. doi: 10.1016/j.neulet.2012.03.082
  24. ^ Zeidan, F., Grant, J. A., Brown, C. A., McHaffie, J. G., & Coghill, R. C. (2012). Mindfulness meditation-related pain relief: Evidence for unique brain mechanisms in the regulation of pain. Neuroscience Letters, 520(2), 165-173. doi: 10.1016/j.neulet.2012.03.082
  25. ^ C.A. Brown, A.K. Jones, Meditation experience predicts less negative appraisal of pain: electrophysiological evidence for the involvement of anticipatory neural responses, Pain 150 (September (3)) (2010) 428–438.
  26. ^ J.A. Grant, J. Courtemanche, E.G. Duerden, G.H. Duncan, P. Rainville, Cortical thickness and pain sensitivity in zen meditators, Emotion 10 (2010) 43–53.
  27. ^ Zeidan, F., Grant, J. A., Brown, C. A., McHaffie, J. G., & Coghill, R. C. (2012). Mindfulness meditation-related pain relief: Evidence for unique brain mechanisms in the regulation of pain. Neuroscience Letters, 520(2), 165-173. doi: 10.1016/j.neulet.2012.03.082
  28. ^ Kang DH, Davidson RJ, Coe CL, Wheeler RW, Tomarken AJ, Ershler WB. Frontal brain asymmetry and immune function. Behav Neurosci 1991;105:860 –9.
  29. ^ Kiecolt-Glaser JK, Glaser R, Gravenstein S, Malarkey WB, Sheridan J. Chronic stress alters the immune response to influenza virus vaccine in older adults. Proc Natl Acad Sci USA 1996;93:3043–7.
  30. ^ Davidson, R. J., Kabat-Zinn, J., Schumacher, J., Rosenkranz, M., Muller, D., Santorelli, S. F., . . . Sheridan, J. F. (2003). Alterations in brain and immune function produced by mindfulness meditation. Psychosomatic Medicine, 65(4), 564-570. doi: 10.1097/01.psy.0000077505.67574.e3
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Mindfulness Meditation: Jon Kabat-Zinn Mindfulness Meditation Pt. 1 Mindfulness Meditation Pt. 2