睡眠对恐惧学习的影响及其认知神经机制

doi:10.3724/SP.J.1042.2023.00631

摘要/Abstract

摘要： 睡眠问题可能会诱发恐惧相关情绪障碍(焦虑、创伤性应激障碍、恐怖症等), 研究睡眠影响恐惧学习的认知神经机制, 有助于增强对恐惧相关情绪障碍的预测、诊断和治疗。以往研究表明睡眠剥夺影响恐惧习得和消退主要是通过抑制vmPFC活动, 阻碍其与杏仁核的功能连接, 从而导致恐惧习得增强或是消退学习受损。进一步研究发现睡眠不同阶段对恐惧学习相关脑区有独特的影响: 剥夺(缺乏)快速眼动睡眠会抑制vmPFC活动、增强杏仁核、海马激活, 导致恐惧习得增强, 消退学习受损, 此外边缘皮层的功能连接减少破坏了记忆巩固(恐惧记忆和消退记忆); 而慢波睡眠主要与海马变化有关, 慢波睡眠期间进行目标记忆重激活可促进恐惧消退学习。未来研究需要增加睡眠影响恐惧泛化的神经机制研究、及昼夜节律中断对恐惧消退的影响, 以及关注动物睡眠研究向人类睡眠研究转化中存在的问题。

关键词: 恐惧习得, 恐惧泛化, 恐惧消退, 快速眼动睡眠, 慢波睡眠, 睡眠剥夺, 睡眠障碍

Abstract: Sleep problems may induce fear-related mood disorders such as anxiety, post-traumatic stress disorder (PTSD), and phobias, among others. Studying the cognitive cognitive and neural mechanisms involved in the relationship between sleep problems and fear learning can help enhance the prediction, diagnosis, and treatment of fear-related mood disorders. Previous studies have shown that sleep deprivation affects fear acquisition mainly by inhibiting the activity of the ventral medial prefrontal cortex (vmPFC) and blocking its functional connections with the amygdala, resulting in impaired safe learning that fails to inhibit fear of threatening stimuli, thus enhancing fear acquisition. In contrast, sleep deprivation during the fear memory consolidation phase impairs the activity of the amygdala and hippocampus, thereby impairing fear memory. On the other hand, sleep deprivation during the extinction learning phase results in delayed activation of brain regions associated with extinction learning, which in turn impairs fear extinction memory. Further studies have reported that different stages of sleep have distinct effects on brain regions associated with fear learning; in particular, rapid eye movement (REM) sleep deprivation (insufficient) and complete sleep deprivation have similar effects on the cognitive and neural mechanisms of fear learning. Deprivation of REM sleep suppresses vmPFC activity, enhances amygdala activation, and thus enhances fear acquisition. In addition, reduced functional connectivity in the limbic cortex disrupts fear memory consolidation. Deprivation of REM sleep after extinction learning phase increases amygdala, insula, and dorsal anterior cingulate cortex (dACC) activity and diminishes mPFC, thereby impairing extinction memory. Therefore, after clinical treatment, quality of sleep, particularly REM sleep, should be ensured at night. In addition to reinforcing recently acquired memories, REM sleep is involved in integrating new information into existing knowledge structures, reorganizing these structures, and generalizing recently acquired memories; therefore, improving REM sleep can promote fading retention and generalization. In contrast, the slow-wave sleep (SWS) stage facilitates fear extinction learning through target memory reactivation, which allows the hippocampus to re-code threatening stimuli and accelerate the consolidation of new safety information in the amygdala. During the SWS stage, participants are not conscious and therefore do not have to directly face the threatening stimulus, thus avoiding some of the drawbacks of traditional extinction therapy applied during wakefulness for patients with fear-related mood disorders, such as anxiety disorders and (PTSD). Clinically relevant studies have found that individuals with insomnia also exhibit delayed activation of the fear extinction brain regions, with related activation occurring only during extinction recall. At the same time, individuals with insomnia have stronger learned fear which causes their insomnia and can easily develop into pathological anxiety or PTSD. Furthermore, sleep immediately following exposure therapy can optimize the therapeutic effect and may even promote extinction generalization; therefore, sleep should be used in combination with traditional exposure therapy. Future research should be conducted to further the study of the neural mechanisms by which sleep affects fear generalization and the effect of circadian rhythm disruption on fear extinction, as well as clarifying the problems in the translation of animal sleep studies to human sleep studies.

Key words: fear acquisition, fear generalization, fear extinction, REM, SWS, sleep deprivation, insomnia disorder

中图分类号:

B845

张婕, 张火垠, 李红, 雷怡. (2023). 睡眠对恐惧学习的影响及其认知神经机制. 心理科学进展 , 31(4), 631-640.

ZHANG Jie, ZHANG Huoyin, LI Hong, LEI Yi. (2023). The effect of sleep on fear learning and its cognitive neural mechanisms. Advances in Psychological Science, 31(4), 631-640.

参考文献

[1] 冯攀, 郑涌. (2015). 睡眠剥夺影响恐惧情绪加工的认知神经机制.心理科学进展, 23(9), 1579-1587.
[2] Ai S.-Z., Chen J., Liu J.-F., He J., Xue Y.-X., Bao Y.-P., ... Shi J. (2015). Exposure to extinction-associated contextual tone during slow-wave sleep and wakefulness differentially modulates fear expression.Neurobiology of Learning and Memory, 123, 159-167.
[3] Baglioni C., Nanovska S., Regen W., Spiegelhalder K., Feige B., Nissen C., Reynolds C. F., & Riemann D. (2016). Sleep and mental disorders: A meta-analysis of polysomnographic research.Psychological bulletin, 142(9), 969-990.
[4] Bottary R., Seo J., Daffre C., Gazecki S., Moore K. N., Kopotiyenko K., Dominguez J. P., Gannon K., Lasko N. B., Roth B., Milad M. R., & Pace-Schott E. F. (2020). Fear extinction memory is negatively associated with REM sleep in insomnia disorder. Sleep, 43(7), zsaa007.
[5] Clark J. W., Hoyer D., Cain S. W., Phillips A., Drummond S., & Jacobson L. H. (2020). Circadian disruption impairs fear extinction and memory of conditioned safety in mice.Behavioural Brain Research, 393, 112788.
[6] Colvonen P. J., Straus L. D., Acheson D., & Gehrman P. (2019). A review of the relationship between emotional learning and memory, sleep, and PTSD.Current Psychiatry Reports, 21(1), 2.
[7] Davidson P., Carlsson I., Jönsson P., & Johansson M. (2018). A more generalized fear response after a daytime nap.Neurobiology of Learning and Memory, 151, 18-27.
[8] Davidson, P., & Pace-Schott, E. (2020). The role of sleep in fear learning and memory.Current Opinion in Psychology, 34, 32-36.
[9] DeMartini J., Patel G., & Fancher T. L. (2019). Generalized anxiety disorder. Annals of Internal Medicine, 170(7), ITC49-ITC64.
[10] Díaz-Román A., Perestelo-Pérez L., & Buela-Casal G. (2015). Sleep in obsessive-compulsive disorder: A systematic review and meta-analysis.Sleep Medicine, 16(9), 1049-1055.
[11] Feng P., Becker B., Feng T., & Zheng Y. (2018). Alter spontaneous activity in amygdala and vmPFC during fear consolidation following 24h sleep deprivation.NeuroImage, 172, 461-469.
[12] Fullana M. A., Albajes-Eizagirre A., Soriano-Mas C., Vervliet B., Cardoner N., Benet O., Radua J., & Harrison B. J. (2018). Fear extinction in the human brain: A meta-analysis of fMRI studies in healthy participants.Neuroscience and Biobehavioral Reviews, 88, 16-25.
[13] Fullana M. A., Harrison B. J., Soriano-Mas C., Vervliet B., Cardoner N., Àvila-Parcet A., & Radua J. (2016). Neural signatures of human fear conditioning: An updated and extended meta-analysis of fMRI studies.Molecular Psychiatry, 21(4), 500-508.
[14] Genzel L., Spoormaker V. I., Konrad B. N., & Dresler M. (2015). The role of rapid eye movement sleep for amygdala- related memory processing.Neurobiology of Learning and Memory, 122, 110-121.
[15] Greco, J. A., & Liberzon, I. (2016). Neuroimaging of Fear-Associated Learning.Neuropsychopharmacology, 41(1), 320-334.
[16] Haaker J., Maren S., Andreatta M., Merz C. J., Richter J., Richter S. H., ... Lonsdorf T. B. (2019). Making translation work: Harmonizing cross-species methodology in the behavioural neuroscience of Pavlovian fear conditioning.Neuroscience and Biobehavioral Reviews, 107, 329-345.
[17] Hauner K. K., Howard J. D., Zelano C., & Gottfried J. A. (2013). Stimulus-specific enhancement of fear extinction during slow-wave sleep.Nature Neuroscience, 16(11), 1553-1555.
[18] He J., Sun H. Q., Li S. X., Zhang W. H., Shi J., Ai S. Z., Li Y., Li X. J., Tang X. D., & Lu L. (2015). Effect of conditioned stimulus exposure during slow wave sleep on fear memory extinction in humans.Sleep, 38(3), 423-431.
[19] Hunter A. S. (2015). Impaired extinction of fear conditioning after REM deprivation is magnified by rearing in an enriched environment.Neurobiology of Learning and Memory, 122, 11-18.
[20] Hunter A. S. (2018). REM deprivation but not sleep fragmentation produces a sex-specific impairment in extinction.Physiology & Behavior, 196, 84-94.
[21] Javaheripour N., Shahdipour N., Noori K., Zarei M., Camilleri J. A., Laird A. R., ... Tahmasian M. (2019). Functional brain alterations in acute sleep deprivation: An activation likelihood estimation meta-analysis.Sleep Medicine Reviews, 46, 64-73.
[22] Jung, T., & Noh, J. (2021). Alteration of fear behaviors in sleep-deprived adolescent rats: Increased fear expression and delayed fear extinction.Animal Cells and Systems, 25(2), 83-92.
[23] Kleim B., Wilhelm F. H., Temp L., Margraf J., Wiederhold B. K., & Rasch B. (2014). Sleep enhances exposure therapy.Psychological Medicine, 44(7), 1511-1519.
[24] Krause A. J., Simon E. B., Mander B. A., Greer S. M., Saletin J. M., Goldstein-Piekarski A. N., & Walker M. P. (2017). The sleep-deprived human brain.Nature Reviews. Neuroscience, 18(7), 404-418.
[25] Lerner I., Lupkin S. M., Sinha N., Tsai A., & Gluck M. A. (2017). Baseline levels of rapid eye movement sleep may protect against excessive activity in fear-related neural circuitry.The Journal of Neuroscience, 37(46), 11233-11244.
[26] Lerner I., Lupkin S. M., Tsai A., Khawaja A., & Gluck M. A. (2021). Sleep to remember, sleep to forget: Rapid eye movement sleep can have inverse effects on recall and generalization of fear memories.Neurobiology of Learning and Memory, 180, 107413.
[27] Ma N., Dinges D. F., Basner M., & Rao H. (2015). How acute total sleep loss affects the attending brain: A meta-analysis of neuroimaging studies.Sleep, 38(2), 233-240.
[28] Maquet P. (2010). Understanding non rapid eye movement sleep through neuroimaging.The World Journal of Biological Psychiatry, 11(Suppl. 1), 9-15
[29] Marek R., Sun Y., & Sah P. (2019). Neural circuits for a top-down control of fear and extinction.Psychopharmacology, 236(1), 313-320.
[30] Marshall A. J., Acheson D. T., Risbrough V. B., Straus L. D., & Drummond S. P. (2014). Fear conditioning, safety learning, and sleep in humans.The Journal of Neuroscience, 34(35), 11754-11760.
[31] McNett S., Lind M. J., Brown R. C., Hawn S., Berenz E. C., Brown E., ... Amstadter A. B. (2021). Sleep quality moderates the relationship between anxiety sensitivity and PTSD symptoms in combat-exposed veterans.Behavioral Sleep Medicine, 19(2), 208-220.
[32] Menz M. M., Rihm J. S., & Büchel C. (2016). REM sleep is causal to successful consolidation of dangerous and safety stimuli and reduces return of fear after extinction.The Journal of Neuroscience, 36(7), 2148-2160.
[33] Montes-Rodríguez C. J., Rueda-Orozco P. E., & Prospéro- García O. (2019). Total sleep deprivation impairs fear memory retrieval by decreasing the basolateral amygdala activity.Brain Research, 1719, 17-23.
[34] Moore K., Bottary R., Gazecki S., Lasko N., Zsido R., Bianchi M., Gannon K., Milad M., & Pace-Schott E. (2017). 0311 Differences in activation of fear and extinction circuitry in individuals with primary insomnia.Sleep, 40(suppl. 1), A115.
[35] Mukli P., Csipo T., Lipecz A., Stylianou O., Racz F. S., Owens C. D., ... Yabluchanskiy A. (2021). Sleep deprivation alters task-related changes in functional connectivity of the frontal cortex: A near-infrared spectroscopy study.Brain and Behavior, 11(8), e02135.
[36] Murkar, A. L. A., & de Koninck, J. (2018). Consolidative mechanisms of emotional processing in REM sleep and PTSD.Sleep Medicine Reviews, 41, 173-184.
[37] Pace-Schott E. F., Bottary R. M., Kim S. Y., Rosencrans P. L., Vijayakumar S., Orr S. P., ... Simon N. M. (2018). Effects of post-exposure naps on exposure therapy for social anxiety.Psychiatry Research, 270, 523-530.
[38] Pace-Schott E. F., Germain A., & Milad M. R. (2015a). Effects of sleep on memory for conditioned fear and fear extinction.Psychological Bulletin, 141(4), 835-857.
[39] Pace-Schott E. F., Germain A., & Milad M. R. (2015b). Sleep and REM sleep disturbance in the pathophysiology of PTSD: The role of extinction memory.Biology of Mood & Anxiety Disorders, 5, 3.
[40] Pace-Schott E. F., Milad M. R., Orr S. P., Rauch S. L., Stickgold R., & Pitman R. K. (2009). Sleep promotes generalization of extinction of conditioned fear.Sleep, 32(1), 19-26.
[41] Pace-Schott E. F., Spencer R. M., Vijayakumar S., Ahmed N. A., Verga P. W., Orr S. P., Pitman R. K., & Milad M. R. (2013). Extinction of conditioned fear is better learned and recalled in the morning than in the evening.Journal of Psychiatric Research, 47(11), 1776-1784.
[42] Pace-Schott E. F., Verga P. W., Bennett T. S., & Spencer R. M. (2012). Sleep promotes consolidation and generalization of extinction learning in simulated exposure therapy for spider fear.Journal of Psychiatric Research, 46(8), 1036-1044.
[43] Pinho N., Moreira K. M., Hipolide D. C., Sinigaglia- Coimbra R., Ferreira T. L., Nobrega J. N., Tufik S., & Oliveira, M. G. M. (2013). Sleep deprivation alters phosphorylated CREB levels in the amygdala: Relationship with performance in a fear conditioning task.Behavioural Brain Research, 236, 221-224.
[44] Pires G. N., Bezerra A. G., Tufik S., & Andersen M. L. (2016). Effects of experimental sleep deprivation on anxiety-like behavior in animal research: Systematic review and meta-analysis.Neuroscience and Biobehavioral Reviews, 68, 575-589.
[45] Rosier M., Le Barillier L., Meunier D., El Yacoubi M., Malleret G., & Salin P. A. (2018). Post-learning paradoxical sleep deprivation impairs reorganization of limbic and cortical networks associated with consolidation of remote contextual fear memory in mice. Sleep, 41(12), zsy188.
[46] Schenker M. T., Ney L. J., Miller L. N., Felmingham K. L., Nicholas C. L., & Jordan A. S. (2021). Sleep and fear conditioning, extinction learning and extinction recall: A systematic review and meta-analysis of polysomnographic findings.Sleep Medicine Reviews, 59, 101501.
[47] Seo J., Moore K. N., Gazecki S., Bottary R. M., Milad M. R., Song H., & Pace-Schott E. F. (2018). Delayed fear extinction in individuals with insomnia disorder. Sleep, 41(8), zsy095.
[48] Seo J., Pace-Schott E. F., Milad M. R., Song H., & Germain A. (2021). Partial and total sleep deprivation interferes with neural correlates of consolidation of fear extinction memory.Biological Psychiatry. Cognitive Neuroscience and Neuroimaging, 6(3), 299-309.
[49] Steele M., Rode N., Stocker R., McNamee R., & Germain A. (2017). 0264 Effect of acute sleep deprivation on cognitive performance and fear extinction recall.Sleep, 40(suppl. 1), A97.
[50] Stickgold, R., & Manoach, D. S. (2017). The importance of sleep in fear conditioning and posttraumatic stress disorder.Biological Psychiatry. Cognitive Neuroscience and Neuroimaging, 2(2), 109-110.
[51] Straus L. D., Acheson D. T., Risbrough V. B., & Drummond S. (2017). Sleep deprivation disrupts recall of conditioned fear extinction.Biological psychiatry. Cognitive Neuroscience and Neuroimaging, 2(2), 123-129.
[52] Tempesta D., Socci V., De Gennaro L., & Ferrara M. (2018). Sleep and emotional processing.Sleep Medicine Reviews, 40, 183-195.
[53] Tovote P., Fadok J. P., & Lüthi A. (2015). Neuronal circuits for fear and anxiety.Nature Reviews. Neuroscience, 16(6), 317-331.
[54] Wang Y. Q., Li R., Zhang M. Q., Zhang Z., Qu W. M., & Huang Z. L. (2015). The neurobiological mechanisms and treatments of REM sleep disturbances in depression.Current Neuropharmacology, 13(4), 543-553.
[55] Webler R. D., Berg H., Fhong K., Tuominen L., Holt D. J., Morey R. A., ... Lissek S. (2021). The neurobiology of human fear generalization: Meta-analysis and working neural model.Neuroscience and Biobehavioral Reviews, 128, 421-436.
[56] Wixted J. T. (2013). Sleep aromatherapy curbs conditioned fear.Nature Neuroscience, 16(11), 1510-1512.
[57] Yu J., Rawtaer I., Fam J., Jiang M.-J., Feng L., Kua E. H., & Mahendran R. (2016). Sleep correlates of depression and anxiety in an elderly Asian population.Psychogeriatrics, 16(3), 191-195.
[58] Zenses A. K., Lenaert B., Peigneux P., Beckers T., & Boddez Y. (2020). Sleep deprivation increases threat beliefs in human fear conditioning.Journal of Sleep Research, 29(3), e12873.