抑郁症自杀未遂者的痛苦逃避与背外侧前额叶−脑岛有效连接特征

doi:10.3724/SP.J.1041.2023.01966

摘要/Abstract

摘要：

以往研究发现心理痛苦三因素模型中的核心成分痛苦逃避对自杀未遂的区分和预测效能显著优于抑郁。然而, 对于脑内的“痛苦网络”如何界定, 以及“痛苦网络”的异常加工模式是否涉及自杀的脑机制仍未阐明。本研究以原创性心理痛苦三因素模型为理论基础, 依据网络识别原则提出“痛苦网络”的关键脑区, 创新性采用Granger因果分析, 考察抑郁症自杀未遂者脑内“痛苦网络”的序列激活模式, 及其与痛苦逃避、自杀未遂的关系。结果表明, 痛苦逃避和自上而下的dlPFC到脑岛有效连接的钝化是抑郁症自杀未遂者的关键行为和神经特征。研究为进一步揭示抑郁症自杀未遂者的痛苦网络加工模式提供了神经影像学的证据。

关键词: 自杀未遂, 心理痛苦三因素模型, 抑郁症, 痛苦网络, 有效连接

Abstract:

Previous research has established pain avoidance as a critical and stable variable for identifying suicide attempts across samples. However, the neural mechanisms underlying pain avoidance and its relationship to suicide attempts remain unclear. Additionally, most previous research on the brain mechanisms of suicide has focused on single brain regions or circuits, neglecting the principle that the brain is organized into networks. Psychological pain is a complex, negative emotional experience that involves cognitive appraisal, psychosomatic responses, and motivational tendencies. Therefore, the brain mechanisms underlying psychological pain mainly involve impairments in pain processing, motivation, and decision-making circuits. Therefore, a more comprehensive approach is necessary to explore the neural mechanisms underlying psychological pain and its relationship with suicide attempts.

The “pain matrix” is a functional brain network that plays an important role in pain processing. The medial pathway of the pain matrix is responsible for processing affective pain information and is considered the neural basis of psychological pain. The three-dimensional psychological pain model divides psychological pain into cognitive, affective, and motivational components. The medial pathway of the pain matrix is responsible for processing the affective components of psychological pain. Pain arousal, as a cognitive component, represents an individual's cognitive appraisal of painful past situations based on the recollection of past negative events and is closely related to the function of the hippocampus. Pain avoidance, as a motivational component, is closely related to the functions of brain regions involved in cognitive control, with the dlPFC being the core node for top-down cognitive control. Therefore, a combination of the medial pathway, dlPFC, and the hippocampus, defined as a “pain processing network”, can be used to explore the neural mechanisms of psychological pain and its relation to suicide attempts.

Previous studies have linked neural mechanisms to the pathophysiology of suicide, based on brain region-specific functional and structural alterations. However, owing to the lack of directional analyses of multiregional connectivity, little is known about the top-down or bottom-up interaction patterns of the crucial brain regions mentioned above during pain processing in suicide. Therefore, this study aims to explore directional interaction patterns of multiple brain regions in the “pain processing network” and their relationships to pain avoidance, painful feelings, and suicide attempts. This may shed new light on the suicidal brain from a psychological pain-processing perspective.

A total of 35 healthy controls (HC), 25 MDD patients with a history of suicide attempts (MDD-SA), and 48 MDD patients without such a history (MDD-NSA) participated voluntarily in this study. All participants completed measures of interested questionnaires and underwent resting-state functional magnetic resonance imaging. Granger causal analysis (GCA) was used to explore the effective connectivity patterns of brain regions in the pain-processing network.

Behavioral results showed that the total TDPPS scores, pain arousal, painful feelings, pain avoidance subscale, BDI, and BSI were significantly higher in the MDD-SA group than in the MDD-NSA and HC groups. Importantly, the MDD-SA group showed weaker top-down effective connectivity from the right dlPFC to the right insula and stronger effective connectivity from the right lateral OFC to the left hippocampus and the right hippocampus to the right thalamus than the other two groups. Interestingly, the MDD-SA group showed stronger parallel effective connectivity from the left amygdala to the right amygdala than the MDD-NSA and HC groups. The MDD-NSA group showed weaker bottom-up effective connectivity from the left insula to the right dlPFC and from the left amygdala to the left dlPFC than did the other two groups. Notably, blunted effective connectivity from the right dlPFC to the right insula was negatively correlated with pain avoidance scores, suicidal ideation at the worst time point, and the number of suicide attempts. Weaker effective connectivity from the insula to the right dlPFC and from the left amygdala to the left dlPFC negatively correlated with the BDI score.

As a pilot study focused on the directionally interactive patterns of the pain-processing network in suicide attempters, the results suggest that reduced top-down connectivity from the dlPFC to the insula plays a crucial role in the shared neural mechanisms underlying pain avoidance and suicide attempts. This blunting of top-down effective connectivity reflects the difficulty of suicide attempters in achieving effective cognitive control and adaptive behaviors in response to intense negative emotions. Consequently, the individual chooses to commit suicide, a non-adaptive behavior driven by powerful pain avoidance motivations. In contrast, the MDD-NSA group exhibited blunted bottom-up connectivity, which is distinguished from the connectivity pattern of the pain-processing network in the MDD-SA group. Therefore, this study provided neuroimaging evidence for the superiority of pain avoidance over depression in identifying suicide attempts.

Key words: suicide attempt, three-dimensional psychological pain model, major depressive disorder, psychological pain network, effective connectivity

中图分类号:

B845

郝子雨, 李欢欢, 林亦轩. (2023). 抑郁症自杀未遂者的痛苦逃避与背外侧前额叶−脑岛有效连接特征. 心理学报, 55(12), 1966-1978.

HAO Ziyu, LI Huanhuan, LIN Yixuan. (2023). Pain avoidance and effective connectivity between dlPFC and insula in suicide attempters with major depressive disorder. Acta Psychologica Sinica, 55(12), 1966-1978.

图/表 6

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脑区	所包含解剖区	坐标点
脑区	所包含解剖区	X	Y	Z
dlPFC	中央前回_L	−38.65	−5.68	50.94
	中央前回_R	41.37	−8.21	52.09
	额中回_L	−33.43	32.73	35.46
	额中回_R	37.59	33.06	34.04
外侧OFC	眶部额上回_L	−16.56	47.32	−13.31
	眶部额上回_R	18.49	48.1	−14.02
	眶部额中回_L	−30.65	50.43	−9.62
	眶部额中回_R	33.18	52.59	−10.73
	眶部额下回_L	−35.98	30.71	−12.11
	眶部额下回_R	41.22	32.23	−11.91
内侧OFC	眶部额内侧_L	−5.17	54.06	−7.4
内侧OFC	眶部额内侧_R	8.16	51.67	−7.13
ACC	ACC_L	−4.04	35.4	13.95
ACC	ACC_R	8.46	37.01	15.84
脑岛	脑岛_L	−35.13	6.65	3.44
脑岛	脑岛_R	39.02	6.25	2.08
丘脑	丘脑_L	−10.85	−17.56	7.98
丘脑	丘脑_R	13	−17.55	8.09
海马	海马_L	−25.03	−20.74	−10.13
海马	海马_R	29.23	−19.78	−10.33
杏仁核	杏仁核	−23.27	−0.67	−17.14
杏仁核	杏仁核_R	27.32	0.64	−17.5

脑区	所包含解剖区	坐标点
脑区	所包含解剖区	X	Y	Z
dlPFC	中央前回_L	−38.65	−5.68	50.94
	中央前回_R	41.37	−8.21	52.09
	额中回_L	−33.43	32.73	35.46
	额中回_R	37.59	33.06	34.04
外侧OFC	眶部额上回_L	−16.56	47.32	−13.31
	眶部额上回_R	18.49	48.1	−14.02
	眶部额中回_L	−30.65	50.43	−9.62
	眶部额中回_R	33.18	52.59	−10.73
	眶部额下回_L	−35.98	30.71	−12.11
	眶部额下回_R	41.22	32.23	−11.91
内侧OFC	眶部额内侧_L	−5.17	54.06	−7.4
内侧OFC	眶部额内侧_R	8.16	51.67	−7.13
ACC	ACC_L	−4.04	35.4	13.95
ACC	ACC_R	8.46	37.01	15.84
脑岛	脑岛_L	−35.13	6.65	3.44
脑岛	脑岛_R	39.02	6.25	2.08
丘脑	丘脑_L	−10.85	−17.56	7.98
丘脑	丘脑_R	13	−17.55	8.09
海马	海马_L	−25.03	−20.74	−10.13
海马	海马_R	29.23	−19.78	−10.33
杏仁核	杏仁核	−23.27	−0.67	−17.14
杏仁核	杏仁核_R	27.32	0.64	−17.5

变量	HC (n = 35)	MDD-NSA (n = 44)	MDD-SA (n = 25)	F/t/χ²	p	η²_p	Post hoc
性别(男, %)	57.1%	36.4%	24%	7.17	0.028	0.07	HC > MDD-SA
年龄	19.86(4.72)	23.48(4.61)	21.6(6.94)	4.59	0.012	0.08	MDD-NSA > HC
受教育年限(年)	13.17(1.15)	13.34(2.68)	12.84(2.43)	0.41	0.666	0.01	-
药物治疗(有, %)	-	45.5%	56%	0.71	0.458	0.10	-
病程(月)	-	22.25(32.39)	33.44(50.74)	−1.12	0.267	-
BDI	3.43(2.37)	31.95(7.24)	37.24(8.71)	136.51	< 0.001	0.85	MDD-SA > MDD-NSA > HC
BSI-C	0.06(0.24)	5.82(5.57)	16.12(8.88)	29.11	< 0.001	0.54	MDD-SA > MDD-NSA > HC
BSI-W	1.03(3.28)	15.02(9.45)	27.64(6.21)	53.65	< 0.001	0.68	MDD-SA > MDD-NSA > HC
TDPPS	25.63(6.70)	57.59(10.27)	66.60(12.18)	78.80	< 0.001	0.76	MDD-SA > MDD-NSA > HC
痛苦唤醒	11.09(3.36)	26.02(5.70)	29.16(6.21)	57.81	< 0.001	0.70	MDD-SA > MDD-NSA > HC
痛苦体验	11.37(3.79)	23.75(3.67)	25.64(5.10)	61.10	< 0.001	0.71	MDD-SA > MDD-NSA > HC
痛苦逃避	3.17(0.62)	7.82(3.47)	11.80(3.16)	53.65	< 0.001	0.60	MDD-SA > MDD-NSA > HC

变量	HC (n = 35)	MDD-NSA (n = 44)	MDD-SA (n = 25)	F/t/χ²	p	η²_p	Post hoc
性别(男, %)	57.1%	36.4%	24%	7.17	0.028	0.07	HC > MDD-SA
年龄	19.86(4.72)	23.48(4.61)	21.6(6.94)	4.59	0.012	0.08	MDD-NSA > HC
受教育年限(年)	13.17(1.15)	13.34(2.68)	12.84(2.43)	0.41	0.666	0.01	-
药物治疗(有, %)	-	45.5%	56%	0.71	0.458	0.10	-
病程(月)	-	22.25(32.39)	33.44(50.74)	−1.12	0.267	-
BDI	3.43(2.37)	31.95(7.24)	37.24(8.71)	136.51	< 0.001	0.85	MDD-SA > MDD-NSA > HC
BSI-C	0.06(0.24)	5.82(5.57)	16.12(8.88)	29.11	< 0.001	0.54	MDD-SA > MDD-NSA > HC
BSI-W	1.03(3.28)	15.02(9.45)	27.64(6.21)	53.65	< 0.001	0.68	MDD-SA > MDD-NSA > HC
TDPPS	25.63(6.70)	57.59(10.27)	66.60(12.18)	78.80	< 0.001	0.76	MDD-SA > MDD-NSA > HC
痛苦唤醒	11.09(3.36)	26.02(5.70)	29.16(6.21)	57.81	< 0.001	0.70	MDD-SA > MDD-NSA > HC
痛苦体验	11.37(3.79)	23.75(3.67)	25.64(5.10)	61.10	< 0.001	0.71	MDD-SA > MDD-NSA > HC
痛苦逃避	3.17(0.62)	7.82(3.47)	11.80(3.16)	53.65	< 0.001	0.60	MDD-SA > MDD-NSA > HC

有效连接	具体脑区	F	p	η²_p	Post hoc
外侧OFC_R→海马_L	眶部额上回_R→海马_L	3.27	0.014	0.12	SA > HC, NSA
海马_R→丘脑_R	-	3.68	0.008	0.13	SA > HC, NSA
杏仁核_L→杏仁核_R	-	2.08	0.088	0.08	SA > HC, NSA
dlPFC_R→脑岛_R	额中回_R→脑岛_R	3.13	0.018	0.11	SA < HC, NSA
外侧OFC_L→dlPFC_L	眶部额下回_L→额中回_L	2.65	0.038	0.10	NSA < HC, SA
脑岛_L→dlPFC_R	脑岛_L→额中回_R	2.47	0.050	0.09	NSA < HC, SA
杏仁核_L→dlPFC_L	杏仁核_L→额中回_L	3.02	0.021	0.11	NSA < HC, SA
dlPFC_L→外侧OFC_R	额中回_L→眶部额中回_R	3.04	0.021	0.11	NSA < HC, SA
dlPFC_L→外侧OFC_L	额中回_L→眶部额中回_L	3.51	0.010	0.12	NSA > HC, SA
内侧OFC_L→内侧OFC_R	眶部额内侧_L→眶部额内侧_R	3.60	0.009	0.13	NSA > HC, SA
外侧OFC_R→dlPFC_L	眶部额上回_R→中央前回_L	2.31	0.063	0.09	HC > NSA, SA
脑岛_R→dlPFC_R	脑岛_R→额中回_R	3.99	0.005	0.14	HC > NSA, SA
dlPFC_R→dlPFC_R	额中回_R→中央前回_R	4.62	0.002	0.16	HC < NSA, SA
外侧OFC_R→外侧OFC_L	眶部额下回_R→眶部额中回_L	4.71	0.002	0.16	HC < NSA, SA