Risk assessment: at the interface of cognition and emotion

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ScienceDirect Risk assessment: at the interface of cognition and emotion D Caroline Blanchard Risk Assessment (RA) is a core component of the defense survival system. Recent studies indicate substantial parallels between eliciting stimuli, behaviors, and functional outcomes for RA in animal models and people, and a rapidly growing literature suggests that some exaggerated or aberrant RA behaviors may be transdiagnostic components of anxiety and depressive disorders. Although the subcortical components of defense systems have been well mapped, RA, standing at the ‘interface of cognition and emotion’, appears to involve a more extensive cortical representation than other specific defenses. Recent analyses of metanetworks potentially interacting with the subcortical defense systems suggest that the Default Mode Network and the Salience Network may be strongly involved in RA. Address Pacific Biosciences Research Center, University of Hawaii at Manoa, Honolulu, HI 96825, USA Corresponding author: Blanchard, D Caroline ([email protected])

Current Opinion in Behavioral Sciences 2018, 24:69–74 This review comes from a themed issue on Survival circuits Edited by Dean Mobbs and Joe LeDoux

https://doi.org/10.1016/j.cobeha.2018.03.006 2352-1546/ã 2018 Published by Elsevier Ltd.

Risk Assessment Risk Assessment (RA) is the cognitive/attentional component of a pattern of defensive behaviors to threat or potential threat (e.g. [1]). The core overt behavior in RA is an intense orientation to, and sensory scanning of, the potential threat. This scanning, while multimodal, may involve different focal sensory modalities in different species, that is olfaction in rodents; vision in primates. RA occurs most clearly in response to stimuli for which there is an important element of threat ambiguity (e.g. [2]), and has a clear nonmonotonic relationship to threat intensity [3]. RA under the rubric of ‘vigilance’ has often been used as a major index of prey responsivity to predator risk (e.g. [4]). While this response is usually elicited by cues or potential cues from the predator itself, some animals may also respond to the defensive responses of conspecifics (e. g. [5]) or even those of other species [6]. www.sciencedirect.com

RA in nonhuman animals Much of the systematic work on RA has been done in laboratory settings, with wild as well as laboratory rats and mice, in seminatural habitats and in test batteries in which relevant stimulus and situational factors were varied (e.g. [7,8]). In these studies, RA has been measured in terms of a variety of specific behaviors, including ‘stretch attend’ (oriented to the stimulus but motionless except for scan/ sniff/ear-related movements) or during an approach (‘stretch approach); or from a place of concealment [9]. It typically involves ‘flat-back’ or ‘stretched’ postures or movements, reducing the probability that the threat stimulus will notice and respond to the risk-assessing animal. These patterns may be supplemented by other investigatory activities, such as burying the threat or throwing debris at it [10], potentially permitting a determination, by the movement of the threat, of its status as animate. Table 1 presents the results of a number of studies analyzing a range of defensive behaviors — flight, freezing, defensive threat/attack, defensive vocalizations, RA — in terms of the particular features of threat stimuli and situations in which the individual defenses were most likely to occur. These range from reflex-like behaviors such as the startle response, little modulated by situational characteristics, to RA, which functions to assess both stimulus and situational characteristics in order to facilitate the optimum choice of specific defenses in that situation. These behavioral differences are coming to be acknowledged in analyses of the neural systems in defense [11]. Particular defenses can occur in various combinations, reflecting different species-typical sensory and motor abilities of both prey and predator in a confrontation (e.g. [12,13]), but the core RA function of gathering information about potential threat sources is manifest in initial orientation to virtually any novel or unexpected stimulus, making RA a component, albeit not necessarily the focal defense, in almost every such encounter.

RA in people: the scenario studies These relationships were subsequently evaluated in people, who provided first choice responses to brief scenarios incorporating relevant threat stimuli or situational features. In these, correlations between threat ambiguity (rated by independent panels) and RA (‘check it out’) were +.86 and +.89 for women and men, respectively [14]. In subsequent replications done in Brazil [15,16] and the United Kingdom [17] as well as in the US [18] the Current Opinion in Behavioral Sciences 2018, 24:69–74

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Table 1 Defensive behaviors (rats, mice). Source of threat (and proximity) Discrete Discrete Discrete Discrete Discrete — close, animate Discrete — sudden Discrete — close, animate Uncertain — potential Uncertain — potential

Modulating features

Behavior

Typical outcome

‘Way out’ available No means of escape Conspecifics nearby Hiding place available No escape

Flight Freezing Alarm cry Hides Def. threat Startle Def. attack Risk assessment Defensive burying

Escape Reduces attack Warns conspecifics No detection/access Threatens attacker Startles attacker Hurts attacker painful Gains information Elicits movement

Substrate available

Table 1 presents common defensive behaviors, as analyzed in a number of rodent antipredator tests (e.g. [1,3,7–10,12,24]), along with relevant features of the eliciting (threat) stimulus; modulating situational features; and typical outcomes.

correlations of RA and threat ambiguity continued to be positive and significant. These scenarios all involved either potential or obvious physical threat from a conspecific. The Harrison et al. (2015) [18] study added new groups of scenarios, with results suggesting that correlations between threat ambiguity and RA are less apparent when social or psychological threats, such as gossip from coworkers or not being invited to a party, are involved. These typically elicited social/verbal means of mitigation, such as appeals to authority or verbal confrontation: notably, however, either of these could involve a substantial RA component. In addition, scenarios involving weather, or animals, also failed to show a substantial correlation with threat ambiguity, possibly for a different reason; a restricted (low) level of ambiguity in the threat potential of a hurricane, tornado, bear or being approached in the water by an animal that could be a shark. Facial expression studies provide additional support for a link between RA and threat ambiguity. Perkins et al. (2012) [19] asked volunteers to model expressions to short scenarios that were designed to elicit a range of emotions. Additional volunteers also labeled photographs/videos of responses to ambiguous threats as ‘anxious’ although expressions in response to clear threats were identified as ‘fear’. Moreover, the ‘anxious’ expressions were characterized by visual scanning behaviors, providing further face validity to the identification of anxiety with RA.

RA and anxiety On behavioral and functional grounds, RA appears to have a specific relationship to anxiety [1,20], with the failure to determine that a stimulus or situation is actually not dangerous being a particularly important mechanism in anxiety [21]. As RA often involves not only attention but also approach to potential danger, while flight constitutes avoidance of it, an RA/anxiety — flight/fear relationship has often been conceptualized in terms of an ‘Approach — Avoidance’ dichotomy as a component of an Current Opinion in Behavioral Sciences 2018, 24:69–74

influential theoretical treatment of anxiety [22]. Although providing a clear criterion for classification, this dichotomy fails to address the specific functional significance of RA, as opposed to the other ‘approach’ defense, defensive attack. Specifically, RA facilitates acquisition of information about threats and the situations in which they occur, permitting (if successful) the determination of an optimal defense for that particular threat stimulus and situation, including a return to nondefensive behavior if threat is not present (e.g. [2,23]). The view that RA is involved in anxiety has also been supported by a number of studies showing that anxiolytic drugs are particularly effective with RA measures in the elevated plus maze [24–26] or rat and mouse defense test batteries [8,27,28], while serotonergic agents often impact eye-gaze measures and rumination linked to anxiety in humans [29]. These findings provide support for a ‘vigilance’ hypothesis of anxiety [30], that is embedded in a substantial number of recent studies of eye-gaze tracking to threat stimuli (see [31,32] for review) in which anxious subjects typically show a faster response to threatening stimuli, sometimes coupled with subsequent avoidance, than do nonanxious individuals. In particular, anxious individuals show a nonvoluntary gaze shift toward peripheral threat cues, even when instructed to maintain central fixation [33]. The status of RA as an interface between cognitive processes and threat-elicited emotion state is also emphasized by its potential links to rumination, which is strongly associated with both anxiety and depression [34,35]. Rumination involves intensive and often intrusive thinking about problems, characterized by particularly passive, negative thoughts focusing on past events and on the ruminator’s emotional reaction to these, rather than on problem solving; suggesting a flawed or deficient form of RA [2]. Michl et al. (2013) [36], suggest that rumination may be responsible for much of the higher rate of anxiety in women than in men. Similarly, an RA-relevant category of ‘excessive’ or ‘uncontrollable’ worry, sometimes differentiated from rumination by its focus on future rather www.sciencedirect.com

Assessment: at the interface of cognition and emotion Blanchard 71

than past events [37] is also associated with anxiety and depression [38,39].

RA, anxiety, and brain systems Recent research has provided systematic and highly replicable evidence for parallel systems for defense in subcortical areas of rodent brains. These systems (see Canteras, this volume) may differ in sub-regional detail for different types of animate threats (e.g. dorsomedial VMH vs ventrolateral VMH activation in response to predators vs conspecific threats [40,41]) but they appear to follow similar trajectories, from amygdala through hypothalamus, to midbrain periaqueductal gray (PAG). Motta et al. (2017) [42] reviewed the connections and functions of the PAG, noting that both flight and RA are strongly responsive to stimulus and environmental features, and may depend on systems involving prosencephalic, in addition to subcortical, sites. They propose (Motta et al., 2017, Fig. 1 [42], illustrated in McNaughton and Corr, this volume) a specific pathway from the dPAG through the dorsolateral zone of the rostral part of the lateral septum, LSr.dl; to the ventral hippocampus (vHipp), and the medial prefrontal cortex (mPFC), to engage cortical systems in these defense processes. Notably, the LSr.dl is linked to the theta rhythm that is associated with anxiety responses (e.g. [43]), and, more specifically, with anxious rumination [44]; while lesions in the vHipp reduce RA [45], and the mPFC directly modulates fear expression in the amygdala (e.g. [46]). Chang and Grace (2018) [47], suggesting that anxiety disorders may result from aberrant functional connectivity in networks rather than in individual structures, outline some complex interactions between the mPFC and the orbitofrontal cortex (OFC), on activity modulated by GABAergic receptors in the lateral/basolateral amygdala. Nuss (2015) [48] also notes a central role for amygdala GABAA receptors, suggesting that these receptors and modulators of their allosteric sites may be involved in pathological anxiety. The mPFC is also a prominent component of the default mode network (DMN [49]). The major areas in this group, the mPFC, medial temporal lobes, and posterior cingulate cortex/retrosplenial cortex, show strong interconnections as well as synchronous EEG oscillations [50] that are higher during behavioral resting stages than in responsivity to external stimuli or during specific cognitive processing. In both anxiety and depression functional connectivity was increased in anterior portions of the DMN but decreased in posterior portions of this network [51]; interpreted as reflecting different functions of the two regions: self-referential and emotional processes for the former, but episodic memory and perceptual processing for the latter: Both anterior and posterior DMN connectivity were associated with clinical response after emotional regulation therapy that incorporated rumination-linked ‘decentering’ [52]. An additional link to RA www.sciencedirect.com

was the finding [53] of DMN intranetwork connectivity changes with worry severity and longer duration of illness in GAD patients. Increased functional connectivity between the DMN and the subgenual prefrontal cortex has been reported to predict depressive rumination [54], while connectivity between specific areas within the DMN was correlated with depression severity and earlier age of onset, for major depressive disorder patients [55]. Additionally, the salience network (SN [56]), consisting of a number of cortical structures originally identified as particularly responsive to novel events, is seen as orienting attention toward salient, often emotion-eliciting, stimuli. During acute stress, the SN appears to promote fear and vigilance [57]. There is also a positive relationship between subjective measures of stress and connectivity between the SN and the DMN, just after stress induction [58,59], while a recent review of fMRI studies [58] indicated that both the SN and the DMN show strong and relatively consistent responsivity to acute stress. Van Oort et al. (2017) [60] suggest that this relationship may reflect a hypervigilant state, in conjunction with selfreferential processing. A metaanalysis [61] reported structural and functional abnormalities in specific core cortical nodes of the SN in a range of psychopathologies. While these were associated with disruptive cognitive control, both the cognitive symptoms and the specifics of the SN abnormalities showed variation across and within psychiatric classifications. They (Peters et al., 2016 [61]) describe the need for better characterization of transdiagnostic cognitive pathologies, in accord with the Research Domain Criteria [62] as well as information on the brain system dysfunctions with which they may be specifically associated, for improved understanding of these relationships.

RA and survival circuits: summary and conceptualizations RA, ranging from vigilance behaviors to complex decision-making concerning threatening events, is the most ubiquitious component of defense: Its potential importance is further increased by suggested relationships to anxiety and depression, perhaps mediated by rumination and excessive worry. While the association of RA and other defensive behaviors with subcortical survival systems is well documented (e.g. [40,41]), and there is evidence of relevant connections from these to prosencephalic structures [42], the cortical systems involved in RA are only beginning to be analyzed or identified, making it difficult at present to conceptualize the relationships between subcortical and cortical components; for example are there two RA systems, one subcortical and the other cortical? Does a substantial cortical involvement in RA [63] call into question the view (McNaughton, this issue) of survival circuits as based in subcortical areas? What is the relationship between defensive RA systems and other important decision-making processes? Current Opinion in Behavioral Sciences 2018, 24:69–74

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Two conceptualizations of suboptimal RA, as rumination and excessive worry, appear to be correlated and also related to mood disorders such as anxiety and depression [37]. These specific RA manifestations, and their relationships to brain system functioning, can only be measured in humans, whereas more specific and precise — and typically invasive — techniques of brain manipulation and imaging are often only possible with animal subjects. LeDoux’ recent, and extensively documented, view that fear and anxiety necessarily involve conscious experience [64] might suggest that nonhuman animals, for which consciousness should not be assumed, are inappropriate subjects for research on these emotions. Although in general agreement that an assumption of consciousness in nonhumans is ill-advised, I suggest that the cognitive and decision-making aspects of RA can indeed be evaluated in the behaviors of nonhuman animals, and that we should seek methods for determining what are or are not appropriate/optimal RA-based decisions for dealing with threat risk across a range of situations. In turn, these behaviors and their origins in activities within particular neural systems should provide a much more precise and dynamic view of the functioning of RA for potential translation to humans, and possible validation or modification there. Consciousness may indeed contribute to the emotion of anxiety, but it would be extremely surprising if the basic outline of RA-related behavior patterns, so crucial to the core functions of defense, were to change substantially in the transition from nonhuman to human animals.

4.

Ayon RE, Putman BJ, Clark RW: Recent encounters with rattlesnakes enhance ground squirrel responsiveness to predator cues. Behavioral Ecol Sociobiol 2017, 71(10):149.

5.

Rauber R, Manser MB: Discrete call types referring to predation risk enhance the efficiency of the meerkat sentinel system. Scient Rep 2017:7. (article 44436).

6.

Schmitt MH, Stears K, Shrader AM: Zebra reduce predation risk in mixed-species herds by eavesdropping on cues from giraffe. Behav Ecol 2016, 27(4):1073-1077.

7.

Blanchard RJ, Blanchard DC: Antipredator defensive behaviors in a visible burrow system. J Compar Psychol 1989, 103(1):7082.

8.

Yang M, Augustsson H, Markham CM, Hubbard DT, Webster D, Wall PM, Blanchard RJ, Blanchard DC: The rat exposure test: a model of mouse defensive behaviors. Physiol Behav 2004, 81:465-473.

9.

Dielenberg RA, McGregor IS: Defensive behavior in rats towards predatory odors: a review. Neurosci Biobehav Rev 2001, 25:597609.

Conflict of interest statement

14. Blanchard DC, Hynd AL, Minke KL, Minemoto T, Blanchard RJ: Human defensive behaviors to threat scenarios show parallels to fear- and anxiety-related defense patterns of non-human mammals. Neurosci Biobehav Rev 2001, 25:761-770.

Nothing declared.

Acknowledgments This research was supported by grants from the National Institute of Mental Health (NIH RO1MH081845) and the National Science Foundation (NSF BNS9111524) to DCB.

References and recommended reading Papers of particular interest, published within the period of review, have been highlighted as:  of special interest  of outstanding interest 1.

Blanchard RJ, Blanchard DC: Attack and defense in rodents as ethoexperimental models for the study of emotion. Prog Neuropsychopharmacol Biol Psychiatry 1989, 13 Suppl:S3-S14.

2. 

Blanchard DC, Griebel G, Pobbe R, Blanchard RJ: Risk assessment as an evolved threat detection and analysis process. Neurosci Biobehav Rev 2011, 35(4):991-998. This article defines and describes risk assessment and its role in the defense process, and points out associations with anxiety, through behavior and drug response in both animal models and people. It links risk assessment to rumination and suggests differences in brain regional activation patterns for risk assessment and flight, another core behavior in defense, suggesting a biological differentiation of anxiety and fear/panic systems. 3.

Blanchard RJ, Blanchard DC, Rodgers RJ, Weiss SW: The characterization and modelling of antipredator defensive behavior. Neurosci Biobehav Rev 1990, 14:463-472.

Current Opinion in Behavioral Sciences 2018, 24:69–74

10. Coss RG, Owings DH: Snake directed behavior by snake naı¨ve and experienced California ground squirrels in a simulated burrow. Zeitschr Tierpsychol 1978, 48:421-435. 11. Canteras NS, Resstel LB, Bertoglio LJ, de Carobrez AP, Guimara˜es FS: Neuroanatomy of anxiety. Curr Top Behav  Neurosci 2010, 2:77-96. Canteras et al. outline focal brain systems involved in defensive behavior, with a focus on medial prefrontal cortex, amygdaloid and hypothalamic nuclei, hipoccampal formation, and midbrain central gray, indicating substantial similarities for these systems in rodents and in primates. It suggests that immediate defensive behaviors may be organized by at least partly distinct brain systems and notes a potential relationship between these systems and anxiety. 12. Edut S, Eilam D: Protean behavior under barn-owl attack: voles alternate between freezing and fleeing and spiny mice flee in alternating patterns. Behav Brain Res 2004, 155:207-216. 13. Lingle S, Pellis S: Fight or flight? Antipredator behavior and the escalation of coyote encounters with deer. Oecologia 2002, 131:154-164.

15. Mesquita SC, Shuhama R, Oso´rio FL, Crippa JA, Loureiro SR, Landeira-Fernandez J, Graeff FG, Del-Ben CM: The response of social anxiety disorder patients to threat scenarios differs from that of healthy controls. Braz J Med Biol Res 2011, 44:1261-1268. 16. Perkins AP, Corr PJ: Reactions to threat and personality: psychometric differentiation of intensity and direction dimensions of human defensive behavior. Behav Brain Res 2006, 169:21-28. 17. Shuhama R, Del-Ben CM, Loureiro SR, Graeff FG: Defensive responses to threat scenarios in Brazilians reproduce the pattern of Hawaiian Americans and non-human mammals. Braz J Med Biol Res 2008, 41:324-332. 18. Harrison LA, Ahn C, Adolphs R: Exploring the structure of human defensive responses from judgments of threat scenarios. PLoS ONE 2015, 10. 19. Perkins AM, Inchley-Mort SL, Pickering AD, Corr PJ, Burgess AP: A facial expression for anxiety. J Pers Soc Psychol 2012,  102:910-924. Perkins et al. tested the human validity of the risk assessment explanation for anxiety by asking volunteers to pose facial expressions in response to emotive scenarios, some of which (those with ambiguous threat) had elicited risk assessment responses. Additional participants selectively labeled the emotion seen in photographs and videos of the ambiguous threat expressions as anxiety, while the expressions posed to clear threat were labeled fear. 20. Blanchard DC, Blanchard RJ, Rodgers RJ: Risk Assessment and animal models of anxiety. In Animal Models in www.sciencedirect.com

Assessment: at the interface of cognition and emotion Blanchard 73

Psychopharmacology. Edited by Olivier BB, Mos J, Slangen JL. Basel: Birkhauser Verlag; 1991:117-134. 21. Woody EZ, Szechtman H: Adaptation to potential threat: the evolution, neurobiology, and psychopathology of the security motivation system. Neurosci Biobehav Rev 2011, 35:1019-1033. 22. McNaughton N, Corr P: A two-dimensional neuropsychology of defense: fear/anxiety and defensive distance. Neurosci Biobehav Rev 2004, 28:285-305. 23. Viellard J, Baldo MV, Canteras NS: Testing conditions in shockbased contextual fear conditioning influence both the behavioral responses and the activation of circuits potentially involved in contextual avoidance. Behav Brain Res 2016, 15:123-129. 24. Griebel G, Rodgers RJ, Perrault G, Sanger DJ: Risk assessment behaviour: evaluation of utility in the study of 5-HT-related drugs in the rat elevated plus-maze test. Pharmacol Biochem Behav 1997, 57:817-827. 25. Rodgers RJ, Johnson NJ: Factor analysis of spatiotemporal and ethological measures in the murine elevated plus-maze test of anxiety. Pharmacol Biochem Behav 1995, 52:297-303. 26. Sorregotti T, Mendes-Gomes J, Rico JL, Rodgers RJ, Nunes-deSouza RL: Ethopharmacological analysis of the open elevated plus-maze in mice. Behav Brain Res 2013, 246:76-85. 27. Blanchard RJ, Griebel G, Henrie JA, Blanchard DC: Differentiation of anxiolytic and panicolytic drugs by effects on rat and mouse defense test batteries. Neurosci Biobehav Rev 1997, 21:783-789. 28. Blanchard DC, Griebel G, Blanchard RJ: The Mouse Defense Test Battery: pharmacological and behavioral assays for anxiety and panic. Eur J Pharmacol 2003, 463:97-116. 29. Blanchard DC, Meyza K: Risk assessment and serotonin: animal models and human psychopathologies. Behav Brain Res 2017 http://dx.doi.org/10.1016/j.bbr.2017.07.008. 30. Weierich MR, Treat TA: Mechanisms of visual threat detection in specific phobia. Cogn Emot 2015, 29:992-1006. 31. Armstrong T, Olatunji BO: Eye tracking of attention in the affective disorders: a meta-analytic review and synthesis. Clin Psychol Rev 2012, 32:704-723. 32. Chen NTM, Clarke PJF: Gaze-based assessments of vigilance  and avoidance in social anxiety: a review. Curr Psychiatry Rep 2017, 19:59. Chen and Clarke review studies of eye tracking and selective attention biases in social anxiety, reporting that socially anxious individuals exhibit a generalized vigilance through hyperscanning of the environment, but may also avoid the maintenance of eye contact; showing both vigilant and avoidant patterns in processing emotional stimuli. 33. Broomfield NM, Turpin G: Covert and overt attention in trait anxiety: a cognitive psychophysiological analysis. Biol Psychology 2005, 68:179-200. 34. Liu DY, Thompson RJ: Selection and implementation of emotion regulation strategies in major depressive disorder: an integrative review. Clin Psychol Rev 2017, 57:183-194. 35. Szabo YZ, Warnecke AJ, Newton TL, Valentine JC: Rumination  and posttraumatic stress symptoms in trauma-exposed adults: a systematic review and meta-analysis. Anxiety Stress Coping 2017, 30:396-414. They review 59 articles on rumination and PTSD symptoms, and report significant correlations between the two. Trait rumination provided larger effect sizes than trauma-focused rumination, but the association between rumination and intrusive re-experiencing was especially high. These effects emphasize a transdiagnostic role for rumination, representing an aberrant form of risk assessment. 36. Michl LC, McLaughlin KA, Shepherd K, Nolen-Hoeksema S: Rumination as a mechanism linking stressful life. J Abnorm Psychol 2013, 122:339-352. 37. Dar KA, Iqbal N: Worry and rumination in generalized anxiety disorder and obsessive compulsive disorder. J Psychol 2015, 149:866-880. www.sciencedirect.com

38. Merino H, Senra C, Ferreiro F: Are worry and rumination specific pathways linking neuroticism and symptoms of anxiety and depression in patients with generalized anxietydisorder, major depressive disorder and mixed anxiety-depressive disorder? PLoS ONE 2016, 11:e0156169. 39. Yang MJ, Kim BN, Lee EH, Lee D, Yu BH, Jeon HJ, Kim JH: Diagnostic utility of worry and rumination: a comparison between generalized anxiety disorder and major depressive disorder. Psychiatry Clin Neurosci 2014, 68:712-720. 40. Gross CT, Canteras NS: The many paths to fear. Nat Rev Neurosci 2012, 13:651-658. 41. Silva BA, Mattucci C, Krzywkowski P, Murana E, Illarionova A, Grinevich V, Canteras NS, Ragozzino D, Gross CT: Independent hypothalamic circuits for social and predator fear. Nat Neurosci 2013, 16:1731-1733. 42. Motta SC, Carobrez AP, Canteras NS: The periaqueductal gray  and primal emotional processing critical to influence complex defensive responses, fear learning and reward seeking. Neurosci Biobehav Rev 2017, 76(Pt A):39-47. Motta et al. examined the role of the PAG as a hub providing emotional tone to prosencephalic sites mediating aversive and appetitive responses, and also involved in the organization of complex patterns of response to these motivation states, including the motivation to hunt and possibly seek drugs, in addition to defense. They suggest specific ascending pathways to cortico-hippocampal-amygdalar circuits in fear learning; connections that may be important in connectivity between subcortical and cortical components of the defense circuitry to unconditioned threat as well. 43. McNaughton N, Swart C, Neo P, Bates V, Glue P: Anti-anxiety drugs reduce conflict-specific “theta” – a possible human anxiety-specific biomarker. J Affect Disord 2013, 148:104-111. 44. Andersen SB, Moore RA, Venables L, Corr PJ: Electrophysiological correlates of anxious rumination. Int J Psychophysiol 2009, 71:156-169. 45. Pentkowski NS, Blanchard DC, Lever C, Litvin Y, Blanchard RJ: Effects of lesions to the dorsal and ventral hippocampus on defensive behaviors in rats. Eur J Neurosci 2006, 23:2185-2196. 46. Milad MR, Quirk GJ: Fear extinction as a model for translational neuroscience: ten years of progress. Annu Rev Psychol 2012, 63:129-151. 47. Chang CH, Grace AA: Inhibitory modulation of orbitofrontal cortex on medial prefrontal cortex-amygdala information flow. Cereb Cortex 2018, 28:1-8. 48. Nuss P: Anxiety disorders and GABA neurotransmission: a disturbance of modulation. Neuropsychiatr Dis Treat 2015, 11:165-175. 49. Greicius MD, Krasnow B, Reiss AL, Menon V: Functional connectivity in the resting brain: a network analysis of the default mode hypothesis. Proc Natl Acad Sci U S A 2003, 100:253-258. 50. Greicius MD, Supekar K, Menon V, Dougherty RF: Resting-state functional connectivity reflects structural connectivity in the default mode network. Cereb Cortex 2009, 19:72-78. 51. Coutinho JF, Fernandesl SV, Soares JM, Maia L, Gonc¸alves O´F, Sampaio A: Default mode network dissociation in depressive and anxiety states. Brain Imaging Behav 2016, 10:147-157. 52. Fresco DM, Roy AK, Adelsberg S, Seeley S, Garcı´a-Lesy E,  Liston C, Mennin DS: Distinct functional connectivities predict clinical response with emotion regulation therapy. Front Hum Neurosci 2017, 11:86. They focus on a subgroup of patients with generalized anxiety disorder or comorbid major depressive disorder that fail to show sufficient improvement with treatment. These patients display increased rumination, in addition to enhanced sensitivity to both threat/safety and reward/loss; suggesting involvement of the default mode network and the Salience Network. 16 sessions of Emotion Regulation Therapy, developed to target this profile, produced reductions in worry, which is associated with functional connectivity in the insular and parietal cortices, and in emotional decentering, associated with functional connectivity in the DN. 53. Andreescu C, Sheu LK, Tudorascu D, Walker S, Aizenstein H: The ages of anxiety – differences across the lifespan in the default Current Opinion in Behavioral Sciences 2018, 24:69–74

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mode network functional connectivity in generalized anxiety disorder. Int J Geriatr Psychiatry 2014, 29:704-712. 54. Hamilton JP, Farmer M, Fogelman P, Gotlib IH: Depressive  rumination, the default-mode network, and the dark matter of clinical neuroscience. Biol Psychiatry 2015, 78:224-230. The subgenual prefrontal cortex (sgPFC) shows elevated activity in association with depression or with response to negative affective challenge in either depressed or nondepressed individuals. Following a metaanalysis of the relationship of functional connectivity between the sqPFC and the default mode network, in major depression, the authors suggest increased functional activity between the two represents an integration of DMN-supported self-referential processes with the affective/behavioral withdrawal associated with the sgPFC. 55. Ho TC, Connolly CG, Henje Blom E, LeWinn KZ, Strigo IA, Paulus MP, Frank G, Max JE, Wu J, Chan M, Tapert SF, Simmons AN, Yang TT: Emotion-dependent functional connectivity of the default mode network in adolescent depression. Biol Psychiatry 2015, 78:635-646. 56. Downar J, Crawley AP, Mikulis DJ, Davis KD: A cortical network sensitive to stimulus salience in a neutral behavioral context across multiple sensory modalities. J Neurophysiol 2002, 87:615-620. 57. Hermans EJ, Henckens MJ, Joe¨ls M, Ferna´ndez G: Dynamic adaptation of large-scale brain networks in response to acute stressors. Trends Neurosci 2014, 37:304-314. 58. Maron-Katz A, Vaisvaser S, Lin T, Hendler T, Shamir R: A largescale perspective on stress-induced alterations in restingstate networks. Sci Rep 2016, 6:21503.

Current Opinion in Behavioral Sciences 2018, 24:69–74

59. Vaisvaser S, Lin T, Admon R, Podlipsky I, Greenman Y, Stern N, Fruchter E, Wald I, Pine DS, Tarrasch R, Bar-Haim Y, Hendler T: Neural traces of stress: cortisol related sustained enhancement of amygdala-hippocampal functional connectivity. Front Hum Neurosci 2013, 7:313. 60. Van Oort J, Tendolkar I, Hermans EJ, Mulders PC, Beckmann CF,  Schene AH, Ferna´ndez G, van Eijndhoven PF: How the brain connects in response to acute stress: a review at the human brain systems level. Neurosci Biobehav Rev 2017, 83:281-297. Van Oort et al. review the effects of a variety of stress induction procedures on activity and connectivity in two major brain networks; the salience network and the default mode network. They report a core coordinating role of the salience network in acute stress responses and also a surprising role of the default mode network (DMN). In the latter, within-network area connectivity increases when the individual is not responding to external stimuli or results, raising the question of its role in the stress response. 61. Peters SK, Dunlop K, Downar J: Cortico-striatal-thalamic loop circuits of the salience network: a central pathway in psychiatric disease and treatment. Front Syst Neurosci 2016, 10:104. 62. Morris SE, Cuthbert BN: Research Domain Criteria: cognitive systems, neural circuits, and dimensions of behavior. Dial Clin Neurosci 2012, 14:29-37. 63. Mobbs D, Hagan CC, Dalgleish T, Silston B, Pre´vost C: The ecology of human fear: survival optimization and the nervous system. Front Neurosci 2015, 9:55. 64. LeDoux JE: Anxious: Using the Brain to Understand and Treat Fear and Anxiety. New York: Viking; 2015.

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