IMVEST, an immersive multimodal virtual environment stress test for humans that adjusts challenge to individual's performance

Laboratory stressors are essential tools to study the human stress response. However, despite considerable progress in the development of stress induction procedures in recent years, the field is still missing standardization and the methods employed frequently require considerable personnel resources. Virtual reality (VR) offers flexible solutions to these problems, but available VR stress-induction tests still contain important sources of variation that challenge data interpretation. One of the major drawbacks is that tasks based on motivated performance do not adapt to individual abilities. Here, we provide open access to, and present, a novel and standardized immersive multimodal virtual environment stress test (IMVEST) in which participants are simultaneously exposed to mental -arithmetic calculations- and environmental challenges, along with intense visual and auditory stimulation. It contains critical elements of stress elicitation – perceived threat to physical self, social-evaluative threat and negative feedback, uncontrollability and unpredictability – and adjusts mathematical challenge to individual's ongoing performance. It is accompanied by a control VR scenario offering a comparable but not stressful situation. We validate and characterize the stress response to IMVEST in one-hundred-and-eighteen participants. Both cortisol and a wide range of autonomic nervous system (ANS) markers – extracted from the electrocardiogram, electrodermal activity and respiration – are significantly affected. We also show that ANS features can be used to train a stress prediction machine learning model that strongly discriminates between stress and control conditions, and indicates which aspects of IMVEST affect specific ANS components.

Stress-induced cognitive and psychopathological alterations

Reto Bisaz, Maria del Carmen Sandi Perez

Intensive research over the past few years has provided evidence, that stress is a potent modulator of brain function and cognition. In particular cognitive and emotional processes have been shown to be susceptible to modulation by stress. Whereas acute stress and/or a transient activation of the stress system can have beneficial consequences on learning and memory processes, prolonged or extensive stress can induce structural and functional alterations in various brain regions, which are accompanied by cognitive impairments and emotional changes. Moreover, increasing evidence points out that inappropriate stress response and/or control might be associated with the development and exacerbation of a variety of neuropsychiatric disorders. The neural cell adhesion molecule (NCAM), a cell surface macromolecule which is abundantly expressed in the vertebrate nervous system, plays a key role during neural development and has been implicated in activity induced synaptic plasticity as well as cognitive and emotional processes in adulthood. Altered expression of NCAM has been hypothesized to be one of the key events underlying structural and functional alterations in response to stress and accumulating evidence in rodents are showing decreased hippocampal NCAM expression after chronic stress. However, since most of the available evidence for this hypothesis has been either correlational or circumstantial, we aimed here to provide evidence for a causal involvement of NCAM in stress-induced cognitive and emotional disturbances. For this purpose, we evaluated the consequence of 4 weeks of chronic stress in adult wild-type mice on NCAM expression levels in brain regions, known to play a key role in cognition and emotions in a variety of cognitive and emotional tests. We found, that chronically stressed mice have reduced hippocampal NCAM expression levels and display learning and memory impairments, in hippocampus dependent behavioral tasks. Strikingly, similar patterns of cognitive impairments were also found in conditional NCAM-deficient mice, in which the NCAM gene is ablated in the forebrain postnatally. Interestingly, spatial learning and memory impairments of these mice could be recovered by treatments with NCAM mimetic peptides, which are known to potentiate NCAM functioning. Moreover, conditional NCAM-deficient mice displayed increased vulnerability to develop cognitive and emotional disturbances following subchronic stress exposure, a condition which has been shown to induce none (or only slight) structural and behavioral alterations in wild-type rodents. In the amygdala, a brain structure involved in consolidation of emotional memories, NCAM expression was increased in mice exposed to chronic stress. Additionally, chronically stressed mice displayed facilitated auditory fear conditioning, a behavioral task that critically depends on amygdala functions. Contrary, conditional NCAM-deficient mice displayed reduced conditioned auditory fear responses, which indicates a possible involvement of changes in amygdala NCAM expression and altered auditory fear conditioning. Together, the findings of the present study support a functional involvement of alterations in NCAM expression levels in stress-induced cognitive and emotional alterations and highlight this molecule as a potential target for the treatment of stress-related cognitive and emotional disturbances.

EPFL2009

Low vagal tone in two rat models of psychopathology involving high or low corticosterone stress responses

Sriparna Ghosal, Jocelin Grosse, Damien Sébastien Huzard, Maria del Carmen Sandi Perez

The two stress-responsive physiological systems, autonomic nervous system (ANS) and hypothalamus-pituitary-adrenal (HPA) axis exert complementary and interrelated actions in the organism. Individuals that suffer stress-related psychopathologies frequently present simultaneous alterations –i.e., either low or high- responsiveness– in both systems. However, there is scarce evidence establishing whether a priori alterations in these systems –i.e., independent of previous stress exposure– may predispose to the development of psychopathologies possibly due to the lack of animal models simultaneously involving aberrant HPA and SNS responses. In this study, we describe two animal models selectively bred according to their differential (either high, ‘High’, or low, ‘Low’) glucocorticoid responsiveness to stress, in comparison to a third line of rats that displays intermediate (‘Inter’) glucocorticoid responses. The two extreme lines may be considered distinct models of psychopathology; the High line representing a model of constitutive mood alterations while the Low line a model of vulnerability to develop stress-induced psychopathologies. We recorded the electrocardiogram in rats from the three lines and quantified heart rate variability and vagal tone indexes during rest and stress challenges. Rats from both High and Low lines displayed higher heart rate and lower basal vagal tone than the Inter group, both at resting and following stress exposure. Specific pharmacological manipulations probing the relative contribution of sympathetic and parasympathetic components on HR modulation confirmed a relative lower vagal tone in High and Low lines and discarded differences in the sympathetic regulation of heart rate between the lines. Therefore, the two genetically-selected High and Low glucocorticoid rat lines emerge as two valuable preclinical models of psychopathology involving two key risk factors for psychiatric and cardiovascular disorders, namely dysregulations in the HPA axis and cardiac vagal functioning.

2019

Stress-induced cognitive and psychopathological alterations

Reto Bisaz, Maria del Carmen Sandi Perez

EPFL2009

Low vagal tone in two rat models of psychopathology involving high or low corticosterone stress responses

Sriparna Ghosal, Jocelin Grosse, Damien Sébastien Huzard, Maria del Carmen Sandi Perez

2019