This meta-analysis reviews 208 laboratory studies of acute psychological stressors and tests a theoretical model delineating conditions capable of eliciting cortisol responses. Psychological stressors increased cortisol levels; however, effects varied widely across tasks. Consistent with the theoretical model, motivated performance tasks elicited cortisol responses if they were uncontrollable or characterized by social-evaluative threat (task performance could be negatively judged by others), when methodological factors and other stressor characteristics were controlled for. Tasks containing both uncontrollable and social-evaluative elements were associated with the largest cortisol and adrenocorticotropin hormone changes and the longest times to recovery. These findings are consistent with the animal literature on the physiological effects of uncontrollable social threat and contradict the belief that cortisol is responsive to all types of stressors.

http://anthro.vancouver.wsu.edu/media/Course_files/anth-260-edward-h-hagen/acute-stressors-and-cortisol-responses-a-theoretical-integration-and-synthesis-of-laboratory-research-1.pdf

Acute stressors and cortisol responses: a theoretical integration and synthesis of laboratory research.

A model of the neuropsychology of anxiety is proposed. The model is based in the first instance upon an analysis of the behavioural effects of the antianxiety drugs (benzodiazepines, barbiturates, and alcohol) in animals. From such psychopharmacologi-cal experiments the concept of a “behavioural inhibition system” (BIS) has been developed. This system responds to novel stimuli or to those associated with punishment or nonreward by inhibiting ongoing behaviour and increasing arousal and attention to the environment. It is activity in the BIS that constitutes anxiety and that is reduced by antianxiety drugs. The effects of the antianxiety drugs in the brain also suggest hypotheses concerning the neural substrate of anxiety. Although the benzodiazepines and barbiturates facilitate the effects of γ-aminobutyrate, this is insufficient to explain their highly specific behavioural effects. Because of similarities between the behavioural effects of certain lesions and those of the antianxiety drugs, it is proposed that these drugs reduce anxiety by impairing the functioning of a widespread neural system including the septo-hippocampal system (SHS), the Papez circuit, the prefrontal cortex, and ascending monoaminergic and cholinergic pathways which innervate these forebrain structures. Analysis of the functions of this system (based on anatomical, physiological, and behavioural data) suggests that it acts as a comparator: it compares predicted to actual sensory events and activates the outputs of the BIS when there is a mismatch or when the predicted event is aversive. Suggestions are made as to the functions of particular pathways within this overall brain system. The resulting theory is applied to the symptoms and treatment of anxiety in man, its relations to depression, and the personality of individuals who are susceptible to anxiety or depression.

https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S0140525X00013066

Précis of The Neuropsychology of Anxiety: An Enquiry into the Functions of the Septo-Hippocampal System..

http://umh1946.edu.umh.es/wp-content/uploads/sites/172/2015/04/Neurocircuitry-of-addiction1.pdf

Neurocircuitry of Addiction

Mechanisms and functional implications of adult neurogenesis.

Temperament describes the idea that individual behavioural differences are repeatable over time and across situations. This common phenomenon covers numerous traits, such as aggressiveness, avoidance of novelty, willingness to take risks, exploration, and sociality. The study of temperament is central to animal psychology, behavioural genetics, pharmacology, and animal husbandry, but relatively few studies have examined the ecology and evolution of temperament traits. This situation is surprising, given that temperament is likely to exert an important influence on many aspects of animal ecology and evolution, and that individual variation in temperament appears to be pervasive amongst animal species. Possible explanations for this neglect of temperament include a perceived irrelevance, an insufficient understanding of the link between temperament traits and fitness, and a lack of coherence in terminology with similar traits often given different names, or different traits given the same name. We propose that temperament can and should be studied within an evolutionary ecology framework and provide a terminology that could be used as a working tool for ecological studies of temperament. Our terminology includes five major temperament trait categories: shyness-boldness, exploration-avoidance, activity, sociability and aggressiveness. This terminology does not make inferences regarding underlying dispositions or psychological processes, which may have restrained ecologists and evolutionary biologists from working on these traits. We present extensive literature reviews that demonstrate that temperament traits are heritable, and linked to fitness and to several other traits of importance to ecology and evolution. Furthermore, we describe ecologically relevant measurement methods and point to several ecological and evolutionary topics that would benefit from considering temperament, such as phenotypic plasticity, conservation biology, population sampling, and invasion biology.

/pdf/integrating-animal-temperament-within-ecology-and-evolution-2rq68t04zd.pdf

Integrating animal temperament within ecology and evolution.

Social defeat stress selectively alters mesocorticolimbic dopamine release: an in vivo microdialysis study

Background and rationale Aggressive outbursts that result in harm and injury present a major problem for the public health and criminal justice systems, but there are no adequate treatment options Obstacles at the level of social policy, institutional regulation, and scientific strategy in developing animal models continue to impede the development of specific anti-aggressive agents for emergency and long-term treatments Objective To be more relevant to the clinical situation, preclinical aggression research has begun to focus on the neurobiological determinants of escalated aggressive behavior that exceeds species-typical patterns It is the goal of this review to examine novel pharmacological and molecular tools that target the neural mechanisms for different kinds of aggressive behavior more selectively than previously possible and to outline potential pharmacotherapeutic options Results and conclusions (1) The preclinical focus on the behavioral characteristics and determinants of intense aggression promises to be most relevant to the clinical distinction between the proposed impulsive-reactive-hostile-affective subtypes of human aggression and the controlled-proactive-instrumental-predatory subtypes of aggression The neural circuits for many types of human and animal aggression critically involve serotonin, dopamine and gamma-aminobutyric acid (GABA) and specific receptor subtypes (2) The dynamic changes in frontal cortical serotonin that are triggered by engaging in aggressive behavior imply that serotonergic drug effects are largely determined by the functional state of the receptors at the time of drug treatment Of the numerous 5-HT receptors currently identified, the 5-HT(1B) receptors offer a promising target for reducing impulsive aggressive behavior, particularly if the action can be limited to sites in the central nervous system (3) Aggressive confrontations are salient stressors, both for the aggressor as well as the victim of aggression, that are accompanied by activation of the mesocorticolimbic but not the striatal dopamine system Dopaminergic manipulations, particularly targeting the D(2) receptor family, can influence aggressive behavior in animals and human patients, suggesting that mesocorticolimbic dopamine may have important enabling or permissive functions (4) GABA is critical in the neurochemical control of aggressive behavior as evidenced by studies that directly modify GABAergic neurotransmission and neurochemical studies that correlate GABA measurements with aggressive behavioral responses in several animal species The GABA(A) receptor complex is a mechanism through which certain benzodiazepines and alcohol enhance and inhibit aggressive behaviors Social and pharmacological experiences decisively determine the effects of GABAergic positive modulators on aggression

Social and neural determinants of aggressive behavior: pharmacotherapeutic targets at serotonin, dopamine and gamma-aminobutyric acid systems.

Essential Roles for the Abl and Arg Tyrosine Kinases in Neurulation

Mice exposed to repeated attacks by other mice showed decreased nociception in response to radiant heat focused on their tails. This form of analgesia was blocked by centrally acting opiate antagonists and was not observed in morphine-tolerant mice; furthermore, mice repeatedly subjected to defeat. Mice of the CXBK strain, which respond weakly to morphine, displayed only moderate analgesia following defeat. These findings suggest that endogenous opioid-mediated analgesic mechanisms are readily activated by situations involving biologically significant forms of stress, such as defeat.

https://science.sciencemag.org/content/sci/215/4539/1520.full.pdf

Klaus A. Miczek

Papers

Social defeat stress selectively alters mesocorticolimbic dopamine release: an in vivo microdialysis study

Social and neural determinants of aggressive behavior: pharmacotherapeutic targets at serotonin, dopamine and gamma-aminobutyric acid systems.

Essential Roles for the Abl and Arg Tyrosine Kinases in Neurulation

Opioid-like analgesia in defeated mice

Aggressive behavioral phenotypes in mice.