Stress (biology)

(Redirected from Stress (physiology))

Stress, whether physiological, biological or psychological, is an organism's response to a stressor such as an environmental condition.[1] When stressed by stimuli that alter an organism's environment, multiple systems respond across the body.[2] In humans and most mammals, the autonomic nervous system and hypothalamic-pituitary-adrenal (HPA) axis are the two major systems that respond to stress.[3] Two well-known hormones that humans produce during stressful situations are adrenaline and cortisol.[4]

Schematic overview of the classes of stresses in plants
Neurohormonal response to stress

The sympathoadrenal medullary (SAM) axis may activate the fight-or-flight response through the sympathetic nervous system, which dedicates energy to more relevant bodily systems to acute adaptation to stress, while the parasympathetic nervous system returns the body to homeostasis.

The second major physiological stress-response center, the HPA axis, regulates the release of cortisol, which influences many bodily functions such as metabolic, psychological and immunological functions. The SAM and HPA axes are regulated by several brain regions, including the limbic system, prefrontal cortex, amygdala, hypothalamus, and stria terminalis.[3] Through these mechanisms, stress can alter memory functions, reward, immune function, metabolism and susceptibility to diseases.[5]

Disease risk is particularly pertinent to mental illnesses, whereby chronic or severe stress remains a common risk factor for several mental illnesses.[6][7]

Psychology

edit

Acute stressful situations where the stress experienced is severe is a cause of change psychologically to the detriment of the well-being of the individual, such that symptomatic derealization and depersonalization, and anxiety and hyperarousal, are experienced.[8] The International Classification of Diseases includes a group of mental and behavioral disorders which have their aetiology in reaction to severe stress and the consequent adaptive response.[9][10] Chronic stress, and a lack of coping resources available, or used by an individual, can often lead to the development of psychological issues such as delusions,[11] depression and anxiety (see below for further information).[12] Chronic stress also causes brain atrophy, which is the loss of neurons and the connections between them. It affects the part of the brain that is important for learning, responding to the stressors and cognitive flexibility.[13]

Chronic stressors may not be as intense as acute stressors such as natural disaster or a major accident, but persist over longer periods of time and tend to have a more negative effect on health because they are sustained and thus require the body's physiological response to occur daily.[14] This depletes the body's energy more quickly and usually occurs over long periods of time, especially when these microstressors cannot be avoided (i.e. stress of living in a dangerous neighborhood). See allostatic load for further discussion of the biological process by which chronic stress may affect the body. For example, studies have found that caregivers, particularly those of dementia patients, have higher levels of depression and slightly worse physical health than non-caregivers.[14]

When humans are under chronic stress, permanent changes in their physiological, emotional, and behavioral responses may occur.[15] Chronic stress can include events such as caring for a spouse with dementia, or may result from brief focal events that have long term effects, such as experiencing a sexual assault. Studies have also shown that psychological stress may directly contribute to the disproportionately high rates of coronary heart disease morbidity and mortality and its etiologic risk factors. Specifically, acute and chronic stress have been shown to raise serum lipids and are associated with clinical coronary events.[16]

However, it is possible for individuals to exhibit hardiness—a term referring to the ability to be both chronically stressed and healthy.[17] Even though psychological stress is often connected with illness or disease, most healthy individuals can still remain disease-free after being confronted with chronic stressful events. This suggests that there are individual differences in vulnerability to the potential pathogenic effects of stress; individual differences in vulnerability arise due to both genetic and psychological factors. In addition, the age at which the stress is experienced can dictate its effect on health. Research suggests chronic stress at a young age can have lifelong effects on the biological, psychological, and behavioral responses to stress later in life.[18]

Etymology and historical usage

edit

The term "stress" had none of its contemporary connotations before the 1920s. It is a form of the Middle English destresse, derived via Old French from the Latin stringere, "to draw tight".[19] The word had long been in use in physics to refer to the internal distribution of a force exerted on a material body, resulting in strain. In the 1920s and '30s, biological and psychological circles occasionally used "stress" to refer to a physiological or environmental perturbation that could cause physiological and mental "strain". The amount of strain in reaction to stress depends on the resilience. Excessive strain would appear as illness.[20][21]

Walter Cannon used it in 1926 to refer to external factors that disrupted what he called homeostasis.[22] But "...stress as an explanation of lived experience is absent from both lay and expert life narratives before the 1930s".[23] Physiological stress represents a wide range of physical responses that occur as a direct effect of a stressor causing an upset in the homeostasis of the body. Upon immediate disruption of either psychological or physical equilibrium the body responds by stimulating the nervous, endocrine, and immune systems. The reaction of these systems causes a number of physical changes that have both short- and long-term effects on the body.[24]

The Holmes and Rahe stress scale was developed as a method of assessing the risk of disease from life changes.[25] The scale lists both positive and negative changes that elicit stress. These include things such as a major holiday or marriage, or death of a spouse and firing from a job.[citation needed]

Biological need for equilibrium

edit

Homeostasis is a concept central to the idea of stress.[26] In biology, most biochemical processes strive to maintain equilibrium (homeostasis), a steady state that exists more as an ideal and less as an achievable condition. Environmental factors, internal or external stimuli, continually disrupt homeostasis; an organism's present condition is a state of constant flux moving about a homeostatic point that is that organism's optimal condition for living.[27] Factors causing an organism's condition to diverge too far from homeostasis can be experienced as stress. A life-threatening situation such as a major physical trauma or prolonged starvation can greatly disrupt homeostasis. On the other hand, an organism's attempt at restoring conditions back to or near homeostasis, often consuming energy and natural resources, can also be interpreted as stress.[28] The brain cannot sustain an equilibrium under chronic stress; the accumulation of such an ever-deepening deficit is called chronic stress.[13]

The ambiguity in defining this phenomenon was first recognized by Hans Selye (1907–1982) in 1926. In 1951 a commentator loosely summarized Selye's view of stress as something that "...in addition to being itself, was also the cause of itself, and the result of itself".[29][30]

First to use the term in a biological context, Selye continued to define stress as "the non-specific response of the body to any demand placed upon it". Neuroscientists such as Bruce McEwen and Jaap Koolhaas believe that stress, based on years of empirical research, "should be restricted to conditions where an environmental demand exceeds the natural regulatory capacity of an organism".[31] The brain cannot live in an harsh family environment, it needs some sort of stability between another brain. People who have reported being raised in harsh environments such as verbal and physical aggression have showed a more immune dysfunction and more metabolic dysfunction.[13] Indeed, in 1995 Toates already defined stress as a "chronic state that arises only when defense mechanisms are either being chronically stretched or are actually failing,"[32] while according to Ursin (1988) stress results from an inconsistency between expected events ("set value") and perceived events ("actual value") that cannot be resolved satisfactorily,[33] which also puts stress into the broader context of cognitive-consistency theory.[34]

Biological background

edit

Stress can have many profound effects on the human biological systems.[35] Biology primarily attempts to explain major concepts of stress using a stimulus-response paradigm, broadly comparable to how a psychobiological sensory system operates. The central nervous system (brain and spinal cord) plays a crucial role in the body's stress-related mechanisms. Whether one should interpret these mechanisms as the body's response to a stressor or embody the act of stress itself is part of the ambiguity in defining what exactly stress is.

The central nervous system works closely with the body's endocrine system to regulate these mechanisms. The sympathetic nervous system becomes primarily active during a stress response, regulating many of the body's physiological functions in ways that ought to make an organism more adaptive to its environment. Below there follows a brief biological background of neuroanatomy and neurochemistry and how they relate to stress.[36]

Stress, either severe, acute stress or chronic low-grade stress may induce abnormalities in three principal regulatory systems in the body: serotonin systems, catecholamine systems, and the hypothalamic-pituitary-adrenocortical axis. Aggressive behavior has also been associated with abnormalities in these systems.[37]

Biology of stress

edit
 
Human brain:
hypothalamus =  
amygdala =  
hippocampus/fornix =  
pons=  
pituitary gland=  

The brain endocrine interactions are relevant in the translation of stress into physiological and psychological changes. The autonomic nervous system (ANS), as mentioned above, plays an important role in translating stress into a response. The ANS responds reflexively to both physical stressors (for example baroreception), and to higher level inputs from the brain.[38]

The ANS is composed of the parasympathetic nervous system and sympathetic nervous system, two branches that are both tonically active with opposing activities. The ANS directly innervates tissue through the postganglionic nerves, which is controlled by preganglionic neurons originating in the intermediolateral cell column. The ANS receives inputs from the medulla, hypothalamus, limbic system, prefrontal cortex, midbrain and monoamine nuclei.[39]

The activity of the sympathetic nervous system drives what is called the "fight or flight" response. The fight or flight response to emergency or stress involves mydriasis, increased heart rate and force contraction, vasoconstriction, bronchodilation, glycogenolysis, gluconeogenesis, lipolysis, sweating, decreased motility of the digestive system, secretion of the epinephrine and cortisol from the adrenal medulla, and relaxation of the bladder wall. The parasympathetic nervous response, "rest and digest", involves return to maintaining homeostasis, and involves miosis, bronchoconstriction, increased activity of the digestive system, and contraction of the bladder walls.[38] Complex relationships between protective and vulnerability factors on the effect of childhood home stress on psychological illness, cardiovascular illness and adaption have been observed.[40] ANS related mechanisms are thought to contribute to increased risk of cardiovascular disease after major stressful events.[41]

The HPA axis is a neuroendocrine system that mediates a stress response. Neurons in the hypothalamus, particularly the paraventricular nucleus, release vasopressin and corticotropin releasing hormone, which travel through the hypophysial portal vessel where they travel to and bind to the corticotropin-releasing hormone receptor on the anterior pituitary gland. Multiple CRH peptides have been identified, and receptors have been identified on multiple areas of the brain, including the amygdala. CRH is the main regulatory molecule of the release of ACTH.[42]

The secretion of ACTH into systemic circulation allows it to bind to and activate Melanocortin receptor, where it stimulates the release of steroid hormones. Steroid hormones bind to glucocorticoid receptors in the brain, providing negative feedback by reducing ACTH release. Some evidence supports a second long term feedback that is non-sensitive to cortisol secretion. The PVN of the hypothalamus receives inputs from the nucleus of the solitary tract, and lamina terminalis. Through these inputs, it receives and can respond to changes in blood.[42]

The PVN innervation from the brain stem nuclei, particularly the noradrenergic nuclei stimulate CRH release. Other regions of the hypothalamus both directly and indirectly inhibit HPA axis activity. Hypothalamic neurons involved in regulating energy balance also influence HPA axis activity through the release of neurotransmitters such as neuropeptide Y, which stimulates HPA axis activity. Generally, the amygdala stimulates, and the prefrontal cortex and hippocampus attenuate, HPA axis activity; however, complex relationships do exist between the regions.[42]

The immune system may be heavily influenced by stress. The sympathetic nervous system innervates various immunological structures, such as bone marrow and the spleen, allowing for it to regulate immune function. The adrenergic substances released by the sympathetic nervous system can also bind to and influence various immunological cells, further providing a connection between the systems. The HPA axis ultimately results in the release of cortisol, which generally has immunosuppressive effects. However, the effect of stress on the immune system is disputed, and various models have been proposed in an attempt to account for both the supposedly "immunodeficiency" linked diseases and diseases involving hyper activation of the immune system. One model proposed to account for this suggests a push towards an imbalance of cellular immunity(Th1) and humoral immunity(Th2). The proposed imbalance involved hyperactivity of the Th2 system leading to some forms of immune hypersensitivity, while also increasing risk of some illnesses associated with decreased immune system function, such as infection and cancer.[7]

Effects of chronic stress

edit

Chronic stress is a term sometimes used to differentiate it from acute stress. Definitions differ, and may be along the lines of continual activation of the stress response,[43] stress that causes an allostatic shift in bodily functions,[5] or just as "prolonged stress".[44] For example, results of one study demonstrated that individuals who reported relationship conflict lasting one month or longer have a greater risk of developing illness and show slower wound healing. It can also reduce the benefits of receiving common vaccines.[13] Similarly, the effects that acute stressors have on the immune system may be increased when there is perceived stress and/or anxiety due to other events. For example, students who are taking exams show weaker immune responses if they also report stress due to daily hassles.[45] While responses to acute stressors typically do not impose a health burden on young, healthy individuals, chronic stress in older or unhealthy individuals may have long-term effects that are detrimental to health.[46]

Immunological

edit

Acute time-limited stressors, or stressors that lasted less than two hours, results in an up regulation of natural immunity and down regulation of specific immunity. This type of stress saw in increase in granulocytes, natural killer cells, IgA, Interleukin 6, and an increase in cell cytotoxicity. Brief naturalistic stressors elicit a shift from Th1 (cellular) to Th2 (humoral) immunity, while decreased T-cell proliferation, and natural killer cell cytotoxicity. Stressful event sequences did not elicit a consistent immune response; however, some observations such as decreased T-Cell proliferation and cytotoxicity, increase or decrease in natural killer cell cytotoxicity, and an increase in mitogen PHA. Chronic stress elicited a shift toward Th2 immunity, as well as decreased interleukin 2, T cell proliferation, and antibody response to the influenza vaccine. Distant stressors did not consistently elicit a change in immune function.[7] Another response to high impacts of chronic stress that lasts for a long period of time, is more immune dysfunction and more metabolic dysfunction. It is proven in studies that when continuously being in stressful situations, it is more likely to get sick. Also, when being exposed to stress, some claim that the body metabolizes the food in a certain way that adds extra calories to the meal, regardless of the nutritional values of the food.[13]

Infectious

edit

Some studies have observed increased risk of upper respiratory tract infection during chronic life stress. In patients with HIV, increased life stress and cortisol was associated with poorer progression of HIV.[43] Also with an increased level of stress, studies have proven evidence that it can reactivate latent herpes viruses.[47]

Chronic disease

edit

A link has been suggested between chronic stress and cardiovascular disease.[43] Stress appears to play a role in hypertension, and may further predispose people to other conditions associated with hypertension.[48] Stress may precipitate abuse of drugs and/or alcohol.[5] Stress may also contribute to aging and chronic diseases in aging, such as depression and metabolic disorders.[49]

The immune system also plays a role in stress and the early stages of wound healing. It is responsible for preparing the tissue for repair and promoting recruitment of certain cells to the wound area.[45] Consistent with the fact that stress alters the production of cytokines, Graham et al. found that chronic stress associated with care giving for a person with Alzheimer's disease leads to delayed wound healing. Results indicated that biopsy wounds healed 25% more slowly in the chronically stressed group, or those caring for a person with Alzheimer's disease.[50]

Development

edit

Chronic stress has also been shown to impair developmental growth in children by lowering the pituitary gland's production of growth hormone, as in children associated with a home environment involving serious marital discord, alcoholism, or child abuse.[51] Chronic stress also has a lot of illnesses and health care problems other than mental that comes with it. Severe chronic stress for long periods of time can lead to an increased chance of catching illnesses such as diabetes, cancer, depression, heart disease and Alzheimer's disease.[13] More generally, prenatal life, infancy, childhood, and adolescence are critical periods in which the vulnerability to stressors is particularly high.[52][53] This can lead to psychiatric and physical diseases which have long term impacts on an individual.[13]

Psychopathology

edit

Chronic stress is seen to affect the parts of the brain where memories are processed through and stored. When people feel stressed, stress hormones get over-secreted, which affects the brain. This secretion is made up of glucocorticoids, including cortisol, which are steroid hormones that the adrenal gland releases, although this can increase storage of flashbulb memories it decreases long-term potentiation (LTP).[54][55] The hippocampus is important in the brain for storing certain kinds of memories and damage to the hippocampus can cause trouble in storing new memories but old memories, memories stored before the damage, are not lost.[56] Also high cortisol levels can be tied to the deterioration of the hippocampus and decline of memory that many older adults start to experience with age.[55] These mechanisms and processes may therefore contribute to age-related disease, or originate risk for earlier-onset disorders. For instance, extreme stress (e.g. trauma) is a requisite factor to produce stress-related disorders such as post-traumatic stress disorder.[6]

Chronic stress also shifts learning, forming a preference for habit based learning, and decreased task flexibility and spatial working memory, probably through alterations of the dopaminergic systems.[39] Stress may also increase reward associated with food, leading to weight gain and further changes in eating habits.[57] Stress may contribute to various disorders, such as fibromyalgia,[58] chronic fatigue syndrome,[59] depression,[60] as well as other mental illnesses[13] and functional somatic syndromes.[61]

Psychological concepts

edit

Eustress

edit

Selye published in year 1975 a model dividing stress into eustress and distress.[62] Where stress enhances function (physical or mental, such as through strength training or challenging work), it may be considered eustress. Persistent stress that is not resolved through coping or adaptation, deemed distress, may lead to anxiety or withdrawal (depression) behavior.

The difference between experiences that result in eustress and those that result in distress is determined by the disparity between an experience (real or imagined) and personal expectations, and resources to cope with the stress. Alarming experiences, either real or imagined, can trigger a stress response.[63]

Coping

edit

Responses to stress include adaptation, psychological coping such as stress management, anxiety, and depression. Over the long term, distress can lead to diminished health and/or increased propensity to illness; to avoid this, stress must be managed.

Stress management encompasses techniques intended to equip a person with effective coping mechanisms for dealing with psychological stress, with stress defined as a person's physiological response to an internal or external stimulus that triggers the fight-or-flight response. Stress management is effective when a person uses strategies to cope with or alter stressful situations.

There are several ways of coping with stress,[64] such as controlling the source of stress or learning to set limits and to say "no" to some of the demands that bosses or family members may make.

A person's capacity to tolerate the source of stress may be increased by thinking about another topic such as a hobby, listening to music, or spending time in a wilderness.

A way to control stress is first dealing with what is causing the stress if it is something the individual has control over. Other methods to control stress and reduce it can be: to not procrastinate and leave tasks for the last minute, do things you like, exercise, do breathing routines, go out with friends, and take a break. Having support from a loved one also helps a lot in reducing stress.[55]

One study showed that the power of having support from a loved one, or just having social support, lowered stress in individual subjects. Painful shocks were applied to married women's ankles. In some trials women were able to hold their husband's hand, in other trials they held a stranger's hand, and then held no one's hand. When the women were holding their husband's hand, the response was reduced in many brain areas. When holding the stranger's hand the response was reduced a little, but not as much as when they were holding their husband's hand. Social support helps reduce stress and even more so if the support is from a loved one.[55]

Cognitive appraisal

edit

Lazarus[65] argued that, in order for a psychosocial situation to be stressful, it must be appraised as such. He argued that cognitive processes of appraisal are central in determining whether a situation is potentially threatening, constitutes a harm/loss or a challenge, or is benign.

Both personal and environmental factors influence this primary appraisal, which then triggers the selection of coping processes. Problem-focused coping is directed at managing the problem, whereas emotion-focused coping processes are directed at managing the negative emotions. Secondary appraisal refers to the evaluation of the resources available to cope with the problem, and may alter the primary appraisal.

In other words, primary appraisal includes the perception of how stressful the problem is and the secondary appraisal of estimating whether one has more than or less than adequate resources to deal with the problem that affects the overall appraisal of stressfulness. Further, coping is flexible in that, in general, the individual examines the effectiveness of the coping on the situation; if it is not having the desired effect, they will, in general, try different strategies.[66]

Assessment

edit

Health risk factors

edit

Both negative and positive stressors can lead to stress. The intensity and duration of stress changes depending on the circumstances and emotional condition of the person with it (Arnold. E and Boggs. K. 2007). Some common categories and examples of stressors include:

General adaptation syndrome

edit
 
A diagram of the general adaptation syndrome model

Physiologists define stress as how the body reacts to a stressor - a stimulus, real or imagined. Acute stressors affect an organism in the short term; chronic stressors over the longer term. The general adaptation syndrome (GAS), developed by Hans Selye, is a profile of how organisms respond to stress; GAS is characterized by three phases: a nonspecific alarm mobilization phase, which promotes sympathetic nervous system activity; a resistance phase, during which the organism makes efforts to cope with the threat; and an exhaustion phase, which occurs if the organism fails to overcome the threat and depletes its physiological resources.[72]

Stage 1

edit

Alarm is the first stage, which is divided into two phases: the shock phase and the antishock phase.[73]

Stage 2

edit

Resistance is the second stage. During this stage, increased secretion of glucocorticoids intensifies the body's systemic response. Glucocorticoids can increase the concentration of glucose, fat, and amino acid in blood. In high doses, one glucocorticoid, cortisol, begins to act similarly to a mineralocorticoid (aldosterone) and brings the body to a state similar to hyperaldosteronism. If the stressor persists, it becomes necessary to attempt some means of coping with the stress. The body attempts to respond to stressful stimuli, but after prolonged activation, the body's chemical resources will be gradually depleted, leading to the final stage.

Stage 3

edit

The third stage could be either exhaustion or recovery:

  • Recovery stage follows when the system's compensation mechanisms have successfully overcome the stressor effect (or have completely eliminated the factor which caused the stress). The high glucose, fat and amino acid levels in blood prove useful for anabolic reactions, restoration of homeostasis and regeneration of cells.
  • Exhaustion is the alternative third stage in the GAS model. At this point, all of the body's resources are eventually depleted and the body is unable to maintain normal function. The initial autonomic nervous system symptoms may reappear (panic attacks, muscle aches, sore eyes, difficulty breathing, fatigue, heartburn, high blood pressure, and difficulty sleeping, etc.). If stage three is extended, long-term damage may result (prolonged vasoconstriction results in ischemia which in turn leads to cell necrosis), as the body's immune system becomes exhausted, and bodily functions become impaired, resulting in decompensation.

The result can manifest itself in obvious illnesses, such as general trouble with the digestive system (e.g. occult bleeding, melena, constipation/obstipation), diabetes, or even cardiovascular problems (angina pectoris), along with clinical depression and other mental illnesses.[citation needed]

History in research

edit

The current usage of the word stress arose out of Hans Selye's 1930s experiments. He started to use the term to refer not just to the agent but to the state of the organism as it responded and adapted to the environment. His theories of a universal non-specific stress response attracted great interest and contention in academic physiology and he undertook extensive research programs and publication efforts.[74]

While the work attracted continued support from advocates of psychosomatic medicine, many in experimental physiology concluded that his concepts were too vague and unmeasurable. During the 1950s, Selye turned away from the laboratory to promote his concept through popular books and lecture tours. He wrote for both non-academic physicians and, in an international bestseller entitled Stress of Life, for the general public.

A broad biopsychosocial concept of stress and adaptation offered the promise of helping everyone achieve health and happiness by successfully responding to changing global challenges and the problems of modern civilization. Selye coined the term "eustress" for positive stress, by contrast to distress. He argued that all people have a natural urge and need to work for their own benefit, a message that found favor with industrialists and governments.[74] He also coined the term stressor to refer to the causative event or stimulus, as opposed to the resulting state of stress.

Selye was in contact with the tobacco industry from 1958 and they were undeclared allies in litigation and the promotion of the concept of stress, clouding the link between smoking and cancer, and portraying smoking as a "diversion", or in Selye's concept a "deviation", from environmental stress.[75]

From the late 1960s, academic psychologists started to adopt Selye's concept; they sought to quantify "life stress" by scoring "significant life events", and a large amount of research was undertaken to examine links between stress and disease of all kinds. By the late 1970s, stress had become the medical area of greatest concern to the general population, and more basic research was called for to better address the issue. There was also renewed laboratory research into the neuroendocrine, molecular, and immunological bases of stress, conceived as a useful heuristic not necessarily tied to Selye's original hypotheses. The US military became a key center of stress research, attempting to understand and reduce combat neurosis and psychiatric casualties.[74]

The psychiatric diagnosis post-traumatic stress disorder (PTSD) was coined in the mid-1970s, in part through the efforts of anti-Vietnam War activists and the Vietnam Veterans Against the War, and Chaim F. Shatan. The condition was added to the Diagnostic and Statistical Manual of Mental Disorders as posttraumatic stress disorder in 1980.[76] PTSD was considered a severe and ongoing emotional reaction to an extreme psychological trauma, and as such often associated with soldiers, police officers, and other emergency personnel. The stressor may involve threat to life (or viewing the actual death of someone else), serious physical injury, or threat to physical or psychological integrity. In some cases, it can also be from profound psychological and emotional trauma, apart from any actual physical harm or threat. Often, however, the two are combined.

By the 1990s, "stress" had become an integral part of modern scientific understanding in all areas of physiology and human functioning, and one of the great metaphors of Western life. Focus grew on stress in certain settings, such as workplace stress, and stress management techniques were developed. The term also became a euphemism, a way of referring to problems and eliciting sympathy without being explicitly confessional, just "stressed out". It came to cover a huge range of phenomena from mild irritation to the kind of severe problems that might result in a real breakdown of health. In popular usage, almost any event or situation between these extremes could be described as stressful.

The American Psychological Association's 2015 Stress In America Study[77] found that nationwide stress is on the rise and that the three leading sources of stress were "money", "family responsibility", and "work".

See also

edit

References

edit
  1. ^ Nachiappan, Vasanthi; Muthukumar, Kannan (December 2010). "Cadmium-induced oxidative stress in Saccharomyces cerevisiae". Indian Journal of Biochemistry and Biophysics. 47 (6): 383–387. ISSN 0975-0959. PMID 21355423. Archived from the original on 25 July 2019. Retrieved 1 August 2019.
  2. ^ Muthukumar, Kannan; Nachiappan, Vasanthi (1 December 2013). "Phosphatidylethanolamine from Phosphatidylserine Decarboxylase2 is Essential for Autophagy Under Cadmium Stress in Saccharomyces cerevisiae". Cell Biochemistry and Biophysics. 67 (3): 1353–1363. doi:10.1007/s12013-013-9667-8. ISSN 1559-0283. PMID 23743710. S2CID 16393480.
  3. ^ a b Ulrich-Lai, Yvonne M.; Herman, James P. (7 February 2017). "Neural Regulation of Endocrine and Autonomic Stress Responses". Nature Reviews Neuroscience. 10 (6): 397–409. doi:10.1038/nrn2647. ISSN 1471-003X. PMC 4240627. PMID 19469025.
  4. ^ "Biology of stress". CESH / CSHS. Retrieved 27 September 2022.
  5. ^ a b c Stephens, Mary Ann C.; Wand, Gary (1 January 2012). "Stress and the HPA Axis". Alcohol Research: Current Reviews. 34 (4): 468–483. ISSN 2168-3492. PMC 3860380. PMID 23584113.
  6. ^ a b Notaras, Michael; van den Buuse, Maarten (3 January 2020). "Neurobiology of BDNF in fear memory, sensitivity to stress, and stress-related disorders". Molecular Psychiatry. 25 (10): 2251–2274. doi:10.1038/s41380-019-0639-2. ISSN 1476-5578. PMID 31900428. S2CID 209540967.
  7. ^ a b c Segerstrom, Suzanne C.; Miller, Gregory E. (7 February 2017). "Psychological Stress and the Human Immune System: A Meta-Analytic Study of 30 Years of Inquiry". Psychological Bulletin. 130 (4): 601–630. doi:10.1037/0033-2909.130.4.601. ISSN 0033-2909. PMC 1361287. PMID 15250815.
  8. ^ Ehlers, Anke; Harvey, Allison G.; Bryant, Richard A. (October 2012) [February 2012]. "Acute stress reactions". In Gelder, Michael; Andreasen, Nancy; Lopez-Ibor, Juan; Geddes, John (eds.). New Oxford Textbook of Psychiatry (2nd ed.). oxfordmedicine.com: Oxford University Press. doi:10.1093/med/9780199696758.001.0001. ISBN 9780199696758. Retrieved 3 July 2021 – via Google.
  9. ^ Drs; Sartorius, Norman; Henderson, A.S.; Strotzka, H.; Lipowski, Z.; Yu-cun, Shen; You-xin, Xu; Strömgren, E.; Glatzel, J.; Kühne, G.-E.; Misès, R.; Soldatos, C.R.; Pull, C.B.; Giel, R.; Jegede, R.; Malt, U.; Nadzharov, R.A.; Smulevitch, A.B.; Hagberg, B.; Perris, C.; Scharfetter, C.; Clare, A.; Cooper, J.E.; Corbett, J.A.; Griffith Edwards, J.; Gelder, M.; Goldberg, D.; Gossop, M.; Graham, P.; Kendell, R.E.; Marks, I.; Russell, G.; Rutter, M.; Shepherd, M.; West, D.J.; Wing, J.; Wing, L.; Neki, J.S.; Benson, F.; Cantwell, D.; Guze, S.; Helzer, J.; Holzman, P.; Kleinman, A.; Kupfer, D.J.; Mezzich, J.; Spitzer, R.; Lokar, J. "The ICD-10 Classification of Mental and Behavioural Disorders Clinical descriptions and diagnostic guidelines" (PDF). www.who.int World Health Organization. Microsoft Word. bluebook.doc. p. 110. Retrieved 23 June 2021 – via Microsoft Bing.
  10. ^ "Meaning of aetiology in English". dictionary.cambridge.org (Cambridge University Press). Retrieved 3 July 2021.
  11. ^ Kingston, Cara; Schuurmans-Stekhoven, James (2016). "Life hassles and delusional ideation: Scoping the potential role of cognitive and affective mediators". Psychology and Psychotherapy: Theory, Research and Practice. 89 (4): 445–463. doi:10.1111/papt.12089. PMID 26846698.
  12. ^ Schlotz W, Yim IS, Zoccola PM, Jansen L, Schulz P (2011). The perceived stress reactivity scale: Measurement invariance, stability, and validity in three countries. Psychol Assess. (pp. 80–94)
  13. ^ a b c d e f g h Barrett, Lisa Feldman (2020). 7 and a half lessons about the brain. Picador.
  14. ^ a b Pinquart M.; Sörensen S. (2003). "Differences between caregivers and non-caregivers in psychological health and physical health: a meta-analysis". Psychology and Aging. 18 (2): 250–267. doi:10.1037/0882-7974.18.2.250. PMID 12825775.
  15. ^ Cohen, S; Janicki-Deverts, D; Miller, GE. (2007). "Psychological Stress and Disease" (PDF). JAMA. 298 (14): 1685–1687. doi:10.1001/jama.298.14.1685. PMID 17925521. S2CID 12159960. Archived from the original (PDF) on 24 September 2015. Retrieved 5 July 2015.
  16. ^ Calderon, R.; Schneider, R. H.; Alexander, C. N.; Myers, H. F.; Nidich, S. I.; Haney, C. (1999). "Stress, stress reduction and hypercholesterolemia in African Americans: a review". Ethnicity & Disease. 9 (3): 451–462. ISSN 1049-510X. PMID 10600068.
  17. ^ Kobasa, S. C. (1982). The Hardy Personality: Toward a Social Psychology of Stress and Health. In G. S. Sanders & J. Suls (Eds.), Social Psychology of Health and Illness (pp. 1–25). Hillsdale, NJ: Lawrence Erlbaum Assoc.
  18. ^ Miller, G.; Chen, E.; Cole, S. W. (2009). "Health psychology: Developing biologically plausible models linking the social world and physical health". Annual Review of Psychology. 60: 501–524. doi:10.1146/annurev.psych.60.110707.163551. PMID 19035829.
  19. ^ Keil R.M.K. (2004). "Coping and Stress: A Conceptual Analysis". Journal of Advanced Nursing. 45 (6): 659–665. doi:10.1046/j.1365-2648.2003.02955.x. PMID 15012643.
  20. ^ IJIP.In (31 December 2013). The International Journal of Indian Psychology, Volume 1, Issue 1. Lulu International Press & RED'SHINE Publication. Inc. ISBN 978-1-365-01645-5.
  21. ^ Cooke-Taylor, C.R. (3 October 1936). "Stress of Homework". The British Medical Journal. 2 (3952): 694. doi:10.1136/bmj.2.3952.694. PMC 2457722.
  22. ^ W. B. Cannon; Physiological Regulation of Normal States: Some Tentative Postulates Concerning Biological Homeostatics; IN: A. Pettit (ed.); A Charles Richet: ses amis, ses collègues, ses élèves; p. 91; Paris; Éditions Médicales; 1926.
  23. ^ Viner, Russell (June 1999). "Putting Stress in Life: Hans Selye and the Making of Stress Theory". Social Studies of Science. 29 (3): 391–410. doi:10.1177/030631299029003003. ISSN 1460-3659. JSTOR 285410. S2CID 145291588.
  24. ^ Demetre, D. C. (25 June 2007). "What is Stress". sciencebeta.com. Retrieved 1 July 2022.
  25. ^ Captain Richard H. Rahe MC USNR; Dr Ransom J. Arthur, MD (1 March 1978). "Life Change and Illness Studies: Past History and Future Directions". Journal of Human Stress. 4 (1): 3–15. doi:10.1080/0097840X.1978.9934972. ISSN 0097-840X. PMID 346993.
  26. ^ Goldstein, David S.; Kopin, Irwin J. (January 2007). "Evolution of concepts of stress". Stress. 10 (2): 109–120. doi:10.1080/10253890701288935. PMID 17514579. S2CID 25072963.
  27. ^ Dattatreya, Shruthi (2014). "Can Stress Take the Cost of Life". doi:10.2139/ssrn.2456211. SSRN 2456211. {{cite journal}}: Cite journal requires |journal= (help)
  28. ^ Worthington, James (9 November 2014). "Six ways to spot emotional manipulation before it destroys you". The Fusion Model. Archived from the original on 19 April 2015. Retrieved 19 April 2015.
  29. ^ Humphrey, James H. (2005). Anthology of Stress Revisited: Selected Works Of James H. Humphrey. Foreword by Paul J. Rosch. Nova Science Publishers. p. viii. ISBN 9781594546402. Archived from the original on 24 October 2015. Retrieved 2 May 2013. Even Selve [sic] had difficulties, and in helping him to prepare his First Annual report on Stress 1951, I included the comments of one physician published in the British Medical Journal, who, using citations from Selye's articles concluded that 'Stress, in addition to being itself, was also the cause of itself, and the result of itself.'
  30. ^ Selye, Hans (1978). The stress of life (Rev. ed.). New York: McGraw-Hill. ISBN 9780070562127.
  31. ^ Koolhaas J, et al. (2011). "Stress revisited: A critical evaluation of the stress concept". Neuroscience and Biobehavioral Reviews. 35 (5): 1291–1301. doi:10.1016/j.neubiorev.2011.02.003. PMID 21316391. S2CID 15584486.
  32. ^ Toates, F.M. (1995). Stress: Conceptual and Biological Aspects. Chichester, England: Wiley.
  33. ^ Ursin, H. (1988). "Expectancy and activation: An attempt to systematize stress theory". In Hellhammer, D.H.; Florin, I.; Weiner, H. (eds.). Neuronal Control of Bodily Function: Basic and Clinical Aspects, Vol. 2: Neurobiological Approaches to Human Disease. Kirkland, WA: Huber. pp. 313–334.
  34. ^ van Kampen, H.S. (2019). "The principle of consistency and the cause and function of behaviour". Behavioural Processes. 159: 42–54. doi:10.1016/j.beproc.2018.12.013. PMID 30562561. S2CID 56478466.
  35. ^ Schacter, Daniel L.; Gilbert, Daniel T.; Wegner, Daniel M. (2011). Psychology (2nd ed.). New York: Worth Publishers. p. 13.7. ISBN 978-1429237192.
  36. ^ PhD, Richard Contrada; PhD, Andrew Baum (29 September 2010). The Handbook of Stress Science: Biology, Psychology, and Health. Springer Publishing Company. ISBN 978-0-8261-1771-7.
  37. ^ Walton, Kenneth G.; Levitsky, Debra K. (2003). "Effects of the Transcendental Meditation program on neuroendocrine abnormalities associated with aggression and crime". Journal of Offender Rehabilitation. 36 (1–4): 67–87. doi:10.1300/J076v36n01_04. S2CID 144374302.
  38. ^ a b McCorry, Laurie Kelly (15 August 2007). "Physiology of the Autonomic Nervous System". American Journal of Pharmaceutical Education. 71 (4): 78. doi:10.5688/aj710478. ISSN 0002-9459. PMC 1959222. PMID 17786266.
  39. ^ a b McKlveen, Jessica M.; Myers, Brent; Herman, James P. (7 February 2017). "The Medial Prefrontal Cortex: Coordinator of Autonomic, Neuroendocrine, and Behavioral Responses to Stress". Journal of Neuroendocrinology. 27 (6): 446–456. doi:10.1111/jne.12272. ISSN 0953-8194. PMC 4580281. PMID 25737097.
  40. ^ El-Sheikh, Mona; Erath, Stephen A. (7 February 2017). "Family conflict, autonomic nervous system functioning, and child adaptation: State of the science and future directions". Development and Psychopathology. 23 (2): 703–721. doi:10.1017/S0954579411000034. ISSN 0954-5794. PMC 3695441. PMID 23786705.
  41. ^ Hering, Dagmara; Lachowska, Kamila; Schlaich, Markus (1 October 2015). "Role of the Sympathetic Nervous System in Stress-Mediated Cardiovascular Disease". Current Hypertension Reports. 17 (10): 80. doi:10.1007/s11906-015-0594-5. ISSN 1534-3111. PMID 26318888. S2CID 30136233.
  42. ^ a b c Smith, Sean M.; Vale, Wylie W. (7 February 2017). "The role of the hypothalamic-pituitary-adrenal axis in neuroendocrine responses to stress". Dialogues in Clinical Neuroscience. 8 (4): 383–395. doi:10.31887/DCNS.2006.8.4/ssmith. ISSN 1294-8322. PMC 3181830. PMID 17290797.
  43. ^ a b c Schneiderman, Neil; Ironson, Gail; Siegel, Scott D. (1 January 2005). "STRESS AND HEALTH: Psychological, Behavioral, and Biological Determinants". Annual Review of Clinical Psychology. 1: 607–628. doi:10.1146/annurev.clinpsy.1.102803.144141. ISSN 1548-5943. PMC 2568977. PMID 17716101.
  44. ^ Herman, James P. (8 August 2013). "Neural control of chronic stress adaptation". Frontiers in Behavioral Neuroscience. 7: 61. doi:10.3389/fnbeh.2013.00061. ISSN 1662-5153. PMC 3737713. PMID 23964212.
  45. ^ a b Graham J.; Christian L.; Kiecolt-Glaser J. (2006). "Stress, Age, and Immune Function: Toward a Lifespan Approach". Journal of Behavioral Medicine. 29 (4): 389–400. doi:10.1007/s10865-006-9057-4. PMC 2805089. PMID 16715331.
  46. ^ Schneiderman N.; Ironson G.; Siegel S. D. (2005). "Stress and health: psychological, behavioral, and biological determinants". Annual Review of Clinical Psychology. 1 (1): 607–628. doi:10.1146/annurev.clinpsy.1.102803.144141. PMC 2568977. PMID 17716101.
  47. ^ Traylen, Christopher M; Patel, Hersh R; Fondaw, Wylder; Mahatme, Sheran; Williams, John F; Walker, Lia R; Dyson, Ossie F; Arce, Sergio; Akula, Shaw M (April 2011). "Virus reactivation: a panoramic view in human infections". Future Virology. 6 (4): 451–463. doi:10.2217/fvl.11.21. ISSN 1746-0794. PMC 3142679. PMID 21799704.
  48. ^ Spruill, Tanya M. (7 February 2017). "Chronic Psychosocial Stress and Hypertension". Current Hypertension Reports. 12 (1): 10–16. doi:10.1007/s11906-009-0084-8. ISSN 1522-6417. PMC 3694268. PMID 20425153.
  49. ^ Aguilera, Greti (1 January 2011). "HPA axis responsiveness to stress: Implications for healthy aging". Experimental Gerontology. 46 (2–3): 90–95. doi:10.1016/j.exger.2010.08.023. ISSN 0531-5565. PMC 3026863. PMID 20833240.
  50. ^ Khansari D.; Murgo A.; Faith R. (May 1990). "Effects of stress on the immune system". Immunology Today. 11 (5): 170–175. doi:10.1016/0167-5699(90)90069-l. PMID 2186751.
  51. ^ Powell, Brasel, & Blizzard, 1967.
  52. ^ Charmandari E, Achermann JC, Carel JC, Soder O, Chrousos GP (2012). "Stress response and child health". Science Signaling (Review). 5 (248): mr1. doi:10.1126/scisignal.2003595. PMID 23112343. S2CID 13920757.
  53. ^ Charmandari E, Kino T, Souvatzoglou E, Chrousos GP (2003). "Pediatric stress: hormonal mediators and human development". Hormone Research (Review). 59 (4): 161–79. doi:10.1159/000069325. PMID 12649570. S2CID 9744754.
  54. ^ "Renew-Stress on the Brain". The Franklin Institute. Archived from the original on 11 May 2012.
  55. ^ a b c d Kalat, J. W. (2013). Biological Psychology. p. 383
  56. ^ Kalat, J. W. (2013). Biological Psychology. p. 97
  57. ^ Yau, Yvonne H. C.; Potenza, Marc N. (7 February 2017). "Stress and Eating Behaviors". Minerva Endocrinologica. 38 (3): 255–267. ISSN 0391-1977. PMC 4214609. PMID 24126546.
  58. ^ Clauw, Daniel J. (2014). "Fibromyalgia". JAMA. 311 (15): 1547–55. doi:10.1001/jama.2014.3266. PMID 24737367.
  59. ^ Wyller, Vegard Bruun (1 January 2007). "The chronic fatigue syndrome—an update". Acta Neurologica Scandinavica Supplementum. 187: 7–14. doi:10.1111/j.1600-0404.2007.00840.x. ISSN 0065-1427. PMID 17419822. S2CID 11247547.
  60. ^ Saveanu, Radu V.; Nemeroff, Charles B. (March 2012). "Etiology of Depression: Genetic and Environmental Factors". Psychiatric Clinics of North America. 35 (1): 51–71. doi:10.1016/j.psc.2011.12.001. PMID 22370490.
  61. ^ Afari, Niloofar; Ahumada, Sandra M.; Wright, Lisa Johnson; Mostoufi, Sheeva; Golnari, Golnaz; Reis, Veronica; Cuneo, Jessica Gundy (7 February 2017). "Psychological Trauma and Functional Somatic Syndromes: A Systematic Review and Meta-Analysis". Psychosomatic Medicine. 76 (1): 2–11. doi:10.1097/PSY.0000000000000010. ISSN 0033-3174. PMC 3894419. PMID 24336429.
  62. ^ Selye (1975). "Confusion and controversy in the stress field". Journal of Human Stress. 1 (2): 37–44. doi:10.1080/0097840X.1975.9940406. PMID 1235113.
  63. ^ de Kloet, E. Ron; Joëls, Marian; Holsboer, Florian (June 2005). "Stress and the brain: from adaptation to disease". Nature Reviews Neuroscience. 6 (6): 463–475. doi:10.1038/nrn1683. PMID 15891777. S2CID 1320302.
  64. ^ "The Silent Denial of Stress in a Competitive World". 17 March 2012. Archived from the original on 19 April 2012. Retrieved 17 March 2012.
  65. ^ Lazarus, R.S. (1966). Psychological Stress and the Coping Process. New York: McGraw-Hill.
  66. ^ Aldwin, Carolyn (2007). Stress, Coping, and Development, Second Edition. New York: The Guilford Press. ISBN 978-1-57230-840-4.
  67. ^ Glavas, M.M.; Weinberg, J. (2006). "Stress, Alcohol Consumption, and the Hypothalamic-Pituitary-Adrenal Axis". In Yehuda, S.; Mostofsky, D.I. (eds.). Nutrients, Stress, and Medical Disorders. Totowa, NJ: Humana Press. pp. 165–183. ISBN 978-1-58829-432-6.
  68. ^ Davis et al. (June 2007). Prenatal Exposure to Maternal Depression and Cortisol Influences Infant Temperament. Journal of the American Academy of Child & Adolescent Psychiatry, v46 n6 p737.
  69. ^ O'Connor; Heron; Golding; Beveridge; Glover (2002). "Maternal antenatal anxiety and children's behavioural/emotional problems at 4 years". Br J Psychiatry. 180 (6): 478–9. doi:10.1192/bjp.180.6.502. PMID 12042228.
  70. ^ Schore, Allan (2003). Affect Regulation & the Repair of the Self. New York: W.W. Norton. ISBN 978-0-393-70407-5.
  71. ^ DeBellis, Michael D.; Chrousos, George P.; D. Dorn, Lorah; Burke, Lillian; Helmers, Karin; Kling, Mitchel A.; K. Trickett, Penelope; Putnam, Frank W. (1994). "Hypothalamic-pituitary-adrenal axis dysregulation in sexually abused girls". The Journal of Clinical Endocrinology & Metabolism. 78 (2): 249–255. doi:10.1210/jcem.78.2.8106608. PMID 8106608.
  72. ^ Taylor, Shelley; Sirois, Fuschia (2012). Health Psychology (2nd Canadian ed.). McGraw-Hill Ryerson. ISBN 978-0070319790.
  73. ^ Gozhenko, AI; Gurkalova, IP; Zukow, W; Kwasnik, Z; Mroczkowska, B (2009). Gozhenko, AI; Zukow, W; Kwasnik, Z (eds.). Pathology: Medical student's library. Radom University. p. 272. ISBN 978-83-61047-18-6. OCLC 750538315.
  74. ^ a b c Viner R (1999). "Putting Stress in Life: Hans Selye and the Making of Stress Theory". Social Studies of Science. 29 (3): 391–410. doi:10.1177/030631299029003003. JSTOR 285410. S2CID 145291588.
  75. ^ Petticrew, Mark P.; Lee, Kelley (March 2011). "The "Father of Stress" Meets "Big Tobacco": Hans Selye and the Tobacco Industry". American Journal of Public Health. 101 (3): 411–418. doi:10.2105/AJPH.2009.177634. ISSN 0090-0036. PMC 3036703. PMID 20466961.
  76. ^ Shalev, Arieh Y.; Yehuda, Rachel; Alexander C. McFarlane (2000). International handbook of human response to trauma. New York: Kluwer Academic/Plenum Press. ISBN 978-0-306-46095-1.; on-line Archived 17 June 2007 at the Wayback Machine.
  77. ^ "2015 Stress in America Snapshot". www.apa.org. Archived from the original on 16 March 2017. Retrieved 6 April 2017.
edit