Allostatic load

Allostatic load is "the wear and tear on the body" which accumulates as an individual is exposed to repeated or chronic stress. The term was coined by McEwen and Stellar in 1993. It represents the physiological consequences of chronic exposure to fluctuating or heightened neural or neuroendocrine response which results from repeated or prolonged chronic stress.

The graph represents the effect of increased stress on the performance of the body. The lower the stress levels are in the body, the less likely the allostatic load model will have a significant effect on the brain and health. Although, an increase in stress levels results in an increase in stress on the brain and the health of individuals, making it more likely for the body to have significant effects on homeostasis and cause breakdown of the body systems.

Regulatory model

The term allostatic load is "the wear and tear on the body" which accumulates as an individual is exposed to repeated or chronic stress.[1] It was coined by McEwen and Stellar in 1993.[2]

The term is part of the regulatory model of allostasis, where the predictive regulation or stabilisation of internal sensations in response to stimuli is ascribed to the brain.[3] Allostasis involves the regulation of homeostasis in the body to decrease physiological consequences on the body.[4][5] Predictive regulation refers to the brain's ability to anticipate needs and prepare to fulfill them before they arise.[3]

Part of efficient regulation is the reduction of uncertainty. Humans naturally do not like feeling as if surprise is inevitable. Because of this, we constantly strive to reduce the uncertainty of future outcomes, and allostasis helps us do this by anticipating needs and planning how to satisfy them ahead of time.[6] But it takes a considerable amount of the brain's energy to do this, and if it fails to resolve the uncertainty, the situation may become chronic and result in the accumulation of allostatic load.[6]

The concept of allostatic load provides that "the neuroendocrine, cardiovascular, neuroenergetic, and emotional responses become persistently activated so that blood flow turbulences in the coronary and cerebral arteries, high blood pressure, atherogenesis, cognitive dysfunction and depressed mood accelerate disease progression."[6] All long-standing effects of continuously activated stress responses are referred to as allostatic load. Allostatic load can result in permanently altered brain architecture and systemic pathophysiology.[6]

Allostatic load minimizes an organism's ability to cope with and reduce uncertainty in the future.[6]

Types

McEwen and Wingfield propose two types of allostatic load with different etiologies and distinct consequences:-

Type 1 allostatic load occurs when energy demand exceeds supply, resulting in activation of the emergency life history stage. This serves to direct the animal away from normal life history stages into a survival mode that decreases allostatic load and regains positive energy balance. The normal life cycle can be resumed when the perturbation has passed. Typical situations ending up in type 1 allostasis are starvation, hibernation and critical illness. Of note, the life-threatening consequences of critical illness may be both cause and consequences of allostatic load[7][8][9].

Type 2 allostatic load results from sufficient or even excess energy consumption being accompanied by social conflict or other types of social dysfunction. The latter is the case in human society and certain situations affecting animals in captivity. In all cases, secretion of glucocorticosteroids and activity of other mediators of allostasis such as the autonomic nervous system, CNS neurotransmitters, and inflammatory cytokines wax and wane with allostatic load. If allostatic load is chronically high, then pathologies may develop. Type 2 allostatic overload does not trigger an escape response, and can only be counteracted through learning and changes in the social structure[10].

Whereas both types of allostatic load are associated with increased release of cortisol and catecholamines, they differentially affect thyroid homeostasis: Concentrations of the thyroid hormone triiodothyronine are decreased in type 1 allostasis, but elevated in type 2 allostasis[9].

Measurement

Allostatic load is generally measured through a composite index of indicators of cumulative strain on several organs and tissues, primarily biomarkers associated with the neuroendocrine, cardiovascular, immune and metabolic systems.[11]

Indices of allostatic load are diverse across studies and are frequently assessed differently, using different biomarkers and different methods of assembling an allostatic load index. Allostatic load is not unique to humans and may be used to evaluate the physiological effects of chronic or frequent stress in non-human primates as well.[11]

In the endocrine system, the increase or repeated levels of stress results in the increased levels of the hormone Corticotropin-Releasing Factor (CRH), which is associated with activation of HPA axis.[5] The Hypothalamic–pituitary–adrenal axis is the central stress response system responsible for modulating inflammatory responses throughout the body. Prolonged stress levels can lead to decreased levels of cortisol in the morning and increased levels in the afternoon, leading to greater daily output of cortisol which in the long term increases blood sugar levels.

In the nervous system, structural and functional abnormalities are a result of chronic prolonged stress. The increase of stress levels causes a shortening of dendrites in a neuron. Therefore, the shortening of dendrites causes the decrease in attention.[5] Chronic stress also causes greater response to fear of the unlearned in the nervous system, and fear conditioning.

In the immune system, the increase in levels of chronic stress results in the elevation of inflammation. The increase in inflammation levels is caused by the ongoing activation of the sympathetic nervous system.[5] The impairment of cell-mediated acquired immunity is also a factor resulting in the immune system due to chronic stress.[5]

Relationship to allostasis and homeostasis

The largest contribution to the allostatic load is the effect of stress on the brain. Allostasis is the system which helps to achieve homeostasis.[12] Homeostasis is the regulation of physiological processes, whereby systems in the body respond to the state of the body and to the external environment.[12] The relationship between allostasis and allostatic load is the concept of anticipation. Anticipation can drive the output of mediators. Examples of mediators include hormones and cortisol. Excess amounts of such mediators will result in an increase in allostatic load, contributing to anxiety and anticipation.[12]

Allostasis and allostatic load are related to the amount of health-promoting and health-damaging behaviours like for example cigarette smoking, consumption of alcohol, poor diet and physical inactivity.[12]

Three physiological processes cause an increase in allostatic load:

  1. Frequent stress: the magnitude and frequency of response to stress is what determines the level of allostatic load which affects the body.
  2. Failed shut-down: the inability of the body to shut off while stress accelerates and levels in the body exceed normal levels, for example, elevated blood pressure.
  3. Inadequate response: the failure of the body systems to respond to challenge, for example, excess levels of inflammation due to inadequate endogenous glucocorticoid responses.

The importance of homeostasis is to regulate the stress levels encountered on the body to reduce allostatic load.

Dysfunctional allostasis causes allostatic load to increase which may, over time, lead to disease, sometimes with decompensation of the allostatically controlled problem. Allostatic load effects can be measured in the body. When tabulated in the form of allostatic load indices using sophisticated analytical methods, it gives an indication of cumulative lifetime effects of all types of stress on the body.[13]

Homeostasis can be statistically modeled with the R package [14] which allows fittings the dynamics of a regulated system experiencing exogenous inputs.

Reducing risk

To reduce and manage high allostatic load, an individual should pay attention to structural and behavioural factors. Structural factors include the social environment, and access to health services. Behavioural factors include diet, physical health and tobacco smoking, which can lead to chronic disease.[4] Actions such as tobacco smoking are brought about from the stress levels that an individual experiences. Therefore, controlling stress levels from the beginning, for example by not leading to tobacco smoking, will reduce the chance of chronic disease development and high allostatic load.

Low socio-economic status affects allostatic load and therefore, focusing on the causes of low SES will reduce allostatic load levels. Reducing societal polarisation, material deprivation, and psychological demands on health helps to manage allostatic load.[15] Support from the community and the social environment can manage high allostatic load[15] Empowering financial help from the government allows people to gain control and improve their psychological health.[15] Improving inequalities in health decreases the stress levels and improves health by reducing high allostatic load on the body.[15]

Interventions can include encouraging sleep quality and quantity, social support, self-esteem and wellbeing, improving diet, avoiding alcohol or drug consumption and participating in physical activity.[16] Providing cleaner and safer environments and the incentive towards a higher education will reduce the chance of stress and improve mental health significantly, therefore, reducing the onset of high allostatic load.[16]

Allostatic load differs by sex and age, and the social status of an individual. Protective factors could, at various times of an individual's life span, be implemented to reduce stress and, in the long run, eliminate the onset of allostatic load.[4] Protective factors include parental bonding, education, social support, health workplaces, a sense of meaning towards life and choices being made[16], and positive feelings in general.[4]

See also

References
  1. Jane Ogden (2004). Health Psychology: A textbook, 3rd edition. Open University Press - McGraw-Hill Education. p. 259. ISBN 978-0335214716.
  2. McEwen, BS; Stellar, E (Sep 27, 1993). "Stress and the individual. Mechanisms leading to disease". Archives of Internal Medicine. 153 (18): 2093–101. doi:10.1001/archinte.153.18.2093. PMID 8379800.
  3. Sterling, P (12 April 2012). "Allostasis: a model of predictive regulation". Physiology & Behavior. 106 (1): 5–15. doi:10.1016/j.physbeh.2011.06.004. PMID 21684297.
  4. Schenk, H.M.; et al. (2017). "Associations of Positive Affect and Negative Affect With Allostatic Load: A Lifelines Cohort Study". Psychosomatic Medicine. 80 (2): 160–166. doi:10.1097/PSY.0000000000000546. PMID 29215457.
  5. Danese, A; McEwen, BS (12 April 2012). "Adverse childhood experiences, allostasis, allostatic load, and age-related disease". Physiology & Behavior. 106 (1): 29–39. doi:10.1016/j.physbeh.2011.08.019. PMID 21888923.
  6. Peters, A; McEwen, BS; Friston, K (September 2017). "Uncertainty and stress: Why it causes diseases and how it is mastered by the brain" (PDF). Progress in Neurobiology. 156: 164–188. doi:10.1016/j.pneurobio.2017.05.004. PMID 28576664.
  7. Brame, AL; Singer, M (October 2010). "Stressing the obvious? An allostatic look at critical illness". Critical Care Medicine. 38 (10 Suppl): S600–7. doi:10.1097/CCM.0b013e3181f23e92. PMID 21164403.
  8. Cuesta, JM; Singer, M (December 2012). "The stress response and critical illness: a review". Critical Care Medicine. 40 (12): 3283–9. doi:10.1097/CCM.0b013e31826567eb. PMID 22975887.
  9. Chatzitomaris, A; Hoermann, R; Midgley, JE; Hering, S; Urban, A; Dietrich, B; Abood, A; Klein, HH; Dietrich, JW (2017). "Thyroid Allostasis-Adaptive Responses of Thyrotropic Feedback Control to Conditions of Strain, Stress, and Developmental Programming". Frontiers in Endocrinology. 8: 163. doi:10.3389/fendo.2017.00163. PMC 5517413. PMID 28775711.
  10. McEwen, BS; Wingfield, JC (January 2003). "The concept of allostasis in biology and biomedicine". Hormones and Behavior. 43 (1): 2–15. doi:10.1016/S0018-506X(02)00024-7. PMID 12614627.
  11. Edes, Ashley; Crews, Douglas (January 1, 2017). "Allostatic load and biological anthropology". American Journal of Physical Anthropology. 162: 44–70. doi:10.1002/ajpa.23146. PMID 28105719.
  12. McEwen, BS (1 May 1998). "Stress, adaptation, and disease. Allostasis and allostatic load". Annals of the New York Academy of Sciences. 840 (1): 33–44. Bibcode:1998NYASA.840...33M. doi:10.1111/j.1749-6632.1998.tb09546.x. PMID 9629234.
  13. McEwen B. S. (2000). "Allostasis and allostatic load: implications for neuropsychopharmacology". Neuropsychopharmacology. 22 (2): 108–24. doi:10.1016/S0893-133X(99)00129-3. PMID 10649824.
  14. DOREMI cran.r-project.org
  15. Kristenson, M; Eriksen, H.R; Sluiter, J.K; Starke, D; Ursin, H (April 2004). "Psychobiological mechanisms of socioeconomic differences in health". Social Science & Medicine. 58 (8): 1511–1522. doi:10.1016/s0277-9536(03)00353-8. ISSN 0277-9536. PMID 14759694.
  16. Juster, Robert-Paul; McEwen, Bruce S.; Lupien, Sonia J. (September 2010). "Allostatic load biomarkers of chronic stress and impact on health and cognition". Neuroscience & Biobehavioral Reviews. 35 (1): 2–16. doi:10.1016/j.neubiorev.2009.10.002. ISSN 0149-7634. PMID 19822172.
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