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| In everyday life, there are numerous factors that recurrently disrupt homeostasis, such as, environmental factors or internal and external stimuli. This coordinated system then works to keep the organism in an incessant flux around particular variables that could be considered optimal conditions for it to live and survive. Any deviation relatively far from the optimal equilibrium and the organism’s specific response, involving a number of processes which strive to restore normal body conditions, can be perceived as Stress.The burden of chronic stress and accompanying changes in personal behaviours is called Allostatic overload (McEwen, 2008; Del Giudice et al., 2011). | In everyday life, there are numerous factors that recurrently disrupt homeostasis, such as, environmental factors or internal and external stimuli. This coordinated system then works to keep the organism in an incessant flux around particular variables that could be considered optimal conditions for it to live and survive. Any deviation relatively far from the optimal equilibrium and the organism’s specific response, involving a number of processes which strive to restore normal body conditions, can be perceived as Stress.The burden of chronic stress and accompanying changes in personal behaviours is called Allostatic overload (Del Giudice et al., 2011; McEwen, 2008). |
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| ||<tablebgcolor="#eeeeee" tablestyle="float:right;font-size:0.85em;margin:700 50 0 0; "style="padding:0.5em; ;text-align:center"> {{attachment:HPA_Axis_Diagram_(Brian_M_Sweis_2012).png|pop-up text|width="500 height=600"}} <<BR>>'''Fig 1.'''<<BR>>''Response to Stress'' || | ||<tablebgcolor="#eeeeee" tablestyle="float:right;font-size:0.85em;margin:700 50 0 0; "style="padding:0.5em; ;text-align:center"> {{attachment:HPA_Axis_Diagram_(Brian_M_Sweis_2012).png|pop-up text|width="500 height=600"}} <<BR>>'''Fig 1.'''<<BR>>''Response to Stress'' || |
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| Fundamentally, the HPA axis responds to stressors through the release of cortisol in a long term, delayed process. The Hypothalamus secretes Corticotropin Releasing Hormone (CRH) and Vasopressin (ADH) into the portal circulation of the pituitary gland by neurons of the Paraventricular nucleus (PVN). These elicit the release of Pro-Opiomelanocortin polypeptide (POMC) from the Adenohypophysis, which can then be cleaved into several hormones. This includes Adrenocotricotropic hormone (ACTH). ACTH, through systemic circulation, arrives at the cortex of the Adrenal gland and stimulates the release of Cortisol. The main task of Cortsiol is to redistribute and allocate energy to the organs and tissues that require it the most during a stress response. CRH itself, also takes part in the physio- and psychological response to stressors (Keenen et al., 2007; Del Giudice et al., 2011). | Fundamentally, the HPA axis responds to stressors through the release of cortisol in a long term, delayed process. The Hypothalamus secretes Corticotropin Releasing Hormone (CRH) and Vasopressin (ADH) into the portal circulation of the pituitary gland by neurons of the Paraventricular nucleus (PVN). These elicit the release of Pro-Opiomelanocortin polypeptide (POMC) from the Adenohypophysis, which can then be cleaved into several hormones. This includes Adrenocotricotropic hormone (ACTH). ACTH, through systemic circulation, arrives at the cortex of the Adrenal gland and stimulates the release of Cortisol. The main task of Cortsiol is to redistribute and allocate energy to the organs and tissues that require it the most during a stress response. CRH itself, also takes part in the physio- and psychological response to stressors (Del Giudice et al., 2011; Keenen et al., 2007). |
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| ||<tablebgcolor="#eeeeee" tablestyle="float:right;font-size:0.85em;margin:700 50 0 0; "style="padding:0.5em; ;text-align:center"> {{attachment:Stress curve and phases 3.jpg|pop-up text|width="500 height=600"}} <<BR>>'''Fig 2.'''<<BR>>''Phases of Stress'' || | ||<tablebgcolor="#eeeeee" tablestyle="float:right;font-size:0.85em;margin:700 50 0 0; "style="padding:0.5em; ;text-align:center"> {{attachment:Stress curve and phases 3.jpg|pop-up text|width="500 height=600"}} <<BR>>'''Fig 2.'''<<BR>>''Phases of Stress'' || |
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| ||<tablebgcolor="#eeeeee" tablestyle="float:right;font-size:0.85em;margin:700 50 0 0; "style="padding:0.5em; ;text-align:center"> {{attachment:cortisol.jpg|pop-up text|width="250 height=100"}} <<BR>>'''Fig 3.'''<<BR>>''Structure of Cortisol'' || | ||<tablebgcolor="#eeeeee" tablestyle="float:right;font-size:0.85em;margin:700 50 0 0; "style="padding:0.5em; ;text-align:center"> {{attachment:cortisol.jpg|pop-up text|width="250 height=100"}} <<BR>>'''Fig 3.'''<<BR>>''Structure of Cortisol'' || |
Multiple Organ Failure as an Endocrine-Mediated Response to Chronic Stress
Homeostasis is the coordinated system of physiological and biochemical processes which regulate and maintain most of the steady states in the organism, attempting to keep the internal conditions relatively constant, for example: pH, internal temperature, etc; in a state of equilibrium. This concept is essential to the understanding of stress.
In everyday life, there are numerous factors that recurrently disrupt homeostasis, such as, environmental factors or internal and external stimuli. This coordinated system then works to keep the organism in an incessant flux around particular variables that could be considered optimal conditions for it to live and survive. Any deviation relatively far from the optimal equilibrium and the organism’s specific response, involving a number of processes which strive to restore normal body conditions, can be perceived as Stress.The burden of chronic stress and accompanying changes in personal behaviours is called Allostatic overload (Del Giudice et al., 2011; McEwen, 2008).
As per the particular event, specific responses to stress is conducted by Sympathetic nervous system (SNS) activation which leads to the Cannon’s reaction, or so-called Fight-or-Flight response. This state cannot be maintained for extended periods of time as it could be detrimental to the physical and mental health of the organism. The Parasympathetic nervous system (PNS) seeks to returns the conditions to the more optimal range. This restoration consumes a lot of energy and resources, putting a lot of strain on the body, but seeks to focus it to repress the immediate problem. One such process to overcome chronic stress is multiple organ failure caused by the organism's own system (McEwen, 2008).
Contents
Stress Response
The system that carries out the stress response lies in the endocrine, and central and peripheral nervous systems. The primary effectors for the stress response are Corticotropin-releasing hormone (CRH), Vasopressin (ADH), Proopiomelanocortin-derived (POMC) peptides α-melanocyte-stimulating hormone and β-endorphin, the glucocorticoids, and the catecholamines norepinephrine and epinephrine are all principals of the stress system (Keenen et al., 2007).
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HypothalamoPituatary Adrenal Axis
The HypothalamoPituataryAdrenal (HPA) axis, is an intricate set of interactions among three endocrine glands, being the hypothalamus, pituitary gland, and adrenal glands. These interactions constitute a major part of the neuroendocrine system responsible for the response to stress, as well numerous body processes that affect the organism both physically and mentally. These include regulation of energy stores and energy expenditure, sexuality, digestion, the immune system as well as emotions.
Fundamentally, the HPA axis responds to stressors through the release of cortisol in a long term, delayed process. The Hypothalamus secretes Corticotropin Releasing Hormone (CRH) and Vasopressin (ADH) into the portal circulation of the pituitary gland by neurons of the Paraventricular nucleus (PVN). These elicit the release of Pro-Opiomelanocortin polypeptide (POMC) from the Adenohypophysis, which can then be cleaved into several hormones. This includes Adrenocotricotropic hormone (ACTH). ACTH, through systemic circulation, arrives at the cortex of the Adrenal gland and stimulates the release of Cortisol. The main task of Cortsiol is to redistribute and allocate energy to the organs and tissues that require it the most during a stress response. CRH itself, also takes part in the physio- and psychological response to stressors (Del Giudice et al., 2011; Keenen et al., 2007).
General Adaptation Syndrome
General Adaptation Syndrome (GAS) outlines an organism’s stress response. It is mediated by the interactions of the HPA axis, and can be distinguished into four phases (Taylor et al., 2012):
Initial phase
The primary factor in the development of stress is the immediate release of ACTH. It acts on the adrenal glands and stimulates the secretion of catecholamines i.e., Epinephrine, Norepinephrine, and Dopamine, which in turn cause an increase in blood pressure, and heart and respiratory rates. This can be referred to as Cannon's alarm response, or theFight-or-Flight theory, and is under the influence of the Sympathetic nervous system (Taylor et al., 2012)
Phase of Resistance
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Catecholamine levels decline, however, ACTH levels remain high resulting in the production of Glucocorticoids by the adrenal cortex, which play an important role in providing the optimal conditions for the body's ability to resist stress. They also ensure that relatively less important processes, not required for immediate survival, such as functioning of the digestive tract, energy storing processes, immune system and insulin secretion,even though hyperglycemia occurs due to excessive gluconeogenesis. Fat oxidation becomes the main energy source. Carbohydrate synthesis is made possible by the utilisation of amino acids that are released during the breakdown of muscle. Due to these factors, the organism is able to withstand the effects of stress for a long time, however, over exposure to these factors over a prolonged perioid could result in one of the following two phases (Taylor et al., 2012).
Phase of Exhaustion
Persistence of stress would result in depletion of available energy reserves, which would lead to collapse and, in due course, death of the animal (Taylor et al., 2012).
Phase of Adaptive Disorders
Adaptive disorders aim to redirect the body's energy and focus, at the expense of another organ's supply and functioning, to systems that would allow it to combat the stress. For example arthritis, chronic hypertension, ulcers or multiple organ failure (Singer et al., 2004; Taylor et al. 2012).
Autonomic Nervous System
Multiple Organ Failure
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Sepsis and other critical illnesses lead to a biphasic inflammatory, immune, hormonal, and metabolic response. A pronounced increase in the secretion of the stress hormones with an associated increase in mitochondrial and metabolic activity, marks the acute phase. As a result of the changes in the endocrine profile and intense inflammation, energy production, metabolic rate, and normal cellular processes decrease drastically, thereby resulting in Multiple Organ Dysfunction or failure. The decline in organ function is triggered by a decrease in mitochondrial activity and oxidative phosphorylation, leading to reduced cellular metabolism. This effect on mitochondria might be the consequence of acute-phase changes in hormones and inflammatory mediators. Cortisol, for example, is responsible for the redirection of energy sources away from the failing organs, and towards body process that require it more, so that the stress could be overcome (Singer et al., 2004).
Though stress is often considered to have a negative effect on the body, it can play a crucial and positively role ensuring adequate performance and wellbeing of the animal, furthermore, ensure social interactions. Failure to exhibit the appropriate stress responses could lead to various physical and mental impediments. For example, decreased growth and development, and immune, endocrine and metabolic disorders could be attributed to this. However, the extent of vulnerability of an individual organism to these impediments is related to its own genetic coding (Charmandari et al., 2005).
The observed organ failure has been postulated to be a potentially protective mechanism to overcome stress. The reason for this being that the reduced cellular metabolism could prospectively heighten their chances of their survival and thus the overall survival of the organ, when exposed to profuse abuse. Singer et al. (2004) propose that "multiple organ failure induced by critical illness is primarily a functional, rather than structural, abnormality". It could be hypothesised that instead of being a 'failure' in the broad sense, ii could possibly be protective, reactive mechanism of the body (Singer et al., 2004)
Benefits of Future Research
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References
Journal Atricles
Other References
Taylor, Shelley, and Sirois, Fuschia. (2012). Health Psychology 2nd Canadian Edition
Figures
Figure 1. Response to Stress, Nature Reviews: Immunology
Figure 2. Phases of Stress, About Stress Problems, Health and Life
Figure 3. Structure of Cortisol, Hormonas Esteroides y Receptores