8.1 Physiological stress response and the HPA axis
3 min read•august 1, 2024
The is your body's stress response system. It kicks into gear when you're faced with a challenge, releasing hormones like to help you cope. This complex process involves your brain, hormones, and organs working together to keep you balanced.
Understanding the HPA axis is key to grasping how stress affects your body. When it's working well, it helps you adapt. But when it's out of whack, it can lead to health problems. Knowing this helps you see why managing stress is so important.
The HPA Axis in Stress
Neuroendocrine System and Stress Response
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HPA axis functions as a complex neuroendocrine system mediating body's response to acute and chronic stress
Activation triggers production and release of glucocorticoids (primarily cortisol in humans) facilitating adaptation to stressors
Interacts with other stress response systems (sympathetic nervous system) coordinating comprehensive physiological response
Maintains and regulates various physiological processes (metabolism, immune function, cardiovascular activity)
HPA Axis Dysregulation and Health Implications
Dysregulation associates with various stress-related disorders (anxiety, depression, post-traumatic stress disorder)
Chronic activation leads to allostatic load potentially causing long-term negative health consequences
Disruption of normal HPA axis function impacts overall physiological balance and stress resilience
Cortisol's Role in Stress
Physiological Effects of Cortisol
Cortisol acts as key mediator of stress response mobilizing energy resources and modulating physiological processes
Promotes gluconeogenesis in liver increasing blood glucose levels for energy during stress response
Suppresses non-essential immune functions redirecting energy to immediate survival needs
Enhances sensitivity of blood vessels to catecholamines maintaining blood pressure during stress
Influences cognitive function modulating attention, memory consolidation, and emotional processing in brain
Cortisol Dynamics and Chronic Elevation
Exhibits diurnal rhythm with levels peaking in morning and declining throughout day (can be disrupted by chronic stress)
Chronic elevation leads to detrimental effects (muscle wasting, bone demineralization, impaired wound healing)
Long-term cortisol dysregulation impacts multiple body systems and overall health
Hormonal Events in the HPA Axis
Activation and Hormone Cascade
Stress response initiates with stressor perception by brain activating paraventricular nucleus (PVN) of
PVN neurons synthesize and release corticotropin-releasing hormone (CRH) and arginine vasopressin (AVP) into hypophyseal portal system
CRH and AVP stimulate anterior to produce and secrete into bloodstream
ACTH binds to melanocortin 2 receptors (MC2R) on adrenocortical cells in
Cortisol Production and Feedback Mechanisms
MC2R stimulation leads to synthesis and release of cortisol from adrenal cortex into general circulation
Cortisol exerts effects on target tissues throughout body (liver, immune cells, cardiovascular system)
Provides negative feedback to hypothalamus and pituitary regulating further HPA axis activation
Process from initial stressor perception to peak cortisol levels typically occurs within 15-30 minutes (gradual return to baseline over several hours)
Allostasis and Stress Response
Allostasis Concept and Adaptation
maintains stability through change allowing body to adapt to environmental challenges and stressors
Expands upon traditional homeostasis concept recognizing physiological set points can change in response to environmental demands
Stress response (mediated by HPA axis and other systems) enables short-term adaptations to acute stressors
Involves complex interactions between multiple physiological systems (HPA axis, autonomic nervous system, immune system) maintaining adaptive functioning
Allostatic Load and Health Implications
Allostatic load represents cumulative wear and tear on body from repeated allostasis cycles (particularly with inadequate recovery between stress responses)
Chronic activation of allostatic systems (including HPA axis) can lead to allostatic overload causing long-term health problems
Increases susceptibility to various diseases and disorders (cardiovascular disease, metabolic syndrome, autoimmune conditions)
Emphasizes importance of considering individual differences and environmental contexts in understanding stress responses and health outcomes