The fight-flight-freeze response is your body’s natural reaction to danger. It’s a type of stress response that helps you react to perceived threats, like an oncoming car or growling dog. Show The response instantly causes hormonal and physiological changes. These changes allow you to act quickly so you can protect yourself. It’s a survival instinct that our ancient ancestors developed many years ago. Specifically, fight-or-flight is an active defense response where you fight or flee. Your heart rate gets faster, which increases oxygen flow to your major muscles. Your pain perception drops, and your hearing sharpens. These changes help you act appropriately and rapidly. Freezing is fight-or-flight on hold, where you further prepare to protect yourself. It’s also called reactive immobility or attentive immobility. It involves similar physiological changes, but instead, you stay completely still and get ready for the next move. Fight-flight-freeze isn’t a conscious decision. It’s an automatic reaction, so you can’t control it. In this article, we’ll further explore what this response entails, along with examples. During a fight-flight-freeze response, many physiological changes occur. The reaction begins in your amygdala, the part of your brain responsible for perceived fear. The amygdala responds by sending signals to the hypothalamus, which stimulates the autonomic nervous system (ANS). The ANS consists of the sympathetic and parasympathetic nervous systems. The sympathetic nervous system drives the fight-or-flight response, while the parasympathetic nervous system drives freezing. How you react depends on which system dominates the response at the time. In general, when your ANS is stimulated, your body releases adrenaline and cortisol, the stress hormone. These hormones are released very quickly, which can affect your:
Your specific physiological reactions depend on how you usually respond to stress. You might also shift between fight-or-flight and freezing, but this is very difficult to control. Usually, your body will return to its natural state after 20 to 30 minutes. While the fight-flight-freeze response causes physiological reactions, it’s triggered by a psychological fear. The fear is conditioned, which means you’ve associated a situation or thing with negative experiences. This psychological response is initiated when you’re first exposed to the situation and develops over time. The thing that you’re scared of is called a perceived threat, or something you consider to be dangerous. Perceived threats are different for each person. When you’re faced with a perceived threat, your brain thinks you’re in danger. That’s because it already considers the situation to be life threatening. As a result, your body automatically reacts with the fight-flight-freeze response to keep you safe. The fight-flight-freeze response can show up in many life situations, including:
Sometimes, the fight-flight-freeze response is overactive. This happens when nonthreatening situations trigger the reaction. Overactive responses are more common in people who have experienced: TraumaAfter a traumatic event, you may develop an exaggerated stress response. It involves a recurrent pattern of reactions related to the initial event. This is more likely if you have a history of: In this case, your brain reacts to related triggers to prepare you for future traumatic situations. The result is an overactive response. An example if you’ve experienced trauma from a car accident. If the sound of a car horn reminds you of the event, you might have a stress response when you hear a car honking. AnxietyAnxiety is when you feel scared or nervous about a situation. It’s a natural response that helps you react appropriately. If you have an anxiety disorder, you’re more likely to feel threatened by nonthreatening stressors. This could spark an exaggerated stress response to daily activities, like riding the bus or sitting in traffic. There are ways to cope with an overactive stress response. This includes various strategies and treatments, such as: Relaxation techniquesBy doing activities that promote relaxation, you can counteract the stress response with the relaxation response. Examples of relaxation techniques include:
When done regularly, these techniques can help improve how you react to stress. Physical activityAnother strategy is regular exercise. Physical activity reduces the stress response by:
These benefits can increase your mood and sense of relaxation, which helps you better cope with stressful scenarios. Social supportIt’s also important to nurture healthy social relationships. Social support can minimize your psychological and physiological reactions to perceived threats. It provides a sense of safety and protection, which makes you feel less fearful. Your social support may include different people, including:
If you’re in a constant state of fight-or-flight, consider visiting a mental health professional. Specifically, you should seek help if you experience the following:
A mental health professional can help you determine the underlying cause of these feelings. They can also create a plan to reduce your stress response, depending on your symptoms and mental health history. Your body’s fight-flight-freeze response is triggered by psychological fears. It’s a built-in defense mechanism that causes physiological changes, like rapid heart rate and reduced perception of pain. This enables you to quickly protect yourself from a perceived threat. If you have a history of trauma or anxiety, you might overreact to nonthreatening situations. A mental health professional can help you find ways to cope. With their guidance, you can develop the most appropriate strategies for your situation. Jennifer Walinga Learning Objectives
Stress can pose a deleterious effect on health outcomes (Thoits, 2010). In 50 years of research concerning the links between stress and health, several major findings emerge (see Figure 16.1, “The Sociopolitical-Economic Factors of Stress”).
Coping with stress depends on high levels of mastery, self-esteem, and/or social support that can reduce the impacts of stressors on health and well-being. Therefore, policy recommendations inspired by the snowballing impacts of stress focus on:
Negative Impacts of Stress on HealthThe human body is designed to react to stress in ways meant to protect against threats from predators and other aggressors. In today’s society, stressors take on a more subtle but equally threatening form such as shouldering a heavy workload, providing for a family, and taking care of children or elderly relatives. The human body treats any perceived stressor as a threat. When the body encounters a perceived threat (e.g., a near-miss accident, shocking news, a demanding assignment), the hypothalamus, a tiny region at the base of the brain, instigates the “fight-or-flight response” — a combination of nerve and hormonal signals. This system prompts the adrenal glands, located at the top of the kidneys, to release a surge of hormones, including adrenaline and cortisol. Adrenaline is a hormone that increases heart rate, elevates blood pressure, and boosts energy supplies. Cortisol, the primary stress hormone, increases sugars (glucose) in the bloodstream, enhances the brain’s use of glucose, and increases the availability of substances that repair tissues. Cortisol also curbs functions that would be nonessential or detrimental in a fight-or-flight situation. It alters immune system responses and suppresses the digestive system, the reproductive system, and growth processes. This complex natural alarm system also communicates with regions of the brain that control mood, motivation, and fear. The body’s stress-response system is usually temporary. Once a perceived threat has passed, hormone levels return to normal. As adrenaline and cortisol levels drop, heart rate and blood pressure return to baseline levels, and other systems resume their regular activities. But when stressors are always present, such as those we experience in a modern, fast-paced society, the body can constantly feel under attack, and the fight-or-flight reaction remains activated. The long-term activation of the stress-response system — and the subsequent overexposure to cortisol and other stress hormones — can disrupt almost all of the body’s processes and increase the risk of numerous mental and physical health problems, including:
Statistics from the Canadian Mental Health Association are alarming in describing the negative health impacts of stress (Higgins, Duxbury, & Lyons, 2008):
Positive Impacts of Stress on HealthWhile research has shown that stress can be extremely deleterious in terms of health outcomes, it can also have positive impacts on health. Because stress is subjective and hinges on perception, the degree to which a person perceives an event as threatening or non-threatening determines the level of stress that person experiences. An individual’s perception or appraisal of an event or instance depends on many factors, such as gender, personality, character, context, memories, upbringing, age, size, relationships, and status – all of which are relative and arbitrary. One individual may perceive a broken-down car on the highway as an extremely stressful event, whereas another individual may perceive such an incident as invigorating, exciting, or a relief. EustressHans Selye, the prominent stress psychologist, proposed the concept of eustress to capture stress that is not necessarily debilitative and could be potentially facilitative to a person’s sense of well-being, capacity, or performance. Selye explained that every experience or change represents a challenge or stressor to the human system, and thus every experience is met with some degree of “alarm” or arousal (1956). It is individual difference, or “how we take it,” that determines whether a stressor is interpreted as eustress (positive or challenging) or dystress (negative or threatening). Likewise, the multidimensional theory of performance anxiety (Jones & Swain, 1992, 1995; Jones & Hardy, 1993; Martens, Burton, Vealey, Bump, & Smith, 1990) includes a directional component for measuring individuals’ anxiety interpretation along with the traditional intensity component.
In 2007, Hanton and associates studied six high-performance athletes to better understand the role and nature of anxiety and stress as it relates to athletic performance. Specifically, the researchers were interested in understanding athletes’ interpretations of competitive stress and the role that experience plays in that interpretation. Athletes were asked to reflect on the influence of positive and negative critical incidents on the interpretation and appraisal of cognitive and somatic experiences of stress and anxiety symptoms. Six elite athletes were interviewed prior to critical athletic incidents such as an important race or game, a final game or match, or a particularly challenging event. Some athletes reported negative interpretations of their anxious or nervous feelings: “I felt anxious thoughts like I had never experienced before. It was the new environment. The fact that we were playing at Wembley with a big crowd. That was unfamiliar and started to overwhelm me. I started to doubt myself and wonder whether I belonged there, whether I had the skills or ability to compete.” Comparatively, one participant described similar anxious thoughts and feelings but interpreted them positively: “When I’m nervous and feeling sick inside, that means that the race is important to me and I’m there to achieve something. This time it was almost as though I could be sick, they [symptoms] were that intense. But that was positive because it showed just how important that race was to me and that I was ready to compete.” The researchers have found a number of reasons for the variation in interpretation of emotional and somatic experiences of anxiety; the factor impacting performance is not the cognitive, emotional, or somatic anxiety itself, but rather the direction or individual’s interpretation of that anxiety that can influence, either facilitatively or debilitatively, performance. Stress-Related GrowthStress has also been associated with personal growth and development. Stress can enhance an individual’s resilience or hardiness. The hardiness theoretical model was first presented by Kobasa (1979) and illustrates resilient stress response patterns in individuals and groups. Often regarded as a personality trait or set of traits, psychological hardiness has been described by Bartone (1999) as a style of functioning that includes cognitive, emotional, and behavioural qualities. The hardy style of functioning distinguishes people who stay healthy under stress from those who develop stress-related problems. Hardiness includes the elements of commitment, control, and challenge. Commitment is the tendency to see the world as interesting and meaningful. Control is the belief in one’s own ability to control or influence events. Challenge involves seeing change and new experiences as exciting opportunities to learn and develop. The hardy person is considered courageous in dealing with new experiences and disappointments, and highly competent. The hardy person is not immune to stress, but is resilient in responding to a variety of stressful conditions. Individuals high in hardiness not only remain healthy, but they also perform better under stress. In this way, hardiness is a chicken-and-egg concept in that hardy people seem to be able to better tolerate and grow from stressful events or become more hardy. It is unclear whether stress fosters hardiness or hardiness is something a person is born with. The inverted U hypothesis asserts that, up to a point, stress can be growth inducing but that there is a turning or tipping point when stress just becomes too much and begins to become debilitative (see Figure 16.2, “The Stress Curve”). Feelings of stress (cognitive or physical) can be interpreted negatively to mean that a person is not ready, or positively to mean that a person is ready. It is the person’s interpretation, not the stress itself, that influences the outcome. Figure 16.2 The Stress Curve.Key Takeaways
Exercises and Critical Thinking
Bartone, P. T. (1999). Hardiness protects against war-related stress in army reserve forces. Consulting Psychology Journal, 51, 72–82. Hanton, S., Cropley, B., Neil, R., Mellalieu, S.D., & Miles, A. (2007). Experience in sport and its relationship with competitive anxiety. International Journal of Sport and Exercise Psychology, 5(1), 28-53. Higgins, C., Duxbury, L. & Lyons, S. (2008). Reducing Work Life Conflict: What works, what doesn’t? Health Canada. Retrieved May 2014 from http://www.hc-sc.gc.ca/ewh-semt/pubs/occup-travail/balancing-equilibre/index-eng.php#ack Jones, G., & Swain, A. B. J. (1992). Intensity and direction dimensions of competitive state anxiety and relationships with competitiveness. Perceptual and Motor Skills, 74, 467–472. Jones, G., & Swain, A. B. J. (1995). Predispositions to experience debilitative and facilitative anxiety in non-elite performers. The Sport Psychologist, 9, 202–212 Jones, G., Swain, A. B. J., & Hardy, L. (1993). Intensity and direction dimensions of competitive state anxiety and Kobasa, S. C. (1979). Stressful life events, personality, and health: An inquiry into hardiness. Journal of Personality and Social Psychology, 37(1), 1–11. Martens, R., Burton, D., Vealey, R. S., Bump, L. A., & Smith, D. E. (1990). Development and validation of the competitive state anxiety inventory-2 (CSAI-2). In R. Martens, R. S. Vealey, & D. Burton (Eds.), Competitive Selye, H. (1956). The stress of life. New York, NY, US: McGraw-Hill. Thoits, P.A. (2010). Strd health: major findings and policy implications. Journal of Health and Social Behavior, 51(1), suppl S41–S53. Yerkes R. M. , & Dodson, J. D. (1908). The relation of strength of stimulus to rapidity of habit-formation. Journal of Comparative Neurology and Psychology, 18, 459–482. Image AttributionsFigure 16.1: By J. Walinga. Figure 16.2: (http://en.wikipedia.org/wiki/File:HebbianYerkesDodson.JPG) is in the public domain. Long DescriptionsFigure 16.1 long description: Stress can hurt physical and mental health which can increase social inequalities and social health gaps which can cause more stress. [Return to Figure 16.1] |