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Introduction to Homeostasis September 2006 Clinical Science Team CardiffUniversitySONMS©CSANTeam.

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Presentation on theme: "Introduction to Homeostasis September 2006 Clinical Science Team CardiffUniversitySONMS©CSANTeam."— Presentation transcript:

1 Introduction to Homeostasis September 2006 Clinical Science Team CardiffUniversitySONMS©CSANTeam

2 Learning Outcomes Define the term homeostasis Define the term internal environment Explain the principle of homeostatic set range Define the term stress as applied to physiological systems Define the term stressor Define the two control systems Describe and illustrate a typical physiological control loop Explain the principle of negative feedback CardiffUniversitySONMS©CSANTeam

3 Homeostasis ‘ The regulatory mechanisms of the body can be understood in terms of a single shared function: that of maintaining constancy of the internal environment. A state of relative constancy of the internal environment is known as homeostasis, and it is maintained by effectors that are regulated by sensory information from the internal environment (Fox 2002, p.5)’ CardiffUniversitySONMS©CSANTeam

4 Homeostasis The Body in Balance CardiffUniversitySONMS©CSANTeam

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6 External Environment CardiffUniversitySONMS©CSANTeam

7 Threats from the External Environment CardiffUniversitySONMS©CSANTeam

8 Internal Environment Nutrients & Oxygen etc Waste Products CardiffUniversitySONMS©CSANTeam

9 Homeostasis A condition in which the body’s internal environment remains within set physiological limits (homeo = same; stasis = standing still). CardiffUniversitySONMS©CSANTeam

10 Physiological set homeostatic points, or the set homeostatic range refer to the normal range of values for given physiological factors equate with normal function and health of both the cell and the individual, for example: Plasma glucose – 4 -7 mmol/litre  Arterial plasma pH – 7.35 -7.45 Set Point or Set Homeostatic Range CardiffUniversitySONMS©CSANTeam

11 STRESS CardiffUniversitySONMS©CSANTeam

12 In physiological terms stress is defined as: any stimulus that creates an imbalance (above or below the set homeostatic range), within the internal environment. Stress CardiffUniversitySONMS©CSANTeam

13 The stimuli that produce imbalances in homeostasis are called stressors. These fall into three categories: 1.Physical 2.Psychological 3.Sociological Stressors CardiffUniversitySONMS©CSANTeam

14 Control Systems The body detects and responds to homeostatic imbalances via two complementary control systems:  The Nervous System  The Endocrine System These two control systems work together to maintain homeostatic balance CardiffUniversitySONMS©CSANTeam

15 Control Systems Respond to and Regulate Imbalances in Homeostasis CardiffUniversitySONMS©CSANTeam

16 Negative Feedback Loops For constancy of the internal environment to be maintained, the body must have:  Sensors (receptors) that are able to detect deviations from a set homeostatic point or range.  An integrating centre that receives information from the sensor (particular region of the brain/spinal cord, or distinct cells within an endocrine gland). The integrating centre responds by influencing the action of effectors.  Effector cells or organs function to re-establish the normal homeostatic range. An analogy of this control loop is seen in temperature control via a house thermostat: CardiffUniversitySONMS©CSANTeam

17 Negative feedback The house thermostat….. Imagine, the thermostat in your house is set to 20°C (set point), it’s a warm day and the temperature soon exceeds 20°C, 1)the thermostat (sensor) senses this change, 2)its equivalent of an integrating centre instructs the air conditioner (effector) to activate which lowers the temperature below the set point. 3)It reverses the temperature change. CardiffUniversitySONMS©CSANTeam

18 Negative feedback CardiffUniversitySONMS©CSANTeam

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20 Antagonistic effectors Most factors are controlled by several effectors These often have antagonistic (opposite) effects Control by antagonistic effectors can be described as ‘push-pull’ Increasing activity of one effector is accompanied by decreasing activity of an antagonistic effector This affords a finer degree of control CardiffUniversitySONMS©CSANTeam

21 Negative feedback loop CardiffUniversitySONMS©CSANTeam

22 Negative feedback loops CardiffUniversitySONMS©CSANTeam

23 Positive feedback Works in the opposite direction to negative feedback Positive feedback amplifies the effect of the change to the set point Think of the thermostat, if the mechanism was positive feedback, a rise in temperature would be amplified by the effector, thus the temperature would continue to increase CardiffUniversitySONMS©CSANTeam

24 Positive feedback An example of positive feedback occurs in child birth 1.Contractions cause uterine muscle stretch 2.Signals sent to posterior pituitory 3.Oxytocin (a hormone) is released 4.Stimulates further contractions +ve feedback

25 Unsuccessful Return to homeostasis NervousEndocrine ImmuneLearned Behavioural Responses Physical & Mental Stressors Internal & External Microbiology Malnutrition INTERVENTIONS Pharmacology Nutrition Nursing MDT Successful Return to homeostasis & health Altered Physiological function - Ill Health Adaptation Monitoring & Regulating systems Imbalance in homeostasis Homeostasis and Health CardiffUniversitySONMS©CSANTeam

26 Conclusion In this session we have briefly explored the following : 1.Homeostasis 2.The internal and external environment 3.Stress in physiological terms 4.Set point/ set range 5.Negative feedback loops 6.Positive feedback CardiffUniversitySONMS©CSANTeam

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