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The ability of a system or living organism to adjust its internal environment to maintain a stable equilibrium; such as the ability of warm-blooded animals to maintain a constant temperature.
When an individual doesn't have enough to eat, the body adjusts to this by slowing down metabolism so that the individual expends less calories in order to conserve the limited energy available from the inadequate diet.
Homeostasis regulates an organism's internal environment and maintains a stable, constant condition of properties such as temperature or pH.
It can be either an open or closed system.
Multiple dynamic equilibrium adjustments and regulation mechanisms make homeostasis possible.
All homeostatic control mechanisms have at least three interdependent components for the variable being regulated.
The receptor is the sensing component that monitors and responds to changes in the environment.
When the receptor senses a stimulus, it sends information to a "control center", the component that sets the range at which a variable is maintained.
The control center determines an appropriate response to the stimulus.
In most homeostatic mechanisms, the control center is the brain.
The control center then sends signals to an effector, which can be muscles, organs, or other structures that receive signals from the control center.
After receiving the signal, a change occurs to correct the deviation by either enhancing it with positive feedback or depressing it with negative feedback.
Positive feedback is a mechanism by which an output is enhanced, such as protein levels.
Positive feedback mechanisms are designed to accelerate or enhance the output created by a stimulus that has already been activated.
Unlike negative feedback mechanisms that initiate to maintain or regulate physiological functions within a set and narrow range, the positive feedback mechanisms are designed to push levels out of normal ranges.
To achieve this purpose, a series of events initiates a cascading process that builds to increase the effect of the stimulus.
This process can be beneficial, but is rarely used by the body due to risks of the acceleration becoming uncontrollable.
One positive feedback example in the body is blood platelet accumulation, which, in turn, causes blood clotting in response to a break or tear in the lining of blood vessels.
Another example is the release of oxytocin to intensify the contractions that take place during childbirth.
Negative feedback mechanisms consist of reducing the output or activity of any organ or system back to its normal range of functioning.
A good example of this is regulating blood pressure.
Blood vessels can sense resistance of blood flow against the walls when blood pressure increases.
The blood vessels act as the receptors to relay this message to the brain.
The brain then sends a message to the heart and blood vessels, both of which are the effectors.
The heart rate would decrease as the blood vessels increase in diameter (known as vasodilation).
This change would cause the blood pressure to fall back to its normal range.
The opposite happens when blood pressure decreases, and causes vasoconstriction.
Similarly, the release of glucocorticoids by the adrenal cortex is stimulated by ACTH release by the anterior pituitary.
As glucocorticoid levels rise, they prevent further release of hormones by the hypothalamus and pituitary, acting as a negative feedback mechanism .
Another important example is seen when the body is deprived of food.
The body then resets the metabolic set point to a lower-than-normal value.
This in turn allows the body to continue to function, at a slower rate, even though the body is starving.
Therefore, people who deprive themselves of food while trying to lose weight would find it easy to shed weight initially and much harder to lose more after.
This is due to the body readjusting itself to a lower metabolic set point to allow the body to survive with its low supply of energy.
Exercise can change this effect by increasing the metabolic demand.
Another good example of negative feedback mechanism is temperature control.
The hypothalamus, which monitors the body temperature, is capable of determining even the slightest variation of normal body temperature (37 degrees Celsius).
Response to such variation could be stimulation of glands that produce sweat to reduce the temperature or signaling various muscles to shiver to increase body temperature.
Both feedbacks are equally important for the healthy functioning of one's body.
blood vessel receptors relay resistance to blood flow to the brain, which lowers heart rate, hypothalamus senses rise in body temperature and stimulates sweat glands, breaks in blood vessels cause blood platelet accumulation and blood clotting, and depriving a body of food causes the metabolic set point to rise to encourage eating
Blood glucose increases, leading to insulin release and causing blood glucose to decrease., Body temperature decreases, muscle cells contract, causing shivering, increasing body temperature., Thyroid hormones are elevated, leading to a decrease in TSH, decreasing thyroid hormone release., and Uterine contractions continuously increase during pregnancy until delivery.