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2 Ecological homeostasis 3 Biological homeostasis 4 See also |
The term usually is used in the sense of biological homeostasis. Multicellular organisms require a homeostatic internal environment, in order to live; many environmentalists believe this principal also applies to the external environment. ecological, biological, and social systems are homeostatic. They oppose change to maintain equilibrium. If the system does not succeed in reestablishing its balance, it will be in a state where constraints are more severe than before. This can ultimately lead to the destruction of the system.
Complex systems, such as a human body, must have homeostasis to maintain stability and to survive. These systems do not only have to endure to survive; they must adapt themselves and evolve to modifications of the environment and it must evolve.
Homeostatic systems show several properties
Main article: feedback
When a change of variable occurs, there are two main types of feedback to which the system reacts:
In the Gaia hypothesis, James Lovelock stated that the entire mass of living matter on Earth (or any planet with life) functions as a vast organism that actively modifies its planet to produce the environment that suits its needs. In this view, the entire planet maintains homeostasis. Whether this sort of system is present on Earth is still open to debate. However, some relatively simple homeostatic mechanisms are generally accepted. For example, when atmospheric carbon dioxide levels rise, plants are able to grow better and thus remove more carbon dioxide from the atmosphere.
Homeostasis is one of the fundamental characteristics of living things. It is the maintenance of the internal environment within tolerable limits.
With regard to any parameter, an organism may be a conformer or a regulator. Regulators try to maintain the parameter at a constant level, regardless of what is happening in its environment. Conformers allow the environment to determine the parameter. For instance, endothermic animals maintain a constant body temperature, while ectothermic animals exhibit wide variation in body temperature.
This is not to say that conformers may not have behavioral adaptations that allow them to exert some control over the parameter in question. For instance, reptiles often sit on sun-heated rockss in the morning to raise their body temperatures.
An advantage of homeostatic regulation is that it allows the organism to function more effectively. For instance, ectotherms tend to become sluggish at low temperatures, whereas endotherms are as active as always. On the other hand, regulation reqires energy. One reason why snakes can eat only once a week is that they use much less energy for maintaining homeostasis.
All sorts of factors affect the suitability of the human body fluids to sustain life; these include properties like temperature, salinity, acidity (carbon dioxide), and the concentrations of nutrients and wastes (urea, glucose, various ion, oxygen). Since these properties affect the chemical reactions that keep bodies alive, there are built-in physiological mechanisms to maintain them at desirable levels.
This control is achieved with various organs in the body. For example:
Overview
Properties of homeostasis
A frequent paradox for those responsible for the maintenance and evolution of a complex system (be it a body, an ecosystem, a state, or a planet) is how can a stable organization whose goal is to maintain itself and endure, be able to change and evolve?Mechanisms of homeostasis: feedback
Ecological homeostasis
Biological homeostasis
Homeostasis in the human body
Most of these organs are controlled by hormones secreted from the pituitary gland, which in turn is directed by the hypothalamus.