Human equivalent: Difference between revisions
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Latest revision as of 17:16, 22 March 2025
Human equivalent is a term used in various fields of study, including pharmacology, toxicology, and physiology, to compare the biological effects of different species. It is often used to translate the results of animal experiments to potential effects in humans. The concept is based on the principle that the effects of a substance are related to the concentration of the substance in the body, which in turn is determined by the dose of the substance and the size of the organism.
Pharmacology and toxicology[edit]
In pharmacology and toxicology, the human equivalent dose (HED) is a measure used to estimate the dose of a drug or substance that would be expected to produce effects in humans similar to those observed in animal studies. The HED is calculated by adjusting the dose used in the animal study to account for differences in body size and metabolism between the animal species and humans.
Physiology[edit]
In physiology, the human equivalent is used to compare the physiological functions of different species. For example, the human equivalent of a mouse's metabolic rate is calculated by adjusting the mouse's metabolic rate to account for differences in body size and metabolic rate between mice and humans.
Calculation[edit]
The calculation of the human equivalent is based on the principle of allometric scaling, which is a method of comparing the characteristics of different species that takes into account the effects of body size. The formula for calculating the human equivalent is:
HED = Animal Dose in mg/kg x (Animal Weight in kg / Human Weight in kg)^(1/3)
Limitations[edit]
While the concept of the human equivalent is useful for comparing the effects of substances and physiological functions across different species, it has several limitations. First, it assumes that the effects of a substance are solely determined by its concentration in the body, which may not always be the case. Second, it assumes that all species respond to substances in the same way, which is not always true. Finally, it does not take into account differences in the way different species metabolize substances.
