لخّصلي

Factors Related to the Substance
Form and Innate Chemical Activity
The form of a substance may have a profound impact on its toxicity especially for metallic elements, also termed heavy metals. For example, the toxicity of mercury vapor differs greatly from methyl mercury. Another example is chromium. Cr3+ is relatively nontoxic whereas Cr6+ causes skin or nasal corrosion and lung cancer.

The innate chemical activity of substances also varies greatly. Some can quickly damage cells causing immediate cell death. Others slowly interfere only with a cell's function. For example:

Hydrogen cyanide binds to the enzyme cytochrome oxidase resulting in cellular hypoxia and rapid death.
Nicotine binds to cholinergic receptors in the central nervous system (CNS) altering nerve conduction and inducing gradual onset of paralysis.
Dosage
The dosage is the most important and critical factor in determining if a substance will be an acute or a chronic toxicant. Virtually all chemicals can be acute toxicants if sufficiently large doses are administered. Often the toxic mechanisms and target organs are different for acute and chronic toxicity. Examples are:

Toxicant Acute Toxicity Chronic Toxic Effects
Ethanol CNS depression Liver cirrhosis
Arsenic Gastrointestinal damage Skin/liver cancer
Table 1. Examples of acute and chronic toxicity

Exposure Route
The way an individual comes in contact with a toxic substance, or exposure route, is important in determining toxicity. Some chemicals may be highly toxic by one route but not by others. Two major reasons are differences in absorption and distribution within the body. For example:

Ingested chemicals, when absorbed from the intestine, distribute first to the liver and may be immediately detoxified.
Inhaled toxicants immediately enter the general blood circulation and can distribute throughout the body prior to being detoxified by the liver.
Different target organs often are affected by different routes of exposure.

Diagram of toxic substances being ingested
Figure 1. Ingestion
(Image Source: ORAU, ©)

Diagram of toxic substances being breathed into the lungs
Figure 2. Inhalation
(Image Source: ORAU, ©)

Absorption
The ability to be absorbed is essential to systemic toxicity. Some chemicals are readily absorbed and others are poorly absorbed. For example, nearly all alcohols are readily absorbed when ingested, whereas there is virtually no absorption for most polymers. The rates and extent of absorption may vary greatly depending on the form of a chemical and the route of exposure to it. For example:

Ethanol is readily absorbed from the gastrointestinal tract but poorly absorbed through the skin.
Organic mercury is readily absorbed from the gastrointestinal tract; inorganic lead sulfate is not.
Factors Related to the Organism
Species
Toxic responses can vary substantially depending on the species. Most differences between species are attributable to differences in metabolism. Others may be due to anatomical or physiological differences. For example, rats cannot vomit and expel toxicants before they are absorbed or cause severe irritation, whereas humans and dogs are capable of vomiting.

Selective toxicity refers to species differences in toxicity between two species simultaneously exposed. This is the basis for the effectiveness of pesticides and drugs. For example:

An insecticide is lethal to insects but relatively nontoxic to animals.
Antibiotics are selectively toxic to microorganisms while virtually nontoxic to humans.
Life Stage
An individual's age or life stage may be important in determining his or her response to toxicants. Some chemicals are more toxic to infants or the elderly than to young adults. For example:

Parathion is more toxic to young animals.
Nitrosamines are more carcinogenic to newborn or young animals.
Illustrated silhouette people of varying ages and sizes standing outdoors under a tree
Figure 3. An individual's life stage can impact that person's response to toxicants
(Image Source: iStock Photos, ©)

Gender
Gender can play a big role in influencing toxicity. Physiologic differences between men and women, including differences in pharmacokinetics and pharmacodynamics, can affect drug activity.

In comparison with men, pharmacokinetics in women generally can be impacted by their lower body weight, slower gastrointestinal motility, reduced intestinal enzymatic activity, and slower kidney function (glomerular filtration rate). Delayed gastric emptying in women may result in a need for them to extend the interval between eating and taking medications that require absorption on an empty stomach. Other physiologic differences between men and women also exist. Slower renal clearance in women, for example, may result in a need for dosage adjustment for drugs such as digoxin that are excreted via the kidneys.

In general, pharmacodynamic differences between women and men include greater sensitivity to and enhanced effectiveness, in women, of some drugs, such as beta blockers, opioids, and some antipsychotics.

Studies in animals also have identified gender-related differences. For example:

Male rats are 10 times more sensitive than females to liver damage from DDT.
Female rats are twice as sensitive to parathion as are male rats.
Male and female gender symbols
Figure 4. Gender symbols for female (left) and male (right)
(Image Source: iStock Photos, ©)

Metabolism
Metabolism, also known as biotransformation, is the conversion of a chemical from one form to another by a biological organism. Metabolism is a major factor in determining toxicity. The products of metabolism are known as metabolites. There are two types of metabolism:

Detoxification
Bioactivation
In detoxification, a xenobiotic is converted to a less toxic form. This is a natural defense mechanism of the organism. Generally, detoxification converts lipid-soluble compounds to polar compounds.

In bioactivation, a xenobiotic may be converted to more reactive or toxic forms. Cytochrome P-450 (CYP450) is an example of an enzyme pathway used to metabolize drugs. In the elderly, CYP450 metabolism of drugs such as phenytoin and carbamazepine may be decreased. Therefore, the effect of those drugs may be less pronounced. CYP450 metabolism also can be inhibited by many drugs. Risk of toxicity may be increased if a CYP450 enzyme-inhibiting drug is given with one that depends on that pathway for metabolism.

There is awareness that the gut microbiota can impact the toxicity of drugs and other chemicals. For example, gut microbes can metabolize some environmental chemicals and bacteria-dependent metabolism of some chemicals can modulate their toxicity. Also, environmental chemicals can alter the composition and/or the metabolic activity of the gastrointestinal bacteria, thus contributing in a meaningful way to shape an individual's microbiome. The study of the consequences of these changes is an emerging area of toxicology.

Learn more about human exposure to pollutants and their interaction with the GI microbiota.

Learn more about the microbiome and toxicology.

Distribution Within the Body
The distribution of toxicants and toxic metabolites throughout the body ultimately determines the sites where toxicity occurs. A major determinant of whether a toxicant will damage cells is its lipid solubility. If a toxicant is lipid-soluble, it readily penetrates cell membranes. Many toxicants are stored in the body. Fat tissue, liver, kidney, and bone are the most common storage sites. Blood serves as the main avenue for distribution. Lymph also distributes some materials.

Excretion
The site and rate of excretion is another major factor affecting the toxicity of a xenobiotic. The kidney is the primary excretory organ, followed by the gastrointestinal tract, and the lungs (for gases). Xenobiotics may also be excreted in sweat, tears, and milk.

A large volume of blood serum is filtered through the kidney. Lipid-soluble toxicants are reabsorbed and concentrated in kidney cells. Impaired kidney function causes slower elimination of toxicants and increases their toxic potential.

Health Status
The health of an individual or organism can play a major role in determining the levels and types of potential toxicity. For example, an individual may have pre-existing kidney or liver disease. Certain conditions, such as pregnancy, also are associated with physiological changes in kidney function that could influence toxicity.

Nutritional Status
Diet (nutritional status) can be a major factor in determining who does or does not develop toxicity. For example:

Consumption of fish that have absorbed mercury from contaminated water can result in mercury toxicity; an antagonist for mercury toxicity is the nutrient selenium.
Some vegetables can accumulate cadmium from contaminated soil; an antagonist for cadmium toxicity is the nutrient zinc.
Grapefruit contains a substance that inhibits the P450 drug detoxification pathway, making some drugs more toxic.
Find out more about nutrition and chemical toxicity here.

Circadian Rhythms
Circadian rhythms can play a role in toxicity. For example, rats administered an immunosuppressive drug had severe toxicity in their intestines 7 hours after light onset compared to controls and to other times in the day. The rats had changes in their digestive enzyme activity and other physiological indicators at this dosing time.

Find out more about circadian rhythm and gut toxicity here.

Other Factors
Presence of Other Chemicals
The presence of other chemicals, at the same time, earlier, or later may:

Decrease toxicity (antagonism)
Add to toxicity (additivity)
Increase toxicity (synergism or potentiation)
For example:

Antidotes used to counteract the effects of poisons function through antagonism (atropine counteracts poisoning by organophosphate insecticides).
Alcohol may enhance the effect of many antihistamines and sedatives.
A synergistic interaction between the antioxidant butylated hydroxytoluene (BHT) and a certain concentration of oxygen results in lung damage in the form of interstitial pulmonary fibrosis.