Median lethal dose


In toxicology, the median lethal dose, LD50, LC50 or LCt50 is a measure of the lethal dose of a toxin, radiation, or pathogen. The value of LD50 for a substance is the dose required to kill half the members of a tested population after a specified test duration. LD50 figures are frequently used as a general indicator of a substance's acute toxicity. A lower LD50 is indicative of increased toxicity.
The test was created by J.W. Trevan in 1927. The term semilethal dose is occasionally used in the same sense, in particular with translations of foreign language text, but can also refer to a sublethal dose. LD50 is usually determined by tests on animals such as laboratory mice. In 2011, the U.S. Food and Drug Administration approved alternative methods to LD50 for testing the cosmetic drug Botox without animal tests.

Conventions

The LD50 is usually expressed as the mass of substance administered per unit mass of test subject, typically as milligrams of substance per kilogram of body mass, sometimes also stated as nanograms, micrograms, or grams per kilogram. Stating it this way allows the relative toxicity of different substances to be compared, and normalizes for the variation in the size of the animals exposed. For substances in the environment, such as poisonous vapors or substances in water that are toxic to fish, the concentration in the environment is used, giving a value of LC50. But in this case, the exposure time is important.
The choice of 50% lethality as a benchmark avoids the potential for ambiguity of making measurements in the extremes and reduces the amount of testing required. However, this also means that LD50 is not the lethal dose for all subjects; some may be killed by much less, while others survive doses far higher than the LD50. Measures such as "LD1" and "LD99" are occasionally used for specific purposes.
Lethal dosage often varies depending on the method of administration; for instance, many substances are less toxic when administered orally than when intravenously administered. For this reason, LD50 figures are often qualified with the mode of administration, e.g., "LD50 i.v."
The related quantities LD50/30 or LD50/60 are used to refer to a dose that without treatment will be lethal to 50% of the population within 30 or 60 days. These measures are used more commonly within Radiation Health Physics, as survival beyond 60 days usually results in recovery.
A comparable measurement is LCt50, which relates to lethal dosage from exposure, where C is concentration and t is time. It is often expressed in terms of mg-min/m3. ICt50 is the dose that will cause incapacitation rather than death. These measures are commonly used to indicate the comparative efficacy of chemical warfare agents, and dosages are typically qualified by rates of breathing for inhalation, or degree of clothing for skin penetration. The concept of Ct was first proposed by Fritz Haber and is sometimes referred to as Haber's Law, which assumes that exposure to 1 minute of 100 mg/m3 is equivalent to 10 minutes of 10 mg/m3.
Some chemicals, such as hydrogen cyanide, are rapidly detoxified by the human body, and do not follow Haber's Law. So, in these cases, the lethal concentration may be given simply as LC50 and qualified by a duration of exposure. The Material Safety Data Sheets for toxic substances frequently use this form of the term even if the substance does follow Haber's Law.
For disease-causing organisms, there is also a measure known as the median infective dose and dosage. The median infective dose is the number of organisms received by a person or test animal qualified by the route of administration. Because of the difficulties in counting actual organisms in a dose, infective doses may be expressed in terms of biological assay, such as the number of LD50's to some test animal. In biological warfare infective dosage is the number of infective doses per cubic metre of air times the number of minutes of exposure.

Limitation

As a measure of toxicity, LD50 is somewhat unreliable and results may vary greatly between testing facilities due to factors such as the genetic characteristics of the sample population, animal species tested, environmental factors and mode of administration.
There can be wide variability between species as well; what is relatively safe for rats may very well be extremely toxic for humans, and vice versa. For example, chocolate, comparatively harmless to humans, is known to be toxic to many animals. When used to test venom from venomous creatures, such as snakes, LD50 results may be misleading due to the physiological differences between mice, rats, and humans. Many venomous snakes are specialized predators on mice, and their venom may be adapted specifically to incapacitate mice; and mongooses may be exceptionally resistant. While most mammals have a very similar physiology, LD50 results may or may not have equal bearing upon every mammal species, such as humans, etc.

Examples

Note: Comparing substances to each other by LD50 can be misleading in many cases due to differences in effective dose. Therefore, it is more useful to compare such substances by therapeutic index, which is simply the ratio of LD50 to ED50.
The following examples are listed in reference to LD50 values, in descending order, and accompanied by LC50 values,, when appropriate.
SubstanceAnimal, RouteLD50

LD50 : g/kg

standardised		Reference
Waterrat, oral90,000 mg/kg90
Sucrose rat, oral29,700 mg/kg29.7
Glucose rat, oral25,800 mg/kg25.8
Monosodium glutamate rat, oral16,600 mg/kg16.6
Stevioside mice and rats, oral15,000 mg/kg15
Gasoline rat14,063 mg/kg14.0
Vitamin C rat, oral11,900 mg/kg11.9
Glyphosate rat, oral10,537 mg/kg10.537
Lactose rat, oral10,000 mg/kg10
Aspartamemice, oral10,000 mg/kg10
Urearat, oral8,471 mg/kg8.471
Cyanuric acidrat, oral7,700 mg/kg7.7
Cadmium sulfiderat, oral7,080 mg/kg7.08
Ethanol rat, oral7,060 mg/kg7.06
Sodium isopropyl methylphosphonic acid rat, oral6,860 mg/kg6.86
Melaminerat, oral6,000 mg/kg6
Methanolhuman, oral810 mg/kg0.81
Taurinerat, oral5,000 mg/kg5
Melamine cyanuraterat, oral4,100 mg/kg4.1
Fructose rat, oral4,000 mg/kg4
Sodium molybdaterat, oral4,000 mg/kg4
Sodium chloride rat, oral3,000 mg/kg3
Paracetamol rat, oral1,944 mg/kg1.944
Delta-9-tetrahydrocannabinol rat, oral1,270 mg/kg1.27
Cannabidiol rat, oral980 mg/kg0.98
Metallic Arsenicrat, oral763 mg/kg0.763
Ibuprofenrat, oral636 mg/kg0.636
Formaldehyderat, oral600–800 mg/kg0.6
Solanine main alkaloid in the several plants in Solanaceae amongst them Solanum tuberosumrat, oral 590 mg/kg0.590
Alkyl dimethyl benzalkonium chloride rat, oral
fish, immersion
aquatic invertebrates, immersion		304.5 mg/kg

0.3045

Coumarin rat, oral293 mg/kg0.293
Psilocybin mouse, oral280 mg/kg0.280
Hydrochloric acidrat, oral238–277 mg/kg0.238
Ketaminerat, intraperitoneal229 mg/kg0.229
Aspirin rat, oral200 mg/kg0.2
Caffeinerat, oral192 mg/kg0.192
Arsenic trisulfiderat, oral185–6,400 mg/kg0.185–6.4
Sodium nitriterat, oral180 mg/kg0.18
Methylenedioxymethamphetamine rat, oral160 mg/kg0.18
Uranyl acetate dihydratemouse, oral136 mg/kg0.136
Dichlorodiphenyltrichloroethane mouse, oral135 mg/kg0.135
Uraniummice, oral114 mg/kg 0.114
Bisoprololmouse, oral100 mg/kg0.1
Cocainemouse, oral96 mg/kg0.096
Cobalt chloriderat, oral80 mg/kg0.08
Cadmium oxiderat, oral72 mg/kg0.072
Thiopental sodium rat, oral64 mg/kg0.064
Demeton-S-methylrat, oral60 mg/kg0.060
Methamphetaminerat, intraperitoneal57 mg/kg0.057
Sodium fluoriderat, oral52 mg/kg0.052
Nicotinerat, oral50 mg/kg0.05
Pentaboranehuman, oral50 mg/kg0.05
Capsaicinmouse, oral47.2 mg/kg0.0472
Vitamin D3 rat, oral37 mg/kg0.037
Piperidine rat, oral30 mg/kg0.030
Heroin mouse, intravenous21.8 mg/kg0.0218
Lysergic acid diethylamide rat, intravenous16.5 mg/kg0.0165
Arsenic trioxiderat, oral14 mg/kg0.014
Metallic Arsenicrat, intraperitoneal13 mg/kg0.013
Sodium cyaniderat, oral6.4 mg/kg0.0064
Chlorotoxin mice4.3 mg/kg0.0043
Hydrogen cyanidemouse, oral3.7 mg/kg0.0037
Carfentanilrat, intravenous3.39 mg/kg0.00339
Nicotinemice, oral3.3 mg/kg0.0033
White phosphorusrat, oral3.03 mg/kg0.00303
Strychninehuman, oral1–2 mg/kg 0.001–0.002
Mercury chloriderat, oral1 mg/kg0.001
Nicotinehuman, oral0.8 mg/kg 0.0008
Cantharidin human, oral500 µg/kg0.0005
Aflatoxin B1 rat, oral480 µg/kg0.00048
Plutoniumdog, intravenous320 µg/kg0.00032
Amatoxin rat300-700 µg/kg0.0007
Tetrodotoxin mice, oral334 µg/kg0.000334
Fentanylmonkey300 µg/kg0.0003
Bufotoxin cat, intravenous300 µg/kg0.0003
Caesium-137mouse, parenternal21.5 µCi/g0.000245
Sarinmouse, subcutaneous injection172 µg/kg0.000172
Robustoxin mice150 µg/kg0.000150
VXhuman, oral, inhalation, absorption through skin/eyes140 µg/kg 0.00014
Venom of the Brazilian wandering spiderrat, subcutaneous134 µg/kg0.000134
Aconitine main alkaloid in Aconitum napellus and related speciesrat, intraveneous80 µg/kg0.000080
Venom of the Inland Taipan rat, subcutaneous25 µg/kg0.000025
Ricin rat, intraperitoneal
rat, oral		22 μg/kg
20–30 mg/kg		0.000022
0.02
2,3,7,8-Tetrachlorodibenzodioxin rat, oral20 µg/kg0.00002
CrTX-A crayfish, intraperitoneal5 µg/kg0.000005
Latrotoxin mice4.3 µg/kg0.0000043
Batrachotoxin human, sub-cutaneous injection2–7 µg/kg 0.000002
Abrin mice, intravenously
human, inhalation
human, oral		0.7 µg/kg
3.3 µg/kg
10–1000 µg/kg		0.0000007
0.0000033
0.00001–0.001
Maitotoxin mouse, intraperitoneal130 ng/kg0.00000013
Polonium-210human, inhalation10 ng/kg 0.00000001
Diphtheria toxinmice10 ng/kg0.00000001
Shiga toxin mice2 ng/kg0.000000002
Tetanospasmin mice2 ng/kg0.000000002
Botulinum toxin human, oral, injection, inhalation1 ng/kg 0.000000001
Ionizing radiationhuman, irradiation5 Gy

Poison Scale

The LD 50 values have a very wide range. The botulinum toxin as the most toxic substance known has an LD 50 value of 1 ng / kg, while the most non-toxic substance water has an LD 50 value of more than 90 g / kg. That's a difference of about 1 in 100 billion or 11 orders of magnitude. As with all measured values that differ by many orders of magnitude, a logarithmic view is advisable. Well-known examples are the indication of the earthquake strength using the Richter scale, the pH value, as a measure for the acidic or basic character of an aqueous solution or of loudness in decibels.
In this case, the negative decimal logarithm of the LD 50 values, which is standardized in kg per kg body weight, is considered.
The dimensionless value found can be entered in a toxin scale. Water as the most important substance has the catchy value 1 in the toxin scale obtained in this way.

Animal rights concerns

and animal-welfare groups, such as Animal Rights International, have campaigned against LD50 testing on animals. Several countries, including the UK, have taken steps to ban the oral LD50, and the Organisation for Economic Co-operation and Development abolished the requirement for the oral test in 2001.

Other measures of toxicity