Carbamate

In organic chemistry, a carbamate is a category of organic compounds with the general formula and structure, which are formally derived from carbamic acid. The term includes organic compounds, formally obtained by replacing one or more of the hydrogen atoms by other organic functional groups; as well as salts with the carbamate anion .
Polymers whose repeat units are joined by carbamate like groups are an important family of plastics, the polyurethanes. See for clarification.

Properties

While carbamic acids are unstable, many carbamate esters and salts are stable and well known.

Equilibrium with carbonate and bicarbonate

In water solutions, the carbamate anion slowly equilibrates with the ammonium cation and the carbonate or bicarbonate anions:
Calcium carbamate is soluble in water, whereas calcium carbonate is not. Adding a calcium salt to an ammonium carbamate/carbonate solution will precipitate some calcium carbonate immediately, and then slowly precipitate more as the carbamate hydrolyzes.

Synthesis

Carbamate salts

The salt ammonium carbamate is generated by treatment of ammonia with carbon dioxide:

Carbamate esters

Carbamate esters also arise via alcoholysis of carbamoyl chlorides:
Alternatively, carbamates can be formed from chloroformates and amines:
Carbamates may be formed from the Curtius rearrangement, where isocyanates formed are reacted with an alcohol.

Natural occurrence

Carbamylated proteins

Within nature carbon dioxide can bind with neutral amine groups to form a carbamate. This post-translational modification is known as carbamylation, and is known to occur on several important proteins.
The N-terminal amino groups of valine residues in the α- and β-chains of deoxyhemoglobin exist as carbamates. They help to stabilise the protein when it becomes deoxyhemoglobin, and increases the likelihood of the release of remaining oxygen molecules bound to the protein. This stabilizing effect should not be confused with the Bohr effect.
The ε-amino groups of the lysine residues in urease and phosphotriesterase also feature carbamate.

CO₂ capture by ribulose 1,5-bisphosphate carboxylase

Perhaps the most prevalent carbamate is the one involved in the capture of CO₂ by plants. This process is necessary for their growth. The enzyme ribulose 1,5-bisphosphate carboxylase/oxygenase fixes a molecule of carbon dioxide as phosphoglycerate in the Calvin cycle. At the active site of the enzyme, a Mg²⁺ ion is bound to glutamate and aspartate residues as well as a lysine carbamate. The carbamate is formed when an uncharged lysine side chain near the ion reacts with a carbon dioxide molecule from the air, which then renders it charged, and, therefore, able to bind the Mg²⁺ ion.

Other biosynthetic pathways

is a carbamate mixed anhydride that is an intermediate in the urea cycle and the biosynthesis of pyrimidines. , a carbamate derivative of aminoimidazole, is an intermediate in the biosynthesis of inosine. Both carbamates are produced via reaction of groups with .

Applications

Synthesis of urea

Although not usually isolated as such, the salt ammonium carbamate is produced on a large scale as an intermediate in the production of the commodity chemical urea from ammonia and carbon dioxide.

Polyurethane plastics

s contain multiple carbamate groups as part of their structure. The "urethane" in the name "polyurethane" refers to these carbamate groups; the term "urethane links" describe how carbamates polymerize. In contrast, the substance commonly called "urethane", ethyl carbamate, is neither a component of polyurethanes, nor is it used in their manufacture. Urethanes are usually formed by reaction of an alcohol with an isocyanate. Commonly, urethanes made by a non-isocyanate route are called carbamates.
Polyurethane polymers have a wide range of properties and are commercially available as foams, elastomers, and solids. Typically, polyurethane polymers are made by combining diisocyanates, e.g. toluene diisocyanate, and diols, where the carbamate groups are formed by reaction of the alcohols with the isocyanates:

Carbamate insecticides

The so-called carbamate insecticides feature the carbamate ester functional group. Included in this group are aldicarb, carbofuran, carbaryl, ethienocarb, fenobucarb, oxamyl, and methomyl. They are synthetic analogues of the toxic alkaloid physostigmine, the study of which led to this class of insecticides. An estimated 25M kg of carbaryl were produced in 1971. These insecticides kill insects by reversibly inactivating the enzyme acetylcholinesterase .
Fenoxycarb has a carbamate group but acts as a juvenile hormone mimic, rather than inactivating acetylcholinesterase.
The insect repellent icaridin is a substituted carbamate.
Besides their common use as arthropodocides/insecticides, they are also nematicidal. One such is Oxamyl.
Sales have declined dramatically over recent decades.

Resistance

Among insecticide resistance mutations in esterases, carbamate resistance most commonly involves acetylcholinesterase desensitization, while organophosphate resistance most commonly is carboxylesterase metabolization.

Carbamate nerve agents

While the carbamate acetylcholinesterase inhibitors are commonly referred to as "carbamate insecticides" due to their generally high selectivity for insect acetylcholinesterase enzymes over the mammalian versions, the most potent compounds such as aldicarb and carbofuran are still capable of inhibiting mammalian acetylcholinesterase enzymes at low enough concentrations that they pose a significant risk of poisoning to humans, especially when used in large amounts for agricultural applications. Other carbamate based acetylcholinesterase inhibitors are known with even higher toxicity to humans, and some such as T-1123 and EA-3990 were investigated for potential military use as nerve agents. However, since all compounds of this type have a quaternary ammonium group with a permanent positive charge, they have poor blood–brain barrier penetration, and also are only stable as crystalline salts or aqueous solutions, and so were not considered to have suitable properties for weaponisation.

Preservatives and cosmetics

is a wood and paint preservative and used in cosmetics.

Chemical research

Some of the most common amine protecting groups, such as Boc, Fmoc, benzyl chloroformate and trichloroethyl chloroformate are carbamates.

Medicine

Ethyl carbamate

Urethane was once produced commercially in the United States as a chemotherapy agent and for other medicinal purposes. It was found to be toxic and largely ineffective. It is occasionally used in veterinary medicine in combination with other drugs to produce anesthesia.

Carbamate derivatives

Some carbamate derivatives are used in human pharmacotherapy:

The acetylcholinesterase inhibitor chemical class includes neostigmine and rivastigmine, both of which have a chemical structure based on the natural alkaloid physostigmine.
The tranquilizer, sedative-hypnotic, and muscle relaxant, meprobamate was commonly prescribed from the 1950s through the 1970s.
Soma is a CNS depressant and a prodrug of meprobamate; initially acting primarily as a mildy-sedating muscle relaxant and muscle pain reliever; after 2-3 hours, 20-30% of initial dose converts into active metabolite meprobamate, synergistically working together to potentiate, or add on to/increase, the existing sedation and muscle relaxation and analgesia.
Valmid or Valamin was a carbamate derivative chemically named ethinamate. It was withdrawn from the market in the U.S. and Netherlands around 1990.
The protease inhibitor darunavir for HIV treatment also contains a carbamate functional group.
Ephedroxane, an aminorex analogue used as a stimulant, also falls into the carbamate category.
Felbamate is an anticonvulsant used in the treatment of epilepsy, with high risk of potentially fatal aplastic anemia and/or liver failure limiting the drug's usage to severe refractory epilepsy.
Toxicity

Besides inhibiting human acetylcholinesterase, carbamate insecticides also target human melatonin receptors. The human health effects of carbamates are well documented in the list of known endocrine disruptor compounds. Clinical effects of carbamate exposure can vary from slightly toxic to highly toxic depending on a variety of factors including such as dose and route of exposure with ingestion and inhalation resulting in the most rapid clinical effects. These clinical manifestations of carbamate intoxication are muscarinic signs, nicotinic signs, and in rare cases central nervous system signs.

Sulfur analogues

There are two oxygen atoms in a carbamate, ROCNR₂, and either or both of them can be conceptually replaced by sulfur. Analogues of carbamates with only one of the oxygens replaced by sulfur are called thiocarbamates. Carbamates with both oxygens replaced by sulfur are called dithiocarbamates, RSCNR₂.
There are two different structurally isomeric types of thiocarbamate:

O-thiocarbamates, ROCNR₂, where the carbonyl group is replaced with a thiocarbonyl group
S-thiocarbamates, RSCNR₂, where the R–O– group is replaced with an R–S– group

O-thiocarbamates can isomerise to S-thiocarbamates, for example in the Newman–Kwart rearrangement.

Etymology

The etymology of the words "urethane" and "carbamate" are highly similar but not the same. The word "urethane" was first coined in 1833 by French chemist Jean-Baptiste Dumas. Dumas states "Urethane. The new ether, brought into contact with liquid and concentrated ammonia, exerts on this substance a reaction so strong that the mixture boils, and sometimes even produces a sort of explosion. If the ammonia is in excess, all the ether disappears. It forms ammonium hydrochlorate and a new substance endowed with interesting properties." Dumas appears to be naming this compound urethane. However, later Dumas states "While waiting for opinion to settle on the nature of this body, I propose to designate by the names of urethane and oxamethane the two materials which I have just studied, and which I regard as types of a new family, among nitrogenous substances. These names which, in my eyes, do not prejudge anything in the question of alcohol and ethers, will at least have the advantage of satisfying chemists who still refuse to accept our theory." The word urethane is derived from the words "urea" and "ether" with the suffix "-ane" as a generic chemical suffix, making it specific for the R₂NCOR' bonding structure.
The use of the word "carbamate" appears to come later only being traced back to at least 1849, in a description of Dumas's work by Henry Medlock. Medlock states "It is well known that the action of ammonia on chloro-carbonate of ethyl gives rise to the formation of the substance which Dumas, the discoverer, called urethane, and which we are now in the habit of considering as the ether of carbamic acid." This suggests that instead of continuing with the urethane family naming convention Dumas coined, they altered the naming convention to ethyl ether of carbamic acid. Carbamate is derived from the words "carbamide", otherwise known as urea, and "-ate" a suffix which indicates the salt or ester of an acid.
Both words have roots deriving from urea. Carbamate is less-specific because the -ate suffix is ambiguous for either the salt or ester of a carbamic acid. However, the -ate suffix is also more specific because it suggests carbamates must be derived from the acid of carbamate, or carbamic acids. Although, a urethane has the same chemical structure as a carbamate ester moiety, a urethane not derived from a carbamic acid is not a carbamate ester. In other words, any synthesis of the R₂NCOR' moiety that does not derive from carbamic acids is not a carbamate ester but instead a urethane. Furthermore, carbamate esters are urethanes but not all urethanes are carbamate esters. This further suggests that polyurethanes are not simply polycarbamate-esters because polyurethanes are not typically synthesized using carbamic acids.
IUPAC states "The esters are often called urethanes or urethans, a usage that is strictly correct only for the ethyl esters." But also states, "An alternative term for the compounds R₂NCOR', esters of carbamic acids, R,NCOH, in strict use limited to the ethyl esters, but widely used in the general sense". IUPAC provides these statements without citation.