The bisulfite ion (IUPAC-recommended nomenclature: hydrogensulfite) is the ion . Salts containing the ion are also known as "sulfite lyes". Sodium bisulfite is used interchangeably with sodium metabisulfite (Na2S2O5). Sodium metabisulfite dissolves in water to give a solution of Na+.
Na2S2O5 + H2O → 2Na[HSO<sub>3</sub>]
The bisulfite anion exists in solution as a mixture of two tautomers. One tautomer has the proton attached to one of the three oxygen centers. In the second tautomer the proton resides on sulfur. The S-protonated tautomer has C3v symmetry. The O-protonated tautomer has only Cs symmetry.
There exist two tautomers of bisulfite. They interconvert readily but can be characterized individually by various spectroscopic methods. They have been observed by 17O NMR spectroscopy:[1]
HSO3− SO2(OH)−K = 4.9
Solutions of bisulfite are typically prepared by treatment of sulfur dioxide with aqueous base:
SO2 + OH− →
is the conjugate base of sulfurous acid, (H2SO3).
is a weak acidic species with a pKa of 6.97. Its conjugate base is sulfite, :
⇌ + H+
Attempted isolation of the common salts of bisulfite results in dehydration of the anion with formation of metabisulfite, also known as disulfite:
2 ⇌ + H2OBecause of this equilibrium, anhydrous sodium and potassium salts of bisulfite cannot be obtained. However, there are some reports of anhydrous bisulfites with large counter ions.[2]
Bisulfite is a good reducing agent, especially for oxygen scrubbing:
2 + O2 → 2 + 2 H+Its reducing properties are exploited to precipitate gold from auric acid (gold dissolved in aqua regia) and reduce chromium(VI) to chromium(III). In water chlorination, sodium bisulfite is used to reduce the residual 'chlorine' which can have a negative impact on aquatic life.
Another use of bisulfite in organic chemistry is as a mild reducing agent, for example to remove traces or excess amounts of chlorine, bromine, iodine, hypochlorite salts, osmate esters, chromium trioxide and potassium permanganate. Sodium bisulfite is a decoloration agent in purification procedures because it reduces strongly coloured oxidizing agents, conjugated alkenes and carbonyl compounds.
Bisulfite is also the key ingredient in the Bucherer reaction. In this reaction an aromatic hydroxyl group is converted to the corresponding amine group. This is a reversible reaction. The first step in this reaction is an addition reaction of sodium bisulfite to an aromatic double bond. The Bucherer carbazole synthesis is a related organic reaction that uses sodium bisulfite as a reagent.
Sodium bisulfite is used in the analysis of the methylation status of cytosines in DNA.
In this technique, sodium bisulfite deaminates cytosine into uracil, but does not affect 5-methylcytosine, a methylated form of cytosine with a methyl group attached to carbon 5.
When the bisulfite-treated DNA is amplified via polymerase chain reaction, the uracil is amplified as thymine and the methylated cytosines are amplified as cytosine. DNA sequencing techniques are then used to read the sequence of the bisulfite-treated DNA. Those cytosines that are read as cytosines after sequencing represent methylated cytosines, while those that are read as thymines represent unmethylated cytosines in the genomic DNA.[4]