Laser spray ionization refers to one of several methods for creating ions using a laser interacting with a spray of neutral particles[1][2][3] or ablating material to create a plume of charged particles.[4] The ions thus formed can be separated by m/z with mass spectrometry.
In one version of the laser spray interface, explosive vaporization and mist formation occur when an aqueous solution effusing from the tip of the stainless steel capillary is irradiated from the opposite side of the capillary by a 10.6 μm infrared laser.[1] Weak ion signals could be detected when the plume was sampled through the ion sampling orifice. When a high voltage (3–4 kV) was applied to the stainless-steel capillary, strong ion signals appeared. The ion abundances were found to be orders of magnitude greater than those obtained by conventional electrospray ionization in the case of aqueous solutions. This approach to laser spray ionization is a hybrid of three basic techniques for the generation of gaseous ions from the condensed phase, i.e., energy-sudden activation, nebulization and the action of an electric field.[1]
Laser spray mass spectrometry can faithfully reflect the solution-phase characteristics of biomolecules. It has been successfully applied to evaluate the binding affinities of protein-DNA.
Laser spray has better ionization efficiency than conventional electrospray ionization (ESI).[1] In particular, the sensitivity became more than one order of magnitude higher in negative ion modes. It was also found that this technique has a potential benefit for the low concentration samples due to condensation effect of the formed droplet by the irradiation of laser.
A newer technique called laserspray ionization (LSI) without the space between laser and spray is so named to reflect the similarity with ESI using a matrix assisted laser desorption/ionization (MALDI) method. Laser ablation of a solid matrix/analyte mixture identical to those used in MALDI produces highly charged ESI-like ions. The mechanism is thought to involve laser induced production of highly charge matrix/analyte clusters that upon evaporation of the matrix produces ions by the same mechanism as ESI.[4]