EP0333912B1 - Method for the evaporation of a sample - Google Patents

Description

The invention relates to a method for vaporizing a sample substance consisting of large molecules, in which the sample substance is exposed to laser beam pulses of high energy, so that the molecules located on the surface of the sample substance are desorbed by the energy of the laser beam pulses.

Such a method is e.g. from Analytical Chemistry, Vol. 50, No. 7, June 19, 1987, pages 985-991, American Chemical Society, Columbus, Ohio, USA; M.A. Posthumus et al .: "Laser Desorption-Mass Spectrometry of Polar Nonvolatile Bio-Organic Molecules" known.

For mass spectroscopic examination it is necessary to convert solid sample substances into a gaseous state. Such a process is associated with considerable difficulties if the sample substance consists of very large molecules which can easily be decomposed by the supply of the energy required for the vaporization. From DE-A-32 24 801 a method for vaporizing a sample substance consisting of large molecules is known, in which the sample substance is exposed to laser beam pulses, the energy and duration of which is dimensioned such that the sample substance evaporates faster than it decomposes. The resulting neutral molecules are added to the jet of a carrier gas, which is cooled adiabatically by expansion. By introducing the neutral molecules into a region of the beam in which it begins to expand and this region is kept at a temperature which is substantially lower than the decomposition temperature of the sample substance, the molecules of the sample substance are effectively cooled, by means of which Decomposition should be largely excluded. The ionization of the sample molecules required for mass spectroscopic analysis takes place within the beam of the carrier gas at a later point in time.

Although the known method can be used successfully with many substances, the mass-spectroscopic examinations of such substances have shown that there are lines in the spectrum which can be regarded as decomposition products of the sample substance. In-depth studies have shown that these decay products arise when the sample substance evaporates and not during later ionization. Although these decay products do not prevent the spectrometric determination of the sample substance, they reduce the yield of undamaged molecules and lead to disruptive lines in the spectrum.

From TRAC (Trends in Analytical Chemistry), Volume 6, No. 4, April 1987, pages 78-81, Elsevier Science Publishers BV, Amsterdam, The Netherlands; R. Isobe et al .: "Direct microanalysis by negative ion fast atom bombardment mass spectrometry "is a method for the mass spectrometric investigation of sample substances which are detached from a matrix by bombardment with fast atoms as molecular ions and subsequently detected.

The present invention has for its object to provide a method for vaporizing large neutral molecules, in which the risk of destruction of the molecules by the energy supplied for vaporizing is greatly reduced, if not completely eliminated.

This object is achieved according to the invention in that the sample substance is mixed with a matrix material which at least one compound, which absorbs light with the wavelength of the laser beam pulse, and which consists of the sample substance and the matrix material existing mixture is exposed to the laser beam pulses, neutral molecules being desorbed and admixed with the beam of a carrier gas, and that at a later point in time the ionization of the sample molecules required for mass spectroscopic analysis takes place within the beam of the carrier gas.

By embedding the sample substance in a slightly disintegrating matrix material, the energy supplied by means of the laser beam pulses is distributed to the sample substance and the matrix material and primarily used to cause the matrix to disintegrate. As a result of this disintegration of the matrix material into gas molecules, an effective destruction of the material takes place in the vicinity of the sample molecules embedded in the matrix substance, with the result that the sample molecules become Loss of connection to the surface and thus also to other molecules and as a result are thrown off the surface of the sample substance. This process could be called a "local explosion". Therefore, when using the method according to the invention, the sensitive molecules of the sample substance are detached from the sample surface without having to absorb a very high energy themselves. At the same time, the disintegration of the matrix material creates a kind of "own jet", which is directed away from the sample surface and whose gas particles effectively cool the desorbed sample molecules before they reach a supersonic jet, for example, in which further cooling takes place in the manner described above.

In a variant of the method according to the invention, a matrix material is used which consists of at least one compound which easily decomposes into gas molecules. It is advantageous for effective protection of the sample substance if a mixture is used in which the number of molecules of the matrix material is greater than the number of molecules of the sample substance. The proportion of the sample substance in the mixture, depending on the type of sample substance on the one hand and the type of compounds used for the matrix on the other hand, can be 10 to 40% by weight.

The above-mentioned condition that the compounds forming the matrix material easily decompose thermally into gaseous molecules is fulfilled by both organic and inorganic compounds. Particularly suitable organic compounds are sugar, in particular pentose or hexose, but also polysaccharides such as cellulose. These compounds decompose thermally to CO₂ and H₂O, so that they do not form residues that could lead to chemical reactions. On inorganic Compounds should be mentioned in particular ammonium nitrate, which disintegrates practically without residue.

In another variant of the method according to the invention, metal dust, preferably gold or silver dust with a grain size of less than 40 μm, is embedded in the matrix material. In this case, matrix materials can also be used which are not thermolytically decomposed due to the absorption of the laser radiation. Although this theory is not fully supported, it can be assumed that plasma waves are generated on the surface of the metal particles, which propagate as shock waves and on the surface of the matrix material cause the matrix to tear and thus release the embedded molecules. The use of a polyethylene as the matrix material has proven to be particularly suitable for this variant of the method according to the invention. The use of polyethylene has the particular advantage that this material is already used as a matrix material in infrared spectroscopy and therefore tried and tested materials and devices for embedding the sample substance in such polyethylene are available.
In particular, pellets can be formed from the matrix material and the sample substance and exposed to the laser beam pulses.

The process according to the invention was used for the vaporization of organic compounds which vary greatly in their chemical composition. So it can easily be used with molecules that have strongly polar groups, as well as with non-polar molecules. Connections are among the first with an acidic and / or basic character, such as peptides, amino acids and dyes, while the latter include aromatic and non-aromatic hydrocarbons. It has been found to be particularly advantageous that the total yield of desorbed sample molecules can be increased by a factor of 4 to 10 compared to evaporation without mixing with a matrix material, depending on the type of sample substance.

In a particularly preferred embodiment of the method according to the invention, pellets made of a spectroscopic polyethylene which is transparent to radiation in the range of 10 »m wavelength with a proportion of about 10⁻¹ to 10⁻² Gew.T. the sample substance and about 10⁻¹ to 10⁻² Gew.T. made of gold or silver dust and exposed to the radiation of a CO₂ laser. In this way, it has not only been possible to considerably increase the sensitivity of the method according to the invention, but also to supply molecules to mass spectroscopy, the examination of which by mass spectroscopy previously seemed impossible, namely nucleotides.

The invention is described and explained in more detail below with the aid of a few examples, the results of which are represented by the diagrams shown in FIGS. 1 to 9 of the drawing.

In the examples illustrated by FIGS. 1 to 4, a sample which was located on a sample holder arranged a few millimeters below a supersonic jet nozzle was used to carry out the method according to the invention irradiated with an IR laser beam pulse, the energy of which was 50 mJ and the duration of which was 20 »s. The supersonic gas jet was switched on in each case after an IR laser beam pulse, so that the gaseous products generated by the laser beam pulse were carried away by the supersonic gas jet and cooled when the gas jet expanded. The gas jet was then passed through means for removing any cations so that only neutral molecules enter a subsequent ionization area in which a UV laser beam cuts the gas jet. Laser beam pulses of 5 ns duration with an energy of 300 »J were generated by the UV laser. The cations generated in this way were fed to a time-of-flight mass spectrometer and detected with a multi-channel plate arrangement. The time-of-flight mass spectrometer used was that of Anal. Instrum., 16, 151 (1986). The typical mass resolution is in the range from 6000 to 10000 according to the FWHM definition.

The sample substances examined with the described device were dipeptides. About 1 mg of the peptide was slurried in 50 »l of water and then 20» l of this slurry was applied to the sample carrier. In most of the spectra obtained, about 10% of the substance applied to the sample carrier was used to generate the spectrum.

Mixtures of dipeptides and matrix materials were prepared in the same way. 1 mg of the peptide was slurried in 50 ml of an aqueous solution of the desired matrix compound, and then 20 ml of the resulting slurry was applied to the sample carrier. In both cases the water is simply removed by air drying. Sucrose and glucose were used as matrix compounds. The water used was triple deionized.

1 shows the mass spectrum of the pure peptide leucine tryptophan obtained in the manner described above. In addition to line 1 for the pure peptide with the mass M resulting from the flight time plotted on the abscissa, the spectrum shows a further line 2 of a substance of the mass M-18. FIG. 2 shows the spectrum of the same peptide leucine-tryptophan, however after embedding the peptide in a glucose matrix in a ratio of 1 mg glucose per 1 mg peptide. Mixing with the glucose results in almost complete suppression of the M-18 line, which is due to the destruction of part of the peptide molecules during evaporation.

Similar to FIGS. 1 and 2, FIGS. 3 and 4 also show the spectrum of a pure peptide or a peptide embedded in a sucrose matrix. This time methionine tyrosine is used as the peptide. This time, the mass / charge ratio M / Z is plotted on the abscissa of the diagrams according to FIGS. 3 and 4, while the coordinate again represents the intensity of the lines. When the substance was ionized, only the A 1 fragment with M / Z = 104 was formed. The designation A fragment is based on the Roepstroff-Fohlman nomenclature [Biodmed. Mass Spectrom. 11,601 (1984)].

Similar to the experiment illustrated by FIGS. 1 and 2, evaporation of the pure peptide also occurs here fragmentation of the peptide leading to the M-18 mass number line. On the other hand, this line disappears completely, as can be seen from FIG. 4, if the peptide is embedded in a sucrose matrix. It is readily understandable that the A 1 fragment which arises only after the evaporation of the peptide molecules during the ionization is retained even in the evaporation of the peptide in a sucrose matrix.

It should also be mentioned that on the samples which led to the spectra treated above, the pyrolysis of the sugar matrix was recognizable as blackening of the sample due to the action of the repeated laser beam pulses. No such darkening occurred in the samples which contained the pure peptides. It is believed that the decomposition of the sugars prevents pyrolytic dehydration of the peptides because the pyrolysis of the sugar leads to an excess of water in the vicinity of the peptide molecules, which drives the dehydration reaction of the peptides in the other direction.

Unless otherwise stated, for the examples illustrated by the diagrams according to FIGS. 5 to 9, pellets were produced from 5 mg of powdered polyethylene, about 0.1 mg of powdered silver or gold and the specified amount of the sample substance. These pellets were exposed to the radiation of a scanning TEA laser with a wavelength of 10.6 »m and a pulse power of 10 mJ. The pulse generated by the laser was bimodal and had a short, sharp peak of 2 »s duration (ie FWHM = 2» s) and a broad trailing edge of 20 »s duration (ie FWHM = 20» s). The intensity of the trailing edge was only about half the intensity of the sharp one Top. The molecules of the sample substance desorbed by the laser beam pulses entered a gas jet generated by a supersonic nozzle, which was at a distance of 1 to 2 mm from the desorption point. The back pressure of the jet was 0.1 to 0.2 MPa (1 to 2 bar). The molecules of the sample substance were distributed over the gas jet after a flight of 80 mm in the direction of the ionization area. The mass spectrometer used was the same as in the previous examples.

5 and 6 illustrate the significant increase in sensitivity that can be obtained by embedding the substance to be examined in a matrix of polyethylene with an admixture of silver. For example, 10 mg of powdered Leu-Tyr-Leu results in a line with an intensity that is only slightly greater than the intensity of the line obtained from only 100 ng of Leu-Tyr-Leu embedded in polyethylene with silver, that is, around 10 ⁻⁵ lesser amount. The reason for this is that the evaporation of the Leu-Tyr-Leu embedded in the polyethylene matrix with the addition of silver powder occurs practically without any destruction of the molecules, while the substance without a protective matrix is bombarded to a high degree by the laser beam gets destroyed.

7 to 9 illustrate the spectra of substances from which no signal could be obtained at all up to now, ie without embedding according to the invention in a matrix material. The spectrum of Fig. 7 shows the line of thymine obtained from only 50 »g of the substance in a matrix of polyethylene with silver. The spectrum according to FIG. 8 was obtained using only 10 »g adenosine in a matrix containing gold dust. Finally, Fig. 9 shows the spectrum of tris-Ru-bipyridyl acetate. The amount used was only 20 »g in a matrix containing gold.

Claims (11)

1. Method for the evaporation of a sample substance comprising large molecules with which the sample substance is subjected to high energy laser beam pulses to desorb molecules located on the surface of the sample substance with the energy of the laser beam pulse,
   characterized in that
   the sample substance is mixed prior to irradiation with a matrix material which easily decomposes under the influence of the laser beam pulse and which contains at least one compound absorbing light at the wavelength of the laser beam pulse and the mixture comprising the sample substance and the matrix material is exposed to the laser beam pulses, whereby neutral molecules are desorbed and mixed with a carrier gas jet and, at a later point in time, an ionization of the sample molecule necessary for mass spectroscopy investigation is carried out within the carrier gas jet.
2. Method according to claim 1, characterized in that a matrix material is utilized which comprises at least one compound which easily decays thermolytically into gas molecules.
3. Method according to claim 1 or 2, characterized in that a mixture is utilized in which the number of matrix material molecules is larger than the number of sample substance molecules.
4. Method according to claim 2, characterized in that the fraction of sample substance in the mixture assumes a value of 10 to 40 % per weight.
5. Method according to one of the preceding claims, characterized in that a sugar, in particular, a pentose or hexose, is utilized as a compound forming the matrix material.
6. Method according to one of the claims 1 through 4, characterized in that a polysaccharide, in particular cellulose, is utilized as a compound forming the matrix material.
7. Method according to one of the claims 1 through 4, characterized in that ammonium nitrate is utilized as a compound forming the matrix material.
8. Method according to one of the preceding claims, characterized in that metallic dust, preferentially gold or silver dust having a grain size of less than 40 »m is embedded in the matrix material.
9. Method according to claim 8, characterized in that polyethylene is utilized as a compound forming the matrix material.
10. Method according to one of the preceding claims, characterized in that pellets are formed from the matrix material, the sample substance and possibly the metal dust and subjected to laser beam pulses.
11. Method according to the claims 8 through 10, characterized in that the pellets are produced from spectroscopic polyethylene transparent to radiation in the wavelength region of 10 »m having a fraction of approximately 10⁻⁴ to 10⁻⁵ by weight of the sample substance and approximately 10⁻⁴ to 10⁻⁵ by weight of gold or silver dust which are subjected to CO₂-laser radiation.

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