EP2417434A1

EP2417434A1 - Method and device for carrying out a quantitative spatially-resolved local and distribution analysis of chemical elements and in situ characterization of the ablated surface regions

Info

Publication number: EP2417434A1
Application number: EP10715085A
Authority: EP
Inventors: Sabine Becker; Dagmar Salber
Original assignee: Forschungszentrum Juelich GmbH
Current assignee: Forschungszentrum Juelich GmbH
Priority date: 2009-04-08
Filing date: 2010-03-17
Publication date: 2012-02-15
Also published as: US20130234015A1; DE102009016512B4; US20120074307A1; US8735813B2; US8497470B2; JP2012523548A; WO2010115394A1; DE102009016512A1

Abstract

A laser ablation chamber, suitable for use in a conventional laser microdissection unit (LMD), enables in combination with the LMD both a quantitative spatially-resolved nano-local and distribution analysis of element concentrations in a sample and a microscopic recording of the surface topography of said sample in the nanometer range. This can optionally be followed by further examinations without for this purpose the sample needing to be removed from a slide comprising the sample. For the examination, a region of the sample to be analyzed is selected with the aid of a microscope of an LMD. In the process, the sample is situated on the underside of a cover glass (slide), which at the same time is part of a laser ablation chamber that is mounted underneath the slide and within the LMD. Part of the sample is ablated and analyzed. Optionally, it is possible to cut out in a targeted fashion certain regions of the tissue in which metals were detected by means of the available LMD instruments for the purpose of further analysis and to collect these regions in sample containers that are attached under the slide after the laser ablation.

Description

Method and apparatus for performing a quantitative spatially resolved local and distributional analysis of chemical elements and in-situ characterization of the ablated surface regions

On the one hand, the invention relates to a method for local analysis and distribution analysis ("imaging" or "mapping") for the quantitative determination of element concentrations in substrates, in particular in thin tissue sections, on individual cells or cell organelles, and in situ characterization of sample surfaces (topography) and after chemical analysis with lateral resolution in the micrometer to nanometer range. Furthermore, the invention relates to a device suitable for carrying out the aforementioned method.

State of the art

As an analytical method for the quantitative determination of lateral element distributions with spatial resolution in the micron range and for the determination of trace elements down to the ng / g and sub-ng / g concentration range in the element mass spectrometry for direct ablation of the sample material to be examined various methods, eg , B. using focused laser beams applied. For example, the method of laser ablation - inductively coupled plasma mass spectrometry (laser ablation inductively coupled plasma mass spectrometry - LA-ICP-MS) is known, which is used for trace, isotope but also surface and micro focal analysis on solid sample materials. However, this method is disadvantageously unable to determine element distributions and concentrations in thin tissue sections (mapping or imaging analysis) with a high lateral resolving power, and in particular in the lower micro- and nanoscale scale below 5 μm, as for example in the analysis of individual cells or cell organelles is required.

Increasingly, lasers, such as the Nd-YAG laser, with a wavelength in the UV range (λ-266 nm or 213 nm) are used in the analysis. These lasers are often used for sample entry in combination with high-detection ICP mass spectrometers. At present, Nd-Y AG laser systems with a laser spot diameter from several μm to several hundred μm for microlocal analysis (e.g., LSX 213, 500 CETAC Technologies, Ohama, USA or UP 213, 266 New WAVE Research, Fremont, USA). It is considered to be disadvantageous that with such commercial laser ablation systems, biological matrices can not be ablated directly at high efficiency with a lateral resolving power in the lower μm range, as a rule. The limiting factor is the diffraction limit, which a laser can not fall below regularly. This means that the possible minimum resolution limit is in the range of one wavelength of the laser. Spatially resolved analyzes below 1 μm are therefore regularly not possible at all.

For many medical-molecular-biological questions, z. For example, for the distributional analysis of metals in biological samples (as in brain slices), however, a lateral resolution of the analytical method to be used in the lower micrometer or from a few hundred nm to the lower nm range is required. Such a spatial resolution could lead to a direct Nanolokalanalytik on individual Zellorganellen would be feasible. In addition, many questions require quantitative information about the metal distribution of diseased versus healthy tissue sections.

Focused IR and UV laser beams are used in commercial instruments (by known laser-assisted microdissection - LMD) to excise a precisely defined area from a tissue. The laser microdissection (LMD), which allows targeted molecular genetic studies on minimal amounts of a specific tissue, also allows the isolated study in selected regions of living single cells. Such high-performance LMD systems with a spatial resolution in the lower micrometre and sometimes in the submicrometer range are nowadays used for isolation and analysis of individual cells or cell areas, for example in the biopsy of individual cancer cells compared to surrounding healthy control cells, small pieces of tissue or DNA strands Routine and research tasks in medicine (pathology), but also in molecular and cell biology, used. Existing commercial systems have excellent possibilities of microscopic observation of the sample surfaces and very precise cutting of tissue pieces by a highly focused laser beam. This achieves a high spatial resolution down to the sub-micron range (up to 0.5 μm) using special laser optics. It is in contrast to the Laser ablation systems - here the ablation of the sample material is controlled by a defined movement of the sample table - the laser beam is moved over the sample surface with the aid of sophisticated optics with a precision of approx. 0.07 μm. The excised tissue samples are then usually after a tryptic digest (cell lysis) fed to another biomolecular mass spectrometric off-line analysis. However, a quantitative elemental analysis with LMD on-line is usually not possible. Such an LMD system has a number of outstanding advantages over commercially available laser ablation systems, for example an improved spatial resolution of about one order of magnitude, a significantly improved microscopic resolution or also in connection with special staining techniques (immunostaining) and the application of highly specific software packages the recognition of special cells ( eg of cancer cells in stained tissue sections).

Task and solution

The object of the invention is to provide a simple method, which on the one hand a qualitative local and distribution analysis in the nanometer range and at the same time the quantitative determination of element concentrations in different

On the other hand, it is also able to display and characterize in a simple manner in a timely manner the examined sample surface before and after the analysis.

Another object of the invention is to provide a device suitable for carrying out the method.

The objects of the invention are achieved by a method with the totality of features according to the main claim and by a device with the totality of features according to the independent claim. Advantageous embodiments of the method and the device can be found in the respective back claims.

Subject of the invention

The invention provides a simple method, which qualitative local and Provide distributional analysis and quantification of elemental concentrations in various nanoscale sample materials, as well as the ability to observe the topographic sample surface to be examined before and after analysis.

It is known that laser microdissection (LMD) devices already have a very sophisticated and high resolution optics in combination with the possibility of cutting out previously observed and defined parts of a sample by means of a focused laser beam which is guided across the sample surface in a defined manner. In the context of this invention, it has now been found that the object tables previously used in conventional laser microdissection devices with recessed slides can be advantageously modified such that a laser ablation can now be carried out directly on site together with a quantitative determination of the element distributions in the selected sample area.

The invention thus combines the advantages of LMD in accurately cutting out thin tissue sections of biological samples by a defined laser ablation of the examined region of analysis in the known line-scan mode combined with a high-resolution microscopic observation of the sample surface with the advantages of the quantitative element mass spectrometric technique, laser ablation -ICP-MS. The invention advantageously makes possible a practical quantification technique for determining the chemical composition of the samples analyzed with respect to metal and non-metal contents, as used, for example, in brain research in the study of neurodegenerative diseases, the growth of carcinogenic tissue, aging processes or questions of metal distribution in individual cases living cells and cell organelles in any biological sample materials is required.

In the method according to the invention, the sample to be examined located in a laser ablation chamber is examined microscopically in a first step, and an area for ablation and thus for mass spectrometric analysis of the trace elements is selected. For this purpose, advantageously, the high-resolution optics of a laser-assisted microdissection device (LMD) can be used. The second step is followed by the laser-induced ablation of the selected region and the distributional analysis of the chemical elements by means of the same already in a LMD laser. Optionally, this can be done together with at least one selected standard, but preferably with several standard samples, with defined element concentrations for the quantification of the chemical elements. Depending on the result, in a third step, a corresponding analogous region can be excised from the sample for further examinations, preferably by laser microdissection (LMD), and after tryptic digestion of the excised tissue by biomolecular mass spectrometry with respect to the structure elucidation of the metal-binding proteins or phosphoproteins to be analyzed.

The advantage of the method according to the invention lies, inter alia, in the fact that the three aforementioned steps can be carried out with the aid of a commercial device in which only a new object table having a laser ablation chamber has to be constructed, and the sample and, if appropriate, suitable standards for quantification are constantly carried out on one Slides can remain.

This procedure is made possible by a special laser ablation chamber, in which the coverslip, which is permeable to laser light, is formed by a slide which can be used simultaneously for laser microdissection. This replaceable slide can be used to fix both the sample and the standard samples required for analysis (brain research uses mostly matrix-matched synthetic laboratory standards). The slide with the sample and the standard samples is inserted into the laser microdissection device for examination in such a way that sample and standard samples are located on the underside of the slide. Previously, the slide is closed with a container forming the lower part of a laser ablation chamber to an ablation chamber, so that sample and standard are located inside the chamber. The ablation chamber thus formed also has a supply line and a discharge line for a transport gas of the ablated material (eg Ar), the discharge line being connected directly to an analytical device, in particular to an inductively coupled plasma mass spectrometer ICP-MS can be. Advantageously, the dimensions of the laser ablation chamber are selected such that the entire chamber can be inserted as an object table into an existing laser microdissection device instead of a normal microscope slide or a slide placed in a cover glass holder. The sample to be examined can first be examined with the aid of the existing high-resolution optics of the microscope of the LMD apparatus (approximately at a magnification of 150 times). For ablation, the laser, which is likewise present, with a corresponding power density (with a spot diameter below 20 μm) is focused on the sample, so that the biological material is completely blanketed.

Together with the ablation of the sample material, the standard samples on the slide are also screened under the same conditions. The thus ablated material of sample and standards is advantageously transported with a carrier gas, such as an argon stream, in the inductively coupled plasma of a highly sensitive and selective ICP mass spectrometer and ionized. Subsequently, the ions in the separation system of the mass spectrometer are separated and detected in a known manner. There is a determination of the elemental composition down to the ultratrace region and a distributional analysis of the examined sample material. As an alternative analyzer, for example, the ICP-OES comes into consideration.

After the results of the distributional analysis of metals and non-metals in the investigated sample are available, it is then possible with the method according to the invention to determine certain analogous regions of the tissue in which metals or phosphorus have been detected (eg plaques) for another Analysis of the metalloproteins and / or phosphoproteins. For this purpose, the selected areas are ablated (cut out) by means of a focused laser beam and collected in suitable sample containers, which are mounted under the microscope slide after the laser ablation examination.

The laser ablation chamber according to the invention which is suitable for carrying out the method has a modular construction. The laser ablation chamber consists of the coverslip, the cover glass holder, and the actual flat laser ablation chamber, preferably Teflon, to avoid contamination during LA-ICP-MS analysis. The cover glass holder and the remaining laser ablation chamber are gas-tightly connected to one another via an agent. Such suitable means may be, for example, clamps or screw connections, where appropriate an additional seal between the wall of the laser Ablationskammer and the cover glass is arranged. In particular, the coverslip may be a typical conventional slide that is transparent to the wavelength of the laser light of the LMD device and that can be fixed to the underside of the sample and any standard reference samples for examination.

For assembling the laser ablation chamber, for example, first the cover glass (slide) with the sample to be examined and the standard samples on its underside can be installed in the cover glass holder on a special microscope stage, and these are then connected in a gas-tight manner to the container, so that neither air enters the Chamber still the transport gas Ar from the chamber can flow into the environment. The ablated material is transported specifically with the transport gas Ar into the inductively coupled plasma of an ICP-MS.

Alternatively, however, the slide with the sample and a standard sample on the underside may also initially be arranged on the container via gaskets and connected in a gas-tight manner with the aid of the cover glass holder arranged thereon. Subsequently, the entire laser ablation chamber is introduced into the laser microdissection device. The LA-ICP-MS chamber, which was specially developed for the slide, is pushed horizontally from the front into the LMD apparatus via an existing displacement unit prior to element mass spectrometric analysis.

The entire laser ablation chamber can thus be connected to a laser microdissection device and advantageously positioned under the lenses using the existing positioning devices for the object table of the LMD.

The ablation chamber according to the invention, which is suitable for use in a conventional laser-assisted microdissection apparatus (LMD), can thus easily be used to combine a microscopic examination with an online LA-ICP-MS examination, and optionally also further examinations, without the sample must be removed from a sample slide or that the slide must be placed in different examination devices. Special description part

The subject matter of the invention will be explained in more detail below with reference to two figures, without the subject of the invention thereby being restricted.

1 shows a detailed arrangement of the laser ablation chamber 10 according to the invention, which can be used in a conventional laser microdissection device (LMD) via a specially adapted holder together with a slide, with a) view of the chamber from above and b) view of the chamber of the side.

Here, in FIGS. 1 and 2:

1 cover slip, z. B. a conventional slide

2 coverslip holder

3 containers (lower part of the laser ablation chamber)

4 sample

5 standard samples for the quantification of the analysis results

6 means for gas-tight connection of container and slide, or cover glass holder

7 seal

The ablation chamber according to the invention is for the direct analysis of small areas of biological samples, such. B. tissue sections or individual cells, by means of LA-ICP-MS suitable.

Advantageously, the already mounted laser ablation chamber with the slide (carrying the sample and the standard reference materials on the underside) is retracted from the front instead of a standard slide frame into an existing LMD apparatus. The slide can also be fixed on a specially designed table of the LMD, the holder of the slide can already be part of the table. The table here has only one recess for the slide, which is gas-tight from below with the container as the lower part of the laser ablation chamber via a seal (eg., By glands or clamps) is connected. The sample and the standard samples are always located on the bottom of the slide, d. H. inside the laser ablation chamber.

The simplest and most practicable variant is the laser ablation chamber outside the LMD assemble and insert for analysis (microscopy and elemental analysis) from the front into the LMD apparatus so that the analysis area to be examined is brought into the focus of the laser beam. To introduce the laser ablation chamber already exists a precise displacement unit in the LMD. Using this arrangement, in the first step, the sample surface is observed in reflected-light microscope mode and the analysis region is selected. In the second step, this area is advantageously ablated in a defined manner with the same arrangement and analyzed by mass spectrometry with respect to the metal and nonmetal distribution. A shift or readjustment of the sample by a transfer into an external laser ablation chamber is thus not necessary.

In a further variant, a sample is then completely ablated, or cut out for further investigations. For this purpose, the slide with the sample and optionally standard samples is removed from the laser ablation chamber according to the invention and inserted into the conventional original sample table of the LMD with the sample containers underneath and inserted into the LMD. In a known manner, it is now possible to selectively cut out certain regions of the sample by means of the focused laser beam in the LMD and to collect them in the sample containers located underneath. Mass spectrometric methods can be used to determine the structures and sequences of the proteins in the sample and to validate the analysis results of the LA-ICP-MS with ICP-MS after digestion of an analogous sample area. The latter technique allows statements about the average contents, e.g. As the metal concentrations and phosphorus contents in the examined sample or standard material.

In principle, two different process sequences are conceivable, which are briefly summarized below:

1 a) If necessary, the sample is located on a slide in the LDM with standard samples. The selection of the area to be examined takes place. b) The slide remains in the LMD and is assembled with a container (lower part of the laser ablation chamber) to the laser ablation chamber. The assembly is difficult due to the limited space below the sample table, but in principle feasible. The laser ablation chamber is sealed gas-tight. The LA-ICP-MS examination of selected areas is carried out according to a known analysis protocol. c) The slide is removed from the laser ablation chamber and individually reinserted into the LDM installed together with the collection containers for the tissue samples to be excised.

2 a) The slide is assembled together with the sample and optionally standard samples with a container (lower part of the laser ablation chamber) to the laser ablation chamber and inserted into the LMD. First the range selection takes place and then the LA-ICP-MS examination. b) The slide is removed from the laser ablation chamber and reinserted individually into the LDM along with the collection containers for the excised samples.

In the second proposed and preferred procedure, the laser ablation chamber is assembled with the slide completely outside the LMD and sealed gas-tight, and then inserted, for example, from the front into the LMD and fixed. The slide is also coverslip of the laser ablation chamber in the variants. The selected area of the tissue sample to be analyzed is sampled along with the standard samples under the same laser ablation experimental conditions using a LMD laser in the proven line-scan mode (line by line). The bombardment of the sample surface takes place with photons of a focused laser beam, in particular of a powerful Nd: YAG laser, wherein a spatial resolution (laser spot diameter) on the surface of the sample should amount to a few μm. Suitable devices realize spot diameters of significantly less than 20 μm.

The arrangement according to the invention of the laser ablation chamber, in which the lid simultaneously serves as a slide with the sample fixed underneath, is advantageously possible with an objective of the LMD almost as far as the slide and thus almost to the sample. As a result, resolutions down to the sub-micron range are possible. The ablation of sample material is thus advantageously possible with a spot diameter of less than 1 .mu.m, in particular less than 0.5 .mu.m.

With the existing LMD instrumentation not only the sample surface before and after the laser ablation can be examined microscopically, but in a further step specific areas of the tissue in which metals and phosphorus were detected can be cut out for further analysis of the metalloproteins Collect sample containers that are mounted under the slide after laser ablation. To the original arrangement of the LMD sample table with sample containers underneath must be restored.

FIG. 2 illustrates the advantageous combination of the laser ablation chamber (10) according to the invention with an existing laser microdissection device. The entire laser ablation chamber according to the invention with container and slide can be simply inserted into the LMD device instead of the usual cover glass holder.

Unlike conventional laser ablation chambers, in which the laser beam is more or less fixed, and only the sample is brought to the desired position via an adjustment, in a laser dissection usually the sample with the aid of the adjustable microscope stage in the correct position for observation brought, and then the laser beam passed through mirrors to the appropriate position. The area to be analyzed is outlined on the screen with a special pen and, after entering the experimental parameters (laser beam diameter in focus, speed of the laser beam, distance between the lines) in line scan mode.

Claims

Patent claims

A laser ablation chamber comprising a container having a supply and Abführunsgleitung for a transport gas, a cover glass holder with a cover glass which is permeable to laser light, which is simultaneously suitable for receiving the sample, and a means for gas-tight connection of cover glass holder and container.

The laser ablation chamber of claim 1, including at least one additional seal disposed between the coverslip holder and the container.

3. laser ablation chamber according to claim 1 or 2, with brackets or fittings as a means for gas-tight connection of cover glass holder and container.

4. laser ablation chamber according to claim 1 to 3, with a cover glass holder made of Teflon.

5. laser ablation chamber according to claim 1 to 4, with a slide as a cover glass.

A laser ablation chamber according to claims 1 to 5, which is suitable for use in a conventional laser assisted microdissection (LMD) apparatus.

7. A method for the quantitative, spatially resolved local and distributional analysis of chemical elements and in-situ characterization of the ablated surface region, using laser ablation - inductively coupled plasma mass spectrometry (LA-ICP-MS) and laser-assisted microdissection (LMD), characterized

- that the sample is fixed to the underside of a cover glass,

that the cover glass is assembled together with a cover glass holder on a container to a laser ablation chamber according to one of claims 1 to 6,

- That the laser ablation chamber is inserted together with the sample in the laser microdissection device and

- That the laser of the LMD is focused through the coverslip on the sample and selected areas or the entire sample to be defined defined.

8. The method of claim 7, wherein in addition to the sample and at least one standard sample (advantageously a plurality of standard reference materials for quantification) is fixed to the underside of the cover glass.

9. The method according to any one of claims 7 to 8, wherein a conventional slide is used as a cover glass.

10. The method according to any one of claims 6 to 9, wherein after the introduction of the laser ablation chamber containing the sample in the LMD first the selection of the area to be examined is carried out, and then an LA-ICP-MS examination of the selected area.

11. The method of claim 10, wherein after the LA-ICP-MS examination, the slide with the sample is removed from the laser ablation chamber and reinserted into the LMD along with a receptacle for excised samples.

12. The method according to any one of claims 7 to 11, wherein for the laser ablation of the present in the LMD laser is used.

13. The method of claim 12, wherein a laser having a wavelength of 355 nm is used.

14. The method according to any one of claims 7 to 13, wherein the sample material with a spot diameter of less than 1 .mu.m, in particular of less than 0.5 microns is lurking.