Abstract: The invention relates to the preparation of biological cells for the mass spectrometric analysis of cellular properties such as taxonomic classification, antibiotic resistances, response to drugs or other active substances, and others. The cells can be prokaryotic or eukaryotic microorganisms which have particularly been cultivated directly on a mass spectrometric sample support, or eukaryotic cells from tissues or cell cultures. The invention proposes that the cells are not disrupted by adding matrix solution for a subsequent ionization by matrix-assisted laser desorption (MALDI), but that they are disrupted in a separate treatment step using acids and/or solvents on the sample support itself. Surprisingly, the cell proteins released then adhere to the sample support so that they can be carefully washed with buffer solution to remove salts and other soluble impurities which can stem from earlier treatment steps, for example from nutrient solution.

Abstract: The invention relates to the preparation of biological cells for the mass spectrometric analysis of cellular properties such as taxonomic classification, antibiotic resistances, response to drugs or other active substances, and others. The cells can be prokaryotic or eukaryotic microorganisms which have particularly been cultivated directly on a mass spectrometric sample support, or eukaryotic cells from tissues or cell cultures. The invention proposes that the cells are not disrupted by adding matrix solution for a subsequent ionization by matrix-assisted laser desorption (MALDI), but that they are disrupted in a separate treatment step using acids and/or solvents on the sample support itself. Surprisingly, the cell proteins released then adhere to the sample support so that they can be carefully washed with buffer solution to remove salts and other soluble impurities which can stem from earlier treatment steps, for example from nutrient solution.

Abstract: The invention relates to the preparation of biological cells for the mass spectrometric analysis of cellular properties such as taxonomic classification, antibiotic resistances, response to drugs or other active substances, and others. The cells can be prokaryotic or eukaryotic microorganisms which have particularly been cultivated directly on a mass spectrometric sample support, or eukaryotic cells from tissues or cell cultures. The invention proposes that the cells are not disrupted by adding matrix solution for a subsequent ionization by matrix-assisted laser desorption (MALDI), but that they are disrupted in a separate treatment step using acids and/or solvents on the sample support itself. Surprisingly, the cell proteins released then adhere to the sample support so that they can be carefully washed with buffer solution to remove salts and other soluble impurities which can stem from earlier treatment steps, for example from nutrient solution.

Abstract: The invention relates to methods and instruments for determining the resistances of microbes to antibiotics, in particular those microbes which produce beta-lactamases. The method determines the resistance of the microbes in less than an hour by incubating a tiny quantity of the microbes on a mass spectrometric sample support plate after they have been combined with a dosed quantity of a suitable antibiotic, for example the beta-lactam antibiotic imipenem, and by direct mass spectrometric measurement of the breakdown of the antibiotic by the microbial enzymes.

Abstract: The invention relates to methods and instruments for determining the resistances of microbes to antibiotics, in particular those microbes which produce beta-lactamases. The method determines the resistance of the microbes in less than an hour by incubating a tiny quantity of the microbes on a mass spectrometric sample support plate after they have been combined with a dosed quantity of a suitable antibiotic, for example the beta-lactam antibiotic imipenem, and by direct mass spectrometric measurement of the breakdown of the antibiotic by the microbial enzymes.

Abstract: The invention relates to methods and instruments for determining the resistances of microbes to antibiotics, in particular those microbes which produce beta-lactamases. The method determines the resistance of the microbes in less than an hour by incubating a tiny quantity of the microbes on a mass spectrometric sample support plate after they have been combined with a dosed quantity of a suitable antibiotic, for example the beta-lactam antibiotic imipenem, and by direct mass spectrometric measurement of the breakdown of the antibiotic by the microbial enzymes.

Abstract: The invention relates to the preparation of biological cells for the mass spectrometric analysis of cellular properties such as taxonomic classification, antibiotic resistances, response to drugs or other active substances, and others. The cells can be prokaryotic or eukaryotic microorganisms which have particularly been cultivated directly on a mass spectrometric sample support, or eukaryotic cells from tissues or cell cultures. The invention proposes that the cells are not disrupted by adding matrix solution for a subsequent ionization by matrix-assisted laser desorption (MALDI), but that they are disrupted in a separate treatment step using acids and/or solvents on the sample support itself. Surprisingly, the cell proteins released then adhere to the sample support so that they can be carefully washed with buffer solution to remove salts and other soluble impurities which can stem from earlier treatment steps, for example from nutrient solution.

Abstract: The invention relates to methods and instruments for determining the resistances of microbes to antibiotics, in particular those microbes which produce beta-lactamases. The method determines the resistance of the microbes in less than an hour by incubating a tiny quantity of the microbes on a mass spectrometric sample support plate after they have been combined with a dosed quantity of a suitable antibiotic, for example the beta-lactam antibiotic imipenem, and by direct mass spectrometric measurement of the breakdown of the antibiotic by the microbial enzymes.