Abstract: A mass spectrometry device includes a sample seating part including an ultrasonic vibrator having a through hole through which liquid particles formed by the ultrasonic vibrator from an adsorbent material including a sample and a solvent are discharged, the adsorbent material being seated on the ultrasonic vibrator; a reaction part in which plasma or an ionization medium generated by plasma come into contact with the liquid particles discharged from the through hole to form an ionized material; an introduction part discharging and introducing the ionized material to a detection part; and the detection part analyzing the ionized material discharged from the introduction part. The mass spectrometry device and the mass spectrometry method can detect the components of various samples by converting a sample into liquid particles using ultrasonic waves and applying plasma and can detect samples in various fields without regard to locations.

Abstract: Provided is a methionyl tRNA synthase (MRS) for the biosynthesis of a photomethionine-labeled protein and a method for preparing a photoactivatable protein G variant using same and, more particularly, to an MRS variant in which alanine at the position of 12th is substituted with glycine, leucine at the position of 13th by serine, tyrosine at the position of 260th by phenylalanine, isoleucine at the position of 297th by valine, and histidine at the position of 301st by leucine from the N-terminal of the amino acid sequence of a wild-type Escherichia coli methionyl tRNA synthase. The MRS variant effectively confirms the biosynthesis of a photomethionine (pM)-labeled target protein and thus can be utilized for the biosynthesis of a pM-labeled target protein.

Abstract: Provided is a methionyl tRNA synthase (MRS) for the biosynthesis of a photomethionine-labeled protein and a method for preparing a photoactivatable protein G variant using same and, more particularly, to an MRS variant in which alanine at the position of 12th is substituted with glycine, leucine at the position of 13th by serine, tyrosine at the position of 260th by phenylalanine, isoleucine at the position of 297th by valine, and histidine at the position of 301st by leucine from the N-terminal of the amino acid sequence of a wild-type Escherichia coli methionyl tRNA synthase. The MRS variant effectively confirms the biosynthesis of a photomethionine (pM)-labeled target protein and thus can be utilized for the biosynthesis of a pM-labeled target protein.

Abstract: The present invention aims to provide a time-of-flight based mass microscope system for an ultra-high speed multi-mode mass analysis, for using a laser beam or an ion beam simultaneously to enable both a low molecular weight analysis such as for drugs/metabolome/lipids/peptides and a high molecular weight analysis such as for genes/proteins, without being limited by the molecular weight of the object being analyzed, and for significantly increasing the measuring speed by using a microscope method instead of a microprobe method.

Abstract: The present invention aims to provide a time-of-flight based mass microscope system for an ultra-high speed multi-mode mass analysis, for using a laser beam or an ion beam simultaneously to enable both a low molecular weight analysis such as for drugs/metabolome/lipids/peptides and a high molecular weight analysis such as for genes/proteins, without being limited by the molecular weight of the object being analyzed, and for significantly increasing the measuring speed by using a microscope method instead of a microprobe method.

Abstract: The present invention relates to a method for quantifying protein tyrosine phosphatase (referred as PTP hereinafter) in biosamples, precisely a diagnostic method for disease by quantifying PTP using mass spectrometry and profiling of comparative PTP levels. By quantifying PTP in biosamples and profiling thereof according to the method of the present invention, disease can be diagnosed and diverse disease conditions and health conditions can be confirmed via profiling.

Abstract: The present invention relates to a method for quantifying protein tyrosine phosphatase (referred as PTP hereinafter) in biosamples, precisely a diagnostic method for disease by quantifying PTP using mass spectrometry and profiling of comparative PTP levels. By quantifying PTP in biosamples and profiling thereof according to the method of the present invention, disease can be diagnosed and diverse disease conditions and health conditions can be confirmed via profiling.