SU1679361A1 - Aminoacid analyzer - Google Patents

Abstract

The invention relates to analytical instrumentation, in particular, to devices for the automated separation of mixtures of proteins, peptides, amino acids, and can be used in the chemical, biological and other industries. The purpose of the invention is to expand the functionality of the analyzer. The analyzer contains tanks for eluent and ninhydrin, pumps, a chromatographic column connected through a mixer to the reaction chamber, a photoelectric meter and a chart recorder. The analyzer is additionally equipped with a spool type switch connected to the output of the chromatographic column and consisting of a body made in the form of a sleeve and a piston placed inside it with the possibility of rotational and reciprocating motion. The body of the piston and the bushing are provided with channels of equal diameter, with the channels of the body made parallel, arranged perpendicular to the longitudinal axis of the body and equipped with sealing channels, and the channels of the piston made adjacent and angled relative to the longitudinal axis of the body. 4 il. (Ls

Description

The invention relates to analytical instrumentation, in particular, to devices for the automated separation of mixtures of proteins, peptides, amino acids, and can be used in the chemical, biological and other industries.

The purpose of the invention is to expand the functionality of the analyzer.

FIG. 1 shows a block diagram of an amino acid analyzer that provides analysis in a preparative-analytical mode; in fig. 2 - prefix to the amino acid analyzer, longitudinal section; in fig. 3 is a block diagram of an amino acid analyzer that provides analysis in an analytical mode; on

FIG. 4 is a block diagram of an amino acid analyzer providing analysis in preparative mode.

The analyzer contains capacity 1 for ninhydrin and capacity 2-4 for buffer solutions, connected through a control valve 5 to pump 6 for supplying buffer solutions through chromatographic column 7 and a spool type switch 8 to mixer 9, as well as pump 10 for feeding to ninhydrin mixer. The mixer 9 is connected through the reaction chamber 11 with a photoelectric calorimeter 12 connected to the recorder 13. Switch 8 has a piston 14 with inclined channels 15 mounted in sleeve 16 with input 17 and output 18 and 19 channels. Sealing

ON X | O CO O

the switch is provided with sealing valves 20-22 and gaskets 23.

The analyzer allows chromatographic analysis in three different modes: preparative-analytical (separation and simultaneous separation of the components of the analyzed mixture in the biologically active state, analytical (separation of the mixture), preparative (separation of the components of the analyzed mixture in the biologically active state).

Example: Preparative analytical chromatography (Fig. 1 and 2).

The material to be analyzed is fractionated on column 7. The supply of buffer solutions is carried out by pump 6 and is controlled by a control valve 5. The eluate leaving the column enters the spool switch 8, which is in preparative chromatographic mode, which is established (Fig. 2) by aligning the common mouth of the through channels 15 of the piston 14 with the inlet t7 of the sleeve 16. Each of its outlets 18 and 19 communicates with the inclined channels 15 of the piston 14. In this position, the eluate entering through the inlet 17 of the spool is uniformly aspredel is between the outlet 18 and the outlet 19, supplying the selection of the eluate fractions. The eluate, leaving the spool through outlet 18, enters the mixer 9 (Fig. 1) containing the ninhydrin solution, which is supplied by pump 10. This reaction mixture enters the reaction chamber 11, where the ninhydrin color reaction with the components of the mixture to be separated occurs and whose products pass through a photoelectric calorimeter 12, whose readings are recorded by a recorder 13.

Example 2: Analytical Chromatography (FIG. 3).

The amino acid analyzer operates as described in Example 1, however, the spool 8 is in the mode of analytical separation of the mixture. This mode is established (FIG. 2) by successively advancing the piston 14 through the channel of the sleeve 16 from itself and by turning it around its axis 180 ° counterclockwise. With this input

17 bushings through one of the inclined channels of the piston 15 communicate with the outlet 18, diverting the eluate into the mixer 9 with ninhydrin, while the other outlet 19 automatically

is isolated from the input of the sleeve 16.

PRI me R 3. Preparative chromatography (Fig. 4).

The amino acid analyzer operates as described in Example 1. The spool 8 is in the preparative mixture separation mode. This mode of operation is established (FIG. 2) by advancing the piston 14 of the attachment along the bushing channel to itself and by turning it 180 ° clockwise, which

between the entrance 17 of the sleeve and one of the inclined channels of the piston 15 and the output 19, which diverts the eluate to the selection of fractions, leads to communication between them, while the other output of the sleeve 18 is automatically turned off.

The amino acid analyzer allows the separation of mixtures in three modes: preparative-analytical, preparative and analytical, and also

fractions in a biologically active state.

Claims (1)

Amino Acid Analyzer, Including Tanks for Eluent and Ninhydrin pumps, a chromatographic column connected through a mixer to the reaction chamber, a photoelectric meter, a recorder, characterized in that, in order to expand the functionality, the analyzer is additionally equipped with a spool-type switch connected to the output of the chromatographic column and consisting of a sleeve made and a piston placed inside it with the possibility of rotational and reciprocating movement the body of the piston and the wall of the sleeve are provided with through channels of equal diameter a, while the channels of the housing are made parallel, arranged perpendicular to the longitudinal axis of the housing and provided with sealing valves, and the channels of the piston are made adjacent and angled relative to the longitudinal axis of the housing. 21 I 18 22 I FIG. 2 sixteen