JPS6260024B2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to an electrophoresis data processing device,
More specifically, when performing predetermined arithmetic processing on a signal from a detector of an electrophoresis analyzer to detect a boundary between different types of ion component zones, the conditions of the arithmetic processing are determined according to the signal level from the detector. The present invention relates to an electrophoresis data processing device that can automatically change parameter values.

Since irregular noise components may be mixed in the signal from the detector of the electrophoresis analyzer, the noise components are canceled out by calculating the average value of the signals at predetermined time intervals. The length of this predetermined time is determined depending on the frequency component of the signal,
Simply put, if the signal change is sudden, it can be set short, and if it is gradual, it can be set relatively long. If the predetermined time is set too long when the signal changes suddenly, the signal changes will be averaged out and accurate information cannot be obtained.On the other hand, if the predetermined time is set short when the signal changes gradually, noise components will be generated. There is a disadvantage that the probability of contamination increases. Therefore, it is important to select and average an appropriate time according to signal changes.

However, in conventional electrophoresis data processing devices, the length of the predetermined time in one analysis is fixed, so signal changes due to each component contained in one sample are all sudden or all gradual. In some cases, there is no problem, but in cases where there are both steep and gradual movements, the above-mentioned inconvenience may occur.

On the other hand, in order to detect the boundary between different types of ion component zones in the signal from the detector of the electrophoresis analyzer, a portion where the time-varying signal of the average value has a peak is detected.

This determination of the peak portion is performed on the condition that the time-varying value of the average value exceeds a predetermined threshold value, and that the time-gradient value of the time-varying value exceeds a predetermined threshold gradient value. It is generally preferable that the threshold change value and threshold gradient value be set large if the signal from the detector changes rapidly, and relatively small if the change is gradual.

However, in conventional electrophoresis data processing equipment, the threshold change value and threshold gradient value in one analysis are fixed, so as in the case of the averaging time mentioned above, If the included components include a mixture of components that exhibit sudden signal changes and components that exhibit gradual signal changes, there is a risk that problems may occur.

The present invention has been made in view of the above circumstances, and at least one of the predetermined time, the threshold change value, and the threshold gradient value can be automatically changed to another different value during one analysis. An electrophoresis data processing device configured as described above is provided.

Hereinafter, this invention will be explained in detail based on embodiments shown in the drawings.

1 shown in FIG. 1 is an example of the configuration of an electrophoresis analysis system, in which an isokinetic electrophoresis analysis device 2, a data processing device 3 such as a microcomputer, and a printer/plotter 4 are successively installed. There is.

There are various types of detectors for electrophoresis analyzers, such as potential gradient detectors, heat detectors, and conductivity detectors, and the present invention can be applied to any of them, but for the sake of explanation, we will use the isokinetic electrophoresis analyzer. 2 has a potential gradient detector. Further, suppose that the signal from the potential gradient detector is as shown in FIG. 2A.

The data processing device 3 reads the signal P from the detector every t (for example, 0.1) seconds for a short period of time, and calculates the average value M every time n signals are read, that is, every predetermined time W (=t×n) seconds. Further, a differential value of the average value M, that is, a time change value V is calculated, and the time change value V and the threshold change value D are compared and calculated. Furthermore, the differential value of the time change value V, that is, the time gradient value G is calculated, and the time gradient value G and the threshold gradient value S are compared and calculated. Then, when the time gradient value G exceeds the threshold gradient value S and immediately after that, the time change value V exceeds the threshold change value D, it is determined that there is a boundary between different types of ion component zones. Furthermore, during these calculation processes, the signal P from the detector is compared with predetermined set values P ₁ and P ₂ , and the predetermined time W and threshold change value D are maintained until the signal P reaches the set value P ₁ . and threshold slope value S respectively W ₁ (e.g. 0.2
seconds), D ₁ (eg 150 μv/sec) and S ₁ (eg 150 μv/sec ² ). These are arithmetic processing condition parameter values suitable for cases where the signal P changes rapidly. When the signal P exceeds the set value _P1 , it causes the predetermined time W, the threshold change value D and the threshold slope value S to be changed to _W2 (for example, 2 seconds), respectively.
The settings are automatically changed to D ₂ (for example, 100 μv/sec) and S ₂ (for example, 15 μv/sec ₂ ). These are arithmetic processing condition parameter values suitable for a case where the signal P changes gradually.

When the signal P exceeds the set value _P2 , it automatically returns the W, D, and S to the _W1 , _D1 , and _S1 again. In addition, W ₁ , W ₂ , D ₁ , D ₂ , S ₁ , S ₂ , P ₁ ,
P ₂ is set by roughly predicting the waveform of the signal P.

As shown in FIG. 2, according to this apparatus 1, the boundary between the leading ion (L) and the first ion component (I ₁ ) of the sample, the first ion component (I ₁ )
and the boundary between the second ionic component (I ₂ ), the boundary between the second ionic component (I ₂ ) and the third ionic component (I ₃ ), and the boundary between the third ionic component (I ₃ ) and the terminal ion ( The boundary portion of T) is properly detected. 1st
There is noise (α) in the signal of the ion component _{( I 1} ) of the second ion component (I ₂ ) and _the third The size is such that the time change value and time gradient value are comparable to the boundary part of the ion component (I ₃ ), but in this device 1, the averaging time is W ₂ and is long enough, so it is averaged and removed. There is. but,
Suppose that the calculation processing condition parameters are set using conventional equipment.
If W ₁ , D ₁ , and S ₁ are fixed, the noise (α)
may be mistaken for the boundary between ionic components. Conversely, if the calculation processing condition parameters are fixed to W ₂ , D ₂ , and S ₂ , the boundary between the second ion component (I ₂ ) and the third ion component (I ₃ ) will be overlooked.

After correctly detecting the boundary between different types of ion component zones as described above, the data processing device 3 obtains the potential gradient value and zone length of each ion component zone, analyzes each component, and prints the results.・
Output to plotter 4.

As can be understood from the above description, the electrophoresis data processing device of the present invention calculates the average value of the signal per predetermined time and the time change value of the average value for the signal from the detector of the electrophoresis analyzer. The time gradient value of the time change value is calculated, and the time change value and the time gradient value are compared with the predetermined threshold change value and threshold gradient value, respectively, and different types of ions are calculated based on the results of these calculations. In an apparatus for detecting a boundary between component zones, a comparison means for comparing a signal value from a detector with a preset value, and a threshold change value and a threshold gradient value for the predetermined time based on the output of the comparison means. It is characterized by comprising a condition changing means for automatically changing the setting of at least one of the above to a different value, thereby making it possible to automatically change the arithmetic processing condition according to the signal level from the detector. Therefore, it becomes possible to detect the boundary between zones of different types of ion components more accurately than before, and therefore, correct electrophoretic analysis can be performed.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram of the configuration of an example of an electrophoresis analysis system including an embodiment of the data processing device for electrophoresis of the present invention, and FIG. This is a graph of the signal. 1... Electrophoresis analysis system, 2... Isokinetic electrophoresis analyzer, 3... Data processing device, 4... Printer plotter, _D1 , _D2 ... Threshold change value,
S ₁ , S ₂ ... Threshold gradient value, P ₁ , P ₂ ... Setting value.

Claims (1)

[Claims] 1. Calculate the average value of the signal per predetermined time, the time change value of the average value, and the time gradient value of the time change value for the signal from the detector of the electrophoresis analyzer, and In a device that compares and calculates a time change value and a time gradient value with predetermined threshold change values and threshold gradient values, respectively, and detects a boundary portion between different types of ion component zones based on the results of these calculations, and a comparison means for comparing the signal value of and a preset value, and automatically setting at least one of the predetermined time, the threshold change value, and the threshold slope value to another different value based on the output of the comparison means. 1. A data processing device for electrophoresis, comprising a condition changing means for changing the conditions, thereby making it possible to automatically change the arithmetic processing conditions according to a signal level from a detector.