CH626728A5 - Automatic blood analyser - Google Patents

Description

The invention relates to an automatic blood analyzer, with additional operations described below, an optical sensor for determining the blood cells of a blood sample, the outputs of the simultaneous correction circuit 8, a calorimetric hemoglobin measuring device jjen to a changeover switch 12 and are controlled by the control switch and by one Hematocrit meter. tiing 10 checked to choose a white blood cell image

A blood analyzer is known in which blood cells in 50 or a red blood cell image are sent to a registration apparatus 16.

add a diluted blood sample through an opening in an opti. The registration apparatus 16 encloses multi-stage regis

pass through sensors in which electrical power pulses are stripped and data interposed. It includes directives

be given an indication of the number of stringers 17, 18, 19 and 20. Each of these registration devices is

Give sample contained cells. The apparatus further comprises - for storing a digital representation of the value -

towards calorimetric hemoglobin measuring devices. An example of a 55 speaking of the white blood cell image value, the red blood cell

Such apparatus can be found in US Pat. No. 3,921,066, which is based on the len image value, the hemoglobin value and the hematocrit for

November 18, 1975 Mr. Henry P. Angel was granted. Another sample is determined.

Furthermore, an apparatus is published which measures the hematocrit of a hematocrit circuit 22 is present with two single blood samples. Hematocrit is the percentage of the volume going, with the output of the amplifier 5 and that of the red blood cells contained in a sample in comparison 60 or 6 in order to determine an analogue size that corresponds to the blood volume of a sample. An example of a circuit for hematocrit for a sample, such as in the above-mentioned use in a hematology meter, is cited in U.S. Patent No. 3,828,260. The output of the hematocrit circuit 3 828 260 shown, which Underwood issued on August 6, 1974 22 is connected to a memory circuit 24. The store was. Circuit 24 preferably includes storage capacities

The invention has for its object a blood analysis 65 storage of the analog values. To create an automatic hemoglobin output analyzer that shows significant improvements is output by a hemoglobin measuring device 23 that points. Calculated and measured parameters as digital blood can be of conventional construction and the one values are to be stored and are supplied by the automatic circuit-changing gear of the memory circuit 24.

626 728

Stored hematocrit and hemoglobin values are fed to the memory circuit 24 in a corresponding manner. This is connected to a first and second potentiometer 25 and 26, respectively. Each of these potentiometers has 28 outputs connected to a changeover switch. The potentiometers 25 and 26 are used to calibrate the hemoglobin and hematocrit levels of the reference standards so that an analog output value corresponding to the predetermined reference value can be achieved. This construction is advantageous because it allows calibration during storage of a certain value in the memory circuit 24. The changeover switch 28 optionally connects the output of the potentiometer 25 or 26 to an analog / digital converter 30. This converter 30 provides an output to a switching body 32, so that the output of the analog / digital converter 30 can either be connected to the hemoglobin registration device 19 or can be connected to the hemato-critical recording device 20. The changeover switches 28 and 32 are controlled by the control circuit 10 in order to selectively supply pulses to the registration device relating to the hemoglobin and hematocrit at different times during the processing of a sample.

A first data bus 36 connects outputs in the correct order from the registration body 16 to a display body 38. The data bus 36 is illustrated as a double line to indicate that digital values are output from the registration apparatus 16 to the display body 38. The display body 38 includes conventional decryption circuitry, display control circuitry, and display body. Other evaluation bodies can be added as needed, such as recorders or other types of data processing circuitry.

A second data bus 40 connects the registration body 16 to a computing device 42, which supplies an output to an evaluation device in the form of a printer circuit 44. The computing device 42 comprises a conventional circuit for coupling the information from the registration apparatus 16 to the printing device 44. Furthermore, the computing device 42 contains means for the further delivery of calculated auxiliary values (blood values), in accordance with the manner described in detail below in FIG. 2. The printing device 44 receives a short report card form and comprises conventional means for translating electrical values of the auxiliary values supplied into printed information. The printing device 44 can be replaced by other evaluation means, e.g. by direct entry into computer memory, or it may contain intermediate data for other data processing means. An example of the printing device is given in this description, since this represents a preferred form of the evaluation devices in hospital laboratories.

The computing device 42 is used to determine optimal computational values, such as the mean corpuscular volume (MCV), which is equal to the quotient of the hematocrit divided by the red blood cell image value, average corpuscular hemoglobin (MCH), which is the quotient of the Value of the hemoglobin result divided by the red blood cell image value and the average corpuscular hemoglobin concentration (MCHC), which corresponds to the quotient of the hemoglobin value from the hematocrit value.

FIG. 2 is a schematic illustration of the circuit for evaluating the values supplied to the registration device 16 in order to determine the calculated values cited above. Conventional data translation circuitry is not shown.

A clock 50 is provided in the computing device 42, which is connected to a decision-making egg and a gate-controlled circuit 52. The decision-making egg and the gate-controlled circuit 52 selectively connect the clock generator 50 at times corresponding to those described below to increase the value in one of the recording devices 17 to 20. A counter is provided,

which serves to reset the recording devices 17, 18, 19 and 20, and leads them back to a setting indicating the reference value. For example, if each of the recorders 17-20 is a three-digit decimal counter, the 5 number one thousand is broadcast by the clock 50. Since the registration devices have only three digits, the values exceeding the one thousand are lost, and at the end of a one thousand value, each registration device retains the value it previously had. The number after an overflow is equal to the number io that was initially set in the registration devices 17, 18, 19 and 20. This operation is also used, as described below, to circulate the values from the registration device 16 to the computer 42.

In order to be able to determine when the evaluation is carried out, a computing control circuit 54 is preset with the operation sequence. At predetermined times, it outputs output digits to a response circuit 56 which has response outputs connected to the decryption circuit 52. The decoder and gated circuit 52 connects the output 20 of the clock 50 to one of the recording devices 17, 18, 19 or 20 for a corresponding period of time in response to the input to the response circuit 56.

A signal which indicates the overflow or the point in time at which a new entry will take place, which indicates the initial value contained in the 25 recording devices 17, 18, 19 and 20, is fed to a gated circuit 58. This operation is used to circulate the values from the registration body 16 to a digital computing device 60. The digital computing device 60 comprises a divisor registration device 62, 30, a comparator 64 and a dividend registration device 66. The comparator 64 supplies separate output values (digital values) in order to the printer circuit 44.

For example, if the preset sequence of the calculator control circuit 54 determines that the average corpuscular volume is to be stored, a value indicating the red blood cell image value is supplied to the divisor registration device 62 and a value indicating the hematocrit is added to the dividend. Registration device 66 supplied. This is accomplished in the following way. A gate 72 is connected to the output of the clock generator 50 and a further output is connected to a gate 74, which in turn supplies a counter input into the divisor registration device 62. The AND gate 72 has a second input from the gate-controlled circuit 58 so that the clock pulses can be fed to the gate 74. The gate 74 has a second input from the arithmetic control unit 54. It is therefore possible for the gate 74 to supply pulses to the divisor registration device 62, while the one thousand value is fed to the red blood cell registration device 18. Accordingly, the 50 time during which the input numbers are fed to the divisor registration device 62 is equal to the time period during which a one thousand value is released and the time after which the registration device 18 showed an overflow (excess). Therefore, the value in divisor registration device 62 will be the same as the red blood cell 55 image value in registration device 18.

Similarly, in order to give a number dependent on the number in an auxiliary value registration device to the dividend registration device 66, a gate 76 is connected between the clock 50 and a counter input of the dividend registration device 66 60. A control circuit 78 can be connected in series between the clock 50 and the gate 76 in order to make a decimal point change to the value to be supplied to the dividend register 66. Gate 76 also has an input from control circuit 54 and gate-65 controlled circuit 58 to effect a similar intermediate period during which values can be fed to dividend register 66. Otherwise an analog circuit can also be used.

626 728

In the preferred mode of operation, the sequence described above is followed and the red blood cell image value is passed on from the registration device 18 to the divisor device 62. Subsequently, at the times determined by the preset sequence in the arithmetic control circuit 54, a value is output by the registration device 20 which is the same as the hematocrit value to the dividing register 66. The divisor registration device 62 supplies an output value (pulse) from the output of the comparator 64 if they are the same and continues to set the dividend register 66 again so that this operation can be repeated. Division is achieved in this way. In order to achieve this operation, the divisor device 62 and the comparator 64 can consist, for example, of an RCA 4585 microcircuit part, which encloses registration and comparator stages. The dividend register 66 selected should have the same number of stages as the divisor and comparator combination. Output pulses (numbers) from comparator 64 are stored in the registration device and printer device 44 for use in a conventional manner. The printer device 44 comprises conventional means for processing values calculated thereon at different times. Similarly, to calculate the average corpuscular hemoglobin, the red blood cell image value is circulated from the logger 18 to the divisor counter 62 and then the hemoglobin value is passed from the logger 20 to the dividend register 66 for a similar operation. Later, in order to produce a calculated value indicating the average corpuscular hemoglobin concentration, the hematocrit value is passed on from the counter 20 to the divisor counter 62 and

4th

the hemoglobin value is then fed from the counter 19 into the dividend recording device 66, so that the number of initial values produced by the comparator 64 indicates the average corpuscular hemoglobin concentration.

5 The white blood cell image value, the red blood cell image value and the hemoglobin and hematocrit values are supplied to the printer device 44 in a conventional manner. In this way, values can be calculated with great reliability and the work processes can be made considerably easier.

10th

The calculated values are created on evaluation bodies for inspection by a technician or for storage. Evaluation means comprise the printer 44 and the display 38. The program buttons 9 comprise a print button and a display button. By depressing the print button of the program buttons 9, the control circuit is activated in order to bring the signals, which indicate the measured and calculated values, onto a print card with the printer 44. However, it is not always necessary to produce the pressure 20 card for reading the measured and calculated auxiliary values. By depressing the display button of the program buttons 9, auxiliary values of the display 38 are optionally created by corresponding elements of the circuit described above, which is controlled by the control circuit 10. In this way, the technician can preview the results achieved and determine whether it is necessary to perform another test on sample 3 before the results are recorded on the print card. The test results of the calibration sample are also available to the technician if the production of a print card is not necessary.

C.

1 sheet of drawings

Claims (5)

626 728 2 PATENT CLAIMS must be made visible before the value impulses on the 1. Blood analyzer can be printed out with an optical probe to the report card. In this way, the blood cells of a blood sample can be determined with a caloric on cards. The report cards for the calibration samples metric hemoglobin measuring device and with a hematocrit should also be omitted. The structure of the machine should be measuring device, characterized in that it simplifies a registration process and with a minimum of circuits for further ready (16) with counters (17-20) for storing and forwarding calculated blood values, such as the average be of pulses representing measured blood values, a series of corpuscular hemoglobin concentration, the mean (42) for determining the blood values, means for average corpuscular hemoglobin and the average pulse transmission from the counters (17-20) corpuscular content in order to enable improved data evaluation (42) and a display acquisition upstream of a printer (44). ready (38). According to the invention, this object is achieved by the 2. Vending machine according to claim 1, characterized in that tomatoes which have the features listed in the characterizing part of the patentable circulation means (50,52,54,56,58,72,74,76,78) for claim 1. Pulse transmission from the counters (17-20) to the computing means in the drawing is an embodiment of the invention. (42) are provided according to a predetermined sequence, 15 of which are shown in the block diagram. Show it: each output pulse of the computing means (42) a blood value Fig. 1 is a block diagram of the machine, and relates. Fig. 2 is a block diagram of a data processing apparatus 3. Machine according to claim 2, characterized in that for determining calculated blood values in the machine of the computing means (42) a digital computing device (60) with a pig. 1. Dividend counter (66) and a divisor counter (62). 20 A blood analyzer can be according to the above 4. Machine according to claim 3, characterized in that US-PS 3 921 066 are constructed and is used to determine the registration apparatus (16) a white blood cell image counter of auxiliary values, the red blood level, the white blood (17) and a red blood cell image counter (18), a hemoglobin and the hemoglobin in the sample. Also has a globin counter (19) and a hematocrit counter (20). a value indicating the hematocrit is also fixed 5. Vending machine according to claim 4, characterized in that 25 represents. The hematocrit circuit may have means in accordance with the circulation means (50-58.72-78) to match the above-cited US Pat. No. 3,828,260. Since a pulse transfer from red blood cell image counter (18) to the divisor description of one of the circuit types that application counter (62) and from the hematocrit counter (20) to the dividend counter can be found in these published patents, 1er (66 ), whereby the digital computing device (60) provides impulses, the system is only briefly described here. matching the average corpuscular volume that the 30 An optical sensor 2 (Fig. 1) is present, the blood cells Circulation means (50-58.72-78) have means for impulsing a sample 3 contained in a sample container 4. Transfer regarding the red blood cell image values to the divi values which indicate the uncorrected blood image are sorzähler (62) and means for pulse transfer, relating to the nem isolation amplifier 5, which has an output for the Value in the hemoglobin counter (19) to the dividend counter (66), the same has 6. The comparator 6 can provide the inputs to the pulses in the digital computing device (60), relating to the 35 amplifier 5 with the individual limit values for the red and average corpuscular hemoglobin, and that the Zirweisse compare blood cell images. Reference voltage values means of calculation (50-58.72-78) have means for the pulse to the comparator 6 are generated in conventional ways Transfer from the hemotocrite counter (20) to the divisor counter (62) (not shown). and for the pulse transfer, regarding the value in the hemoglobin blood cell image values, are compared by the comparator 6 by means of a counter (19), the digital computing device (60) comparing an output selector 7 to a simultaneous correction circuit 8. impuls delivers, regarding the average corpuscular ben, and thus determines the corrected blood cell image values. The Hemoglobin concentration. Selector 7 is connected to a control circuit 10, which reacts to an operating selector switch 9, e.g. in the given US Pat. No. 3,921,066. The control circuit 10 contains 45 furthermore conventional time regulation circuits for synchronization