CN114324941A - Gynecological secretion detection device and sample reaction mechanism and method thereof - Google Patents

Abstract

The invention discloses a gynecological secretion detection device and a sample reaction mechanism and method thereof, wherein the sample reaction mechanism comprises a turbidity detection unit for accommodating a sample to be detected and carrying out turbidity detection on the sample to be detected; the dilution unit comprises a dilution pipeline and a dilution driving piece, and the dilution pipeline is respectively connected with the turbidity detection unit and the dilution driving piece so as to fill diluent into the turbidity detection unit under the driving action of the dilution driving piece; and the reagent unit comprises a reagent pipeline and a reagent driving part, and the reagent pipeline is respectively connected with the turbidity detection unit and the reagent driving part so as to fill reaction reagents into the turbidity detection unit under the driving action of the reagent driving part. Because adopt turbidity detecting element to carry out turbidity detection to the sample to realize automated inspection and dilution, turbidity detecting element compares the manual work and has more accurate turbidity judgement ability, and the control that can be more accurate dilutes the volume, and then has higher external detection precision.

Description

Gynecological secretion detection device and sample reaction mechanism and method thereof

Technical Field

The invention relates to the technical field of in-vitro detection, in particular to a gynecological secretion detection device and a sample reaction mechanism and method thereof.

Background

The detection of gynecological secretion can help women to know own physical conditions, and can play a role in diagnosing and preventing diseases. At present, the detection of gynecological secretion realizes automatic detection, wherein the gynecological secretion sample is mainly subjected to sample preparation, dry chemical detection and morphological detection.

Wherein the turbidity detects to the sample need be carried out to the morphology testing in-process to avoid the turbidity too high, in the in-process sample lamination of microscopic examination together, influence the statistics of shooing. The existing turbidity detection adopts manual experience judgment to dilute a sample with high turbidity, but the manual judgment is easy to generate deviation, thereby influencing the detection precision.

Disclosure of Invention

The invention provides a gynecological secretion detection device capable of improving detection precision, and a sample reaction mechanism and method thereof.

In one embodiment, a sample reaction mechanism for gynecological secretion detection is provided, which includes the following steps:

the turbidity detection unit is used for accommodating a sample to be detected and carrying out turbidity detection on the sample to be detected;

the dilution unit comprises a dilution pipeline and a dilution driving piece, and the dilution pipeline is respectively connected with the turbidity detection unit and the dilution driving piece so as to fill diluent into the turbidity detection unit under the driving action of the dilution driving piece;

and the reagent unit comprises a reagent pipeline and a reagent driving part, wherein the reagent pipeline is respectively connected with the turbidity detection unit and the reagent driving part so as to fill reaction reagents into the turbidity detection unit under the driving action of the reagent driving part.

Further, the turbidity detecting unit comprises a transmitter, a receiver and a processor, the dilution pipeline comprises a dilution pipe and a dilution needle, the dilution needle is connected with the dilution pipe, and the dilution needle is used for injecting a dilution liquid into a sample in the turbidity detecting unit.

Further, the dilution unit still includes dilution valve and diluent container, dilute the pipe with the diluent container is connected, dilute the valve and install dilute on the pipe, dilute the driving piece with the dilution valve is connected, dilute the valve and be used for switching dilute the driving piece respectively with the diluent container with the dilution needle communicates.

Further, the reagent pipeline comprises a reagent tube and a reagent needle, the reagent needle is connected with the reagent tube, and the reagent needle is used for filling a reagent into the sample after the turbidity detection is finished.

Further, the reagent unit also comprises a reagent valve and a reagent liquid container, the reagent tube is connected with the reagent liquid container, the reagent valve is installed on the reagent tube, the reagent driving member is connected with the reagent valve, and the reagent valve is used for switching the communication between the reagent driving member and the reagent liquid container and the reagent needle respectively.

Furthermore, the sample reaction mechanism further comprises a cleaning unit, wherein the cleaning unit comprises a cleaning pipeline and a cleaning driving piece, and the cleaning pipeline is respectively connected with the turbidity detection unit and the cleaning driving piece so as to fill the cleaning liquid into the turbidity detection unit under the driving action of the cleaning driving piece.

Further, sample reaction mechanism still includes the waste liquid collection unit, the waste liquid collection unit includes waste liquid pipeline and waste liquid driving piece, the waste liquid pipeline respectively with turbidity detecting element reaches the waste liquid driving piece is connected, with collect under the drive effect of waste liquid driving piece washing waste liquid in the turbidity detecting element.

Further, the turbidity detecting unit comprises a reaction container, an emitter and a receiver, the dilution pipeline and the reagent pipeline are connected with the reaction container, and the emitter is used for irradiating detection light to a sample; the receiver is configured to receive the detected light passing through the sample and generate a detection signal.

The embodiment of the utility model provides a gynecological secretion detection device, including detection mechanism, sampling mechanism and control mechanism, still include foretell gynecological secretion detection's sample reaction mechanism, detection mechanism is used for detecting the sample of accomplishing reagent filling, control mechanism with detection mechanism sampling mechanism with sample reaction mechanism connects, is used for control detection mechanism sampling mechanism with sample reaction mechanism.

In one embodiment, a gynecological secretion detection method is provided, and the gynecological secretion detection device performs the following steps:

a turbidity detection unit detects whether a sample to be detected needs to be diluted or not;

if yes, the diluting unit and the reagent unit respectively and sequentially fill the diluting liquid and the reagent into the sample after the turbidity detection is finished;

and if not, the reagent unit fills the reagent into the sample after the turbidity detection is finished.

According to the gynecological secretion detection device and the sample reaction mechanism and method thereof of the embodiment, the turbidity detection unit is adopted to carry out turbidity detection on the sample so as to realize automatic detection and dilution, and the turbidity detection unit has more accurate turbidity judgment capability compared with manual work, can control the dilution amount more accurately and further has higher in-vitro detection precision.

Drawings

FIG. 1 is a schematic diagram of a sample reaction mechanism according to an embodiment;

FIG. 2 is a schematic diagram of a turbidity detecting unit according to an embodiment;

FIG. 3 is a schematic diagram of a diluting unit according to an embodiment;

FIG. 4 is a schematic diagram of the structure of a reagent unit in one embodiment;

FIG. 5 is a schematic diagram of a cleaning unit according to an embodiment;

FIG. 6 is a schematic diagram of the structure of a waste liquid collecting unit in one embodiment;

FIG. 7 is a flow chart of a method of gynecological secretion detection in one embodiment;

FIG. 8 is a flow diagram of the turbidity detection sub-step in one embodiment.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings. Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings).

The first embodiment is as follows:

the embodiment provides a sample reaction mechanism for gynecological secretion detection, which is mainly used for carrying out turbidity detection and dyeing on a sample so as to enable the processed sample to be capable of carrying out morphological detection. This sample reaction mechanism detects the turbidity of sample, judges whether the sample needs dilute to make the sample can be spread out on the reading card in the microscopic examination district, avoid the sample range upon range of the influence of piling up to the reading.

Referring to fig. 1, the sample reaction mechanism of the present embodiment mainly includes a turbidity detecting unit 10, a diluting unit 20, and a reagent unit 30. The turbidity detection unit 10 is used for carrying out turbidity detection on the sample and judging whether the sample needs to be diluted; the dilution unit 20 is used for performing dilution processing on the sample; the reagent unit 30 is used for a dyeing process.

Specifically, the turbidity detecting unit 10 includes a reaction container 11, a transmitter 12 and a receiver 13, the reaction container 11 is used for containing a sample to be detected, the transmitter 12 and the receiver 13 are respectively installed at two sides of the reaction container 11, and the transmitter 12 and the receiver 13 are located at a lower end position of the reaction container 11, so that the transmitter 12 and the receiver 13 can detect the sample.

In other embodiments, the turbidity detecting unit 10 does not include the reaction container 11, but is provided with a reaction container placing position, and when detecting, the reaction container 11 is placed on the reaction container placing position, and the turbidity detection of the sample to be detected can be realized.

In this embodiment, the emitter 12 is a light source, the emitter 12 is configured to emit detection light to irradiate the sample in the reaction container 11, the receiver 13 is a photoelectric sensor, and the receiver 13 is configured to obtain the detection light transmitted by the sample and generate a corresponding sensing signal according to the obtained detection light. When the turbidity of the sample in the reaction container 11 is large, the detection light obtained by the receiver 13 is small, and when the turbidity of the sample in the reaction container 11 is small, the detection light obtained by the receiver 13 is large, that is, different turbidities of the sample have different light transmittances, and the turbidity of the sample can be judged by detecting the light transmittance of the sample.

Referring to fig. 2, in the embodiment, the transmitter 12 and the receiver 13 are connected to a processor 20 of the detection apparatus, the processor 20 is configured to control the transmitter 12 to transmit the detection light and further configured to obtain a detection signal generated by the receiver 13, and the processor 20 calculates the detection light obtained by the receiver 13 according to the detection signal and then compares the detection light with the emission light of the transmitter 12 to calculate the light transmittance of the sample. A threshold value of the light transmittance is prestored in the processor 20, and when the calculated light transmittance is detected to be greater than or equal to the threshold value, the turbidity of the sample is judged to be too low, and dilution processing is not needed; when the light transmittance calculated by the detection is smaller than the threshold value, the turbidity of the sample is determined to be high, and the dilution process is required.

In order to further improve the dilution accuracy, the processor 20 also compares the detected and calculated light transmittance with a threshold value to obtain the filling amount of the diluent. The method is characterized in that a large amount of diluent is added to a sample with high turbidity for dilution, and a small amount of diluent is added to a sample with high turbidity generally, namely, the addition amount of the diluent is matched with the turbidity of the sample, so that samples with different turbidity can be diluted to obtain samples with the same turbidity.

In other embodiments, the turbidity detection unit 10 comprises a separate processor that is only used for the calculation and determination of turbidity detection.

Referring to fig. 1 and 3, the dilution unit 20 includes a diluent container 21, a dilution line including a dilution tube 22 and a dilution needle 24, and a dilution driving member 23, both ends of the dilution tube 22 are connected to the diluent container 21 and the dilution needle 24, respectively, and the dilution driving member 23 is mounted on the dilution tube 22. The dilution needle 24 is mounted on a dilution moving unit capable of moving the dilution needle 24 into the reaction vessel 11. When the dilution needle 24 is moved into the reaction vessel 11, the dilution driving unit 23 first sucks the diluent in the diluent vessel 21 by negative pressure, and then injects the sucked diluent into the reaction vessel 11 through the dilution needle 24 by positive pressure.

Specifically, the dilution driving member 23 includes a plunger pump 231 and a dilution valve 232, specifically, the dilution valve 232 may be a three-way valve, the plunger pump 13 is connected to the dilution pipe 22 through the dilution valve 232, the dilution valve 232 has two modes, one mode is switched to connect the plunger pump 231 with the dilution liquid container 21, the other mode is switched to connect the plunger pump 231 with the dilution needle 24, and then the dilution valve 232 can assist the plunger pump 13 in sucking liquid and discharging liquid.

In other embodiments, the dilution unit 20 may not include the dilution needle 24, and may directly connect one end of the dilution tube 22 to the reaction vessel 11, or may fix one end of the dilution tube 22 at an upper position of the reaction vessel 11, and may also fill the dilution liquid into the reaction vessel 11. The dilution valve 232 may also be two-position two-way solenoid valves, and the two-position two-way solenoid valves are respectively installed on pipes connected to the inlet and the outlet of the plunger pump 13 to respectively control the opening and closing of the inlet and the outlet of the plunger pump 13.

Referring to fig. 1 and 4, in the present embodiment, the reagent unit 30 includes a reagent container 31, a reagent pipeline including a reagent tube 32 and a reagent needle 34, and a reagent driving member 33, wherein both ends of the reagent tube 32 are respectively connected to the reagent container 31 and the reagent needle 34, and the reagent driving member 33 is mounted on the reagent tube 32. The reagent container 31 is used for storing a coloring agent, and the reagent driving member 33 is used for filling the coloring agent in the reagent container 31 from the reagent needle 34 into the reaction container 11. The staining agent is used for staining the sample so that the sample can be photographed in a microscopic region.

Specifically, the reagent driving unit 33 includes a plunger pump 331 and a reagent valve 332, the reagent valve 332 may be a three-way valve, the plunger pump 331 is connected to the reagent tube 32 through the reagent valve 332, and the reagent valve 332 has two modes, one mode is switched to communicate between the plunger pump 331 and the reagent container 31, and the other mode is switched to communicate between the plunger pump 331 and the reagent needle 34, so that the reagent valve 332 can assist the plunger pump 331 in pipetting and draining.

In other embodiments, the reagent unit 30 may not include the reagent needle 34, and directly connect one end of the reagent tube 32 to the reaction container 11, or fix one end of the reagent tube 32 at an upper position of the reaction container 11, and may also fill the coloring agent into the reaction container 11. The reagent valve 332 may also be two-position two-way electromagnetic valves, and the two-position two-way electromagnetic valves are respectively installed on the pipes connected to the inlet and the outlet of the plunger pump 331, and respectively control the opening and the closing of the inlet and the outlet of the plunger pump 13.

The sample reaction mechanism in this embodiment further includes a cleaning unit 40 and a waste liquid collecting unit 50, the cleaning unit 40 is used for filling a cleaning liquid into the reaction container 11 to clean the corresponding container 11, and the waste liquid collecting unit 50 is used for collecting a cleaning waste liquid in the reaction container 11.

Referring to fig. 1 and 5, the cleaning unit 40 includes a cleaning solution container 41, a cleaning pipeline 42 and a cleaning driving member 43, the cleaning solution container 41 is used for storing a cleaning solution, two ends of the cleaning pipeline 42 are respectively connected to the cleaning solution container 41 and the reaction container 11, the cleaning driving member 43 is connected to the cleaning pipeline 42, the cleaning driving member 43 is a diaphragm pump, and the cleaning driving member 43 is used for filling the cleaning solution in the cleaning solution container 41 into the reaction container 11 to clean the reaction container 11.

Referring to fig. 1 and 6, the waste liquid collecting unit 50 includes a waste liquid collecting container 51, a waste liquid collecting pipeline 52 and a waste liquid collecting driving member 53, the waste liquid collecting container 51 is used for collecting cleaning waste liquid, two ends of the waste liquid collecting pipeline 52 are respectively connected with the waste liquid collecting container 51 and the reaction container 11, the waste liquid collecting driving member 53 is connected with the waste liquid collecting pipeline 52, the waste liquid collecting driving member 53 is a diaphragm pump, the waste liquid collecting driving member 53 is used for filling the cleaning liquid in the waste liquid collecting container 51 into the reaction container 11, and the cleaning waste liquid in the reaction container 11 is collected.

The sample reaction mechanism that gynaecology's secretion detected of this embodiment is owing to adopt turbidity detecting element to carry out turbidity detection to the sample to realize automatic detection and dilution, turbidity detecting element compares the manual work and has more accurate turbidity judgement ability, and the control that can be more accurate dilutes the volume, and then has higher external detection precision.

Example two:

the embodiment provides a gynecological secretion detection method, which is executed by the sample reaction mechanism in the embodiment.

Referring to fig. 7, the method for detecting gynecological secretions of the present embodiment includes the following steps:

s10: detecting whether dilution is needed or not by turbidity;

referring to fig. 8, after the sample adding mechanism adds the sample into the reaction container 11, the turbidity detecting unit 10 performs turbidity detection on the sample in the reaction container 11, and includes the following sub-steps:

s11: emitting detection light;

the processor 20 controls the emitter 12 to emit preset detection light to irradiate the sample in the reaction vessel 11;

s12: receiving detection light;

the receiver 13 acquires the detection light transmitted by the sample and generates a corresponding detection signal;

s13: judging whether dilution is needed;

the processor 20 obtains the detection signal generated by the receiver 13, converts the detection signal into a receiving light parameter, compares the receiving light parameter with a preset emitting light parameter, and calculates the light transmittance of the sample in the reaction container 11.

A threshold is prestored in the processor 20, and if the detected and calculated light transmittance is greater than or equal to the threshold, it is determined that the sample does not need to be diluted; if the detected and calculated transmittance is less than the threshold, it is determined that the sample needs to be diluted.

S14: and calculating the filling amount of the diluent.

If the processor 20 determines that the sample needs to be diluted, the detected and calculated light transmittance is further calculated, the calculated light transmittance is converted into the filling amount of the diluent, and the lower the light transmittance is, the higher the filling amount of the diluent is, so that the final sample can meet the requirement of microscopic examination.

S20: diluting;

if it is determined that the sample needs to be diluted, the dilution needle 24 injects a predetermined amount of diluent into the reaction container 11, and the diluent dilutes the sample.

In order to avoid the agglomeration of the sample and uneven dilution, the diluted sample is subjected to the following blending operation:

and a sampling needle of the sample adding unit is inserted into the diluted sample, the sample is sucked and discharged under the action of positive and negative pressure of the driving pump, the operation is repeated, and the diluted sample is uniformly mixed by the sampling needle in a sucking and spitting mode.

The sampling needle can also mix the sample evenly in a stirring mode, and the moving mechanism connected with the sampling needle drives the sampling needle to rotate clockwise and anticlockwise alternately in the reaction container 11 so as to mix the diluted sample evenly.

S30: dyeing;

after the sample is diluted and mixed, or for the sample without dilution, the reagent needle 34 fills a certain amount of the staining agent into the reaction container 11, and the staining agent stains the sample. In order to improve the uniformity of staining, the stained sample is subjected to a mixing operation.

And a sampling needle of the sample adding unit is inserted into the dyed sample, the sample is sucked and discharged under the action of positive and negative pressure of the driving pump, the operation is repeated, and the dyed sample is uniformly mixed by the sampling needle in a sucking and spitting mode.

The sampling needle can also be used for uniformly mixing the sample in a stirring mode, and the moving mechanism connected with the sampling needle drives the sampling needle to rotate clockwise and anticlockwise alternately in the reaction container 11 so as to uniformly mix the dyed sample.

S40: sample suction;

after the sample is dyed and mixed uniformly, the sampling needle of the sample adding unit is inserted into the reaction container 11 again to suck the dyed and mixed sample.

And the sampling needle of the sample adding unit is used for adding the uniformly dyed sample to the detection card of the microscopic examination area for the microscopic examination unit to take a picture.

S50: cleaning;

after the sample uniformly dyed in the reaction container 11 is sucked and transferred by the sampling needle of the sample adding unit, the cleaning driving member 43 drives the cleaning pipeline 42 to fill the cleaning solution in the cleaning solution container 41 into the reaction container 11, and clean the reaction container 11.

The waste liquid collecting drive member 53 drives the waste liquid collecting line 52 to collect the cleaning waste liquid in the reaction vessel 11 into the waste liquid collecting vessel 51.

After the reaction vessel 11 is cleaned, the next cycle of S10 turbidity test can be performed.

The gynecological secretion detection method of the embodiment is characterized in that the turbidity detection unit is adopted to carry out turbidity detection on a sample so as to realize automatic detection and dilution, the turbidity detection unit has more accurate turbidity judgment capability compared with manual work, and can control dilution amount more accurately, thereby having higher in vitro detection precision.

Example three:

the device comprises the sample reaction mechanism in the embodiment, and further comprises a sample feeding mechanism, a detection mechanism, a control mechanism and the like.

The sampling mechanism is used for sampling the sample container to a position which can be sucked by the sampling needle.

The detection mechanism comprises a dry chemistry detection unit and a morphology detection unit, wherein the dry chemistry detection unit and the morphology detection unit are both camera shooting units, the dry chemistry detection unit is used for carrying out dry chemistry detection on samples on a dry chemistry detection area of the detection card, and the morphology detection unit is used for carrying out morphology detection on the samples on the morphology detection area of the detection card.

The control mechanism is connected with the sample introduction mechanism, the detection mechanism and the sample reaction mechanism and is used for controlling the sample introduction mechanism, the detection mechanism and the sample reaction mechanism to work so as to complete full-automatic dry chemical detection and morphological detection.

Because application of sample reaction mechanism includes turbidity detecting element and reagent unit for this device can carry out turbidity detection and dyeing to the sample, compares the manual work and has more accurate turbidity judgement ability, and control dilution that can be more accurate, and then has higher external detection precision.

The present invention has been described in terms of specific examples, which are provided to aid understanding of the invention and are not intended to be limiting. For a person skilled in the art to which the invention pertains, several simple deductions, modifications or substitutions may be made according to the idea of the invention.

Claims (10)

1. A sample reaction mechanism for gynecological secretion detection is characterized by comprising:

the turbidity detection unit is used for accommodating a sample to be detected and carrying out turbidity detection on the sample to be detected;

the dilution unit comprises a dilution pipeline and a dilution driving piece, and the dilution pipeline is respectively connected with the turbidity detection unit and the dilution driving piece so as to fill diluent into the turbidity detection unit under the driving action of the dilution driving piece;

and the reagent unit comprises a reagent pipeline and a reagent driving part, wherein the reagent pipeline is respectively connected with the turbidity detection unit and the reagent driving part so as to fill reaction reagents into the turbidity detection unit under the driving action of the reagent driving part.

2. The gynecological secretion test sample reaction mechanism of claim 1, wherein the dilution pipeline comprises a dilution tube and a dilution needle, the dilution needle is connected with the dilution tube, and the dilution needle is used for injecting a dilution liquid into the sample in the turbidity test unit.

3. The gynecological secretion testing sample reaction mechanism of claim 2, wherein the dilution unit further comprises a dilution valve and a dilution liquid container, the dilution tube is connected with the dilution liquid container, the dilution valve is mounted on the dilution tube, the dilution driving member is connected with the dilution valve, and the dilution valve is used for switching the dilution driving member to respectively communicate with the dilution liquid container and the dilution needle.

4. The gynecological secretion test sample reaction mechanism of claim 1, wherein the reagent pipeline comprises a reagent tube and a reagent needle, the reagent needle is connected with the reagent tube, and the reagent needle is used for filling a reagent into the sample after the turbidity test is completed.

5. The gynecological secretion testing sample reaction mechanism of claim 4, wherein the reagent unit further comprises a reagent valve and a reagent liquid container, the reagent tube is connected with the reagent liquid container, the reagent valve is installed on the reagent tube, the reagent driving member is connected with the reagent valve, and the reagent valve is used for switching the communication between the reagent driving member and the reagent liquid container and the reagent needle respectively.

6. The gynecological secretion testing sample reaction mechanism of claim 1, further comprising a cleaning unit, wherein the cleaning unit comprises a cleaning pipeline and a cleaning driving member, and the cleaning pipeline is respectively connected to the turbidity detecting unit and the cleaning driving member, so as to fill the turbidity detecting unit with a cleaning solution under the driving action of the cleaning driving member.

7. The gynecological secretion test sample reaction mechanism of claim 6, further comprising a waste liquid collection unit, wherein the waste liquid collection unit comprises a waste liquid pipeline and a waste liquid driving member, and the waste liquid pipeline is connected with the turbidity test unit and the waste liquid driving member respectively, so as to collect the cleaning waste liquid in the turbidity test unit under the driving action of the waste liquid driving member.

8. The gynecological secretion test sample reaction mechanism according to any one of claims 1 to 7, wherein the turbidity detecting unit comprises a reaction vessel, a transmitter and a receiver, the dilution line and the reagent line are connected with the reaction vessel, and the transmitter is used for irradiating detection light to the sample; the receiver is configured to receive the detected light passing through the sample and generate a detection signal.

9. The gynecological secretion detection device is characterized by comprising a detection mechanism, a sample injection mechanism and a control mechanism, and further comprising a sample reaction mechanism for gynecological secretion detection according to any one of claims 1 to 8, wherein the detection mechanism is used for detecting a sample for completing reagent filling, and the control mechanism is connected with the detection mechanism, the sample injection mechanism and the sample reaction mechanism and is used for controlling the detection mechanism, the sample injection mechanism and the sample reaction mechanism.

10. A gynecological secretion detection method, which is performed by the gynecological secretion detection device of claim 9, comprising the steps of:

a turbidity detection unit detects whether a sample to be detected needs to be diluted or not;

if yes, the diluting unit and the reagent unit respectively and sequentially fill the diluting liquid and the reagent into the sample after the turbidity detection is finished;

and if not, the reagent unit fills the reagent into the sample after the turbidity detection is finished.

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