阅读说明：本技术 一种血液检测仪、血液检测识别系统及识别方法 (Blood detector, blood detection identification system and identification method ) 是由 杨奕 陈龙飞 刘彦彤 于 2021-07-12 设计创作，主要内容包括：本发明属于医疗检测技术领域,公开了一种血液检测仪、血液检测识别系统及识别方法。将血液和水凝胶前驱液通过微流控芯片的芯片入口部通入至微流控芯片的芯片腔室,芯片腔室中设置有微水凝胶柱,通过蓝光曝光将血细胞固化在微水凝胶柱中制成水凝胶致动器；通过图像采集传输组件采集获取血细胞原始图像；按压力学传输组件,使得水凝胶致动器中的血细胞制动；通过图像采集传输组件采集获取血细胞形变图像；通过图像采集传输组件将血细胞原始图像和血细胞形变图像传输至识别设备；通过识别设备得到分类识别结果信息。本发明解决了现有技术中血液检测的装置体积较大、成本较高、操作较复杂的问题。(The invention belongs to the technical field of medical detection, and discloses a blood detector, a blood detection identification system and an identification method. Introducing blood and hydrogel precursor liquid into a chip chamber of the microfluidic chip through a chip inlet part of the microfluidic chip, wherein a micro-hydrogel column is arranged in the chip chamber, and curing blood cells in the micro-hydrogel column through blue light exposure to prepare a hydrogel actuator; acquiring and obtaining a blood cell original image through an image acquisition and transmission assembly; pressing the mechanical transmission component to brake blood cells in the hydrogel actuator; acquiring and obtaining a blood cell deformation image through an image acquisition and transmission assembly; transmitting the blood cell original image and the blood cell deformation image to identification equipment through an image acquisition and transmission assembly; and obtaining classification identification result information through the identification equipment. The invention solves the problems of larger volume, higher cost and more complex operation of the blood detection device in the prior art.)

1. A blood test meter, comprising: the device comprises a micro-fluidic chip, a mechanical transmission assembly, an image acquisition transmission assembly and a shell;

the micro-fluidic chip comprises a chip inlet part, a chip outlet part, a chip chamber and a micro-hydrogel column;

the micro-fluidic chip and the image acquisition and transmission assembly are arranged in the shell; the mechanical transmission assembly is arranged on the shell and is arranged above the micro-hydrogel column;

the microfluidic chip is used for providing an imaging platform for blood cells; leading blood and hydrogel precursor liquid into the chip chamber through the chip inlet part, positioning the micro-hydrogel column in the chip chamber, and solidifying blood cells in the micro-hydrogel column through blue light exposure to prepare a hydrogel actuator;

the mechanical transmission component is used for transmitting the force generated by external pressing to the hydrogel actuator so as to brake blood cells in the hydrogel actuator;

the image acquisition and transmission assembly is used for acquiring and acquiring a blood cell original image and a blood cell deformation image and transmitting the blood cell original image and the blood cell deformation image to external identification equipment.

2. The blood testing instrument of claim 1, wherein the mechanical transmission assembly comprises: springs, buttons and spacers;

one end of the spring is connected with the gasket, and the spring is arranged above the gasket; the button is connected with the other end of the spring and arranged above the spring; the lower surface of the gasket is tightly attached to the upper surface of the micro-hydrogel column.

3. The blood testing instrument of claim 1, wherein the image capture and transmission assembly comprises: the device comprises a patch type light source module, an optical lens, an image acquisition module and an image transmission module;

the patch type light source module is arranged above the microfluidic chip, the optical lens, the image acquisition module and the image transmission module are all arranged below the microfluidic chip, and the image acquisition module is respectively connected with the image transmission module and the optical lens;

the patch type light source module is used for providing a light source for blood cell imaging; the optical lens is used for carrying out focusing adjustment on blood cell imaging; the image acquisition module is used for acquiring the blood cell original image and the blood cell deformation image; the image transmission module is used for transmitting the blood cell original image and the blood cell deformation image to external identification equipment.

4. A blood detection and identification system, comprising: an identification device, and a blood detector according to any of claims 1-3;

the identification equipment is connected with the blood detector through a data line; the identification equipment is used for receiving the blood cell original image and the blood cell deformation image and obtaining classification identification result information according to the blood cell original image and the blood cell deformation image.

5. The blood detection and identification system according to claim 4, wherein the identification device comprises an image preprocessing module, a training optimization module and a classification identification module;

the image preprocessing module is used for preprocessing the obtained blood cell original image and the blood cell deformation image to obtain an image vector and a parameter vector of the blood cell; the image vectors comprise original image vectors and deformation image vectors, and the parameter vectors comprise morphological parameter vectors and mechanical parameter vectors;

the training optimization module is used for training and optimizing a pre-constructed blood detection classification model to obtain a trained blood detection classification model;

and the classification and identification module is used for preprocessing the blood cell original image to be classified and identified and the corresponding blood cell deformation image, inputting the preprocessed blood cell original image and the preprocessed blood cell deformation image into the trained blood detection and classification model, and acquiring classification and identification result information.

6. The blood detection and identification system of claim 5, wherein the blood detection classification model is constructed based on a deep convolutional neural network, and comprises six convolutional layers and three fully-connected layers; the three fully-connected layers contain 40, 64 and 20 vectors, respectively, with the first fully-connected layer containing 32 image vectors and 8 parameter vectors.

7. The blood detection and identification system of claim 5, wherein the preprocessing comprises: converting the original image into a gray image; converting the gray image into a binary image based on the set threshold; filling the outline of the binary image by adopting filling hole operation; and carrying out pixel analysis on the filled image to obtain the parameter vector.

8. The blood detection and identification system according to claim 4, wherein the identification device is a smartphone or a tablet computer, and the identification device obtains the classification and identification result information based on cloud computing.

9. A blood detection and identification method is characterized by comprising the following steps:

step 1, introducing blood and hydrogel precursor liquid into a chip chamber of a microfluidic chip through a chip inlet part of the microfluidic chip, wherein a micro hydrogel column is arranged in the chip chamber, and curing blood cells in the micro hydrogel column through blue light exposure to prepare a hydrogel actuator;

step 2, acquiring and obtaining a blood cell original image through an image acquisition and transmission assembly;

step 3, pressing the mechanical transmission component, and transmitting the force generated by external pressing to the hydrogel actuator through the mechanical transmission component so as to brake blood cells in the hydrogel actuator;

step 4, acquiring and obtaining a blood cell deformation image through the image acquisition and transmission assembly;

step 5, transmitting the blood cell original image and the blood cell deformation image to an identification device through the image acquisition and transmission assembly;

and 6, obtaining classification recognition result information through the recognition equipment.

10. The blood detection and identification method according to claim 9, wherein the step 6 comprises the substeps of:

6.1, preprocessing the obtained blood cell original image and the blood cell deformation image through an image preprocessing module in the identification equipment to obtain an image vector and a parameter vector of the blood cell; the image vectors comprise original image vectors and deformation image vectors, and the parameter vectors comprise morphological parameter vectors and mechanical parameter vectors;

6.2, training and optimizing a pre-constructed blood detection classification model through a training optimization module in the recognition equipment to obtain a trained blood detection classification model;

step 6.3, preprocessing the blood cell original image to be classified and recognized and the corresponding blood cell deformation image through a classification recognition module in the recognition equipment, and inputting the preprocessed blood cell original image and the preprocessed blood cell deformation image into a trained blood detection classification model to obtain classification recognition result information;

the blood detection classification model is constructed on the basis of a deep convolutional neural network and comprises six convolutional layers and three full-connection layers; the three fully-connected layers contain 40, 64 and 20 vectors, respectively, wherein the first fully-connected layer contains 32 image vectors and 8 parameter vectors;

and the identification equipment obtains the classification identification result information based on cloud computing.

Technical Field

The invention belongs to the technical field of medical detection, and particularly relates to a blood detector, a blood detection and identification system and an identification method.

Background

Existing blood tests or analyses are typically performed in hospitals or laboratories, and the test equipment employed is typically bulky, costly, and complex to operate. It remains a challenge in the art to provide a portable blood test meter that can be used to perform a high-precision, low-cost, and easy-to-operate multi-function blood test.

Disclosure of Invention

The invention provides a blood detector, a blood detection and identification system and an identification method, and solves the problems of large volume, high cost and complex operation of a blood detection device in the prior art.

The present invention provides a blood detector, comprising: the device comprises a micro-fluidic chip, a mechanical transmission assembly, an image acquisition transmission assembly and a shell;

the micro-fluidic chip comprises a chip inlet part, a chip outlet part, a chip chamber and a micro-hydrogel column;

the micro-fluidic chip and the image acquisition and transmission assembly are arranged in the shell; the mechanical transmission assembly is arranged on the shell and is arranged above the micro-hydrogel column;

the microfluidic chip is used for providing an imaging platform for blood cells; leading blood and hydrogel precursor liquid into the chip chamber through the chip inlet part, positioning the micro-hydrogel column in the chip chamber, and solidifying blood cells in the micro-hydrogel column through blue light exposure to prepare a hydrogel actuator;

the mechanical transmission component is used for transmitting the force generated by external pressing to the hydrogel actuator so as to brake blood cells in the hydrogel actuator;

the image acquisition and transmission assembly is used for acquiring and acquiring blood cell original images and blood cell deformation images and transmitting the blood cell original images and the blood cell deformation images to external identification equipment.

Preferably, the mechanical transmission assembly comprises: springs, buttons and spacers;

one end of the spring is connected with the gasket, and the spring is arranged above the gasket; the button is connected with the other end of the spring and arranged above the spring; the lower surface of the gasket is tightly attached to the upper surface of the micro-hydrogel column.

Preferably, the image acquisition and transmission assembly comprises: the device comprises a patch type light source module, an optical lens, an image acquisition module and an image transmission module;

the patch type light source module is arranged above the microfluidic chip, the optical lens, the image acquisition module and the image transmission module are all arranged below the microfluidic chip, and the image acquisition module is respectively connected with the image transmission module and the optical lens;

the patch type light source module is used for providing a light source for blood cell imaging; the optical lens is used for carrying out focusing adjustment on blood cell imaging; the image acquisition module is used for acquiring the blood cell original image and the blood cell deformation image; the image transmission module is used for transmitting the blood cell original image and the blood cell deformation image to external identification equipment.

The invention provides a blood detection and identification system, comprising: an identification device, and the blood test meter described above;

the identification equipment is connected with the blood detector through a data line; the identification equipment is used for receiving the blood cell original image and the blood cell deformation image and obtaining classification identification result information according to the blood cell original image and the blood cell deformation image.

Preferably, the recognition device comprises an image preprocessing module, a training optimization module and a classification recognition module;

the image preprocessing module is used for preprocessing the obtained blood cell original image and the blood cell deformation image to obtain an image vector and a parameter vector of the blood cell; the image vectors comprise original image vectors and deformation image vectors, and the parameter vectors comprise morphological parameter vectors and mechanical parameter vectors;

the training optimization module is used for training and optimizing a pre-constructed blood detection classification model to obtain a trained blood detection classification model;

and the classification and identification module is used for preprocessing the blood cell original image to be classified and identified and the corresponding blood cell deformation image, inputting the preprocessed blood cell original image and the preprocessed blood cell deformation image into the trained blood detection and classification model, and acquiring classification and identification result information.

Preferably, the blood detection classification model is constructed based on a deep convolutional neural network, and comprises six convolutional layers and three full-connection layers; the three fully-connected layers contain 40, 64 and 20 vectors, respectively, with the first fully-connected layer containing 32 image vectors and 8 parameter vectors.

Preferably, the pretreatment comprises: converting the original image into a gray image; converting the gray image into a binary image based on a set threshold; filling the outline of the binary image by adopting filling hole operation; and carrying out pixel analysis on the filled image to obtain the parameter vector.

Preferably, the identification device is a smart phone or a tablet computer, and the identification device obtains the classification identification result information based on cloud computing.

The invention provides a blood detection and identification method, which comprises the following steps:

step 1, introducing blood and hydrogel precursor liquid into a chip chamber of a microfluidic chip through a chip inlet part of the microfluidic chip, wherein a micro hydrogel column is arranged in the chip chamber, and curing blood cells in the micro hydrogel column through blue light exposure to prepare a hydrogel actuator;

step 2, acquiring and obtaining a blood cell original image through an image acquisition and transmission assembly;

step 3, pressing the mechanical transmission component, and transmitting the force generated by external pressing to the hydrogel actuator through the mechanical transmission component so as to brake blood cells in the hydrogel actuator;

step 4, acquiring and obtaining a blood cell deformation image through the image acquisition and transmission assembly;

step 5, transmitting the blood cell original image and the blood cell deformation image to an identification device through the image acquisition and transmission assembly;

and 6, obtaining classification recognition result information through the recognition equipment.

Preferably, said step 6 comprises the following sub-steps:

6.1, preprocessing the obtained blood cell original image and the blood cell deformation image through an image preprocessing module in the identification equipment to obtain an image vector and a parameter vector of the blood cell; the image vectors comprise original image vectors and deformation image vectors, and the parameter vectors comprise morphological parameter vectors and mechanical parameter vectors;

6.2, training and optimizing a pre-constructed blood detection classification model through a training optimization module in the recognition equipment to obtain a trained blood detection classification model;

step 6.3, preprocessing the blood cell original image to be classified and recognized and the corresponding blood cell deformation image through a classification recognition module in the recognition equipment, and inputting the preprocessed blood cell original image and the preprocessed blood cell deformation image into a trained blood detection classification model to obtain classification recognition result information;

the blood detection classification model is constructed on the basis of a deep convolutional neural network, and comprises six convolutional layers and three full-connection layers; the three fully-connected layers contain 40, 64 and 20 vectors, respectively, wherein the first fully-connected layer contains 32 image vectors and 8 parameter vectors;

and the identification equipment obtains the classification identification result information based on cloud computing.

One or more technical schemes provided by the invention at least have the following technical effects or advantages:

in the invention, the provided blood detector utilizes the hydrogel actuator to accurately control the deformation of blood cells in blood through continuous pressure and maintain stable detection, and can realize high-precision, easy-to-operate and low-cost blood detection and blood quality monitoring. And by combining the identification equipment, classification identification result information can be obtained according to the blood cell original image and the blood cell deformation image, so that the effect of accurately identifying the blood cells is achieved.

Drawings

Fig. 1 is a schematic structural diagram of a blood detection and identification system according to an embodiment of the present invention;

fig. 2 is a comparison graph of monitoring performance between a blood detection and identification system provided by an embodiment of the present invention and a laser diffraction-based erythrocyte deformation analyzer in the prior art;

fig. 3 is a schematic diagram of a blood detection and identification method combining a neural network and cloud computing according to an embodiment of the present invention.

The device comprises a micro-fluidic chip 1, a mechanical transmission component 2, a surface mount type light source module 3, an optical lens 4, an image transmission module 5, an image acquisition module 6, an upper cover part 7, a lower cover part 8 and a clamp part 9;

11-chip inlet part, 12-chip outlet part, 13-chip chamber and 14-micro hydrogel column;

21-spring, 22-button, 23-spacer.

Detailed Description

In order to better understand the technical solution, the technical solution will be described in detail with reference to the drawings and the specific embodiments.

Example 1:

embodiment 1 provides a blood test apparatus, see fig. 1, comprising: the device comprises a micro-fluidic chip 1, a mechanical transmission assembly 2, an image acquisition transmission assembly and a shell. The microfluidic chip 1 comprises a chip inlet part 11, a chip outlet part 12, a chip chamber 13 and a micro-hydrogel column 14. The micro-fluidic chip 1 and the image acquisition and transmission assembly are arranged in the shell; the mechanical transmission assembly 2 is mounted on the housing and is disposed above the micro-hydrogel column 14. The microfluidic chip 1 is used for providing an imaging platform for blood cells; blood and hydrogel precursor liquid are led into the chip chamber 13 through the chip inlet 11, the micro-hydrogel column 14 is positioned in the chip chamber 13, and blood cells are solidified in the micro-hydrogel column 14 through blue light exposure to form the hydrogel actuator. The mechanical transmission component 2 is used for transmitting the force generated by external pressing to the hydrogel actuator, so that blood cells in the hydrogel actuator are braked. The image acquisition and transmission assembly is used for acquiring a blood cell original image and a blood cell deformation image and transmitting the blood cell original image and the blood cell deformation image to external identification equipment.

Wherein the mechanical transmission assembly 2 comprises: a spring 21, a button 22 and a washer 23. One end of the spring 21 is connected with the gasket 23, and the spring 21 is arranged above the gasket 23; the button 22 is connected with the other end of the spring 21, and the button 22 is arranged above the spring 21; the lower surface of the spacer 23 is closely attached to the upper surface of the micro-hydrogel column 14.

The image acquisition transmission assembly comprises: the device comprises a patch type light source module 3, an optical lens 4, an image acquisition module 6 and an image transmission module 5. The patch type light source module 3 is arranged above the micro-fluidic chip 1, the optical lens 4, the image acquisition module 6 and the image transmission module 5 are all arranged below the micro-fluidic chip 1, and the image acquisition module 6 is respectively connected with the image transmission module 5 and the optical lens 4. The patch type light source module 3 is used for providing a light source for blood cell imaging; the optical lens 4 is used for carrying out focusing adjustment on blood cell imaging; the image acquisition module 6 is used for acquiring the blood cell original image and the blood cell deformation image; the image transmission module 5 is configured to transmit the blood cell original image and the blood cell deformation image to an external identification device.

The housing includes an upper cover portion 7, a lower cover portion 8, and a clamp portion 9. The upper cover part 7 and the lower cover part 8 form a main space of the shell, the microfluidic chip 1 and the image acquisition and transmission assembly are arranged in the space, the clamp part 9 is arranged above the upper cover part 7, and the mechanical transmission assembly 2 is arranged on the clamp part 9.

For example, the housing is manufactured by a 3D printing process using ABS material, the template of the microfluidic chip 1 is manufactured by uv lithography, and the microfluidic chip 1 is made of polydimethylsiloxane (PDMS, refractive index 1.406).

The button 22 is an acrylonitrile-butadiene-styrene copolymer with a diameter of 1.3 cm; the stiffness coefficient of the spring 21 is 5N/cm; the diameter of the gasket 23 is 1cm, and a glass gasket is specifically adopted.

Example 2:

embodiment 2 provides a blood test identification system, see fig. 1, comprising an identification device, and a blood test meter as described in embodiment 1. The identification equipment is connected with the blood detector through a data line; the identification equipment is used for receiving the blood cell original image and the blood cell deformation image and obtaining classification identification result information according to the blood cell original image and the blood cell deformation image.

The recognition device comprises an image preprocessing module, a training optimization module and a classification recognition module. The image preprocessing module is used for preprocessing the obtained blood cell original image and the blood cell deformation image to obtain an image vector and a parameter vector of the blood cell; the image vectors comprise original image vectors and deformation image vectors, and the parameter vectors comprise morphological parameter vectors and mechanical parameter vectors. The training optimization module is used for training and optimizing a pre-constructed blood detection classification model to obtain a trained blood detection classification model. And the classification identification module is used for preprocessing the blood cell original image to be classified and identified and the corresponding blood cell deformation image, inputting the preprocessed blood cell original image and the preprocessed blood cell deformation image into the trained blood detection classification model, and acquiring classification identification result information.

Specifically, the blood detection classification model is constructed based on a deep convolutional neural network, and comprises six convolutional layers and three full-connection layers; the three fully-connected layers contain 40, 64 and 20 vectors, respectively, with the first fully-connected layer containing 32 image vectors and 8 parameter vectors.

The pretreatment comprises the following steps: converting the original image into a gray image; converting the gray level image into a binary image based on a set threshold value; filling the outline of the binary image by adopting filling hole operation; and carrying out pixel analysis on the filled image to obtain the parameter vector.

The identification device adopts a smart phone or a tablet personal computer, and the identification device obtains the classification identification result information based on cloud computing.

Example 3:

embodiment 3 provides a blood detection and identification method, including the following steps:

step 1, introducing blood and hydrogel precursor liquid into a chip chamber of a microfluidic chip through a chip inlet part of the microfluidic chip, wherein a micro hydrogel column is arranged in the chip chamber, and curing blood cells in the micro hydrogel column through blue light exposure to prepare a hydrogel actuator;

step 2, acquiring and obtaining a blood cell original image through an image acquisition and transmission assembly;

step 3, pressing the mechanical transmission component, and transmitting the force generated by external pressing to the hydrogel actuator through the mechanical transmission component so as to brake blood cells in the hydrogel actuator;

step 4, acquiring and obtaining a blood cell deformation image through the image acquisition and transmission assembly;

step 5, transmitting the blood cell original image and the blood cell deformation image to an identification device through the image acquisition and transmission assembly;

and 6, obtaining classification recognition result information through the recognition equipment.

Wherein the step 6 comprises the following substeps:

6.1, preprocessing the obtained blood cell original image and the blood cell deformation image through an image preprocessing module in the identification equipment to obtain an image vector and a parameter vector of the blood cell; the image vectors comprise original image vectors and deformation image vectors, and the parameter vectors comprise morphological parameter vectors and mechanical parameter vectors;

6.2, training and optimizing a pre-constructed blood detection classification model through a training optimization module in the recognition equipment to obtain a trained blood detection classification model;

and 6.3, preprocessing the blood cell original image to be classified and recognized and the corresponding blood cell deformation image through a classification recognition module in the recognition equipment, and inputting the preprocessed blood cell original image and the preprocessed blood cell deformation image into a trained blood detection classification model to obtain classification recognition result information.

The blood detection classification model is constructed on the basis of a deep convolutional neural network, and comprises six convolutional layers and three full-connection layers; the three fully-connected layers contain 40, 64 and 20 vectors, respectively, wherein the first fully-connected layer contains 32 image vectors and 8 parameter vectors; and the identification equipment obtains the classification identification result information based on cloud computing.

For example, the ratio of blood to hydrogel precursor is 1: 100; exposure was performed by blue light (Flashlight, FENIX TK25RB) under a photomask (Filin film, jixiangungdian).

The present invention is further described below.

The blood detection and identification system provided by the invention can realize accurate cell identification based on dual marks of the shape and mechanics of the hydrogel actuator, the hydrogel actuator is operated by utilizing the mechanics transmission component, so that the shape (diameter, roundness, axial ratio and corresponding distribution width) and the mechanics parameters (deformability and distribution width) of blood cells are changed, an adjustable imaging platform is designed to capture blood cell images on different focusing surfaces, and the collected blood cell images are processed by utilizing identification equipment, so that the blood cells are accurately identified by combining the shape and the mechanics dual identification.

For example, a smartphone is adopted to collect blood cell images in a 360-micron × 360-micron micro-hydrogel column field through an optical lens, and the images are converted into 8-bit grayscale images; after the software automatically adjusts the light intensity and the contrast, the blood cell image is converted into a binary image through threshold operation; a threshold is set for clearing cell debris and stacking; then, the outline is filled by adopting filling hole operation, so that the calculation precision is improved; and finally, calculating the area and the perimeter through software pixel analysis. Accurate cell identification is achieved through multivariate assistance of morphological parameters (diameter, roundness, axial ratio and corresponding distribution width) and mechanical parameters (deformability and distribution width thereof).

The invention realizes the blood classification recognition based on deep learning by introducing cloud computing, takes data (including dual variable parameters of morphology and mechanics) integrated by a smart phone as the input of the cloud computing, converts the data into a vector table, loads the vector table into an image vector, and performs the classification recognition of blood disease types according to a trained neural network. Wherein the deep convolutional neural network can handle a flexible number of input images.

Cloud computing based on deep learning: firstly, data enhancement is carried out on an original image through random rotation, cutting and overturning to obtain an input image. Training was then performed on the ImageNet dataset using AlexNet with pre-training weight coefficients. The layer before the last layer is set to have 32 neurons to meet the accuracy and time consuming requirements. After training is finished, the vectors are extracted as feature vectors in an embedded space for neural network learning. All inputs were adjusted to 224 x 224 pixels for cell imaging in the hydrogel actuators, the scale of the image was 0.1 mm x 0.1 mm, and the image should be cropped to the same scale-0.1 mm x 0.1 mm before being used as an input. The 32-dimensional feature vectors extracted in the images are combined with the 8-dimensional mechanical and morphological data obtained from the imaging analysis and the combined feature vectors to train a neural network with two hidden fully connected layers. A conjugate method is adopted in the training process so as to avoid overfitting and improve generalization performance.

In order to verify the monitoring function of the present invention, the monitoring performance of the blood cell deformation by the blood detection and identification system provided by the present application and the laser diffraction-based red blood cell deformation analyzer in the prior art are respectively compared, see fig. 2. Specifically, fig. 2a shows scatter plots of RBC elongation index values (EI, average 0.5373, σ 0.0082) obtained by laser diffraction-based red blood cell deformation analyzer (Lorrca, shear stress 6Pa) on 63 healthy red blood cell samples and hydrogel actuator-based red blood cell deformability values (Dr, average 1.210, σ 0.0046) obtained by the present invention (stress 3 kPa). FIG. 2b shows the mean deviation of the hydrogel actuator-based red blood cell deformability values from the laser diffraction red blood cell deformability analyzer by a Bland-Altman analysis of 0.6723 with an SD of 0.0059. The limit of anastomosis (LOA) is between 0.6607 and 0.6840. Figure 2c shows that the mountain plot analysis calculated the percentile of each ranking difference in cell deformability for the laser diffraction method and the hydrogel actuator method, with the vertical dashed line representing the center of the mountain and the horizontal dashed line representing the 5 th to 95 th percentiles. Figure 2 illustrates the miniaturization of the device provided by the present invention while maintaining a high degree of accuracy.

FIG. 3 shows that images and multivariate (morphology: diameter, roundness, axial ratio and corresponding distribution width; mechanics: deformability and distribution width) collected by the smart phone are integrated and loaded to the cloud end, classification and identification are carried out based on the trained neural network, and referring to FIGS. 3a to 3d, classification and identification data are returned to the smart phone; the patient can share the classification recognition result and the detailed parameters with the doctor through cloud sharing. Referring to fig. 3e to 3j, five typical hematological diseases including Megaloblastic Anemia (MA), Myelofibrosis (MF), Iron Deficiency Anemia (IDA), thrombocytopenic purpura (TTP), and Thalassemia (THAL), and corresponding models in healthy state were constructed. FIG. 3j shows the performance of the blood test classification model after being trained by three training methods, the first is morphological training, the second is morphological combined image training, and the third is combined morphological, mechanical and image training. By comparison, the classification model combining the image, morphology and mechanical parameters achieves 100% of classification recognition accuracy in six classifications (n-432).

In conclusion, the invention can realize blood detection and blood quality monitoring with high precision, easy operation and low cost. The combination identification device can obtain classification identification result information according to the blood cell original image and the blood cell deformation image, and achieves the effect of accurately identifying the blood cells.

Finally, it should be noted that the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to examples, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.