CN117379622A - Hemodialysis data acquisition and processing method and system based on mobile terminal - Google Patents

Abstract

The invention provides a hemodialysis data acquisition and processing method and system based on a mobile terminal, which are used for receiving a dialysis request of a patient terminal and acquiring a virtual twin model and patient data corresponding to the patient terminal based on determination information of the dialysis request of a doctor terminal. And updating the virtual twin model according to the patient data to obtain a customized twin model, and transmitting the customized twin model to a doctor, wherein the customized twin model comprises a dialysis module and a patient module. Based on the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor, updating the customized twin model to obtain a monitoring twin model, wherein the liquid level configuration data comprises brand new liquid level data and historical liquid level data. And calling a liquid level monitoring strategy to monitor liquid level data of the monitoring twin model, and sending the obtained monitoring data to a doctor side.

Description

Hemodialysis data acquisition and processing method and system based on mobile terminal

Technical Field

The invention relates to a data processing technology, in particular to a hemodialysis data acquisition and processing method and system based on a mobile terminal.

Background

Hemodialysis is called hemodialysis for short, and popular expression is also called artificial kidney, and kidney washing is one of blood purification technologies. Currently, patients typically use dialysis equipment to remove waste and toxins from the body.

The dialysis equipment comprises a dialyzer, dialysate, physiological saline, a heparin pump, a waste liquid tank and the like. In the dialysis process, the liquid medicine and the waste liquid need to be replaced in time, otherwise, the dialysis process of a patient can be influenced. In the prior art, when the liquid medicine is about to run out or the waste liquid barrel is about to be filled, a patient generally presses a calling button to call medical staff to replace the liquid medicine or the waste liquid, and the dialysis process of the patient can not be automatically monitored in the mode, so that the situation that the liquid medicine or the waste liquid can not be replaced in time due to negligence is easy to occur.

Therefore, how to automatically monitor the dialysis process of the patient, and timely remind medical staff through monitoring data becomes a problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides a hemodialysis data acquisition and processing method and system based on a mobile terminal, which can automatically monitor the dialysis process of a patient and timely remind medical staff through monitoring data.

In a first aspect of an embodiment of the present invention, a method for collecting and processing hemodialysis data based on a mobile terminal is provided, including:

receiving a dialysis request of a patient end, and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of a doctor end on the dialysis request;

Updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module;

updating the customized twin model based on liquid level configuration data of a dynamic monitoring module in the dialysis module by the doctor side to obtain a monitoring twin model, wherein the liquid level configuration data comprises brand new liquid level data and historical liquid level data;

and calling a liquid level monitoring strategy to monitor the liquid level data of the monitoring twin model, and sending the obtained monitoring data to the doctor.

Optionally, in one possible implementation manner of the first aspect, receiving a dialysis request of a patient side, and acquiring a virtual twin model and patient data corresponding to the patient side based on determination information of the dialysis request by a physician side, includes:

receiving scanning information of the patient end on actual dialysis equipment, acquiring a dialysis request of the patient end according to the scanning information, and sending the dialysis request to the doctor end;

based on the determination information of the doctor end on the dialysis request, a virtual twin model corresponding to the actual dialysis equipment is obtained, the virtual twin model is bound with the patient end, and patient data corresponding to the patient end is obtained.

Optionally, in a possible implementation manner of the first aspect, updating the virtual twin model according to the patient data, to obtain a customized twin model, and sending the customized twin model to the physician, where the customized twin model includes a dialysis module and a patient module, and includes:

analyzing the patient data to obtain basic patient information and patient condition information, and generating a patient customized model according to the basic patient information and the patient medical record information;

updating the patient module in the virtual twin model based on the patient customized model to obtain a customized twin module, and sending the customized twin module to the doctor.

Optionally, in a possible implementation manner of the first aspect, updating the customized twin model based on the level configuration data of the dynamic monitoring module in the dialysis module by the physician side to obtain a monitoring twin model, where the level configuration data includes brand new level data and historical level data, and includes:

receiving trigger information of the doctor end on the corresponding dynamic monitoring module in the dialysis module, and determining the corresponding dynamic monitoring module as a configuration monitoring module according to the trigger information;

Acquiring liquid level configuration data input by the doctor end to the configuration monitoring module, and generating a configuration monitoring image according to the module attribute of the configuration monitoring module and the liquid level configuration data, wherein the configuration monitoring image comprises a plurality of customized liquid level lines corresponding to the configuration monitoring module;

receiving an alarm liquid level line input by the doctor terminal based on the configuration monitoring image, and updating the configuration monitoring image according to the alarm liquid level line to obtain a customized monitoring image;

filling the customized monitoring image into an image slot corresponding to the configuration monitoring module to obtain a liquid level monitoring module, and updating the customized twin model according to the liquid level monitoring module to obtain a monitoring twin model.

Optionally, in one possible implementation manner of the first aspect, acquiring liquid level configuration data input by the physician end to the configuration monitoring module, generating a configuration monitoring image according to a module attribute of the configuration monitoring module and the liquid level configuration data, where the configuration monitoring image includes a plurality of customized liquid level lines corresponding to the configuration monitoring module, and includes:

receiving liquid level configuration data input by the doctor end to the configuration monitoring module, wherein the liquid level configuration data comprises configuration liquid quantity;

A preset module image corresponding to the configuration monitoring module is called, a first scale line corresponding to the configuration liquid quantity in the preset module image is obtained, and a total liquid level line is generated according to the first scale line;

acquiring module attributes of the configuration monitoring module, wherein the module attributes comprise consumption attributes and addition attributes;

obtaining a plurality of sub liquid level lines in the preset module image according to the module attribute and the configuration liquid quantity, determining that the total liquid level line and the sub liquid level lines are custom liquid level lines, and updating the preset module image according to the custom liquid level lines to obtain a configuration monitoring image.

Optionally, in one possible implementation manner of the first aspect, obtaining a plurality of sub-liquid level lines in the preset module image according to the module attribute and the configuration liquid amount, determining the total liquid level line and the sub-liquid level lines as custom liquid level lines, and updating the preset module image according to the custom liquid level lines to obtain a configuration monitoring image includes:

determining that the configuration monitoring module of the consumption attribute is a first module, and the configuration monitoring module of the added attribute is a second module;

acquiring the monitoring quantity input by the doctor end to the first module or the second module, and acquiring a plurality of sub-liquid level lines in the preset module image according to the monitoring quantity and the configuration liquid quantity;

And determining the total liquid level line and the sub liquid level line as customized liquid level lines, and updating the preset module image according to the customized liquid level lines to obtain a configuration monitoring image.

Optionally, in one possible implementation manner of the first aspect, acquiring a monitoring number input by the doctor end to the first module or the second module, and obtaining a plurality of sub-level lines in the preset module image according to the monitoring number and the configuration liquid amount includes:

acquiring the monitoring quantity of the physician end for inputting the configuration liquid quantity of the first module, and obtaining a unit liquid quantity according to the ratio of the configuration liquid quantity to the monitoring quantity;

sequentially decrementing to obtain a plurality of second scale marks in the preset module image based on the configuration liquid amount and the unit liquid amount, and generating sub liquid level lines according to the second scale marks; or alternatively, the first and second heat exchangers may be,

obtaining a maximum liquid amount corresponding to the second module, and obtaining an idle liquid amount according to a difference value between the maximum liquid amount and the configuration liquid amount;

receiving the monitoring quantity of the physician end for inputting the idle liquid quantity, and obtaining a unit liquid quantity according to the ratio of the idle liquid quantity to the monitoring quantity;

And sequentially and progressively acquiring a plurality of second scale marks in the preset module image according to the configuration liquid quantity and the unit liquid quantity, and generating sub liquid level lines according to the second scale marks.

Optionally, in a possible implementation manner of the first aspect, receiving a warning level line input by the doctor end based on the configuration monitoring image, updating the configuration monitoring image according to the warning level line to obtain a customized monitoring image, including:

receiving a reminding request of the doctor end, calling the configuration monitoring image and sending the configuration monitoring image to the doctor end;

acquiring a warning liquid level line input by the doctor terminal based on the configuration monitoring image, and if the configuration monitoring module is a first module, acquiring a customized liquid level line which is positioned in the consumption opposite direction in the configuration monitoring image and is closest to the warning liquid level line as an adjustment liquid level line;

if the configuration monitoring module is a second module, acquiring a customized liquid level line which is positioned in the opposite direction of the increase and closest to the warning liquid level line in the configuration monitoring image as an adjustment liquid level line;

and moving the warning liquid level line to a position corresponding to the liquid level adjustment line to obtain a customized monitoring image.

Optionally, in one possible implementation manner of the first aspect, the invoking a liquid level monitoring policy monitors liquid level data of the monitoring twin model, and the obtaining monitoring data is sent to the doctor side, including:

analyzing the liquid level data to obtain reminding liquid amounts corresponding to the customized liquid level lines in the customized monitoring images corresponding to the liquid level monitoring modules;

acquiring current flow data corresponding to the liquid level monitoring module in real time based on flow monitoring equipment of the liquid level monitoring module, and acquiring current liquid quantity corresponding to the liquid level monitoring module according to the current flow data;

when the current liquid quantity is the same as the reminding liquid quantity, acquiring a customized liquid level line corresponding to the reminding liquid quantity in the customized monitoring image as a reminding liquid level line, and calling a preset pixel value to update the reminding liquid level line to obtain a real-time monitoring image;

if the prompt liquid level line is overlapped with the warning liquid level line, determining that the liquid level monitoring module is a warning module, and calling a warning pixel value to update module data in the customized monitoring image to obtain a warning monitoring image;

and generating monitoring data according to the real-time monitoring image and the warning monitoring image, and sending the monitoring data to the doctor.

In a second aspect of the embodiment of the present invention, there is provided a hemodialysis data collection and processing system based on a mobile terminal, including:

the request module is used for receiving a dialysis request of a patient end and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of the doctor end on the dialysis request;

the customization module is used for updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module;

the configuration module is used for updating the customized twin model based on the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor end to obtain a monitoring twin model, and the liquid level configuration data comprises brand new liquid level data and historical liquid level data;

and the monitoring module is used for invoking a liquid level monitoring strategy to monitor the liquid level data of the monitoring twin model, obtaining monitoring data and sending the monitoring data to the doctor.

The beneficial effects of the invention are as follows:

1. the invention can automatically monitor the dialysis process of the patient and timely remind medical staff through monitoring data. According to the invention, the virtual twin model corresponding to the patient end is firstly obtained, and then the patient module in the virtual twin model is updated according to the patient data, so that a doctor end can check corresponding patient data through the updated customized twin model, and the customized twin model is corresponding to the patient. The invention can obtain a monitoring twin model according to the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor end, so that the liquid level data during monitoring can be correspondingly configured according to the requirements of the doctor end, and then the liquid level data in the monitoring twin model can be correspondingly updated through the liquid volume data monitored by the flow monitoring equipment in real time, so that the dialysis process of a patient can be monitored through the monitoring data.

2. When the dynamic monitoring module is updated, the plurality of customized liquid level lines corresponding to the dynamic monitoring module are obtained according to different modes by combining different attributes of the dynamic monitoring module, wherein the attributes of the dynamic monitoring module comprise consumption attributes and addition attributes, so that liquid volume data monitored by the flow monitoring equipment in real time can be displayed through the obtained customized liquid level lines, a doctor side can check liquid level change data in the dialysis process of a corresponding patient, and the dialysis process of the patient is monitored. And the invention can also combine the warning liquid level line input by the doctor end to carry out corresponding warning reminding on the doctor end, when the liquid level data is overlapped with the warning liquid level line, the invention can generate warning monitoring images to remind the doctor end, thereby enabling medical staff to replace liquid medicine or clear waste liquid in time.

3. When the patient module is updated, the patient customization model is generated by combining the patient basic information and the patient medical record information, and the patient module is correspondingly updated through the patient customization model, so that a doctor terminal can intuitively check the patient data corresponding to the corresponding dialysis equipment, and correspondingly customize the dialysis data of the patient by combining the patient data.

Drawings

Fig. 1 is a schematic flow chart of a hemodialysis data collection and processing method based on a mobile terminal according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a hemodialysis data collection and processing system based on a mobile terminal according to an embodiment of the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, a schematic diagram of a hemodialysis data collection and processing method based on a mobile terminal according to an embodiment of the present invention is shown, where an execution body of the method shown in fig. 1 may be a software or hardware device. The execution bodies of the present application may include, but are not limited to, at least one of: user equipment, network equipment, etc. The user equipment may include, but is not limited to, computers, smart phones, personal digital assistants (Personal Digital Assistant, abbreviated as PDA), and the above-mentioned electronic devices. The network device may include, but is not limited to, a single network server, a server group of multiple network servers, or a cloud of a large number of computers or network servers based on cloud computing, where cloud computing is one of distributed computing, and a super virtual computer consisting of a group of loosely coupled computers. This embodiment is not limited thereto. The method comprises the steps S1 to S4, and specifically comprises the following steps:

S1, receiving a dialysis request of a patient end, and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of a doctor end on the dialysis request.

The patient end can be user equipment of a patient, and the doctor end can be a large display screen of an office computer or a medical station of medical staff.

The virtual twin model is composed of a dialysis module and a patient module, wherein the dialysis module is virtual twin corresponding to the dialysis equipment, and the patient module is virtual twin corresponding to the patient.

The dialysis module of the virtual twin model and the actual dialysis equipment are mutually corresponding, and the dialysis module comprises virtual twin parts corresponding to the actual equipment parts such as a container for containing dialysate, a waste liquid box, a physiological saline bottle, a blood pump, a dialyzer, a heparin pump, a pipeline and the like, and the virtual twin parts can be preset by a user.

In practice, there may be differences in dialysis equipment as the dialysis equipment manufacturer of the target hospital may be different. Therefore, the virtual twin model dialysis module can be built according to different types of dialysis equipment purchased by a hospital, and each type of dialysis equipment is provided with a corresponding dialysis module. These dialysis modules will be stored in a library of virtual twin models.

In order to monitor the dialysis process of a corresponding patient through the virtual twin model, the patient module is updated according to the patient data in the following steps, and the dialysis module is updated based on the dialysis data, so that the dialysis process of the corresponding patient can be monitored according to the updated virtual twin model, and specific updating steps are described in detail in the following steps and are not described in detail herein.

In some embodiments, step S1 may be implemented through steps S11 to S12, specifically as follows:

s11, receiving scanning information of the patient end on actual dialysis equipment, acquiring a dialysis request of the patient end according to the scanning information, and sending the dialysis request to the doctor end.

In some practical application scenarios, the dialysis device may display a two-dimensional code for the patient to scan, and after the patient scans the two-dimensional code, the patient may send a dialysis request from the patient end to the physician end.

S12, based on the determination information of the doctor side on the dialysis request, a virtual twin model corresponding to the actual dialysis equipment is obtained, the virtual twin model and the patient side are bound, and patient data corresponding to the patient side are obtained.

The dialysis request information can contain the dialysis equipment number of the patient scanning code, a virtual twin model corresponding to the dialysis equipment number can be obtained from a model library through the dialysis equipment number, and the virtual twin model is bound with the patient end after the determination of the doctor end.

In addition, after binding, the physician 'S side may also obtain patient data from the patient' S side for customizing the patient model in step S2.

S2, updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module.

The method updates the patient module in the virtual twin model according to the patient data, and then sends the obtained customized twin model to a doctor end for customizing the data in the subsequent dialysis module.

Specifically, the customized twin model obtained through step S21 to step S22 may be sent to the physician end as follows:

s21, analyzing the patient data to obtain basic patient information and patient condition information, and generating a patient customized model according to the basic patient information and the patient medical record information.

The patient basic information may be name, age, sex, etc., and the condition information may be a name of a disease suffered by the patient, for example: acute renal failure, chronic renal failure, ketoacidosis, etc.

In some embodiments, the patient-customized model may be generated by:

first, a plurality of age groups, for example, 1-15 years old, 16-35 years old, 36-59 years old and over 60 years old, can be preset, and a total of 8 initial models of patients with male sex and female sex are set in each age group. An area in which text can be displayed is reserved in each patient initial model.

When the patient data is acquired, the corresponding initial patient model is selected according to the basic patient information, and then the medical record information of the patient is displayed in a text area in a text form, so that a customized patient model is generated.

S22, updating the patient module in the virtual twin model based on the patient customized model, and sending the obtained customized twin module to the doctor.

In practical application, a filling area for filling the patient customized model can be preset in the patient module, and when the patient module is updated according to the patient customized model, the patient customized model can be filled into the filling area.

By the method, the doctor end can intuitively check the patient data corresponding to the corresponding dialysis equipment, so that the doctor end can customize the corresponding dialysis data in the dialysis module by combining the customized twin model later.

And S3, updating the customized twin model based on the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor end to obtain a monitoring twin model, wherein the liquid level configuration data comprises brand new liquid level data and historical liquid level data.

The dynamic monitoring module is composed of a component twin body which needs to store solution in the virtual twin model and comprises a fresh dialysis solution storage tank, a physiological saline storage bottle and a component twin body corresponding to the waste liquid storage tank.

The containers for storing the liquid medicine can also be used in different amounts according to different treatment schemes of patients, and the scheme can update the corresponding dynamic monitoring modules according to liquid data configured by a doctor. The brand-new liquid level data refers to liquid data which is configured brand-new at the doctor side, such as dosage data corresponding to physiological saline, and the historical liquid level data refers to historical liquid data configured at the doctor side, such as current liquid amount data of dialysate and waste liquid.

It can be appreciated that, because the physiological saline needs to be replaced before each use, the doctor can configure brand new liquid level data for the physiological saline. The fresh dialysate needs to be replaced in time after being used, but in order to save fresh dialysate materials, in practical situations, a patient may need to use up the dialysate in the fresh dialysate storage tank before replacement. Therefore, the liquid level data at the end of the dialysis of the previous patient can be used as the historical liquid level data of the fresh dialysis liquid required by the current patient. The waste liquid storage box can be replaced after being full, so that the waste liquid data of the last patient after dialysis is finished can be used as the history liquid level data corresponding to the waste liquid storage box.

In some embodiments, step S3 may be implemented through steps S31 to S33, specifically as follows:

s31, receiving trigger information of the doctor end on the corresponding dynamic monitoring module in the dialysis module, and determining the corresponding dynamic monitoring module to be a configuration monitoring module according to the trigger information.

In practical application, the trigger information may be click information, and the corresponding dynamic monitoring module may be selected as the configuration monitoring module according to the click information of the doctor end.

S32, acquiring liquid level configuration data input by the doctor end to the configuration monitoring module, and generating a configuration monitoring image according to the module attribute of the configuration monitoring module and the liquid level configuration data, wherein the configuration monitoring image comprises a plurality of customized liquid level lines corresponding to the configuration monitoring module.

It can be understood that different dynamic monitoring modules have different attributes, liquid data corresponding to some dynamic monitoring modules are gradually reduced, such as physiological liquid medicine and dialysate, and liquid data corresponding to some dynamic monitoring modules are gradually increased, such as waste liquid, so that when a configuration monitoring image is generated, the configuration monitoring image can be generated through the module attributes and the liquid level configuration data, and the monitored liquid level data can be updated through the configuration monitoring image in the follow-up process.

When the monitored liquid level data is updated through configuration of the monitoring image, the scheme displays the change condition of the liquid level data by customizing the liquid level line.

Specifically, in the dialysis process, the liquid medicine or waste liquid in the container can be reduced or increased, and when the liquid level is lowered or raised to a certain customized liquid level line, the corresponding customized liquid level line can be highlighted, so that the liquid level data can be updated correspondingly.

In some embodiments, step S32 may be implemented from step S321 to step S324, specifically as follows:

s321, receiving liquid level configuration data input by the doctor end to the configuration monitoring module, wherein the liquid level configuration data comprises configuration liquid quantity.

The physician's end inputs fluid level configuration data into the configuration monitoring module, which may be the patient's fluid usage, the current volume of dialysate, or the current volume of waste fluid.

S322, a preset module image corresponding to the configuration monitoring module is called, a first scale line corresponding to the configuration liquid quantity in the preset module image is obtained, and a total liquid level line is generated according to the first scale line.

In practical applications, the preset module image may correspond to the configuration monitoring module, for example, if the configuration monitoring module corresponds to a dialysate container, the preset module image may correspond to the dialysate container.

The first scale line is scale data corresponding to the liquid level height, for example, if the configuration liquid amount is 10ml, the first scale line corresponding to 10ml in the preset module image can be obtained first when the total liquid level line is generated, and then the total liquid level line is generated according to the first scale line.

In practical application, the graduation marks may be preset by a worker.

S323, obtaining module attributes of the configuration monitoring module, wherein the module attributes comprise consumption attributes and addition attributes.

The liquid medicine containers corresponding to different configuration monitoring modules can have different attributes, and it can be understood that the volumes of liquid medicine in some liquid medicine containers can be continuously reduced, for example, a physiological saline bottle and a fresh dialysis liquid box, and the liquid medicine in the liquid medicine containers can be continuously consumed along with the dialysis history, so that the module attributes corresponding to the configuration monitoring modules can be consumption attributes. Some liquid medicine containers have liquid medicine in the volume which is continuously increased, for example, a waste liquid tank, fresh dialysate and the like are changed into waste liquid after use and are injected into the waste liquid tank, and the liquid medicine in the liquid medicine containers is continuously increased along with the dialysis time, so that the module attribute corresponding to the configuration monitoring module can be an increasing attribute.

S324, obtaining a plurality of sub liquid level lines in the preset module image according to the module attribute and the configuration liquid quantity, determining the total liquid level line and the sub liquid level lines as customized liquid level lines, and updating the preset module image according to the customized liquid level lines to obtain a configuration monitoring image.

It can be understood that, because the module attributes are different, when generating the sub-liquid level lines, the corresponding sub-liquid level lines can be generated by the module attributes and the configuration liquid amount, then the total liquid level line and the sub-liquid level line are determined to be custom liquid level lines, and the preset module image is updated according to the custom liquid level lines to obtain the configuration monitoring image.

In some embodiments, step S324 may be implemented through steps S3241 to S3242, as follows:

s3241, determining the configuration monitoring module of the consumption attribute as a first module and the configuration monitoring module of the added attribute as a second module.

In practical application, the first module may be a configuration monitoring module corresponding to physiological saline and dialysate, and the second module may be a configuration monitoring module corresponding to waste liquid.

S3242, obtaining the monitoring quantity input by the doctor end to the first module or the second module, and obtaining a plurality of sub-liquid level lines in the preset module image according to the monitoring quantity and the configuration liquid quantity.

The monitoring quantity refers to the monitoring number of liquid data divided by the first module or the second module.

In some embodiments, the plurality of sub-level lines in the preset module image may be derived from the monitored quantity and the configured liquid quantity by:

s32421, acquiring the monitoring quantity of the configuration liquid quantity input of the doctor end to the first module, and obtaining the unit liquid quantity according to the ratio of the configuration liquid quantity to the monitoring quantity.

For example, in dialysis, it is necessary to use 500mL of physiological saline, that is, 500mL of the liquid is disposed, and 10 is monitored, and 50mL of the unit liquid is measured, so that the unit liquid is obtained, and the sub-liquid level lines corresponding to the respective unit liquid are obtained later based on the unit liquid.

S32422, a plurality of second scale marks in the preset module image are obtained in a descending mode in sequence based on the configuration liquid amount and the unit liquid amount, and sub liquid level lines are generated according to the second scale marks.

When the monitoring module is configured as a consumption attribute, the sub-level line may be generated by:

and sequentially subtracting the configured liquid amount and the unit liquid amount, then obtaining a second scale mark corresponding to the liquid amount after each subtraction, and finally generating a corresponding sub-liquid level line according to the second scale mark.

For example, if the configuration liquid amount is 500mL and the unit liquid amount is 50mL, the first subtraction is followed by 450mL, at this time, a corresponding sub-liquid level line can be generated by obtaining a second scale line corresponding to 450mL, then the unit liquid amount is subtracted continuously according to 450mL, a corresponding sub-liquid level line is generated by obtaining a second scale line corresponding to 400mL, and so on, a plurality of sub-liquid level lines can be obtained.

S32423, or, obtaining the maximum liquid amount corresponding to the second module, and obtaining the idle liquid amount according to the difference value between the maximum liquid amount and the configuration liquid amount.

When the configuration monitoring module is of an added attribute, the configuration monitoring module is used for monitoring the idle liquid quantity when monitoring the liquid level data, wherein the idle liquid quantity is the waste liquid quantity which can be contained in the waste liquid barrel corresponding to the second module.

S32424, receiving the monitoring quantity of the physician end input to the idle liquid quantity, and obtaining the unit liquid quantity according to the ratio of the idle liquid quantity to the monitoring quantity.

When the unit liquid quantity corresponding to the increased attribute is obtained, the unit liquid quantity is obtained according to the idle liquid quantity and the monitoring quantity.

For example, in the dialysis process, the capacity of a waste liquid barrel matched with dialysis equipment is 10L, 3L of waste liquid is added in the barrel after the last dialysis use, at this time, 7L of idle liquid volume is actually remained in the barrel, and when the monitoring quantity input by a doctor end is 7, the unit liquid volume is 1L.

And S32425, sequentially and progressively acquiring a plurality of second scale marks in the preset module image according to the configuration liquid amount and the unit liquid amount, and generating sub liquid level lines according to the second scale marks.

When the monitoring module is configured to add an attribute, the sub-level line may be generated by:

and sequentially adding the configured liquid amount and the unit liquid amount, then obtaining a second scale mark corresponding to the liquid amount after each addition, and finally generating a corresponding sub-liquid level line according to the second scale mark.

For example, if the configuration liquid amount is 3L and the unit liquid amount is 1L, the first addition is followed by 4L, at this time, a corresponding sub-level line can be generated by obtaining a second scale line corresponding to 4L, then the unit liquid amount is continuously added according to 4L, a corresponding sub-level line can be generated by obtaining a second scale line corresponding to 5L, and so on, a plurality of sub-level lines can be obtained.

S3243, determining the total liquid level line and the sub liquid level line as customized liquid level lines, and updating the preset module image according to the customized liquid level lines to obtain a configuration monitoring image.

The customized liquid level line comprises a total liquid level line and a sub liquid level line, and the change of liquid level data in the dialysis process can be correspondingly displayed in the follow-up process through configuration of the monitoring image.

S33, receiving a warning liquid level line input by the doctor end based on the configuration monitoring image, and updating the configuration monitoring image according to the warning liquid level line to obtain a customized monitoring image.

It can be understood that the warning liquid level line is arranged to correspondingly remind the doctor end according to the requirements of the doctor end, so that the doctor end can timely replace liquid medicine or clear waste liquid.

In some embodiments, step S33 may be implemented through steps S331 to S334, specifically as follows:

s331, receiving a reminding request of the doctor terminal, calling the configuration monitoring image and sending the configuration monitoring image to the doctor terminal.

It can be appreciated that sending the configuration monitoring image to the doctor end can enable the doctor end to input the warning liquid level line correspondingly according to the configuration monitoring image.

S332, acquiring a warning liquid level line input by the doctor end based on the configuration monitoring image, and if the configuration monitoring module is a first module, acquiring a customized liquid level line which is positioned in the opposite consumption direction in the configuration monitoring image and is closest to the warning liquid level line as an adjustment liquid level line.

Because the warning liquid level line is set up by the doctor end, under some circumstances, warning liquid level line and sub-liquid level line are not necessarily the complete coincidence, consequently after obtaining the warning liquid level line, this scheme still can remove the warning liquid level line, makes it correspond to corresponding customization liquid level line to can carry out corresponding warning through corresponding customization liquid level line in the follow-up.

It can be appreciated that if the configuration monitoring module is the first module, the liquid amount is gradually consumed, and when the adjustment liquid level line is determined, the customized liquid level line which is located in the opposite direction of consumption and is closest to the warning liquid level line can be determined as the adjustment liquid level line, so that the doctor can be given more sufficient time to perform corresponding nursing treatment.

Wherein if the consumption direction is a downward direction, the opposite direction of consumption may be an upward direction.

S333, if the configuration monitoring module is a second module, acquiring a customized liquid level line which is located in the opposite direction of the increase of the configuration monitoring image and is closest to the warning liquid level line as an adjustment liquid level line.

If the configuration monitoring module is a second module, the liquid amount is gradually increased, and when the adjustment liquid level line is determined, the customized liquid level line which is positioned in the opposite direction of the increase and is closest to the warning liquid level line can be determined as the adjustment liquid level line, so that a doctor can be given more sufficient time to clean the waste liquid.

Wherein if the increasing direction is an upward direction, the increasing reverse direction may be a downward direction.

And S334, moving the warning liquid level line to a position corresponding to the adjustment liquid level line to obtain a customized monitoring image.

When the adjusting direction and the adjusting position of the warning liquid level line are determined, the warning liquid level line can be adjusted to the corresponding position to obtain the customized monitoring image.

And S34, filling the customized monitoring image into an image slot corresponding to the configuration monitoring module to obtain a liquid level monitoring module, and updating the customized twin model according to the liquid level monitoring module to obtain a monitoring twin model.

In some embodiments, when the custom monitoring image is filled into the image slot corresponding to the configuration monitoring module, the center point of the custom monitoring image may be positioned according to the center point of the image slot, and the custom monitoring image may be filled into the image slot.

By the method, corresponding liquid level line data can be customized according to user requirements, so that the dialysis process of a patient can be monitored through the liquid level line data later.

And S4, a liquid level monitoring strategy is called to monitor the liquid level data of the monitoring twin model, and the obtained monitoring data is sent to the doctor side.

After the monitoring twin model is obtained, the monitoring twin model is updated according to the liquid level data acquired in real time, so that monitoring data are obtained and sent to a doctor side, and the doctor side can monitor the dialysis process of a patient through the monitoring data.

In some embodiments, step S4 may be implemented through steps S41 to S45, specifically as follows:

s41, analyzing the liquid level data to obtain reminding liquid amounts corresponding to the customized liquid level lines in the customized monitoring images corresponding to the liquid level monitoring modules.

In practical application, the reminding liquid amount corresponding to each customized liquid level line can be obtained through scale data corresponding to the customized liquid level line, for example, if the scale data corresponding to the customized liquid level line is a scale corresponding to 10L, the reminding liquid amount corresponding to the customized liquid level line is 10L.

S42, acquiring current flow data corresponding to the liquid level monitoring module in real time based on flow monitoring equipment of the liquid level monitoring module, and acquiring current liquid quantity corresponding to the liquid level monitoring module according to the current flow data.

In practical application, when the current liquid amount is obtained, the current liquid amount can be obtained according to the product of the current flow data and time.

And S43, when the current liquid quantity is the same as the reminding liquid quantity, acquiring a customized liquid level line corresponding to the reminding liquid quantity in the customized monitoring image as a reminding liquid level line, and calling a preset pixel value to update the reminding liquid level line to obtain a real-time monitoring image.

The preset pixel value may be a pixel value corresponding to a color such as blue. The liquid level data in the dialysis process of the patient can be displayed to the doctor end through the real-time monitoring image, so that medical staff can monitor the dialysis process of the patient.

S44, if the prompt liquid level line is overlapped with the warning liquid level line, determining that the liquid level monitoring module is a warning module, and calling a warning pixel value to update module data in the customized monitoring image to obtain a warning monitoring image.

The warning pixel value may be different from the preset pixel value, for example, the warning pixel value may be a pixel value corresponding to red.

S45, generating monitoring data according to the real-time monitoring image and the warning monitoring image, and sending the monitoring data to the doctor.

Through the mode, the dialysis process of the patient can be monitored, and medical staff can be timely reminded of carrying out corresponding nursing treatment on the patient.

Referring to fig. 2, a schematic structural diagram of a hemodialysis data collection and processing system based on a mobile terminal according to an embodiment of the present invention includes:

the request module is used for receiving a dialysis request of a patient end and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of the doctor end on the dialysis request;

The customization module is used for updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module;

the configuration module is used for updating the customized twin model based on the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor end to obtain a monitoring twin model, and the liquid level configuration data comprises brand new liquid level data and historical liquid level data;

and the monitoring module is used for invoking a liquid level monitoring strategy to monitor the liquid level data of the monitoring twin model, obtaining monitoring data and sending the monitoring data to the doctor.

The apparatus of the embodiment shown in fig. 2 may be correspondingly used to perform the steps in the embodiment of the method shown in fig. 1, and the implementation principle and technical effects are similar, and are not repeated here.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same. Although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments may be modified or some or all of the technical features may be replaced with equivalents. Such modifications and substitutions do not depart from the spirit of the invention.

Claims (10)

1. The hemodialysis data acquisition and processing method based on the mobile terminal is characterized by comprising the following steps of:

receiving a dialysis request of a patient end, and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of a doctor end on the dialysis request;

updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module;

updating the customized twin model based on liquid level configuration data of a dynamic monitoring module in the dialysis module by the doctor side to obtain a monitoring twin model, wherein the liquid level configuration data comprises brand new liquid level data and historical liquid level data;

and calling a liquid level monitoring strategy to monitor the liquid level data of the monitoring twin model, and sending the obtained monitoring data to the doctor.

2. The method of claim 1, wherein the step of determining the position of the substrate comprises,

receiving a dialysis request of a patient end, and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of a doctor end on the dialysis request, wherein the method comprises the following steps:

receiving scanning information of the patient end on actual dialysis equipment, acquiring a dialysis request of the patient end according to the scanning information, and sending the dialysis request to the doctor end;

Based on the determination information of the doctor end on the dialysis request, a virtual twin model corresponding to the actual dialysis equipment is obtained, the virtual twin model is bound with the patient end, and patient data corresponding to the patient end is obtained.

3. The method of claim 1, wherein the step of determining the position of the substrate comprises,

updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module and comprises the following components:

analyzing the patient data to obtain basic patient information and patient condition information, and generating a patient customized model according to the basic patient information and the patient medical record information;

updating the patient module in the virtual twin model based on the patient customized model to obtain a customized twin module, and sending the customized twin module to the doctor.

4. The method of claim 1, wherein the step of determining the position of the substrate comprises,

based on the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor side, updating the customized twin model to obtain a monitoring twin model, wherein the liquid level configuration data comprises brand new liquid level data and historical liquid level data, and the method comprises the following steps:

Receiving trigger information of the doctor end on the corresponding dynamic monitoring module in the dialysis module, and determining the corresponding dynamic monitoring module as a configuration monitoring module according to the trigger information;

acquiring liquid level configuration data input by the doctor end to the configuration monitoring module, and generating a configuration monitoring image according to the module attribute of the configuration monitoring module and the liquid level configuration data, wherein the configuration monitoring image comprises a plurality of customized liquid level lines corresponding to the configuration monitoring module;

receiving an alarm liquid level line input by the doctor terminal based on the configuration monitoring image, and updating the configuration monitoring image according to the alarm liquid level line to obtain a customized monitoring image;

filling the customized monitoring image into an image slot corresponding to the configuration monitoring module to obtain a liquid level monitoring module, and updating the customized twin model according to the liquid level monitoring module to obtain a monitoring twin model.

5. The method of claim 4, wherein the step of determining the position of the first electrode is performed,

acquiring liquid level configuration data input by the doctor end to the configuration monitoring module, and generating a configuration monitoring image according to the module attribute of the configuration monitoring module and the liquid level configuration data, wherein the configuration monitoring image comprises a plurality of customized liquid level lines corresponding to the configuration monitoring module, and the configuration monitoring image comprises the following steps:

Receiving liquid level configuration data input by the doctor end to the configuration monitoring module, wherein the liquid level configuration data comprises configuration liquid quantity;

a preset module image corresponding to the configuration monitoring module is called, a first scale line corresponding to the configuration liquid quantity in the preset module image is obtained, and a total liquid level line is generated according to the first scale line;

acquiring module attributes of the configuration monitoring module, wherein the module attributes comprise consumption attributes and addition attributes;

obtaining a plurality of sub liquid level lines in the preset module image according to the module attribute and the configuration liquid quantity, determining that the total liquid level line and the sub liquid level lines are custom liquid level lines, and updating the preset module image according to the custom liquid level lines to obtain a configuration monitoring image.

6. The method of claim 5, wherein the step of determining the position of the probe is performed,

obtaining a plurality of sub-liquid level lines in the preset module image according to the module attribute and the configuration liquid amount, determining that the total liquid level line and the sub-liquid level lines are custom liquid level lines, and updating the preset module image according to the custom liquid level lines to obtain a configuration monitoring image, wherein the method comprises the following steps:

determining that the configuration monitoring module of the consumption attribute is a first module, and the configuration monitoring module of the added attribute is a second module;

Acquiring the monitoring quantity input by the doctor end to the first module or the second module, and acquiring a plurality of sub-liquid level lines in the preset module image according to the monitoring quantity and the configuration liquid quantity;

and determining the total liquid level line and the sub liquid level line as customized liquid level lines, and updating the preset module image according to the customized liquid level lines to obtain a configuration monitoring image.

7. The method of claim 6, wherein the step of providing the first layer comprises,

acquiring the monitoring quantity input by the doctor end to the first module or the second module, and acquiring a plurality of sub-liquid level lines in the preset module image according to the monitoring quantity and the configuration liquid quantity, wherein the monitoring quantity comprises:

acquiring the monitoring quantity of the physician end for inputting the configuration liquid quantity of the first module, and obtaining a unit liquid quantity according to the ratio of the configuration liquid quantity to the monitoring quantity;

sequentially decrementing to obtain a plurality of second scale marks in the preset module image based on the configuration liquid amount and the unit liquid amount, and generating sub liquid level lines according to the second scale marks; or alternatively, the first and second heat exchangers may be,

obtaining a maximum liquid amount corresponding to the second module, and obtaining an idle liquid amount according to a difference value between the maximum liquid amount and the configuration liquid amount;

Receiving the monitoring quantity of the physician end for inputting the idle liquid quantity, and obtaining a unit liquid quantity according to the ratio of the idle liquid quantity to the monitoring quantity;

and sequentially and progressively acquiring a plurality of second scale marks in the preset module image according to the configuration liquid quantity and the unit liquid quantity, and generating sub liquid level lines according to the second scale marks.

8. The method of claim 6, wherein the step of providing the first layer comprises,

receiving an alarm liquid level line input by the doctor terminal based on the configuration monitoring image, updating the configuration monitoring image according to the alarm liquid level line to obtain a customized monitoring image, and comprising the following steps:

receiving a reminding request of the doctor end, calling the configuration monitoring image and sending the configuration monitoring image to the doctor end;

acquiring a warning liquid level line input by the doctor terminal based on the configuration monitoring image, and if the configuration monitoring module is a first module, acquiring a customized liquid level line which is positioned in the consumption opposite direction in the configuration monitoring image and is closest to the warning liquid level line as an adjustment liquid level line;

if the configuration monitoring module is a second module, acquiring a customized liquid level line which is positioned in the opposite direction of the increase and closest to the warning liquid level line in the configuration monitoring image as an adjustment liquid level line;

And moving the warning liquid level line to a position corresponding to the liquid level adjustment line to obtain a customized monitoring image.

9. The method of claim 8, wherein the step of determining the position of the first electrode is performed,

the liquid level monitoring strategy is called to monitor the liquid level data of the monitoring twin model, the obtained monitoring data is sent to the doctor side, and the method comprises the following steps:

analyzing the liquid level data to obtain reminding liquid amounts corresponding to the customized liquid level lines in the customized monitoring images corresponding to the liquid level monitoring modules;

acquiring current flow data corresponding to the liquid level monitoring module in real time based on flow monitoring equipment of the liquid level monitoring module, and acquiring current liquid quantity corresponding to the liquid level monitoring module according to the current flow data;

when the current liquid quantity is the same as the reminding liquid quantity, acquiring a customized liquid level line corresponding to the reminding liquid quantity in the customized monitoring image as a reminding liquid level line, and calling a preset pixel value to update the reminding liquid level line to obtain a real-time monitoring image;

if the prompt liquid level line is overlapped with the warning liquid level line, determining that the liquid level monitoring module is a warning module, and calling a warning pixel value to update module data in the customized monitoring image to obtain a warning monitoring image;

And generating monitoring data according to the real-time monitoring image and the warning monitoring image, and sending the monitoring data to the doctor.

10. Hemodialysis data acquisition and processing system based on mobile terminal, characterized by comprising:

the request module is used for receiving a dialysis request of a patient end and acquiring a virtual twin model and patient data corresponding to the patient end based on determination information of the doctor end on the dialysis request;

the customization module is used for updating the virtual twin model according to the patient data to obtain a customized twin model, and sending the customized twin model to the doctor, wherein the customized twin model comprises a dialysis module and a patient module;

the configuration module is used for updating the customized twin model based on the liquid level configuration data of the dynamic monitoring module in the dialysis module by the doctor end to obtain a monitoring twin model, and the liquid level configuration data comprises brand new liquid level data and historical liquid level data;

and the monitoring module is used for invoking a liquid level monitoring strategy to monitor the liquid level data of the monitoring twin model, obtaining monitoring data and sending the monitoring data to the doctor.