CN117524442A - Hemodialysis information management method and system based on doctor-side interaction - Google Patents

Abstract

The invention discloses a hemodialysis information management method and system based on doctor-side interaction, wherein the method comprises the following steps: generating a current dialysis workflow area, wherein the current dialysis workflow area comprises each working time point and each corresponding working item; determining work handover contents and handover doctor ends based on interaction of the current doctor ends to the current dialysis workflow area and handover personnel determination requests; establishing a first working time axis corresponding to a current doctor end in a current dialysis workflow area based on the starting working time of the current doctor end and the working handover content; updating the current dialysis workflow area according to the first work time axis and the work handover content to obtain a handover dialysis workflow area; and sending the handover dialysis workflow area to a handover doctor end, and establishing a second working time axis corresponding to the handover doctor end. The invention at least improves the work handover efficiency and the information accuracy of the work handover.

Description

Hemodialysis information management method and system based on doctor-side interaction

Technical Field

The invention relates to the technical field of data processing, in particular to a hemodialysis information management method and system based on doctor-side interaction.

Background

Hemodialysis (hemomodialysis), clinically means that some waste in the blood is removed through a semi-permeable membrane. Hemodialysis is one of the safer, easier and widely used blood purification methods. Dialysis refers to the movement of solutes across a semipermeable membrane from a high concentration solution to a low concentration. Hemodialysis involves movement of solutes and movement of water, i.e., the blood and dialysate are subjected to mass exchange in a dialyzer (artificial kidney) by semi-permeable membrane contact and concentration gradient, so that metabolic waste and excessive electrolytes in the blood move toward the dialysate, and calcium ions, bases, etc. in the dialysate move toward the blood. If the mixed solution of albumin and urea is put into a dialyzer, the outside of the tube is soaked by water, at the moment, the urea in the tube of the dialyzer can move to the water outside the tube through the artificial kidney membrane hole, and the albumin molecules are larger and cannot pass through the membrane hole. This phenomenon of mass movement through which small molecular substances pass but large molecular substances cannot pass through the semipermeable membrane is called dispersion. The clinical method of separating and purifying blood by using dispersion phenomenon is the basic principle of hemodialysis.

The inventor finds that the dialysis work comprises a corresponding work flow in the research process, the work flow comprises each time point and work items corresponding to each time point, when a doctor performs the dialysis work, the doctor can execute the corresponding work items according to each time point in the work flow, and various emergency conditions possibly occur in a hospital, so that the doctor can be required to process various emergency conditions preferentially to perform the corresponding dialysis work delivery, but the existing work delivery mode often adopts a oral mode, and the oral mode can have the problems of missing information and lower work delivery efficiency.

Disclosure of Invention

In view of the foregoing, the present invention has been made to provide a hemodialysis information management method and system based on doctor-side interaction that overcomes or at least partially solves the foregoing problems.

According to one aspect of the present invention, there is provided a hemodialysis information management method based on doctor-side interaction, including the steps of:

generating a current dialysis workflow area corresponding to a current doctor end, wherein the current dialysis workflow area comprises working time points which are arranged in time sequence along a first direction and working items which are arranged along a second direction and respectively correspond to the working time points;

Determining work handover contents and handover doctor terminals corresponding to work handover time based on the interaction of the current doctor terminal to the current dialysis workflow area and the initiated handover personnel determination request;

establishing a first work time axis extending along the first direction corresponding to the current doctor end in the current dialysis workflow area based on the starting work time and work handover content of the current doctor end;

updating the current dialysis workflow area according to the first working time axis and the working handover content to obtain a handover dialysis workflow area;

the handover dialysis workflow area is sent to the handover doctor end, and a second work time axis corresponding to the handover doctor end and extending along the first direction is established in the handover dialysis workflow area based on the work handover time.

Optionally, in the method according to the present invention, generating a current dialysis workflow area corresponding to a current doctor side, the current dialysis workflow area including work time points arranged in time sequence along a first direction and work items respectively corresponding to the work time points arranged along a second direction, including:

Generating a current dialysis workflow area corresponding to a current doctor end based on the digital twin space;

responding to interaction of a management end on the dialysis workflow area, and establishing each working time point arranged in time sequence along a first direction and each working item respectively corresponding to each working time point arranged along a second direction in the current dialysis workflow area;

the management end selects the current doctor end according to the called preset doctor end list, and distributes the current dialysis workflow to the current doctor end.

Optionally, in the method according to the present invention, determining the task delivery content and the delivery doctor end corresponding to the task delivery time based on the interaction of the current doctor end with the current dialysis workflow area and the initiated delivery person determining request includes:

the current doctor side invokes a work handover content selection line, and selects the current dialysis workflow area based on the work handover content selection line to obtain work handover content corresponding to the work handover time;

and sending other dialysis workflow areas respectively corresponding to the other doctor ends to the current doctor end in response to the determination request of the handover personnel of the current doctor end, wherein the current doctor end determines one of the other doctor ends as the handover doctor end based on the other dialysis workflow areas respectively corresponding to the other doctor ends.

Optionally, in the method according to the present invention, the determining, by the current doctor end, one of the other doctor ends as the handover doctor end based on the other dialysis workflow area to which the other doctor ends respectively correspond, includes:

determining each working time point included in the dialysis workflow area according to other dialysis workflow areas corresponding to other doctor ends respectively;

judging whether an overlapping condition exists between each working time point included in the work handover content and each working time point included in other dialysis workflow areas according to the comparison of the two working time points;

and if no overlapping condition exists, determining the corresponding other doctor end as the handover doctor end.

Optionally, in the method according to the invention, each work item within the current dialysis workflow zone is changed from an incomplete state to a completed state in response to an interaction of the current doctor end with the work item;

the current doctor side invokes a work handover content selection line, and interacts with the current dialysis workflow area based on the work handover content selection line, and selects the work handover content, including:

determining a target working time point in the current dialysis workflow zone that is proximate thereto based on the working handover time;

Determining all work items in unfinished states corresponding to the target working time point;

determining all work items in unfinished states corresponding to the target working time point and all work items corresponding to other working time points after the target working time point as the work handover content;

and the current doctor terminal invokes a work handover content selection line, and interacts with the current dialysis workflow area based on the work handover dividing line to select the work handover content.

Optionally, in the method according to the present invention, in response to interaction of the current doctor end with each work item within the current dialysis workflow zone, changing each work item from an incomplete state to a completed state comprises:

responding to interaction of the current doctor end on each work item in a current dialysis work flow area, uploading each dialysis data corresponding to each work item to the current dialysis work flow area, and changing each work item from an incomplete state to a completed state;

establishing a link relation between each work item and each dialysis data corresponding to each work item respectively;

And calling and displaying each piece of dialysis data with a link relation with each work item based on interaction of each work item in the current dialysis work flow area.

Optionally, in the method according to the present invention, establishing a first work time axis extending in the first direction corresponding to the current doctor end in the current dialysis workflow area based on the start work time of the current doctor end and the work handover content includes:

determining a first working time point in all working time points in the current dialysis workflow area as an initial working time of the current doctor end, and taking the initial working time as a first time point;

if at least one work item in an unfinished state exists in each work item corresponding to the target work time point, taking the work time point positioned before the target work time point as a second time point;

if the work items corresponding to the target working time point do not exist in the work items in the unfinished state, taking the target working time point as a second time point;

and taking the first time point as a starting point and the second time point as an ending point, establishing a first working time axis which corresponds to the current doctor end and extends along a first direction in the current dialysis workflow area, wherein a first end part of the first working time axis and the first time point are positioned at the same horizontal position, and a second end part of the first working time axis and the second time point are positioned at the same horizontal position.

Optionally, in the method according to the present invention, when the second time point is a working time point located before the target working time point, updating the current dialysis workflow area based on the first working time axis and the working handover content to obtain a handover dialysis workflow area, including:

generating a transitional working time shaft corresponding to the target working time point and extending along the first direction, wherein the end part of the transitional working time shaft is connected with the first working time shaft;

sequentially carrying out primary region division and secondary region division on the current dialysis workflow region to obtain a handover dialysis workflow region;

the method comprises the steps that a current dialysis workflow area is divided into areas based on a first special-shaped area frame to obtain a completed work area, wherein the completed work area comprises a first work time axis, a second time point and all work items which are in a completed state and correspond to all work time points located before the second time point, and all work items which are in a completed state and correspond to a target work time point;

dividing the dialysis workflow area into secondary areas based on a second special-shaped area frame to obtain a handover work area, wherein the handover work area comprises all work items in unfinished states corresponding to a target work time point and all work items respectively corresponding to all work time points located behind the target work time point;

Or,

when the second time point is the target working time point, updating the current dialysis workflow area based on the first working time axis and the working handover content to obtain a handover dialysis workflow area, including:

sequentially carrying out primary region division and secondary region division on the current dialysis workflow region to obtain a handover dialysis workflow region;

performing primary region division on the current dialysis workflow region based on a first non-special-shaped region frame to obtain a completed work region, wherein the completed work region comprises work items corresponding to a first work time axis and a target work time point;

and carrying out secondary region division on the dialysis workflow region based on a second non-special-shaped region frame to obtain a handover working region, wherein the handover working region comprises all working items respectively corresponding to all working time points positioned behind a target working time point.

Optionally, in the method according to the present invention, sending the handover dialysis workflow area to the handover doctor end, and establishing a second work time axis corresponding to the handover doctor end and extending in the first direction in the handover dialysis workflow area based on a work handover time, including:

Sending the handover dialysis workflow area to the handover doctor end, responding to the reception of the handover dialysis workflow area by the handover doctor end, initiating a second work time axis customization request for the handover doctor end, and selecting a customization form and a customization color in a preset customization column according to the second work time axis customization request by the handover doctor end;

and in response to the selection of the custom form and custom color by the handover doctor, establishing a second work time axis extending along the first direction in the handover dialysis workflow area, wherein the second work time axis is connected with the end part of the first work time axis.

According to still another aspect of the present invention, there is provided a hemodialysis information management system based on doctor-side interaction, including:

a generation module configured to generate a current dialysis workflow area corresponding to a current doctor end, the current dialysis workflow area including work time points arranged in time sequence along a first direction and work items respectively corresponding to the work time points arranged along a second direction;

a work handover information determining module configured to determine work handover contents and handover doctor terminals corresponding to a work handover time based on interaction of the current doctor terminal with the current dialysis workflow area and an initiated handover person determining request;

A first work time axis creation module configured to create a first work time axis extending in the first direction corresponding to the current doctor end in the current dialysis workflow area based on a start work time of the current doctor end and a work handover content;

the updating module is configured to update the current dialysis workflow area according to the first working time axis and the working handover content to obtain a handover dialysis workflow area;

a second work time axis creation module configured to send the handover dialysis workflow area to the handover doctor end and create a second work time axis extending in the first direction corresponding to the handover doctor end in the handover dialysis workflow area based on a work handover time.

According to the scheme of the invention, the working time point and the corresponding working point of the current doctor end can be clearly known by generating the current dialysis workflow area corresponding to the current doctor end, in the working handover process, the current doctor end can determine the corresponding working handover content and the handover doctor end based on the current dialysis workflow area, and generate the first working time axis corresponding to the current doctor end, and update the current dialysis workflow area based on the first working time axis and the working handover content, so that the handover dialysis workflow area sent to the handover doctor end is obtained, and the second working time axis corresponding to the handover doctor end is established, thereby realizing the on-line working communication process, and improving the working handover efficiency and the working handover accuracy; and the first working time axis and the second working time axis are established, so that the current doctor end and the handover doctor end can be well marked, and the corresponding display effect is further improved.

The foregoing description is only an overview of the present invention, and is intended to be implemented in accordance with the teachings of the present invention in order that the same may be more clearly understood and to make the same and other objects, features and advantages of the present invention more readily apparent.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to designate like parts throughout the figures. In the drawings:

FIG. 1 shows a schematic diagram of a computing device 100 according to one embodiment of the invention;

FIG. 2 illustrates a flow chart of a method of hemodialysis information management based on physician-side interactions in accordance with another embodiment of the present invention;

fig. 3 shows a schematic diagram of a first handover dialysis workflow zone according to the present embodiment;

fig. 4 shows a schematic diagram of a second handover dialysis workflow zone according to the present embodiment;

fig. 5 shows a block diagram of a hemodialysis information management system based on physician-side interactions, according to yet another embodiment of the present invention.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

Hemodialysis (hemomodialysis), clinically means that some waste in the blood is removed through a semi-permeable membrane. Hemodialysis is one of the safer, easier and widely used blood purification methods. Dialysis refers to the movement of solutes across a semipermeable membrane from a high concentration solution to a low concentration. Hemodialysis involves movement of solutes and movement of water, i.e., the blood and dialysate are subjected to mass exchange in a dialyzer (artificial kidney) by semi-permeable membrane contact and concentration gradient, so that metabolic waste and excessive electrolytes in the blood move toward the dialysate, and calcium ions, bases, etc. in the dialysate move toward the blood. If the mixed solution of albumin and urea is put into a dialyzer, the outside of the tube is soaked by water, at the moment, the urea in the tube of the dialyzer can move to the water outside the tube through the artificial kidney membrane hole, and the albumin molecules are larger and cannot pass through the membrane hole. This phenomenon of mass movement through which small molecular substances pass but large molecular substances cannot pass through the semipermeable membrane is called dispersion. The clinical method of separating and purifying blood by using dispersion phenomenon is the basic principle of hemodialysis.

The inventor finds that the dialysis work comprises a corresponding work flow in the research process, the work flow comprises each time point and work items corresponding to each time point, when a doctor performs the dialysis work, the doctor can execute the corresponding work items according to each time point in the work flow, and various emergency conditions possibly occur in a hospital, so that the doctor can be required to process various emergency conditions preferentially to perform the corresponding dialysis work delivery, but the existing work delivery mode often adopts a oral mode, and the oral mode can have the problems of missing information and lower work delivery efficiency.

The present inventors have proposed the present invention in order to solve the problems in the prior art described above. One embodiment of the present invention provides a hemodialysis information management method based on physician-side interactions, which can be performed in a computing device. FIG. 1 illustrates a block diagram of a computing device 100 according to one embodiment of the invention. As shown in FIG. 1, in a basic configuration 102, a computing device 100 typically includes a system memory 106 and one or more processors 104. The memory bus 108 may be used for communication between the processor 104 and the system memory 106.

Depending on the desired configuration, the processor 104 may be any type of processing including, but not limited to: microprocessor (μp), microcontroller (μc), digital information processor (DSP), or any combination thereof. The processor 104 may include one or more levels of caches, such as a first level cache 110 and a second level cache 112, a processor core 114, and registers 116. The example processor core 114 may include an Arithmetic Logic Unit (ALU), a Floating Point Unit (FPU), a digital signal processing core (DSP core), or any combination thereof. The example memory controller 118 may be used with the processor 104, or in some implementations, the memory controller 118 may be an internal part of the processor 104.

Depending on the desired configuration, system memory 106 may be any type of memory including, but not limited to: volatile memory (such as RAM), non-volatile memory (such as ROM, flash memory, etc.), or any combination thereof. Physical memory in a computing device is often referred to as volatile memory, RAM, and data in disk needs to be loaded into physical memory in order to be read by processor 104. The system memory 106 may include an operating system 120, one or more applications 122, and program data 124. The application 122 is actually a plurality of program instructions for instructing the processor 104 to perform a corresponding operation. In some implementations, the application 122 may be arranged to execute instructions on an operating system by the one or more processors 104 using the program data 124 in some implementations. The operating system 120 may be, for example, linux, windows or the like, which includes program instructions for handling basic system services and performing hardware-dependent tasks. The application 122 includes program instructions for implementing various functions desired by the user, and the application 122 may be, for example, a browser, instant messaging software, a software development tool (e.g., integrated development environment IDE, compiler, etc.), or the like, but is not limited thereto. When an application 122 is installed into computing device 100, a driver module may be added to operating system 120.

When the computing device 100 starts up running, the processor 104 reads the program instructions of the operating system 120 from the memory 106 and executes them. Applications 122 run on top of operating system 120, utilizing interfaces provided by operating system 120 and underlying hardware to implement various user-desired functions. When a user launches the application 122, the application 122 is loaded into the memory 106, and the processor 104 reads and executes the program instructions of the application 122 from the memory 106.

Computing device 100 also includes storage device 132, storage device 132 including removable storage 136 and non-removable storage 138, both removable storage 136 and non-removable storage 138 being connected to storage interface bus 134.

Computing device 100 may also include an interface bus 140 that facilitates communication from various interface devices (e.g., output devices 142, peripheral interfaces 144, and communication devices 146) to basic configuration 102 via bus/interface controller 130. The example output device 142 includes a graphics processing unit 148 and an audio processing unit 150. They may be configured to facilitate communication with various external devices such as a display or speakers via one or more a/V ports 152. Example peripheral interfaces 144 may include a serial interface controller 154 and a parallel interface controller 156, which may be configured to facilitate communication with external devices such as input devices (e.g., keyboard, mouse, pen, voice input device, touch input device) or other peripherals (e.g., printer, scanner, etc.) via one or more I/O ports 158. An example communication device 146 may include a network controller 160, which may be arranged to facilitate communication with one or more other computing devices 162 via one or more communication ports 164 over a network communication link.

The network communication link may be one example of a communication medium. Communication media may typically be embodied by computer readable instructions, data structures, program modules, and may include any information delivery media in a modulated data signal, such as a carrier wave or other transport mechanism. A "modulated data signal" may be a signal that has one or more of its data set or changed in such a manner as to encode information in the signal. By way of non-limiting example, communication media may include wired media such as a wired network or special purpose network, and wireless media such as acoustic, radio Frequency (RF), microwave, infrared (IR) or other wireless media. The term computer readable media as used herein may include both storage media and communication media.

Computing device 100 also includes a storage interface bus 134 that is coupled to bus/interface controller 130. The storage interface bus 134 is coupled to the storage device 132, and the storage device 132 is adapted to store data. An example storage device 132 may include removable storage 136 (e.g., CD, DVD, U disk, removable hard disk, etc.) and non-removable storage 138 (e.g., hard disk drive HDD, etc.).

In computing device 100 according to the present invention, application 122 includes a plurality of program instructions to perform method 200.

Fig. 2 illustrates a flow chart of a method 200 according to another embodiment of the invention, the method 200 being adapted to be performed in a computing device, such as the aforementioned computing device 100.

As shown in fig. 2, the method 200 is for implementing a hemodialysis information management method based on doctor-side interaction, and starts in step S202, and in step S202, the method includes the following steps:

a current dialysis workflow area corresponding to the current doctor end is generated, wherein the current dialysis workflow area comprises working time points which are arranged in time sequence along a first direction and working items which are arranged along a second direction and respectively correspond to the working time points.

For example, in this embodiment, the doctor terminal may be a terminal device with an online communication function, such as a computer, a mobile phone, etc.; the dialysis workflow areas can be generated through the server, and each dialysis workflow area can generate corresponding working time points and working items corresponding to the working time points according to the actual dialysis workflow; each operating point in time may include: work items corresponding to 7:30, 8:00, 8:30, 9:00, 9:30, 9:45 and 11:30,7:30 are for example measuring blood pressure; the 8:00 corresponding work items may include, for example, intravenous bolus injection for a patient; the 8:30 corresponding work items may include, for example, preparing a dialysis tool; the 9:00 corresponding work items may for example comprise a record of starting dialysis data; the 9:30 corresponding work items may include, for example, measuring blood pressure again; the 9:45 corresponding work items may include, for example, accessing the corresponding dialysis medication to the dialysis machine tubing, and preparing to push the medication before dialysis is completed; the 11:30 corresponding work items may for example comprise ending dialysis and performing machine sterilization.

Wherein, each working time point can be arranged along the first direction according to the time sequence, and each working item corresponding to each working time point can be arranged along the second direction, thereby improving the data arrangement uniformity; the first direction may be a horizontal direction, and the second direction may be a vertical direction, for example.

For example, the above-mentioned "generating a current dialysis workflow area corresponding to a current doctor side, where the current dialysis workflow area includes each working time point arranged in time sequence along a first direction and each working item respectively corresponding to each working time point arranged along a second direction", may further include the following steps:

generating a current dialysis workflow area corresponding to a current doctor end based on the digital twin space;

responding to interaction of the management end to the dialysis workflow area, and establishing each working time point arranged in time sequence along a first direction and each working item respectively corresponding to each working time point arranged along a second direction in the current dialysis workflow area;

the management end obtains the current doctor end according to the called preset doctor end list, and distributes the current dialysis workflow to the current doctor end.

In this regard, on the one hand, the digital twin space in this embodiment may be understood as a simulation process that fully uses data such as a physical model, sensor update, operation history, and the like, integrates multiple disciplines, multiple physical quantities, multiple scales, and multiple probabilities, and reflects a full life cycle process of corresponding physical equipment by completing mapping in a virtual space. Digital twinning can be considered as a digital mapping system of one or more important, mutually dependent equipment systems; on the other hand, the preset doctor-side list in this embodiment can be understood as a list having a plurality of doctor-sides, and the scheduled content corresponding to each doctor-side in the list.

Specifically, in the above scheme, after the management end establishes the scheduling plan of each corresponding working time point and each working item in the current dialysis working flow area generated based on the digital twin space, the management end may check the scheduled content of each doctor end included in the current dialysis working flow area by calling a preset doctor end list, determine whether the scheduled content of each doctor end conflicts with the scheduling plan of the current dialysis working flow area, and if the time corresponding to the scheduled content of one doctor end does not conflict with the working time point of the current dialysis working flow area, select the doctor end as the current doctor end, and allocate the current dialysis working flow area to the doctor end, thereby completing the allocation of the scheduling plan of the current dialysis working flow area, further improving the work allocation efficiency, and the current doctor end may complete the work item by item based on each working time point based on the scheduling plan of the current dialysis working flow area, and also synchronously improving the work completion efficiency.

In step S204, the following steps are included: and determining work handover contents and handover doctor ends corresponding to the work handover time based on the interaction of the current doctor end to the current dialysis workflow area and the initiated handover personnel determination request.

In this embodiment, if the current doctor end needs to interrupt the work and perform the work handover due to personal factors or other factors during the work based on the scheduling plan of the current dialysis workflow area, the current doctor end may determine the work handover content and the handover doctor end corresponding to the work handover time by interacting with the current dialysis workflow area and initiating a corresponding handover personnel determination request, so as to ensure that the handover of the remaining work is performed without delaying the normal completion of the work.

For example, the above-mentioned "determining the work delivery content and the delivery doctor end corresponding to the work delivery time based on the interaction of the current doctor end with the current dialysis workflow area and the initiated delivery person determination request" may further include the following steps:

the doctor terminal at present invokes the work handover content selection line, and selects the current dialysis workflow area based on the work handover content selection line to obtain the work handover content corresponding to the work handover time;

And responding to the determination request of the handover personnel of the current doctor terminal, sending other dialysis workflow areas corresponding to the other doctor terminals to the current doctor terminal, and determining one of the other doctor terminals as the handover doctor terminal by the current doctor terminal based on the other dialysis workflow areas corresponding to the other doctor terminals.

In this embodiment, firstly, after the current doctor terminal invokes the work handover content selection line, the current dialysis workflow area can be selected according to the work handover content selection line, which specifically includes the work handover content that needs to be handed over, and because the current doctor terminal always performs work based on the scheduling plan of the current dialysis workflow area during the work process, the selected work handover content is corresponding to the work handover time; then, after finishing the selection of the work handover content, the current doctor end can send a corresponding handover personnel determination request to the server, and the server can send other dialysis workflow areas corresponding to the other doctor ends respectively to the current doctor end after receiving the request; finally, since the other dialysis workflow areas corresponding to the other doctor terminals respectively have the scheduling plans corresponding to the other doctor terminals, the current doctor terminal can compare the working time points in the scheduling plans corresponding to the other doctor terminals according to the working time points related in the working handover content, and one of the other doctor terminals meeting the conditions is determined as the handover doctor terminal according to the comparison result.

Further, the above-mentioned "the current doctor terminal determines one of the other doctor terminals as the handover doctor terminal based on the other dialysis workflow areas respectively corresponding to the other doctor terminals" may further include the following steps:

determining each working time point included in the dialysis workflow area according to other dialysis workflow areas corresponding to other doctor ends respectively;

judging whether the two work time points are overlapped or not according to the comparison of the work time points included in the work handover content and the work time points included in other dialysis workflow areas;

if no overlapping condition exists, the corresponding other doctor end is determined to be the handover doctor end.

In this embodiment, when the current doctor end determines the handover doctor end, each working time point of the other dialysis workflow area corresponding to each other doctor end may be determined first; then comparing with each working time point in the working handover content; finally, if there is overlap between the two, it is indicated that the other doctor end does not have idle time to process the work handover content; and there is no overlap between the two, indicating that the other doctor has free time to work for the handover, which can determine the other doctor as the handover doctor. Therefore, the situation that after the work handover is finished, the handover doctor end cannot finish the handover in time due to no idle time can be avoided, and the corresponding handover accuracy is improved.

In order to distinguish between the work items in the completed state and the work items in the unfinished state in the current dialysis workflow area, in this embodiment, the current doctor side may interact with each work item in the current dialysis workflow area to change the state of each work item, for example, from the incomplete state to the completed state, and mark the work items in the completed state, so as to realize visual distinction; specifically, work items in the completed state may have diagonal line marks, while work items in the unfinished state do not have diagonal line marks.

Based on the difference between the work items in the completed state and the unfinished state, the above-mentioned "the current doctor side invokes the work handover content selection line, and interacts with the current dialysis workflow area based on the work handover content selection line, and selects the work handover content", and may further include the following steps:

determining a target working time point which is close to the current dialysis workflow area based on the working handover time;

determining all work items in unfinished states corresponding to a target work time point;

Determining all work items in unfinished states corresponding to the target working time point and all work items corresponding to other working time points after the target working time point as work handover contents;

the doctor terminal at present invokes the work handover content selection line, and interacts with the current dialysis workflow area based on the work handover dividing line, so as to select the work handover content.

In this embodiment, since the current doctor end completes the corresponding dialysis work based on each work item corresponding to each work time point included in the current dialysis flow area, each work item corresponding to each work time point before the work handover time may be completed, and according to this feature, the quick selection of the work handover content may be performed, which specifically includes: first, a target working time point which is close to the working time point is determined in the current dialysis workflow based on the working handover time, wherein the target working time point can be understood as the same working time point as the working handover time or a working time point which is positioned before the working handover time; then, based on the target working time, determining all work items corresponding to the target working time in an unfinished state; then, each work item corresponding to the target working time point and each work item corresponding to other working time points after the target working time point in an unfinished state can be determined to be the work handover content; finally, the working handover content is selected through the working handover content selection line which is called by the current doctor end, so that the determination of the working handover content is rapidly completed, and the corresponding working handover efficiency and the information accuracy of the working handover are improved.

When each work item corresponding to the target work time point is in the completed state, each work item corresponding to another work time point after the target work time point is directly determined as the work delivery content.

The scheme is further described below in conjunction with the actual application scenario:

assuming that the working handover time is 10:45, the target working time point close to the working handover time is 10:30, the other working time points after the target working time point are 11:30 and 12:00, and the working item corresponding to the target working time point comprises a working item A (completed state); work item B (completed state) and work item C (unfinished state), at this time, each work item corresponding to two other work time points, namely work item C, 11:30 and 12:00, can be determined to be work handover content, so that a doctor terminal can call a corresponding work handover content selection line to select the work handover content, and further the selection efficiency and accuracy are improved.

Further, the above-mentioned "changing the completed state of each work item from the incomplete state in response to the interaction of the current doctor side with each work item in the current dialysis workflow area" includes:

Responding to interaction of the current doctor end to each work item in the current dialysis work flow area, uploading each dialysis data corresponding to each work item to the current dialysis work flow area, and changing each work item from an incomplete state to a completed state;

establishing a link relation between each work item and each dialysis data corresponding to each work item respectively;

based on the interaction of each work item in the current dialysis workflow area, each dialysis data with a link relation with each work item is called for display.

For example, in this embodiment, during the working based on the scheduling plan of the current dialysis workflow area, each work item may generate corresponding dialysis data after completion, for example, blood pressure data may be generated by measuring blood pressure corresponding to 7:30, bolus data may be generated by intravenous bolus corresponding to 8:30, and in order to be able to correspond the generated dialysis data to each work item of the current workflow area, the dialysis data corresponding to each work item may be uploaded, and the status of the corresponding work item may be changed from the incomplete status to the completed status based on the uploading of each dialysis data.

After uploading the corresponding dialysis data, in order to enable the server, the management end, the current doctor end or other terminals such as the handover doctor end to view the corresponding dialysis data, a link relation between each work item and each dialysis data corresponding to each work item can be established, so that each dialysis data with the link relation with each work item can be called for display based on interaction of each work item in the current dialysis workflow area; in addition, in order to prevent other terminals from changing the dialysis data, corresponding operation steps such as flow logs, data fixing and the like can be generated after the dialysis data is uploaded, so that the corresponding working efficiency is improved.

In step S206, the following steps are included: a first work time axis extending in a first direction corresponding to the current doctor's end is established in the current dialysis workflow area based on the starting work time of the current doctor's end and the work handover content.

In this embodiment, in order to further mark the completed work content of the current doctor end, a first work time axis corresponding to the current doctor end may be established in the current dialysis workflow area based on the starting work time and the work handover content of the current doctor end, where the first work time axis extends along the first direction, and the first work time axis may be located at one side of each work time point that is also set along the first direction.

For example, the above-mentioned "establishing a first work time axis extending in a first direction corresponding to the current doctor end in the current dialysis workflow area based on the start work time of the current doctor end and the work handover content" may further include the steps of:

determining the first working time point in all working time points in the current dialysis workflow area as the initial working time of the current doctor end, and taking the initial working time as the first time point;

if at least one work item in an unfinished state exists in each work item corresponding to the target work time point, taking the work time point positioned before the target work time point as a second time point;

if the work items corresponding to the target working time point do not exist in the work items in the unfinished state, taking the target working time point as a second time point;

and establishing a first working time axis which corresponds to the current doctor end and extends along a first direction in the current dialysis workflow area by taking the first time point as a starting point and the second time point as an important point, wherein the first end part of the first working time axis and the first time point are positioned at the same horizontal position, and the second end part of the first working time axis and the second time point are positioned at the same horizontal position.

For example, in this embodiment, the first working time axis is used to indicate the completed working content corresponding to the current doctor end, so the first working time axis can be established based on the starting working time and the working handover content of the current doctor end, the starting working time can be used as a first time point, the second time point can be obtained based on the working handover content, two ends corresponding to the first working time axis are obtained according to the first time point and the second time point, so the first working time axis extending along the first direction is established in the current dialysis workflow area, the first end of the first working time axis is at the same horizontal position as the first time point, and the second end of the first working time axis is at the same horizontal position as the second time point.

Specifically, the initial working time of the current doctor end can be determined according to the first working time point in all working time points in the current dialysis working flow, and the working time point is taken as a first time point; the second time point may be obtained according to the above-mentioned target working time point, and since each working item corresponding to the target working time point may include a working item in a completed unfinished state, the second time point may be determined based on two cases: 1. judging whether each work item corresponding to the target work time point has at least one work item in an unfinished state, and if so, taking the work time point positioned before the target work time point as a second time point; 2. judging whether each work item corresponding to the target working time point has at least one work item in an unfinished state, and if all work items are in a finished state, taking the target working time point as a second time point.

Through the judgment of the second time point, the first working time axis established based on the first time point and the second time point can mark the working content completed at the current doctor end, so that in the subsequent handover working process, the distinction between the working handover content and the completed working content is further improved, and the working handover efficiency is further improved.

In step S208, the following steps are included: and updating the current dialysis workflow area according to the first work time axis and the work handover content to obtain a handover dialysis workflow area.

For example, after the first work time axis and the work handover content are obtained, the current dialysis workflow area may be updated based on the first work time axis and the work handover content, so as to obtain a handover dialysis workflow area available for handover, where the update manner may be to sequentially perform primary area division and secondary area division on the current dialysis workflow area, so as to obtain a completed work area and a handover work area, so as to implement that the completed work content and the work handover content can be distinguished in the handover dialysis workflow area.

Further, when the second time point is a working time point located before the target working time point, the above-mentioned "updating the current dialysis workflow area based on the first working time axis and the working handover content to obtain the handover dialysis workflow area" may further include the following steps:

Generating a transitional working time shaft corresponding to the target working time point and extending along a first direction, wherein the end part of the transitional working time shaft is linked with the first working time shaft;

sequentially carrying out primary region division and secondary region division on the current dialysis workflow to obtain a handover dialysis workflow region;

the method comprises the steps that a first special-shaped region frame is used for carrying out primary region division on a current dialysis workflow region to obtain a completed work region, wherein the completed work region comprises a first work time axis, a second time point and all work items which are in a completed state and correspond to all work time points located before the second time point, and all work items which are in a completed state and correspond to target work time points;

and carrying out secondary region division on the dialysis workflow region based on the second special-shaped region to obtain a handover working region, wherein the handover working region comprises all work items which are in unfinished states and correspond to the target working time point, and all work items which are positioned behind the target working time point and correspond to the working time points respectively.

For example, in this embodiment, when the second time point is the working time point located before the target working time point, it is indicated that each working item corresponding to the target working time point includes a working item in an incomplete state, so that the target working time point can be considered as a working time point that needs to be transitioned, and a transitional working time axis is established based on the target working time point, and the transitional working time axis extends along the first direction and is used for marking the target working time point, so as to further improve the marking effect on the target working time point; after the corresponding transitional working time axis is acquired, the current dialysis workflow area is divided into areas and secondary areas sequentially.

The above-mentioned primary area division may be performed by using a first special-shaped area frame, and since the target working time point includes a working item in a completed state and a working item in an unfinished state, the first special-shaped area frame may divide the current dialysis workflow into a completed working area, where the completed working area includes all completed working items corresponding to the current doctor end and a corresponding first working time axis;

the secondary region division can be performed by adopting a second special-shaped region frame, the second special-shaped region frame can divide the current dialysis workflow into a handover working region, and the handover working tool comprises all unfinished work items corresponding to the current doctor end;

through the secondary region division and the establishment of the transition time axis, all completed work items, all unfinished work items and the transition work time axis corresponding to the target work time points of the work items including the completed state and the unfinished state at the current doctor end can be divided respectively, so that the marking effect on the contents of all parts is improved, and the corresponding work handover efficiency and the display effect are improved.

It may be noted that, as shown in fig. 3, the first special-shaped area frame and the second special-shaped area frame may be dashed-line frames including a part of special-shaped structures, where the part of special-shaped structures are mainly used for dividing work items in completed states and unfinished states corresponding to a target working time point (in fig. 3, the target working time point is 9:00, the part of special-shaped structures select a work item of "measuring blood pressure again", and three bar structures on the left side in fig. 3 are respectively a first working time axis, a transitional working time axis and a second working time axis from top to bottom), and the dashed-line frames are mainly used for dividing other parts of contents.

Further, when the second time point is the target working time point, the above-mentioned "updating the current dialysis workflow area based on the first working time axis and the working handover content to obtain the handover dialysis workflow area" may further include the following steps:

sequentially carrying out primary region division and secondary region division on the current dialysis workflow region to obtain a handover dialysis workflow region;

performing primary region division on the current dialysis workflow region based on a first non-special-shaped region frame to obtain a completed work region, wherein the completed work region comprises a first work time axis and work items corresponding to target work time points;

and carrying out secondary region division on the dialysis workflow region based on the second non-special-shaped region frame to obtain a handover working region, wherein the handover working region comprises all working items respectively corresponding to all working time points positioned behind the target working time point.

Similarly, in this embodiment, when the second time point is the target working time point, it indicates that each working item corresponding to the target working time point is not a working item in an unfinished state, so the target working time point can be considered as a working time point that does not need to be transited, and therefore, a corresponding transitional working time axis does not need to be established, and the primary area division and the secondary area division can be directly performed on the current dialysis workflow area.

The above-mentioned primary region division can be performed by adopting a first non-special-shaped region frame, so that a corresponding completed working region is divided, and the completed working region comprises a first working time axis and each working item corresponding to a target working time point;

the secondary region division can be performed by adopting a second non-special-shaped region frame, so that a corresponding handover working region is divided, and the handover working region comprises all working items respectively corresponding to all working time points after the target working time point.

Through the secondary region division, all completed work items and all unfinished work items at the end of a doctor can be divided respectively, so that the marking effect on the content of each part is improved, and the corresponding work handover efficiency and the display effect are improved.

It may be noted that, as shown in fig. 4, the first non-irregular area frame and the second non-irregular area frame may include a dashed-line frame (in fig. 4, the target operating time point is 9:00, and the two bar structures on the left side in fig. 4 are the first operating time axis and the second operating time axis from top to bottom, respectively).

In step S210, the following steps are included: the handover dialysis workflow area is sent to the handover doctor end, and a second work time axis extending along the first direction corresponding to the handover doctor end is established in the handover dialysis workflow area based on the work handover time.

For example, in this embodiment, after the current dialysis workflow is updated to obtain the handover dialysis workflow area, the handover dialysis workflow area may be sent to the handover doctor end, so that the handover doctor end can check the content of the handover work and perform corresponding work based on the handover dialysis workflow, and in addition, in order to mark the content of the handover work corresponding to the handover doctor end, a second work time axis may be established in the handover dialysis workflow area, where the second work time axis corresponds to the handover doctor end and extends along the first direction, so as to improve the marking effect.

Further, the above-mentioned "send the handover dialysis workflow area to the handover doctor end, and establish a second work time axis extending along the first direction corresponding to the handover doctor end in the handover dialysis workflow area based on the work handover time" may further include the following steps:

transmitting the handover dialysis workflow area to a handover doctor end, responding to the reception of the handover dialysis workflow area by the handover doctor end, initiating a second work time axis customization request for the handover doctor end, and selecting the customization form and the customization color in a preset customization column according to the second work time axis customization request by the handover doctor end;

In response to selection of the custom configuration, custom color at the physician's end of the handover, a second work time axis extending along the first direction is established at the handover dialysis workflow area, wherein the second work time axis is connected to an end of the first work time axis.

For example, in this embodiment, after the handover doctor receives the corresponding handover dialysis workflow area, the server may initiate a second work time axis customization request to the handover doctor, and customize the second work time axis according to feedback from the handover doctor, so as to complete creation of the second work time axis for marking the work handover content corresponding to the handover doctor, and when the handover dialysis workflow area includes the transition time axis, the second work time axis may be connected to an end of the transition time axis; when the transition time shaft is not included in the handover dialysis workflow, the second work time shaft can be connected to the end of the first work time shaft, so that the display effect is further improved.

It may be noted that the preset customization column may be preset, where the preset customization column includes different customization modes and customization colors, and the customization modes include: the custom colors may include red, yellow, blue, green, white, etc. in various other colors, both irregular and regular.

In summary, according to the solution of the present invention, by generating the current dialysis workflow area corresponding to the current doctor end, the working time point and the corresponding working point of the current doctor end can be clearly known, in the process of working handover, the current doctor end can determine the corresponding work handover content and the handover doctor end based on the current dialysis workflow area, and generate the first working time axis corresponding to the current doctor end, update the current dialysis workflow area based on the first working time axis and the work handover content, thereby obtaining the handover dialysis workflow area sent to the handover doctor end, and establish the second working time axis corresponding to the handover doctor end, thereby realizing the on-line work exchange process, and improving the work handover efficiency and the accuracy of the work handover; and the first working time axis and the second working time axis are established, so that the current doctor end and the handover doctor end can be well marked, and the corresponding display effect is further improved.

Yet another embodiment of the present invention provides a hemodialysis information management system based on doctor-side interaction, and fig. 5 is a block diagram of a corresponding apparatus thereof, where the hemodialysis information management system includes:

A generation module configured to generate a current dialysis workflow area corresponding to a current doctor end, the current dialysis workflow area including work time points arranged in time sequence along a first direction and work items respectively corresponding to the work time points arranged along a second direction;

a work handover information determining module configured to determine work handover contents and handover doctor terminals corresponding to a work handover time based on interaction of the current doctor terminal with the current dialysis workflow area and an initiated handover person determining request;

a first work time axis creation module configured to create a first work time axis extending in the first direction corresponding to the current doctor end in the current dialysis workflow area based on a start work time of the current doctor end and a work handover content;

the updating module is configured to update the current dialysis workflow area according to the first working time axis and the working handover content to obtain a handover dialysis workflow area;

a second work time axis creation module configured to send the handover dialysis workflow area to the handover doctor end and create a second work time axis extending in the first direction corresponding to the handover doctor end in the handover dialysis workflow area based on a work handover time.

The various techniques described herein may be implemented in connection with hardware or software or, alternatively, with a combination of both. Thus, the methods and apparatus of the present invention, or certain aspects or portions of the methods and apparatus of the present invention, may take the form of program code (i.e., instructions) embodied in tangible media, such as removable hard drives, U-drives, floppy diskettes, CD-ROMs, or any other machine-readable storage medium, wherein, when the program is loaded into and executed by a machine, such as a computer, the machine becomes an apparatus for practicing the invention.

In the case of program code execution on programmable computers, the computing device will generally include a processor, a storage medium readable by the processor (including volatile and non-volatile memory and/or storage elements), at least one input device, and at least one output device. Wherein the memory is configured to store program code; the processor is configured to perform the method of the invention in accordance with instructions in said program code stored in the memory.

By way of example, and not limitation, readable media comprise readable storage media and communication media. The readable storage medium stores information such as computer readable instructions, data structures, program modules, or other data. Communication media typically embodies computer readable instructions, data structures, program modules or other data in a modulated data signal such as a carrier wave or other transport mechanism and includes any information delivery media. Combinations of any of the above are also included within the scope of readable media.

In the description provided herein, algorithms and displays are not inherently related to any particular computer, virtual system, or other apparatus. Various general-purpose systems may also be used with examples of the invention. The required structure for a construction of such a system is apparent from the description above. In addition, the present invention is not directed to any particular programming language. It should be appreciated that the teachings of the present invention as described herein may be implemented in a variety of programming languages and that the foregoing description of specific languages is provided for disclosure of preferred embodiments of the present invention.

In the description provided herein, numerous specific details are set forth. However, it is understood that embodiments of the invention may be practiced without these specific details. In some instances, well-known methods, structures and techniques have not been shown in detail in order not to obscure an understanding of this description.

Similarly, it should be appreciated that in the foregoing description of exemplary embodiments of the invention, various features of the invention are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of one or more of the various inventive aspects. However, the disclosed method should not be construed as reflecting the intention that: i.e., the claimed invention requires more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus, the claims following the detailed description are hereby expressly incorporated into this detailed description, with each claim standing on its own as a separate embodiment of this invention.

Those skilled in the art will appreciate that the modules or units or components of the devices in the examples disclosed herein may be arranged in a device as described in this embodiment, or alternatively may be located in one or more devices different from the devices in this example. The modules in the foregoing examples may be combined into one module or may be further divided into a plurality of sub-modules.

Those skilled in the art will appreciate that the modules in the apparatus of the embodiments may be adaptively changed and disposed in one or more apparatuses different from the embodiments. The modules or units or components of the embodiments may be combined into one module or unit or component and, furthermore, they may be divided into a plurality of sub-modules or sub-units or sub-components. Any combination of all features disclosed in this specification (including any accompanying claims, abstract and drawings), and all of the processes or units of any method or apparatus so disclosed, may be used in combination, except insofar as at least some of such features and/or processes or units are mutually exclusive. Each feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise.

Furthermore, those skilled in the art will appreciate that while some embodiments described herein include some features but not others included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the invention and form different embodiments. For example, in the following claims, any of the claimed embodiments can be used in any combination.

Furthermore, some of the embodiments are described herein as methods or combinations of method elements that may be implemented by a processor of a computer system or by other means of performing the functions. Thus, a processor with the necessary instructions for implementing the described method or method element forms a means for implementing the method or method element. Furthermore, the elements of the apparatus embodiments described herein are examples of the following apparatus: the apparatus is for carrying out the functions performed by the elements for carrying out the objects of the invention.

As used herein, unless otherwise specified the use of the ordinal terms "first," "second," "third," etc., to describe a general object merely denote different instances of like objects, and are not intended to imply that the objects so described must have a given order, either temporally, spatially, in ranking, or in any other manner.

While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of the above description, will appreciate that other embodiments are contemplated within the scope of the invention as described herein. Furthermore, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and may not have been selected to delineate or circumscribe the inventive subject matter. Accordingly, many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the appended claims. The disclosure of the present invention is intended to be illustrative, but not limiting, of the scope of the invention, which is defined by the appended claims.

Claims (10)

1. The hemodialysis information management method based on doctor-side interaction is characterized by comprising the following steps of:

generating a current dialysis workflow area corresponding to a current doctor end, wherein the current dialysis workflow area comprises working time points which are arranged in time sequence along a first direction and working items which are arranged along a second direction and respectively correspond to the working time points;

Determining work handover contents and handover doctor terminals corresponding to work handover time based on the interaction of the current doctor terminal to the current dialysis workflow area and the initiated handover personnel determination request;

establishing a first work time axis extending along the first direction corresponding to the current doctor end in the current dialysis workflow area based on the starting work time and work handover content of the current doctor end;

updating the current dialysis workflow area according to the first working time axis and the working handover content to obtain a handover dialysis workflow area;

the handover dialysis workflow area is sent to the handover doctor end, and a second work time axis corresponding to the handover doctor end and extending along the first direction is established in the handover dialysis workflow area based on the work handover time.

2. The hemodialysis information management method based on doctor-side interaction of claim 1, wherein,

generating a current dialysis workflow area corresponding to a current doctor end, wherein the current dialysis workflow area comprises all working time points which are arranged in a time sequence along a first direction and all working items which are arranged along a second direction and respectively correspond to all the working time points, and the current dialysis workflow area comprises the following components:

Generating a current dialysis workflow area corresponding to a current doctor end based on the digital twin space;

responding to interaction of a management end on the current dialysis workflow area, and establishing each working time point arranged in time sequence along a first direction and each working item respectively corresponding to each working time point arranged along a second direction in the current dialysis workflow area;

the management end selects the current doctor end according to the called preset doctor end list, and distributes the current dialysis workflow to the current doctor end.

3. The hemodialysis information management method based on doctor-side interaction of claim 1, wherein,

determining work handover contents and handover doctor terminals corresponding to work handover time based on the interaction of the current doctor terminal to the current dialysis workflow area and the initiated handover personnel determination request, including:

the current doctor side invokes a work handover content selection line, and selects the current dialysis workflow area based on the work handover content selection line to obtain work handover content corresponding to the work handover time;

and sending other dialysis workflow areas respectively corresponding to the other doctor ends to the current doctor end in response to the determination request of the handover personnel of the current doctor end, wherein the current doctor end determines one of the other doctor ends as the handover doctor end based on the other dialysis workflow areas respectively corresponding to the other doctor ends.

4. The hemodialysis information management method based on doctor-side interaction of claim 3, wherein,

the current doctor end determines one of the other doctor ends as the handover doctor end based on the other dialysis workflow areas respectively corresponding to the other doctor ends, including:

determining each working time point included in the dialysis workflow area according to other dialysis workflow areas corresponding to other doctor ends respectively;

judging whether an overlapping condition exists between each working time point included in the work handover content and each working time point included in other dialysis workflow areas according to the comparison of the two working time points;

and if no overlapping condition exists, determining the corresponding other doctor end as the handover doctor end.

5. The hemodialysis information management method based on doctor-side interaction of claim 3, wherein,

changing each work item in the current dialysis workflow area from an incomplete state to a completed state in response to interaction of the current doctor's end with the work item;

the current doctor side invokes a work handover content selection line, and interacts with the current dialysis workflow area based on the work handover content selection line, and selects the work handover content, including:

Determining a target working time point in the current dialysis workflow zone that is proximate thereto based on the working handover time;

determining all work items in unfinished states corresponding to the target working time point;

determining all work items in unfinished states corresponding to the target working time point and all work items corresponding to other working time points after the target working time point as the work handover content;

and the current doctor terminal invokes a work handover content selection line, and interacts with the current dialysis workflow area based on the work handover dividing line to select the work handover content.

6. The hemodialysis information management method based on doctor-side interaction of claim 5, wherein,

in response to interaction of the current physician's end with each work item within the current dialysis workflow area, changing each work item from an incomplete state to a completed state, comprising:

responding to interaction of the current doctor end on each work item in a current dialysis work flow area, uploading each dialysis data corresponding to each work item to the current dialysis work flow area, and changing each work item from an incomplete state to a completed state;

Establishing a link relation between each work item and each dialysis data corresponding to each work item respectively;

and calling and displaying each piece of dialysis data with a link relation with each work item based on interaction of each work item in the current dialysis work flow area.

7. The hemodialysis information management method based on doctor-side interaction of claim 5, wherein,

establishing a first work time axis extending along the first direction corresponding to the current doctor end in the current dialysis workflow area based on the starting work time and work handover content of the current doctor end, wherein the first work time axis comprises:

determining a first working time point in all working time points in the current dialysis workflow area as an initial working time of the current doctor end, and taking the initial working time as a first time point;

if at least one work item in an unfinished state exists in each work item corresponding to the target work time point, taking the work time point positioned before the target work time point as a second time point;

if the work items corresponding to the target working time point do not exist in the work items in the unfinished state, taking the target working time point as a second time point;

And taking the first time point as a starting point and the second time point as an ending point, establishing a first working time axis which corresponds to the current doctor end and extends along a first direction in the current dialysis workflow area, wherein a first end part of the first working time axis and the first time point are positioned at the same horizontal position, and a second end part of the first working time axis and the second time point are positioned at the same horizontal position.

8. The hemodialysis information management method based on doctor-side interaction of claim 7, wherein,

when the second time point is a working time point located before the target working time point, updating the current dialysis workflow area based on the first working time axis and the working handover content to obtain a handover dialysis workflow area, including:

generating a transitional working time shaft corresponding to the target working time point and extending along the first direction, wherein the end part of the transitional working time shaft is connected with the first working time shaft;

sequentially carrying out primary region division and secondary region division on the current dialysis workflow region to obtain a handover dialysis workflow region;

The method comprises the steps that a current dialysis workflow area is divided into areas based on a first special-shaped area frame to obtain a completed work area, wherein the completed work area comprises a first work time axis, a second time point and all work items which are in a completed state and correspond to all work time points located before the second time point, and all work items which are in a completed state and correspond to a target work time point;

dividing the dialysis workflow area into secondary areas based on a second special-shaped area frame to obtain a handover work area, wherein the handover work area comprises all work items in unfinished states corresponding to a target work time point and all work items respectively corresponding to all work time points located behind the target work time point;

or,

when the second time point is the target working time point, updating the current dialysis workflow area based on the first working time axis and the working handover content to obtain a handover dialysis workflow area, including:

sequentially carrying out primary region division and secondary region division on the current dialysis workflow region to obtain a handover dialysis workflow region;

performing primary region division on the current dialysis workflow region based on a first non-special-shaped region frame to obtain a completed work region, wherein the completed work region comprises work items corresponding to a first work time axis and a target work time point;

And carrying out secondary region division on the dialysis workflow region based on a second non-special-shaped region frame to obtain a handover working region, wherein the handover working region comprises all working items respectively corresponding to all working time points positioned behind a target working time point.

9. The hemodialysis information management method based on doctor-side interaction of claim 1, wherein,

sending the handover dialysis workflow area to the handover doctor end, and establishing a second work time axis corresponding to the handover doctor end and extending along the first direction in the handover dialysis workflow area based on work handover time, comprising:

sending the handover dialysis workflow area to the handover doctor end, responding to the reception of the handover dialysis workflow area by the handover doctor end, initiating a second work time axis customization request for the handover doctor end, and selecting a customization form and a customization color in a preset customization column according to the second work time axis customization request by the handover doctor end;

and in response to the selection of the custom form and custom color by the handover doctor, establishing a second work time axis extending along the first direction in the handover dialysis workflow area, wherein the second work time axis is connected with the end part of the first work time axis.

10. Hemodialysis information management system based on doctor-side interaction, which is characterized by comprising:

a generation module configured to generate a current dialysis workflow area corresponding to a current doctor end, the current dialysis workflow area including work time points arranged in time sequence along a first direction and work items respectively corresponding to the work time points arranged along a second direction;

a work handover information determining module configured to determine work handover contents and handover doctor terminals corresponding to a work handover time based on interaction of the current doctor terminal with the current dialysis workflow area and an initiated handover person determining request;

a first work time axis creation module configured to create a first work time axis extending in the first direction corresponding to the current doctor end in the current dialysis workflow area based on a start work time of the current doctor end and a work handover content;

the updating module is configured to update the current dialysis workflow area according to the first working time axis and the working handover content to obtain a handover dialysis workflow area;

A second work time axis creation module configured to send the handover dialysis workflow area to the handover doctor end and create a second work time axis extending in the first direction corresponding to the handover doctor end in the handover dialysis workflow area based on a work handover time.