CN117594215A

CN117594215A - Life information processing system and processing method

Info

Publication number: CN117594215A
Application number: CN202311019234.6A
Authority: CN
Inventors: 章蕾; 谈琳; 潘瑞玲; 代巍巍; 黄丽云
Original assignee: Shenzhen Mindray Bio Medical Electronics Co Ltd
Current assignee: Shenzhen Mindray Bio Medical Electronics Co Ltd
Priority date: 2022-08-12
Filing date: 2023-08-11
Publication date: 2024-02-23

Abstract

The application provides a life information processing system and a method, wherein the method comprises the following steps: acquiring object data of a plurality of monitoring objects; determining at least one physiological structure associated with each monitored subject; arranging and displaying the presentation information of a plurality of monitoring objects, wherein the presentation information of one monitoring object occupies one display area; the presentation information of the first monitoring object at least comprises the following information: the method comprises the steps of identifying information of a first monitoring object, at least one identification corresponding to at least one physiological structure associated with the first monitoring object one by one, and monitoring data of monitoring parameters corresponding to the at least one physiological structure determined based on the corresponding relation between the physiological structure and the monitoring parameters. According to the life information processing system and the life information processing method, the monitoring parameters of the monitored object are divided in the physiological structure and are displayed in the display area in a concentrated mode, so that a user can view information of each dimension more conveniently.

Description

Life information processing system and processing method

Technical Field

The invention relates to the technical field of medical equipment, in particular to a life information processing system and a life information processing method.

Background

In clinical work, when medical personnel carry out management diagnosis and treatment to a plurality of patients, the whole condition of the patients needs to be quickly known at first, so that the states of the patients are identified to assist subsequent operation. For the overall condition of the patient, it is often necessary to interpret various monitoring data of the patient from different dimensions, and these monitoring data may include physiological monitoring data, diagnostic test data and the like (such as laboratory test indexes and the like), so that the medical staff can meet different clinical working requirements by interpreting the multi-dimensional monitoring data.

However, there has been no device or set of devices that can cover the clinical scenario described above. For example, a multi-bed central station for data integration through vital sign monitoring equipment can only reflect the real-time state of a patient, and when a medical staff wants to trace back the change of the illness state of the patient for a period of time, the medical staff needs to enter another set of management equipment or another piece of equipment to check, so that inconvenience is caused to the work of the medical staff.

Disclosure of Invention

According to a first aspect, there is provided in one embodiment a vital information processing apparatus including: a memory for storing an executable program, a processor for executing the executable program, and a display, such that the processor performs the following operations:

Acquiring object data of a plurality of monitoring objects, wherein the object data of each monitoring object comprises an information identifier of each monitoring object and monitoring data of a plurality of monitoring parameters of each monitoring object, and the information identifier comprises an identity information identifier;

determining at least one physiological structure associated with each of the monitored subjects;

wherein the plurality of monitoring objects includes a first monitoring object;

the at least one physiological structure associated with the first monitored object is preset, and/or the at least one physiological structure associated with the first monitored object is determined according to the acquired monitoring data of the plurality of monitoring parameters of the first monitored object and based on the set physiological structure and the corresponding relation of the monitoring parameters;

controlling the display to display the presentation information of the plurality of monitoring objects in an array manner, wherein the presentation information of one monitoring object occupies one display area of the display;

the presentation information of the first monitoring object at least comprises the following information: the information identifier of the first monitoring object, at least one identifier corresponding to at least one physiological structure associated with the first monitoring object one by one, and monitoring data of monitoring parameters corresponding to the at least one physiological structure determined based on the corresponding relation between the physiological structure and the monitoring parameters;

And the monitoring data of the identification and the monitoring parameters corresponding to each physiological structure associated with the first monitoring object are displayed in an associated mode, and each associated display occupies one sub-display area in the display area corresponding to the first monitoring object.

According to a second aspect, in one embodiment, there is provided a vital information processing method including:

wherein the plurality of monitoring objects includes a first monitoring object;

arranging and displaying the presentation information of the plurality of monitoring objects, wherein the presentation information of one monitoring object occupies one display area;

According to a third aspect, there is provided in one embodiment a vital information processing apparatus including: a memory for storing an executable program, a processor for executing the executable program, and a display, such that the processor performs the following operations:

controlling the display to display the presentation information of the plurality of monitoring objects, wherein the presentation information of one monitoring object occupies one display area of the display;

wherein the plurality of monitoring objects includes a first monitoring object; the presentation information of the first monitoring object at least comprises the following information: the information identifier of the first monitoring object, at least two identifiers corresponding to the at least two physiological structures associated with the first monitoring object one by one, and monitoring data of different monitoring parameters corresponding to the at least two physiological structures determined based on the corresponding relation between the set physiological structures and the monitoring parameters;

and displaying the identification corresponding to each physiological structure associated with the first monitoring object and the monitoring data of the monitoring parameters in an associated way.

According to a fourth aspect, there is provided in one embodiment a vital information processing method including:

displaying the presentation information of the plurality of monitoring objects, wherein the presentation information of one monitoring object occupies one display area;

wherein the plurality of monitoring objects includes a first monitoring object; the presentation information of the first monitoring object at least comprises the following information: the information identifier of the first monitoring object, at least one identifier corresponding to at least one physiological structure associated with the first monitoring object one by one, and monitoring data of monitoring parameters corresponding to the at least one physiological structure determined based on the corresponding relation between the physiological structure and the monitoring parameters;

According to a fifth aspect, in one embodiment there is provided a monitoring device comprising:

a memory for storing a program;

and the processor is used for executing the program stored in the memory to realize the method.

According to a sixth aspect, an embodiment provides a computer readable storage medium having a program stored thereon, the program being executable by a processor to implement the above method.

The life information processing apparatus and the information processing method in the above embodiments have the following advantageous effects:

(1) When the presentation information of a plurality of monitoring objects is displayed, the parameter data of the monitoring parameters are divided according to the physiological structures, so that a user can intensively view the monitoring data of the monitoring parameters related to one physiological structure.

(2) The identification of the physiological structure and the monitoring data of the corresponding monitoring parameters are displayed in a correlated mode, so that the relation between the physiological structure and the monitoring data is more visual.

(3) According to the thinking logic of the medical staff, the same or similar layout is adopted in a plurality of display areas or views to integrally display the monitoring parameters, so that the cognitive cost and the learning cost of the medical staff are reduced.

Drawings

FIG. 1 is a structural frame diagram of a vital information processing apparatus of an embodiment;

FIG. 2a is a display interface of presentation information of a plurality of monitoring objects according to one embodiment;

FIG. 2b is a schematic diagram of a display area of the first monitor object in FIG. 2 a;

FIG. 3a is a display interface for presenting information of a plurality of monitoring objects according to another embodiment;

FIG. 3b is a schematic diagram of a display area of the first monitor object in FIG. 3 a;

FIG. 4a is a display interface of presentation information of a plurality of monitoring objects according to yet another embodiment;

FIG. 4b is a schematic diagram of a display area of the first monitor object in FIG. 4 a;

FIG. 5 is a schematic diagram of a template setup interface of an embodiment;

FIG. 6 is a display interface of presentation information of a plurality of monitoring objects according to one embodiment;

FIG. 7 is a flowchart of a method of processing vital information according to an embodiment;

200. a display area;

210. a sub display area;

220. identity information identification;

230. status flags.

Detailed Description

The invention will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, some operations associated with the present application have not been shown or described in the specification to avoid obscuring the core portions of the present application, and may not be necessary for a person skilled in the art to describe in detail the relevant operations based on the description herein and the general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated.

The inventor finds out in practical work that clinical staff needs to know the full view of the monitored object from multiple dimensions. For example: 1. when a doctor wants to know the real-time states of a plurality of monitoring objects at the same time, the doctor needs to pay attention to the current real-time physiological parameters and waveforms of the monitoring objects, such as ECG, HR, spO2 waveforms and parameters … …;2. when a doctor needs to track the overall state of a monitored object for a period of time, judging the state of the monitored object (such as lactic acid reacting to oxygenation status, oxygenation index reacting to oxygenation status, etc.) through the trend of key physiological parameters of the monitored object and key biochemical indexes; 3. when targeted therapy is being performed clinically, especially for critically ill patients, the physician is more concerned about the condition of the subject vital signs reaching the target range.

The most important concept of the invention is to effectively integrate information of multiple dimensions of a monitored object and reduce the cognitive cost and learning cost of knowing the information of the multiple dimensions.

Referring to fig. 1, the vital information processing apparatus 100 of the embodiment of the present invention includes a memory 110, a processor 120, and a display 130, the memory 110 storing an executable program, the processor 120 executing the executable program.

The vital information processing apparatus 100 of the embodiment of the present invention includes, but is not limited to, any one of a monitor, a local central station, a remote central station, a cloud service system, a personal computer, a mobile terminal, or a combination thereof. The vital information processing apparatus 100 may be a portable vital information processing apparatus, a transportable vital information processing apparatus, a mobile vital information processing apparatus, or the like.

In one embodiment, the vital information processing apparatus 100 may be a monitor for real-time monitoring of monitoring parameters of a monitored subject, which may include a bedside monitor, a wearable monitor, and the like. The monitors may include ventilator monitors, anesthesia monitors, defibrillation monitors, intracranial pressure monitors, electrocardiographic monitors, and the like.

The vital information processing apparatus 100 may also include a central station for receiving the monitoring data transmitted by the monitors and for centrally monitoring the monitoring data. The central station may include a local central station or a remote central station, among others. The central station connects monitors in a department or a plurality of departments through a network so as to achieve the purposes of real-time centralized monitoring and mass data storage. For example, the central station stores monitoring data, basic information of a monitoring object, medical history information, diagnostic information, and the like, but is not limited thereto.

In some embodiments, the monitor and the central station may form an interconnection platform through a BeneLink to enable data communication between the monitor and the central station, e.g., the central station may access monitoring data monitored by the monitor. In other embodiments, the monitor and the central station may also establish a data connection through a communication unit including, but not limited to, wifi, bluetooth, or 2G, 3G, 4G, 5G, etc. communication units for mobile communications.

The vital information processing device 100 according to the embodiment of the present invention may be other devices besides monitoring devices, such as an image capturing device, a treatment and support device, an information system (such as CIS, HIS, shift software, decision support system, etc.), a mobile terminal (such as a ward-round vehicle), etc.

The processor 120 of the vital information processing apparatus 100 may be a central processing unit (Central Process ing Unit, CPU), but may also be other general purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Appl icat ion Specific Integrated Circuit, ASIC), field-programmable gate arrays (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The processor 120 is a control center of the vital information processing apparatus 100, and connects the respective parts of the entire vital information processing apparatus 100 using various interfaces and lines.

The memory 110 of the vital information processing apparatus 100 is used for storing an executable program, and further, the memory 110 may also store monitoring data such as vital sign data of a monitoring object with which the vital information processing apparatus 100 is associated. By way of example, the memory 110 may primarily include a program storage area and a data storage area, wherein the program storage area may store an operating system, application programs required for a plurality of functions, and the like. In addition, memory 110 may include high-speed random access memory, and may also include non-volatile memory, such as a hard disk, memory, plug-in hard disk, smart memory card, secure digital card, flash card multiple disk storage devices, flash memory devices, or other volatile solid state storage devices.

The display 130 is used to provide visual display output to the user. In particular, the display 130 may be used to provide a visual display interface for a user, including but not limited to a monitoring interface, a monitoring parameter setting interface, and the like. By way of example, the display 130 may be implemented as a touch display, or the display 130 may have an input panel, i.e., the display 130 may function as an input/output device.

In some embodiments, the vital information processing apparatus 100 further comprises a data acquisition unit, such as a sensor. The sensor can be used for continuously collecting monitoring data of monitoring parameters of a monitored object. The continuous collection means that the sensor continuously measures the monitoring data for a plurality of times at intervals of preset time, wherein the preset time means the shortest time corresponding to the time when the sensor returns one monitoring data. The data acquisition unit and the processor 120 may be connected by a wired communication protocol or a wireless communication protocol, so that data interaction may be performed between the data acquisition unit and the processor 120. Wireless communication techniques include, but are not limited to: various generations of mobile communication technologies (2G, 3G, 4G, and 5G), wireless networks, bluetooth (Bluetooth), zigBee, ultra wideband UWB, NFC, and the like.

Specifically, the data acquisition unit is used for acquiring vital sign data of the monitored object. In some embodiments, the data acquisition unit may be independently provided outside the vital information processing apparatus 100 to be detachably connected with the vital information processing apparatus 100. The processor 120 is also used for data processing of vital sign data from the data acquisition unit. In some embodiments, the vital information processing apparatus 100 may not include a sensor, and the vital information processing apparatus 100 may receive the monitoring data collected by the external monitoring accessory through the communication unit.

The vital information processing apparatus 100 may further comprise a communication unit connected to the processor 120. In some embodiments, the vital information processing apparatus 100 may establish data communication with a third party device through a communication unit. The processor 120 also controls the communication unit to acquire data of the third party device, or transmits vital sign data acquired by the data acquisition unit to the third party device. The communication units include, but are not limited to, wiFI, bluetooth, NFC, zigBee, ultra wideband UWB, or 2G, 3G, 4G, 5G, and the like mobile communication units. In other embodiments, the vital information processing apparatus 100 may also establish a connection with a third party device via a cable. Third party devices include, but are not limited to, medical devices such as monitoring devices, ventilator devices, anesthesia machine devices, infusion pump devices, image acquisition devices, and the like. The vital information processing device 100 may provide a centralized display of data collected from a plurality of third party devices. The third party device may also be a cloud service system or a non-medical device such as a television, monitor, cell phone, tablet, notebook or desktop computer, as well as one or more other devices having a hardware processor configured to execute a data display system. The vital information processing apparatus 100 may also communicate with a hospital system, for example, the vital information processing apparatus 100 may communicate wirelessly or otherwise with a third party data management system, such as a data management system for medical personnel recording information of admission, discharge, transfer, etc., or an electronic medical record (Electronic Medical Record, EMR) system.

The processor 120 in the embodiment of the present invention is configured to obtain object data of a plurality of monitoring objects, and determine at least one physiological structure associated with each monitoring object, where the object data of each monitoring object includes an information identifier of each monitoring object, and monitoring data of a plurality of monitoring parameters of each monitoring object. The information identification includes at least an identity information identification 220, the identity information identification 220 may be used to distinguish between different monitored objects, and in some embodiments, the identity information identification 220 includes any one of the following: bed number, name, age, or subject ID.

Illustratively, the physiological structure comprises a physiological system, a physiological organ, a physiological site, a tissue, a feature of the physiological system and/or a feature of the physiological organ, wherein the physiological system comprises at least one of a motor system, a nervous system, an endocrine system, a circulatory system, a respiratory system, a digestive system, a urinary system, and a reproductive system, the physiological organ comprises at least one of a brain, a heart, a lung, a liver, a stomach, and a kidney, the physiological site comprises at least one of a head, a chest, and an abdomen, the tissue comprises at least one of muscle tissue, nerve tissue, and epithelial tissue, and the feature of the physiological system or the feature of the physiological organ comprises at least one of blood coagulation, nutrition, infection, and blood glucose.

In some embodiments, the monitoring data of the monitoring parameter includes at least one of the following information:

and monitoring the real-time monitoring data of the parameters. For example, the monitored parameter is blood oxygen, and the monitored data of the monitored parameter includes a real-time blood oxygen value.

And monitoring the change trend of the monitoring data of the parameters. For example, the monitored parameter is respiration rate, and the monitored data of the monitored parameter includes a historical trend of respiration rate.

And comparing the monitoring data of the monitoring parameters with a preset threshold value or a preset threshold value range. The comparison result, which is used to characterize the comparison of the monitoring data of the monitoring parameter over the predetermined period of time with the predetermined threshold value or the presence thereof in the predetermined threshold value range, can be graphically represented, for example in fig. 3a and 3b, by means of a dashboard, showing that the heart rate falls within the range of 60 to 80 percent over the predetermined period of time.

Abnormal event information of physiological structures. For example, where the physiological structure is the respiratory system, the monitored data of the monitored parameter may include man-machine countermeasure events, man-machine dyssynchrony events, etc. that occurred over a period of time.

Diagnosis and treatment information related to the physiological structure at least comprises examination data and/or illness state data of the physiological structure. The disease condition data comprises at least one of monitoring object basic information, disease diagnosis data, treatment data, nursing data and electronic medical record data, and the examination data comprises at least one of DR image data, CT image data, MRI image data, PET image data, ultrasonic image data, scale data and physical examination data.

The plurality of monitoring objects includes a first monitoring object, and at least one of at least two physiological structures associated with the first monitoring object is preset. For example, in fig. 5, templates of monitoring parameters of heart, circulatory system and respiratory system are preset, and the defined templates can be used by one key to improve working efficiency. In some embodiments, the at least one physiological structure associated with the first monitored subject is determined from the acquired monitoring data of the plurality of monitoring parameters of the first monitored subject and based on the set physiological structure and the correspondence of the monitoring parameters. For example, a correspondence between a physiological structure and a monitoring parameter may be preset, after the monitoring parameter is acquired, the monitoring parameter is classified under a physiological structure according to the correspondence, for example, if monitoring data of a blood oxygen parameter of a monitored object is acquired, the physiological structure associated with the monitored object is set to include a respiratory system in advance, if monitoring data of a heart rate of the monitored object is acquired, the physiological structure associated with the monitored object is set to include a heart, and the monitoring parameter of a first monitored object includes the blood oxygen parameter and does not include the heart, and the physiological structure associated with the first monitored object includes a respiratory system and does not include the heart.

In some embodiments, associating different physiological structures may be preset for different monitored subjects.

In some embodiments, in a scenario in which the physiological structure associated with the monitored object is determined based on the set correspondence between the physiological structure and the monitored parameter and the acquired monitored parameter, the physiological structure associated with different monitored objects may be different according to different monitored data of the acquired monitored parameter. In other embodiments, even if the acquired monitoring data of the monitoring parameters are different, the physiological structures associated with different monitoring objects may be the same, and in this scenario, the same physiological structure may have different monitoring parameters. For example, if the monitoring data of the monitoring parameter a of the monitoring object a is obtained in advance, it is determined that the physiological structure associated with the monitoring object a includes the physiological structure a, the monitoring parameter a is classified under the physiological structure a, and if the monitoring data of the monitoring parameter B of the monitoring object B is obtained in advance, it is determined that the physiological structure associated with the monitoring object B includes the physiological structure a, and the monitoring parameter B is classified under the physiological structure a. In this case, although the physiological structures associated with the monitor object a and the monitor object B each include the physiological structure a, the monitor parameters classified under the physiological structure a are different, and naturally, the monitor data of the monitor parameters are also different.

The processor 120 controls the display 130 to display presentation information of a plurality of monitoring objects, and the presentation information of one monitoring object occupies one display area 200 of the display 130. In some embodiments, the presentation information of the plurality of monitoring objects is displayed in a permutation according to the bed numbers of the plurality of monitoring objects, for example, in fig. 2a, where there are 6 monitoring objects, the display interface of the display 130 is divided into 6 display areas 200, and the presentation information of the 6 monitoring objects is arranged according to a sequence from 01 bed to 06 bed.

The presentation information of the first monitoring object at least comprises the following information: the method comprises the steps of identifying information of a first monitoring object, at least one identification corresponding to at least one physiological structure associated with the first monitoring object one by one, and monitoring data of monitoring parameters corresponding to the at least one physiological structure determined based on the corresponding relation between the physiological structure and the monitoring parameters, wherein the identification corresponding to each physiological structure associated with the first monitoring object and the monitoring data of the monitoring parameters are displayed in a correlated mode (hereinafter referred to as a correlated display).

In one embodiment, each associated display occupies one of the sub-display sections 210 in the display section 200 corresponding to the first monitor object.

The following describes presentation information of the first monitoring object with [ Li Qiansai ] of the 01 bed in fig. 2a as the first monitoring object. The information identifier of [ Li Qiansai ] includes an identity information identifier 220, which is a bed number, a name, and an age, respectively, and the identity information identifier 220 can distinguish [ Li Qiansai ] from other monitoring objects.

The physiological structure Li Qiansai in fig. 2b includes three physiological structures, namely, a heart, a respiratory system and a circulatory system, so that 3 sub-display areas 210,3 physiological structures are formed to correspond to the 3 sub-display areas 210 one by one, and the 3 sub-display areas 210 are arranged up and down.

In some embodiments, the sub-display area 210 in the display area 200 corresponding to the monitored object may be arranged in a left-right manner or a combination of the left-right and the up-down manners. Optionally, there are visual boundaries between different sub-display sections.

For example, in fig. 6, the sub-display area 210 of the monitoring object of the 03 bed has a top-bottom layout and a left-right layout. In fig. 2b, the visualized boundaries are formed by thin lines between the sub-display sections 210, and in other embodiments, the visualized boundaries between the sub-display sections 210 may not be provided. It is understood that when there is only one physiological structure associated with the first monitoring object, there may be only one sub-display area 210 in the display area 200 corresponding to the first monitoring object, and whether the layout relationship or the boundary is visualized may not be defined.

The heart system is taken as an illustration of the display of the correlation between the identification of the physiological structure and the monitoring data of the monitored subject. The left side of the heart-corresponding sub-display area 210 of [ Li Qiansai ] is displayed with an identification of the heart, which simulates the shape outline of the heart to indicate that the sub-display area 210 corresponds to the heart, the right side of the heart-corresponding sub-display area 210 is displayed with an identification of the heart, and the left side of the heart-corresponding sub-display area 210 is displayed with monitoring data of heart-corresponding monitoring parameters, so that the identification of the heart and the relevant monitoring data are displayed in a correlated manner. In other embodiments, the identification of a physiological structure and the monitoring data corresponding to the monitoring parameter may be displayed in association in other manners, for example, the identification of a physiological structure and the monitoring data corresponding to the monitoring parameter may be arranged up and down in the sub-display area 210.

In some embodiments, when the physiological structure comprises a physiological organ, the identification of the physiological organ is used to indicate at least one item of information: outline of physiological organ and composition of physiological organ. For example [ Li Qiansai ] the identification of the heart simulates the contours of the heart.

In some embodiments, when at least two associated displays exist in the display area corresponding to the first monitoring object, the at least two associated displays are arranged and displayed according to an arrangement rule of the identifiers of the at least two physiological structures.

Three associated displays exist in the display area 200 corresponding to [ Li Qiansai ], and the three associated displays are arranged according to the arrangement rules of the identifiers of the three physiological structures. Specifically, if it is determined that the physiological structure of [ Li Qiansai ] includes the respiratory system and the circulatory system, the identification of the respiratory system may be arranged above the identification of the circulatory system, and correspondingly, the display of the association between the identification of the respiratory system and the monitored parameter of the respiratory system may also be arranged above the display of the association between the identification of the circulatory system and the monitored parameter of the circulatory system. Intuitively, the sub-display areas 210 corresponding to the respiratory system are above the sub-display areas 210 corresponding to the circulatory system, in other words, the sub-display areas 210 corresponding to the physiological systems are arranged based on the arrangement rule of the identifiers of the physiological structures. For example, the identifier of the physiological structure a may be arranged above the physiological structure B, so for any one monitoring object in the display interface, as long as it is determined that the physiological structure associated with the monitoring object includes the physiological structure a and the physiological structure B, the sub-display area 210 corresponding to the physiological structure a is above the sub-display area 210 corresponding to the physiological structure B, so that the associated display of multiple monitoring objects presents an overall unified layout, and the user can conveniently view the required information.

In some embodiments, the at least one physiological structure associated with the first monitored subject includes at least two monitoring parameters. For example, only one physiological structure is associated with the first monitoring parameter, and the monitoring parameters corresponding to the physiological structure include three physiological structures, then in the sub-display area 210 corresponding to the physiological structure, the identification of the physiological structure is displayed in association with the monitoring data of the three monitoring parameters. For another example, two physiological structures associated with the first monitoring parameter are respectively an a physiological structure and a B physiological structure, the two monitoring parameters corresponding to the a physiological structure are included, the three monitoring parameters corresponding to the B physiological structure are included, then in the sub-display area 210 corresponding to the a physiological structure, the identification of the a physiological structure is displayed in association with the monitoring data of the two monitoring parameters, and the identification of the B physiological structure is displayed in association with the monitoring data of the three monitoring parameters. The above-mentioned division to monitoring parameter uses physiological structure as the unit to every physiological structure divides to two at least monitoring parameter, compares in every physiological structure only corresponds the condition of a monitoring parameter, if divide two monitoring parameter into in a physiological structure, can more embody categorised effect, help medical personnel to look for its relevant information fast.

It was described hereinabove that the first subject associated physiological structure includes at least one, and in some embodiments, the first subject is included, and each subject associated physiological structure includes at least two. In some embodiments, the physiological structure associated with the first monitored subject includes at least two of: circulatory system, respiratory system, nervous system. For example, the first subject-associated physiological structure includes a circulatory system and a respiratory system, and for another example, the first subject-associated physiological structure includes a respiratory system and a circulatory system, and for another example, the first subject-associated physiological structure includes a circulatory system, a respiratory system, and a nervous system. That is, there is at least one physiological structure of the subject including at least two of circulatory system, respiratory system and nervous system among the plurality of subjects. In some embodiments, the corresponding monitored parameter of the circulatory system includes at least blood pressure; the corresponding monitored parameters of the respiratory system include at least one of: respiration rate and blood oxygen; the corresponding monitored parameters of the nervous system include at least intracranial pressure. In other embodiments, the physiological structure associated with the first subject includes at least the circulatory system, the respiratory system, and the heart, that is, the physiological structure of at least one subject in the plurality of subjects includes the circulatory system, the respiratory system, and the heart. In some embodiments, the corresponding monitored parameter of the circulatory system includes at least blood pressure; the corresponding monitored parameters of the respiratory system include at least one of: respiration rate and blood oxygen; the heart-corresponding monitoring parameters include at least heart rate.

In some embodiments, the information identification further includes a status evaluation result of the monitored object. The state evaluation result of the monitoring object includes at least one of the following: the evaluation result of the at least one physiological structure associated with the first monitoring object, the evaluation result of the overall state of the first monitoring object, to reflect the overall condition of the physiological function of the portion. The following will specifically describe.

In some embodiments, the evaluation result of the physiological structure associated with the first monitoring object is determined according to at least one of the following: the critical degree of the first monitoring object, the disease type of the first monitoring object, the stability of the state of the first monitoring object, the clinical operation performed on the physiological structure, and the monitoring data of the monitoring parameter corresponding to the at least one physiological structure of the first monitoring object.

Illustratively, the respiratory system may be evaluated in accordance with the following monitoring parameters: the evaluation of the respiratory system may include overall state of the respiratory system (e.g., respiratory instability), current problems of the respiratory system (transient hypoxia, intermittent compliance reduction), possible risks (risk of pressure injury), etc.

By way of example, the circulation system may be evaluated in accordance with the following monitoring parameters: shock index, blood pressure (which may be invasive or non-invasive), cardiac output, lactic acid (Lac), laboratory indicators and hemodynamic parameters related to hemodynamic and perfusion conditions, information about support or treatment equipment related to the circulatory system, and the like. Among them, laboratory indicators include, but are not limited to, hemoglobin (Hb or HGB), red blood cell count (RBC), pH, HCO3, base remaining (BE); hemodynamic parameters include, but are not limited to, central venous pressure, CVP, peripheral vascular resistance index, SVRI, pulmonary water index, ELWI, central venous oxygen saturation, scvO2; the information about the circulatory system-related support device or treatment device includes the treatment mode in which the support device or treatment device is used, key parameters of the device, etc., for example, whether to use the circulatory support device such as ECMO, whether to use the balloon refute pump IABP, whether to use the vasoactive drug, etc. The evaluation result of the circulatory system may include the overall state of the circulatory system (e.g., circulatory instability).

By way of example, the nervous system may be evaluated according to the following monitoring parameters: consciousness score, brain blood pressure and blood oxygen index, clinical assessment results related to the nervous system, etc. Where the clinically common consciousness score is the GCS score (glasgo coma score), but also allows the user to define consciousness scoring rules by themselves. Clinical assessment results related to the nervous system include assessment of pupil size, pupil light reflex assessment, extremity muscle strength assessment, etc.

By way of example, the heart may be evaluated in accordance with the following monitoring parameters: TIMI (myocardial infarction thrombolysis treatment) score, GRACE (global acute coronary syndrome registration) score; heart rate and cardiac-related biochemical markers such as creatine kinase isozymes (CK-MB), troponin (cTn), titanium natriuretic (NT-proBNP), and the like; cardiac related alarm events, such as ST elevation or depression events, arrhythmia events, and the like.

For example, the liver may be assessed according to liver function assessment indicators such as alanine Aminotransferase (ALT), gamma-glutamyl transfer (GGT), total bilirubin (Tbi), direct bilirubin (Dbi l), and ammonia-blood (AMM).

For example, kidneys may be evaluated based on urine volume and fluid ingress and egress. The liquid input/output amounts include a liquid input amount and a liquid output amount, wherein the liquid input amount includes a total input amount for 24 hours, and a liquid input amount by which the infusion pump pumps into the human body within 24 hours. Further, the liquid intake may also include a dietary liquid amount and the like. Fluid output includes 24 hours urine, 24 hours drainage, other equipment dehydration, etc. Fluid output may also include perspiration, excretion, vomiting, bleeding fluid output, and the like.

In addition, the evaluation result of the physiological structure of the first monitoring object may be an evaluation result under other evaluation criteria, or may be a score subjectively manually set by the user, for example, according to clinical experience.

Illustratively, in fig. 2b, the evaluation result of the physiological structure is represented by a status flag 230 representing the evaluation result of the physiological structure, the status flag 230 of the circulatory system is red, the status flag 230 of the respiratory system is green, the evaluation result of the circulatory system is not optimistic, and the evaluation result of the respiratory system is good.

After the result of the evaluation of the physiological structure is obtained, in some embodiments, the identification corresponding to the physiological structure is used to indicate the result of the evaluation of the physiological structure. Illustratively, the evaluation result of the physiological structure may be indicated by a display attribute of the identifier of the physiological structure, where the display attribute includes, but is not limited to, color, brightness, background color, contrast, etc., for example, the critical level of the physiological structure a is higher than that of the physiological structure B, the brightness of the identifier corresponding to the physiological structure a is higher than that of the identifier corresponding to the generating structure B, and for example, the identifier corresponding to the physiological structure a is displayed in a striking manner such as red, and the identifier corresponding to the physiological structure B is displayed in green.

In some embodiments, the evaluation result of the overall state of the first monitoring object is determined according to at least one of the following: the criticality of the first subject, the type of condition of the first subject, the stability of the state of the first subject, a clinical procedure performed on the first subject, pre-entered information related to a level judgment of the first subject, a time of admission to the first subject, the type or dose of medication ingested by the first subject, an assessment of at least one physiological structure associated with the first subject, an SOFA (sequential organ failure) score, a NEWS (early warning in the united kingdom) score, or a user-entered score. The aim of the SOFA score is to describe the occurrence and development of multiple organ dysfunction and evaluate the morbidity, and the SOFA score relates to six score indexes of respiratory system, blood system, liver, cardiovascular system, central nervous system and kidney, wherein the score interval of each score index is 0-4 points, the sum of scores is the total SOFA score, and the higher the score is, the worse the prognosis is. The NEWS score relates to six score indexes of respiratory rate, blood oxygen saturation, body temperature, systolic pressure, pulse and consciousness level, the score interval of each score index is 0-3 points, when a monitored subject needs to inhale oxygen, another 2 points are counted, and the sum of the scores of all the indexes is the total score of the NEWS score. For example, the evaluation result of the at least one physiological structure associated with the first monitoring object may be a cardiopulmonary status classification evaluation result, which is an evaluation result obtained by performing classification evaluation on the cardiopulmonary status according to both respiratory and circulatory aspects, wherein the evaluation result of which the severity of one of respiratory instability and circulatory instability is high, the evaluation result of which neither respiratory instability nor circulatory instability is high is medium, neither respiratory nor circulatory instability is found to be low, and a higher level indicates that the condition is more serious.

In addition, the evaluation result of the overall state of the first monitoring object may be an evaluation result under other evaluation criteria, or may be a score set subjectively and manually by the user, for example, according to clinical experience. For example, the critical score in fig. 3a to 4b may represent an evaluation result of the overall state of the monitoring object.

In some embodiments, the information identification further includes a level of the monitored object, and the object data of the monitored object further includes data for determining the level of the monitored object. When the level of the monitoring object is evaluated, the level of the monitoring object can be directly classified according to the data, or the state of the monitoring object can be evaluated according to the data, so that the state evaluation result of the monitoring object described above is obtained, and then the monitoring object is classified according to the state evaluation result of the monitoring object. If the acquired data includes the state evaluation result of the monitoring object, the monitoring object can be classified directly according to the state evaluation structure in the data.

In some embodiments, the data for determining the level of the monitored subject includes at least one of vital sign data, test data, examination data, and condition data.

Exemplary vital sign data of the monitored subject includes, but is not limited to, at least one of an electrocardiograph, blood pressure, pulse, blood oxygen, respiration, body temperature, cardiac output, carbon dioxide, motion data, video data, respiratory mechanics parameters, hemodynamic parameters, oxygen metabolism parameters, electroencephalogram parameters, dual frequency index, and microcirculation parameters. The processor 120 may acquire vital sign data acquired by the vital information processing apparatus 100 itself from the data acquisition unit, or may receive vital sign data of a monitored subject from an external apparatus through the communication unit. Illustratively, the external devices include a treatment device including a ventilator, an anesthesia machine, an infusion pump, an extracorporeal circulation device, and the like, an examination device including an ultrasound imaging device, an endoscope device, and the like, and a third party system including a PACS system (image archiving and communication system), an LIS system (laboratory information system), a CIS system (clinical information system), and the like.

Illustratively, the condition data includes at least one of basic information of the monitored subject, disease diagnosis data, treatment data, care data, and electronic medical record data. The basic information of the monitoring object comprises age, weight, gender and the like, and the disease diagnosis data comprises medical history, diagnosis report, medical advice, inquiry dialogue, the type of a department where the monitoring object is located, the sickbed number of the monitoring object, information which is input in advance by medical care and related to the level judgment of the monitoring object, the time of admission of the monitoring object, the type or dosage of medicines ingested by the monitoring object and the like. The vital information processing apparatus 100 can acquire the condition data of the monitored subject through the electronic medical record, or receive the condition data input by the medical staff.

The test data includes, for example, biochemical test index data collected by the in vitro diagnostic device, the biochemical test index data including at least one of blood routine test data, liver function test data, kidney function test data, thyroid test data, urine test data, immune test data, blood coagulation test data, blood gas test data, stool routine test data, and tumor marker test data, and the vital information processing device 100 may acquire test data of a monitoring subject through a hospital laboratory information management system.

The examination data includes data acquired by a medical imaging device, specifically at least one of DR image data, CT image data, MRI image data, PET image data, ultrasound image data, scale data, and physical examination data, and the vital information processing device 100 may acquire the examination data from the medical imaging device or an image induction and communication system.

Illustratively, the state evaluation results include at least one of cardiopulmonary state grading evaluation results, SOFA scores, NEWS scores, and user-entered scores, which evaluation results or scores are described above and are not described herein.

Illustratively, in fig. 2a and 2b, the level of the monitored subject is indicated by roman numerals, and the current level [ Li Qiansai ] is level I, indicating that the condition of [ Li Qiansai ] is in the most serious state.

In some embodiments, the presentation information of the plurality of monitoring objects is displayed according to the levels of the plurality of monitoring objects, for example, in fig. 2a, the presentation information of the monitoring objects is arranged in order from low level to high level.

After the level of the monitored object is obtained, in some embodiments, the information identifier further includes information characterizing a change in the level of the monitored object over a preset period of time. For example, if the level of the first monitor object is changed from I to II within 24 hours, an upward arrow may be displayed near the level when the level of the first monitor object is displayed to indicate that the level of the first monitor object is higher than before, which helps the user to understand the overall condition change of the first monitor object, and if a clinical operation such as treatment is performed on the first monitor object within a preset time, the effect of the clinical operation may be evaluated.

In some embodiments, when the display 130 is controlled to display presentation information of a plurality of monitoring objects in an arrangement, the display 130 is controlled to display the presentation information of the plurality of monitoring objects in any one of a real-time parameter view, a physical sign trend view, and a real-time target view. For the first monitored object, the monitoring data of the monitoring parameters of the physiological structure associated with the first monitored object in the real-time parameter view comprises real-time monitoring data of the monitoring parameters, or comprises signal waveforms and real-time monitoring data of the monitoring parameters. For example, in fig. 3b, a real-time heart rate value 75 is included, along with a real-time heart rate waveform. The monitored data of the monitored parameter of the physiological structure associated with the first monitored subject in the vital signs trend view includes a trend graph of the monitored data of the monitored parameter. For example in fig. 4b, a historical trend of heart rate. The monitoring data of the monitoring parameters of the physiological structure associated with the first monitoring object in the real-time target view comprises a comparison result of the monitoring data of the monitoring parameters and a preset threshold value or a preset threshold value range, and the comparison result is used for representing the comparison condition of the monitoring data of the monitoring parameters and the preset threshold value or the condition of the monitoring data of the monitoring parameters being located in the preset threshold value range in a preset time period. The meaning of the monitoring data of the monitoring parameters in each view has been explained above, and will not be described here. In some embodiments, the three views may not be strictly differentiated, for example, one view may include both real-time monitoring data of the monitored parameter and a comparison result of the monitoring data of the monitored parameter and a preset threshold value or a preset threshold range, and the view may be regarded as a real-time parameter view or a real-time target view.

For example, in fig. 3a, the view of the plurality of monitoring objects for displaying the presentation information can be regarded as a real-time parameter view or a real-time target view, while in fig. 4a, the plurality of monitoring objects display the presentation information through a sign trend view.

In some embodiments, the different views may be further switched, and the processor 120 is configured to switch the presentation information of the plurality of currently displayed monitoring objects from a first view to a second view based on the view switching instruction, where the first view is one of a real-time parameter view, a sign trend view, and a real-time target view, and the second view is another one of the real-time parameter view, the sign trend view, and the real-time target view.

In some embodiments, the view switching command is triggered by a user's one-step operation, where one-step operation refers to that from the user's perspective, only one action needs to be performed to complete the switching of the view.

For example, the view switching instruction may be determined by a click operation of the user. For example, left and right arrows are provided on the display interface, and when the user clicks the left arrow, the current view is switched to the previous view, and when the user clicks the right arrow, the current view is switched to the next view.

For example, the view switching instruction may be determined by a sliding operation of the user. For example, when the user slides left on the display, the current view is switched to the previous view, and when the user slides right on the display interface, the current view is switched to the next view. In addition, the view switching instruction can be determined through gesture operation or voice operation of a user.

In some embodiments, the view switch instruction is triggered by a two or more step operation by the user, such as in fig. 3a and 4a, the user may click on the drop down menu in the upper right corner and then further manipulate the view displayed in the display interface.

In some embodiments, at least two associated displays exist in the display area 200 corresponding to the first monitoring object, and the arrangement manner of the at least two associated displays in the first view and the second view is the same. For example, the first monitored object is [ Li Qiansai ], the physiological structure of [ Li Qiansai ] includes three, respectively, a heart, a respiratory system, and a circulatory system, and also has three associated displays, respectively, an associated display between an identification of the heart and monitored data of monitored parameters of the heart, an associated display between an identification of the respiratory system and monitored data of monitored parameters of the respiratory system, and an associated display between an identification of the circulatory system and monitored data of monitored parameters of the circulatory system. The three associated displays are arranged in the same mode in each view, for example, the associated display of the heart, the associated display of the respiratory system and the associated display of the circulatory system are arranged in sequence from top to bottom in the real-time parameter view, and the associated display of the heart, the associated display of the respiratory system and the associated display of the circulatory system are also arranged in sequence from top to bottom in the real-time target view. In this way, the user may not need to re-adapt the respective display areas 200 of the display interface when the different views are switched.

In some embodiments, the display positions of the markers corresponding to the at least two physiological structures in the first view and the second view are the same, for example, the first monitored object is [ Li Qiansai ], the position of the marker of the heart in the first view is the same as the position of the marker of the heart in the second view, and the position of the marker of the respiratory system in the first view is the same as the position of the marker of the respiratory system in the second view.

In some embodiments, the processor 120 is further configured to determine a target monitor object group from at least one monitor object group based on a group selection operation of a user, and obtain object data of a plurality of monitor objects according to monitor objects included in the target monitor object group, that is, the plurality of monitor objects in the display interface belong to the target monitor object group. For example, the monitoring objects included in each group may be preset according to the identity of the medical staff, the department to which the medical staff belongs, and the like, and when the medical staff inputs the identity of the medical staff, the group may be directly selected, so that the monitoring object to acquire the monitoring data may be rapidly determined. For example, four subgroups are shown on the upper left corner of fig. 3a, and the user clicks on one of the subgroups to cause the display interface to quickly display the presentation information of a group of monitoring objects.

In some embodiments, the processor 120 is further configured to control the display 130 to display a detail interface of the first monitor object based on a detail view instruction for the first monitor object, for example, the detail view instruction may be triggered based on a click operation of clicking the identity information identifier 220 of the first monitor object by a user, that is, after clicking the identity information identifier 220 of the first monitor object by the user, the current display interface is switched to the detail interface of the first monitor object, and the detail interface of the first monitor object may be integrated with information in the views, so that the user may find information of each dimension in one interface.

Referring to fig. 7, fig. 7 further provides a method for processing life information, which includes:

step S100, object data of a plurality of monitoring objects are acquired. The object data of each monitored object includes an information identification of each monitored object, and monitoring data of a plurality of monitoring parameters of each monitored object. The information identification includes at least an identity information identification 220, the identity information identification 220 may be used to distinguish between different monitored objects, and in some embodiments, the identity information identification 220 includes any one of the following: bed number, name, age, or subject ID.

Step S200, determining at least one physiological structure associated with each monitored subject.

The plurality of monitoring objects includes a first monitoring object, and at least one of at least two physiological structures associated with the first monitoring object is preset. For example, according to the name or age of the first monitoring object, it may be determined which physiological structures are associated with the monitoring object, the correspondence between the physiological structures and the monitoring parameters may be preset, after the monitoring parameters are obtained, the monitoring parameters are classified under a certain physiological structure according to the correspondence, for example, in fig. 5, templates of the monitoring parameters of the heart, the circulatory system and the respiratory system are preset, and the defined templates may be used by one key, so as to improve the working efficiency. In some embodiments, the at least one physiological structure associated with the first monitored subject is determined from the acquired monitoring data of the plurality of monitoring parameters of the first monitored subject and based on the set physiological structure and the correspondence of the monitoring parameters. For example, if the monitoring data of the blood oxygen parameter of the monitoring object is obtained, the physiological structure associated with the monitoring object is set to include a respiratory system, if the monitoring data of the heart rate of the monitoring object is obtained, the physiological structure associated with the monitoring object is set to include a heart, and the monitoring parameter of the first monitoring object includes the blood oxygen parameter and does not include the heart, and the physiological structure associated with the first monitoring object includes the respiratory system and does not include the heart.

Step S300, displaying the presentation information of a plurality of monitoring objects in an array mode. The presence information of one monitored object occupies one display area 200.

In some embodiments, the presentation information of the plurality of monitoring objects is displayed in an arrangement according to the bed numbers of the plurality of monitoring objects, for example, in fig. 2a, with 6 monitoring objects, the display interface is divided into 6 display areas 200, and the presentation information of the 6 monitoring objects is arranged according to the order from 01 bed to 06 bed.

The presentation information of the first monitoring object at least comprises the following information: the information identifier of the first monitoring object, at least one identifier corresponding to at least one physiological structure associated with the first monitoring object one by one, and monitoring data of monitoring parameters corresponding to the at least one physiological structure determined based on a correspondence relationship between the physiological structure and the monitoring parameters, wherein each of the identifiers corresponding to each of the physiological structures associated with the first monitoring object and the monitoring data of the monitoring parameters are displayed in association (hereinafter referred to as association display), and each of the association displays occupies one of the sub-display areas 210 in the display area 200 corresponding to the first monitoring object.

The physiological structure Li Qiansai in fig. 2b includes three physiological structures, namely, a heart, a respiratory system and a circulatory system, so that 3 sub-display areas 210,3 physiological structures are formed to correspond to the 3 sub-display areas 210 one by one, and the 3 sub-display areas 210 are arranged up and down. In some embodiments, the sub-display sections 210 in the display section 200 corresponding to the monitored object may be arranged left and right, or the left and right arrangement may be combined with the up and down arrangement. For example, in fig. 6, the sub-display area 210 of the monitoring object of the 03 bed has a top-bottom layout and a left-right layout. In fig. 2b, the visualized boundaries are formed by thin lines between the sub-display sections 210, and in other embodiments, the visualized boundaries between the sub-display sections 210 may not be provided. It is understood that when there is only one physiological structure associated with the first monitoring object, there may be only one sub-display area 210 in the display area 200 corresponding to the first monitoring object, and whether the layout relationship or the boundary is visualized may not be defined.

The heart system is taken as an illustration of the display of the correlation between the identification of the physiological structure and the monitoring data of the monitored subject. The left side of the heart-corresponding sub-display area 210 of [ Li Qiansai ] is displayed with an identification of the heart, which simulates the shape outline of the heart to indicate that the sub-display area 210 corresponds to the heart, the right side of the heart-corresponding sub-display area 210 is displayed with an identification of the heart, and the left side of the heart-corresponding sub-display area 210 is displayed with monitoring data of heart-corresponding monitoring parameters, so that the identification of the heart and the relevant monitoring data are displayed in a correlated manner. In other embodiments, the identification of a physiological structure and the monitoring data corresponding to the monitoring parameter may be displayed in association in other manners, for example, the identification of a physiological structure and the monitoring data corresponding to the monitoring parameter may be arranged up and down in the sub-display area 210. In some embodiments, when the physiological structure comprises a physiological organ, the identification of the physiological organ is used to indicate at least one item of information: outline of physiological organ and composition of physiological organ. For example [ Li Qiansai ] the identification of the heart simulates the contours of the heart.

In some embodiments, the evaluation result of the at least one physiological structure associated with the first monitored subject is determined according to at least one of: the method comprises the steps of criticality of the first subject, disease type of the first subject, stability of the state of the first subject, clinical procedures performed on at least one physiological structure of the first subject, monitoring data of a monitoring parameter corresponding to the at least one physiological structure of the first subject.

Exemplary vital sign data of the monitored subject includes, but is not limited to, at least one of an electrocardiograph, blood pressure, pulse, blood oxygen, respiration, body temperature, cardiac output, carbon dioxide, motion data, video data, respiratory mechanics parameters, hemodynamic parameters, oxygen metabolism parameters, electroencephalogram parameters, dual frequency index, and microcirculation parameters. Vital sign data acquired by the vital information processing apparatus 100 itself may be acquired from the data acquisition unit, or vital sign data of the monitoring subject may be received from an external apparatus through the communication unit. Illustratively, the external devices include a treatment device including a ventilator, an anesthesia machine, an infusion pump, an extracorporeal circulation device, and the like, an examination device including an ultrasound imaging device, an endoscope device, and the like, and a third party system including a PACS system (image archiving and communication system), an LIS system (laboratory information system), a CIS system (clinical information system), and the like.

In some embodiments, the presentation information of the plurality of monitoring objects is displayed in an arrangement according to the levels of the plurality of monitoring objects, for example, in fig. 2a, the presentation information of the monitoring objects is arranged in an order from low level to high level.

In some embodiments, when the presentation information of the plurality of monitoring objects is displayed in an arrangement, the presentation information of the plurality of monitoring objects is displayed in an arrangement of any one of a real-time parameter view, a physical sign trend view, and a real-time target view. For the first monitored object, the monitoring data of the monitoring parameters of the physiological structure associated with the first monitored object in the real-time parameter view comprises real-time monitoring data of the monitoring parameters, or comprises signal waveforms and real-time monitoring data of the monitoring parameters. For example, in fig. 3b, a real-time heart rate value 75 is included, along with a real-time heart rate waveform. The monitored data of the monitored parameter of the physiological structure associated with the first monitored subject in the vital signs trend view includes a trend graph of the monitored data of the monitored parameter. For example in fig. 4b, a historical trend of heart rate. The monitoring data of the monitoring parameters of the physiological structure associated with the first monitoring object in the real-time target view comprises a comparison result of the monitoring data of the monitoring parameters and a preset threshold value or a preset threshold value range, and the comparison result is used for representing the comparison condition of the monitoring data of the monitoring parameters and the preset threshold value or the condition of the monitoring data of the monitoring parameters being located in the preset threshold value range in a preset time period. The meaning of the monitoring data of the monitoring parameters in each view has been explained above, and will not be described here. In some embodiments, the three views may not be strictly differentiated, for example, one view may include both real-time monitoring data of the monitored parameter and a comparison result of the monitoring data of the monitored parameter and a preset threshold value or a preset threshold range, and the view may be regarded as a real-time parameter view or a real-time target view.

In some embodiments, the different views may further be switched, and based on the view switching instruction, the present information of the plurality of currently displayed monitoring objects may be switched from a first view to a second view, where the first view is one of a real-time parameter view, a sign trend view, and a real-time target view, and the second view is another one of the real-time parameter view, the sign trend view, and the real-time target view.

In some embodiments, the target monitor object group may be determined from at least one monitor object group based on a group selection operation of the user, and object data of a plurality of monitor objects are obtained according to the monitor objects included in the target monitor object group, that is, the plurality of monitor objects in the display interface belong to the target monitor object group. For example, the monitoring objects included in each group may be preset according to the identity of the medical staff, the department to which the medical staff belongs, and the like, and when the medical staff inputs the identity of the medical staff, the group may be directly selected, so that the monitoring object to acquire the monitoring data may be rapidly determined. For example, four subgroups are shown on the upper left corner of fig. 3a, and the user clicks on one of the subgroups to cause the display interface to quickly display the presentation information of a group of monitoring objects.

In some embodiments, the detail interface of the first monitor object may be displayed based on a detail view instruction for the first monitor object, for example, the detail view instruction may be triggered based on a clicking operation of clicking the identity information identifier 220 of the first monitor object by a user, that is, after clicking the identity information identifier 220 of the first monitor object by the user, the current display interface is switched to the detail interface of the first monitor object, and the detail interface of the first monitor object may be integrated with information in each view, so that the user may find information in each dimension in one interface.

According to the vital information processing apparatus and the processing method in the above embodiments:

(1) When the presentation information of a plurality of monitoring objects is displayed in an arrangement mode, parameter data of monitoring parameters are divided according to physiological structures, so that a user can intensively view the monitoring data of the monitoring parameters related to one physiological structure.

The monitoring method of the embodiment effectively provides monitoring information with multiple dimensions for medical staff, so that the medical staff can quickly know the profile of the monitoring object, the cognitive cost and the learning cost of the medical staff are reduced, and the monitoring object is automatically screened based on the user permission, so that interference caused by information overload is avoided.

Reference is made to various exemplary embodiments herein. However, those skilled in the art will recognize that changes and modifications may be made to the exemplary embodiments without departing from the scope herein. For example, the various operational steps and components used to perform the operational steps may be implemented in different ways (e.g., one or more steps may be deleted, modified, or combined into other steps) depending on the particular application or taking into account any number of cost functions associated with the operation of the device.

Additionally, as will be appreciated by one of skill in the art, the principles herein may be embodied in a computer program product on a computer readable storage medium preloaded with computer readable program code. Any tangible, non-transitory computer readable storage medium may be used, including magnetic storage devices (hard disks, floppy disks, etc.), optical storage devices (CD-ROMs, DVDs, blu-Ray disks, etc.), flash memory, and/or the like. These computer program instructions may be loaded onto a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions which execute on the computer or other programmable data processing apparatus create means for implementing the functions specified. These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including means which implement the function specified. The computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified.

While the principles herein have been shown in various embodiments, many modifications of structure, arrangement, proportions, elements, materials, and components, which are particularly adapted to specific environments and operative requirements, may be used without departing from the principles and scope of the present disclosure. The above modifications and other changes or modifications are intended to be included within the scope of this document.

The foregoing detailed description has been described with reference to various embodiments. However, those skilled in the art will recognize that various modifications and changes may be made without departing from the scope of the present disclosure. Accordingly, the present disclosure is to be considered as illustrative and not restrictive in character, and all such modifications are intended to be included within the scope thereof. Also, advantages, other advantages, and solutions to problems have been described above with regard to various embodiments. The benefits, advantages, solutions to problems, and any element(s) that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as a critical, required, or essential feature. The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, apparatus, article, or apparatus. Furthermore, the term "couple" and any other variants thereof are used herein to refer to physical connections, electrical connections, magnetic connections, optical connections, communication connections, functional connections, and/or any other connection.

Those skilled in the art will recognize that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the invention. Accordingly, the scope of the invention should be determined from the following claims.

Claims

1. A vital information processing apparatus, characterized by comprising: a memory for storing an executable program, a processor for executing the executable program, and a display, such that the processor performs the following operations:

wherein the plurality of monitoring objects includes a first monitoring object, and the at least one physiological structure associated with the first monitoring object includes at least two physiological structures;

at least one of the at least two physiological structures associated with the first monitored object is preset, and/or is determined according to the acquired monitoring data of the plurality of monitoring parameters of the first monitored object and based on the set physiological structure and the corresponding relation of the monitoring parameters;

the presentation information of the first monitoring object at least comprises the following information: the information identifier of the first monitoring object, at least two identifiers corresponding to the at least two physiological structures associated with the first monitoring object one by one, and monitoring data of different monitoring parameters corresponding to the at least two physiological structures determined based on the corresponding relation between the set physiological structures and the monitoring parameters;

2. The vital information processing apparatus according to claim 1, wherein M sub-display areas are provided in the display area corresponding to the first monitoring object, M being the number of physiological structures associated with the first monitoring object, the M sub-display areas being in an up-down layout, the M physiological structures being in one-to-one correspondence with the M sub-display areas.

3. The vital information processing apparatus according to claim 1, wherein in the associated display of each sub-display section, the monitor data of the identification and the monitor parameter corresponding to the physiological structure is presented in a left-right layout.

4. The vital information processing apparatus of claim 1, wherein there are visualized boundaries between different sub-display sections.

5. The vital information processing apparatus according to claim 1, wherein at least two associated displays exist in the display area corresponding to the first monitoring object, and the at least two associated displays are arranged according to an arrangement rule of the identifiers of the at least two physiological structures.

6. The vital information processing device of claim 1, wherein the physiological structure categories associated with different monitored subjects are the same.

7. The vital information processing device of any of claims 1-6, wherein the at least two physiological structures associated with the first monitored subject include at least two of: circulatory system, respiratory system, nervous system.

8. The vital information processing apparatus of claim 7, wherein the processor,

The corresponding monitoring parameters of the circulation system at least comprise: blood pressure;

the corresponding monitored parameters of the respiratory system include at least one of: respiration rate and blood oxygen;

the monitoring parameters corresponding to the nervous system at least comprise: intracranial pressure.

9. The vital information processing device of any one of claims 1-6, wherein the at least two physiological structures associated with the first monitored subject are included in at least one of the following classes: a physiological system, a physiological organ, a physiological site, a tissue, a feature of the physiological system, and/or a feature of the physiological organ.

10. The vital information processing device of claim 9, wherein the physiological system comprises at least one of a motor system, a nervous system, an endocrine system, a circulatory system, a respiratory system, a digestive system, a urinary system, and a reproductive system, the physiological organ comprises at least one of a brain, a heart, a lung, a liver, a stomach, and a kidney, the physiological site comprises at least one of a head, a chest, and an abdomen, the tissue comprises at least one of muscle tissue, nerve tissue, and epithelial tissue, and the characteristic of the physiological system or the characteristic of the physiological organ comprises at least one of blood coagulation, nutrition, infection, and blood glucose.

11. The vital information processing device of claim 10, wherein if the at least two physiological structures associated with the first monitored subject include the physiological organ, the identification of the physiological organ is used to indicate at least one of: the contour of the physiological organ, the composition of the physiological organ.

12. The vital information processing apparatus according to any one of claims 1 to 11, wherein the monitoring data of the monitoring parameter of one physiological structure includes at least one of the following information:

real-time monitoring data of the monitoring parameters;

a change trend of the monitoring data of the monitoring parameters;

the comparison result of the monitoring data of the monitoring parameters and a preset threshold value or a preset threshold value range is used for representing the comparison condition of the monitoring data of the monitoring parameters and the preset threshold value or the condition of the monitoring data of the monitoring parameters and the preset threshold value range in a preset time period;

abnormal event information of the physiological structure;

the diagnosis and treatment information related to the physiological structure at least comprises examination data and/or illness state data of the physiological structure.

13. The apparatus according to any one of claims 1 to 11, wherein presentation information of the plurality of monitoring objects is displayed in a line according to bed numbers of the plurality of monitoring objects and/or levels of the plurality of monitoring objects.

14. The vital information processing apparatus of any one of claims 1 to 11, wherein the information identification further comprises at least one of: the level of the monitoring object, the state evaluation result of the monitoring object and information representing the change of the level of the monitoring object in a preset time period.

15. The vital information processing apparatus according to claim 13 or 14, wherein the object data of the monitor object further includes data for judging a level of the monitor object;

wherein the data for judging the level of the monitoring object includes at least one of vital sign data, test data, examination data and illness state data, or the data for judging the level of the monitoring object includes a state evaluation result.

16. The vital information processing device of claim 15, wherein the vital sign data comprises at least one of an electrocardiograph, a blood pressure, a pulse, an blood oxygen, a respiration, a body temperature, a heart displacement, carbon dioxide, motion data, video data, a respiratory mechanics parameter, a hemodynamic parameter, an oxygen metabolism parameter, an electroencephalogram parameter, a double frequency index, and a microcirculation parameter;

The disease condition data comprises at least one of monitoring object basic information, disease diagnosis data, treatment data, nursing data and electronic medical record data;

the test data comprises at least one of blood routine test data, liver function test data, kidney function test data, thyroid test data, urine test data, immunity test data, blood coagulation test data, blood gas test data, stool routine test data and tumor marker test data;

the inspection data comprises at least one of DR image data, CT image data, MRI image data, PET image data, ultrasonic image data, scale data and physical examination data;

the state evaluation results comprise at least one of cardiopulmonary state grading evaluation results, SOFA scores, NEWS scores, and user-entered scores.

17. The vital information processing apparatus of claim 14, wherein the status evaluation result of the first monitored object includes at least one of: the method comprises the step of evaluating the overall state of the first monitoring object and evaluating at least one physiological structure associated with the first monitoring object.

18. The apparatus according to claim 17, wherein the evaluation result of the overall state of the first monitoring object is judged in accordance with at least one of: the criticality of the first subject, the type of condition of the first subject, the stability of the state of the first subject, a clinical procedure performed on the first subject, pre-entered information related to a level judgment of the first subject, a time of admission of the first subject, a type or dose of medication ingested by the first subject, an assessment of at least one physiological structure associated with the first subject, an SOFA score, a NEWS score, or a user-entered score; the evaluation result of the at least one physiological structure associated with the first monitoring object is judged according to at least one of the following: the critical degree of the first monitoring object, the disease type of the first monitoring object, the stability of the state of the first monitoring object, the clinical operation performed on at least one physiological structure of the first monitoring object, and the monitoring data of the monitoring parameters corresponding to the at least one physiological structure of the first monitoring object.

19. The vital information processing device of any one of claims 1-18, wherein the plurality of monitoring objects belong to a target monitoring object group, the processor further configured to: and determining the target monitoring object group from at least one monitoring object group based on group selection operation of a user, and acquiring object data of the plurality of monitoring objects according to the monitoring objects included in the target monitoring object group.

20. The vital information processing apparatus of claim 1, wherein the identity information identifier comprises any one of: bed number, name, age, or subject ID.

21. The apparatus according to any one of claims 1 to 20, wherein the controlling the display to arrange and display presentation information of the plurality of monitoring objects includes:

controlling the display to display the presentation information of the plurality of monitoring objects in an arrangement mode according to any one of a real-time parameter view, a physical sign trend view and a real-time target view;

for the first monitored object, the monitoring data of the monitoring parameters of the physiological structure associated with the first monitored object in the real-time parameter view comprises real-time monitoring data of the monitoring parameters, or comprises signal waveforms of the monitoring parameters and real-time monitoring data, the monitoring data of the monitoring parameters of the physiological structure associated with the first monitored object in the physical sign trend view comprises a change trend chart of the monitoring data of the monitoring parameters, the monitoring data of the monitoring parameters of the physiological structure associated with the first monitored object in the real-time target view comprises a comparison result of the monitoring data of the monitoring parameters and a preset threshold value or a preset threshold value range, and the comparison result is used for representing the comparison condition of the monitoring data of the monitoring parameters and the preset threshold value or the condition within the preset threshold value range in a preset time period.

22. The vital information processing device of claim 21, wherein the processor is further configured to:

based on a view switching instruction, switching the present information of the plurality of currently displayed monitoring objects from a first view to a second view, wherein the first view is one of a real-time parameter view, a sign trend view and a real-time target view, and the second view is the other of the real-time parameter view, the sign trend view and the real-time target view;

the view switching instruction may be determined by any one of a click operation, a slide operation, a gesture operation, and a voice operation of a user.

23. The vital information processing apparatus of claim 22, wherein at least two associated displays exist in the display area corresponding to the first monitored object, and the arrangement of the at least two associated displays in the first view and the second view is the same; and/or, the display positions of the marks corresponding to the at least two physiological structures in the first view and the second view are the same.

24. The vital information processing device of claim 1, wherein the processor is further configured to: and controlling the display to display a detail interface of the first monitoring object based on the detail viewing instruction aiming at the first monitoring object.

25. The vital information processing device of any one of claims 1-24, wherein each of the plurality of monitoring subjects is associated with at least two physiological structures.

26. The vital information processing device of any one of claims 1-25, wherein the at least two physiological structures associated with the first monitored subject comprise: circulatory system, respiratory system and heart.

27. The vital information processing device of claim 26, wherein the processor is configured to,

the corresponding monitoring parameters of the heart at least comprise: heart rate.

28. A vital information processing method, comprising:

at least one of the at least two physiological structures associated with the first monitored object is preset, and/or is determined according to the acquired monitoring data of the plurality of monitoring parameters of the first monitored object and based on the corresponding relation between the set physiological structure and the monitoring parameters;

the presentation information of the first monitoring object at least comprises the following information: the information identifier of the first monitoring object, at least two identifiers corresponding to at least two physiological structures associated with the first monitoring object one by one, and monitoring data of different monitoring parameters corresponding to the at least two physiological structures determined based on the corresponding relation between the physiological structures and the monitoring parameters;

29. A vital information processing apparatus, characterized by comprising: a memory for storing an executable program, a processor for executing the executable program, and a display, such that the processor performs the following operations:

30. The vital information processing device of claim 29, wherein the at least two monitoring parameters correspond to at least one physiological structure associated with the first monitored subject.

31. The vital information processing device of claim 29, wherein the identification of the physiological structure correspondence is used to indicate an evaluation of the physiological structure.

32. The vital information processing apparatus of any one of claims 29 to 31, wherein the monitored data of the monitored parameter of a physiological structure includes at least one of:

real-time monitoring data of the monitoring parameters;

a change trend of the monitoring data of the monitoring parameters;

abnormal event information of the physiological structure;

33. The vital information processing device of any one of claims 29 to 31, wherein the information identification further comprises at least one of: the level of the monitoring object, the state evaluation result of the monitoring object and information representing the change of the level of the monitoring object in a preset time period.

34. The vital information processing apparatus of claim 33, wherein the status evaluation result of the first monitored object comprises at least one of: the method comprises the step of evaluating the overall state of the first monitoring object and evaluating at least one physiological structure associated with the first monitoring object.

35. The vital information processing apparatus of any one of claims 29 to 33, wherein the control of the display arrangement to display presentation information of the plurality of monitor objects comprises:

36. The vital information processing device of claim 35, wherein the processor is further configured to:

37. The apparatus according to any one of claims 29 to 36, wherein each of the associated displays occupies one of the display areas corresponding to the first monitor object, there are M sub-display areas in the display area corresponding to the first monitor object, M is the number of physiological structures associated with the first monitor object, the M sub-display areas are in an up-down layout, and the M physiological structures are in one-to-one correspondence with the M sub-display areas.

38. The vital information processing apparatus of any one of claims 29 to 37, wherein in the associated display of each sub-display section, the monitor data of the identification and the monitor parameter corresponding to the physiological structure is presented in a left-right layout.

39. The vital information processing device of any one of claims 29-38, wherein the at least one physiological structure associated with the first monitored subject is preset and/or is determined from acquired monitoring data of a plurality of monitoring parameters of the first monitored subject and based on a set physiological structure to monitoring parameter correspondence.

40. The vital information processing device of any of claims 29-38, wherein the physiological structure categories associated with different monitored subjects are the same.

41. A vital information processing method, comprising:

42. A monitoring device, comprising:

a memory for storing a program;

a processor for implementing the method according to claim 28 or 41 by executing a program stored in the memory.

43. A computer readable storage medium, characterized in that the medium has stored thereon a program executable by a processor for implementing the method according to claim 28 or 41.