WO2020133426A1 - 移动监测装置、监护设备、监护系统及病人状态监测方法 - Google Patents

移动监测装置、监护设备、监护系统及病人状态监测方法 Download PDF

Info

Publication number
WO2020133426A1
WO2020133426A1 PCT/CN2018/125662 CN2018125662W WO2020133426A1 WO 2020133426 A1 WO2020133426 A1 WO 2020133426A1 CN 2018125662 W CN2018125662 W CN 2018125662W WO 2020133426 A1 WO2020133426 A1 WO 2020133426A1
Authority
WO
WIPO (PCT)
Prior art keywords
monitoring device
parameter value
data
mobile monitoring
parameter
Prior art date
Application number
PCT/CN2018/125662
Other languages
English (en)
French (fr)
Inventor
张健慧
蒋霞
陈钰
刘中华
曹建芳
岑建
Original Assignee
深圳迈瑞生物医疗电子股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 深圳迈瑞生物医疗电子股份有限公司 filed Critical 深圳迈瑞生物医疗电子股份有限公司
Priority to CN201880099009.9A priority Critical patent/CN113015479B/zh
Priority to PCT/CN2018/125662 priority patent/WO2020133426A1/zh
Priority to CN202410306637.7A priority patent/CN118303851A/zh
Publication of WO2020133426A1 publication Critical patent/WO2020133426A1/zh
Priority to US17/362,851 priority patent/US20210321886A1/en

Links

Images

Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons

Definitions

  • the present application relates to the technical field of patient state monitoring, in particular to a mobile monitoring device, monitoring equipment, monitoring system, and patient state monitoring method.
  • Traditional in-hospital monitoring equipment usually includes a bedside monitor for the serious patient, which is used to monitor the state of the patient, for the doctor to understand the patient's physical recovery status, and to indicate the patient's possible vital signs risk , Played an important role in the rehabilitation of patients and the prevention of accidents.
  • Existing monitors are ward-grade monitors/bedside monitors placed at the head of the ward in the ward, and usually the position cannot be moved.
  • Some patients, such as sub-severe patients real-time monitoring is required The state needs to be moved within a certain range. For example, if you walk outside the ward, how to meet the state monitoring of the sub-severe patients can be active outside the ward, which has become a problem to be solved.
  • the present invention provides a mobile monitoring device, monitoring equipment, monitoring system, and patient state monitoring method to solve the above problems.
  • An embodiment of the present invention provides a mobile monitoring device.
  • the mobile monitoring device includes a first type sensor, a second type sensor, and a processor.
  • the first type of sensor is used to obtain basic physiological sign parameter values, and the basic physiological sign parameter values include at least one of electrocardiographic parameter values, respiratory parameter values, blood oxygen parameter values, blood pressure parameter values, and body temperature parameter values.
  • the second type of sensor is used to obtain non-physiological sign parameter values, and the non-physiological characteristic parameter values include at least one of sleep parameter values, exercise parameter values, and pain parameter values.
  • the processor is configured to use the acquired basic physiological sign parameter value and non-physiological sign parameter value as the patient state recovery parameter value, and control to output the patient state recovery parameter value.
  • An embodiment of the present invention also provides a monitoring device.
  • the monitoring device includes a communication unit, a display screen, and a processor.
  • the processor is used to receive the relevant data of the patient state recovery parameter value through the communication unit, and control the display screen to display the received relevant data of the patient state recovery parameter value; wherein, the relevant data of the patient state recovery parameter value includes the basic physiological sign parameter value
  • Data related to non-physiological sign parameter values basic physiological sign parameter values include at least one of ECG parameter values, respiratory parameter values, blood oxygen parameter values, blood pressure parameter values, and body temperature parameter values
  • non-physiological characteristic parameter values include sleep At least one of a parameter value, an exercise parameter value, and a pain parameter value.
  • An embodiment of the present invention also provides a monitoring system.
  • the monitoring system includes a mobile monitoring device and a monitoring device.
  • the mobile monitoring device includes a first type sensor, a second type sensor, and a processor.
  • the first type of sensor is used to obtain basic physiological sign parameter values, and the basic physiological sign parameter values include at least one of electrocardiographic parameter values, respiratory parameter values, blood oxygen parameter values, blood pressure parameter values, and body temperature parameter values.
  • the second type of sensor is used to obtain non-physiological sign parameter values, and the non-physiological characteristic parameter values include at least one of sleep parameter values, exercise parameter values, and pain parameter values.
  • the processor is configured to use the acquired basic physiological sign parameter value and non-physiological sign parameter value as the patient state recovery parameter value, and control to output the patient state recovery parameter value.
  • the monitoring equipment includes a communication unit, a display screen and a processor. The processor is used to receive the relevant data of the patient state recovery parameter value through the communication unit, and control the display screen to display the received relevant data of the patient state recovery
  • An embodiment of the present invention also provides a patient state monitoring method, which is applied to a mobile monitoring device.
  • the method includes: acquiring basic physiological sign parameter values through a first type sensor of the mobile monitoring device, and the basic physiological sign parameter values include electrocardiographic parameters At least one of the value, the respiratory parameter value, the blood oxygen parameter value, the blood pressure parameter value, and the body temperature parameter value; obtain the non-physiological sign parameter value through the second type sensor of the mobile monitoring device, and the non-physiological characteristic parameter value includes the sleep parameter value, At least one of exercise parameter values and pain parameter values; and use the acquired basic physiological sign parameter values and non-physiological sign parameter values as the patient state recovery parameter values, and output the patient state recovery parameter values.
  • An embodiment of the present invention also provides a patient state monitoring method, which is applied to a monitoring device.
  • the monitoring device includes a communication unit and a display screen.
  • the method includes: receiving related data of patient state recovery parameter values through the communication unit; and controlling the display screen Display the received relevant data of the patient's state recovery parameter value; wherein, the patient's state recovery parameter value includes the relevant data of the basic physiological sign parameter value and the non-physiological sign parameter value, and the basic physiological sign parameter value includes the electrocardiogram parameter, respiratory parameter, blood oxygen At least one of a parameter, a blood pressure parameter, and a body temperature parameter, and the non-physiological characteristic parameter value includes at least one of a sleep parameter, an exercise parameter, and a pain parameter.
  • FIG. 1 is a schematic diagram of a monitoring system used in a hospital.
  • FIG. 2 is a block diagram of a mobile monitoring device.
  • FIG. 3 is a schematic structural diagram of a mobile monitoring device.
  • FIG. 4 is a schematic diagram of a parameter interface displayed on a display screen of a mobile monitoring device.
  • 5 is a schematic diagram of pairing prompt information displayed by a mobile monitoring device.
  • FIG. 6 is a pairing diagram displayed by a mobile monitoring device.
  • FIG. 7 is a block diagram of a monitoring device module.
  • FIG. 8 is a schematic diagram of a parameter interface displayed by a monitoring device.
  • FIG. 9 is a schematic diagram of pairing prompt information displayed by a monitoring device.
  • FIG. 10 is a schematic diagram of pairing displayed by a monitoring device.
  • FIG. 11 is a schematic diagram of a parameter interface displayed by a monitoring device.
  • FIG. 12 is a system framework diagram of a multi-parameter monitor or module assembly.
  • FIG. 13 is a flowchart of a method for monitoring patient status.
  • FIG. 14 is a flowchart of a method for monitoring patient status.
  • 15 is a flow chart of a method for monitoring patient status.
  • FIG. 1 is a schematic diagram of a monitoring system 100 used in a hospital.
  • the monitoring system 100 can save the data of the monitor as a whole, centrally manage patient information and nursing information, and store the two in association, which is convenient for historical data. Save and correlate alarms.
  • the monitoring system includes at least one mobile monitoring device 200 and at least one monitoring device 300.
  • the at least one monitoring device 300 includes at least one of a bedside monitoring device, a department-level workstation device, and a hospital-level data center/hospital-level emergency center management device.
  • the mobile monitoring device 200 may specifically be a wearable monitoring device.
  • the monitoring device 300 includes a bedside monitor 301, wherein a bedside monitor 301 may be provided for each bed, and the bedside monitor 301 may be a multi-parameter monitor or a plug-in monitor.
  • each bedside monitor 301 can also be paired with a mobile monitoring device 200.
  • the mobile monitoring device 200 provides a simple and portable multi-parameter monitor or module assembly, but it can be worn on the patient's body to move the patient. Monitoring, after wired or wireless communication with the bedside monitor 301 through the mobile monitoring device 200, the patient status data generated by the mobile monitoring can be transmitted to the bedside monitor 301 for display. As shown in FIG.
  • the monitoring device 300 may further include a department-level workstation device 302 and a hospital-level data center/hospital emergency center management device 303, and the mobile monitoring device 200 transmits the patient status data generated by the mobile monitoring to the department-level workstation device 302 is for the doctor or nurse to view, or transmitted to the hospital-level data center/hospital-level emergency center management device 303 through the bedside monitor 301 for storage and/or display.
  • the mobile monitoring device 200 can also directly transmit the patient status data generated by mobile monitoring to the department-level workstation device 302 through the wireless network node N1 installed in the hospital for storage and display, or through the wireless network node N1 installed in the hospital.
  • the patient status data generated by the mobile monitoring is transmitted to the hospital-level data center/hospital-level emergency center management device 303 for storage. It can be seen that the data corresponding to the patient status parameters displayed on the bedside monitor 301 can be derived from the sensor accessory directly connected to the bedside monitor, or from the mobile monitoring device 200, or from the department-level workstation equipment 302, hospital -Level data center/hospital-level emergency center management equipment 303.
  • each mobile monitoring device 200 can also store the patient status data obtained by itself
  • the bedside monitor 301 can also store the patient status data obtained by the sensor accessory connected to the bedside monitor, and store the mobile monitoring device 200 , Department-level workstation equipment 302, hospital-level data center / hospital-level emergency center management equipment 303 and other patient status data received.
  • Department-level workstation equipment 302 and hospital-level data center/hospital-level emergency center management equipment 303 can store patient status data sent by any mobile monitoring device 200.
  • FIG. 2 is a block diagram of the mobile monitoring device 200.
  • the mobile monitoring device 200 includes a first type sensor 21, a second type sensor 22 and a processor 23.
  • the processor 23 is connected to the first type sensor 21 and the second type sensor 22.
  • the first type of sensor 21 is used to obtain basic physiological sign parameter values, and the basic physiological sign parameter values include at least one of electrocardiogram parameter values, respiratory parameter values, blood oxygen parameter values, blood pressure parameter values, and body temperature parameter values.
  • the second type of sensor 22 is used to obtain non-physiological sign parameter values, and the non-physiological characteristic parameter values include at least one of sleep parameter values, exercise parameter values, and pain parameter values.
  • the processor 23 is configured to use the acquired basic physiological sign parameter value and non-physiological sign parameter value as the patient state recovery parameter value, and control to output the patient state recovery parameter value.
  • the processor 23 aggregates the acquired basic physiological sign parameter values and non-physiological sign parameter values to form a patient state recovery parameter value.
  • the mobile monitoring device 200 can obtain the basic physiological sign parameter value and the non-physiological sign parameter value at the same time, can obtain the user's physiological conditions such as electrocardiogram, breathing, and non-physiological states such as sleep and exercise, and can more fully detect The state of the patient.
  • the mobile monitoring device 200 can be a wearable monitoring device, which is used for the patient to move outside the ward after wearing, and can continuously monitor the patient's state recovery parameter value, which satisfies that the patient (such as sub-severe patients) can move outside the ward at the same time The need for condition monitoring.
  • the mobile monitoring device 200 further includes a wearable body 201, a parameter measurement cable 202, an ECG (electrocardiogram, electrocardiogram) module 203, and several electrode sheet connectors 204.
  • the wearable body 201 is connected to one end of the above-mentioned parameter measurement cable 202.
  • the parameter measurement cable 202 is provided with the ECG module 203 and the plurality of electrode pad connectors 204 in series from an end close to the wearable body 201 to an end remote from the wearable body 201.
  • the electrode pad connector 204 is used to hold the electrode pad 205.
  • the above-mentioned parameter measurement cable 202 may adopt a cable structure in which a one-line parameter measurement cable composed of the above-mentioned ECG module 203 and the above-mentioned electrode pad connectors 204 are serially connected, and It can be constructed with a bifurcated cable structure.
  • the parameter measurement cable 202 adopts a bifurcated cable structure
  • the parameter measurement cable 202 includes a trunk portion and a plurality of bifurcation portions, one end of the trunk portion is connected to the wearable body 201, and the other end of the trunk portion is connected to several branches
  • each branch portion is provided with at least one electrode sheet connector, and the above-mentioned ECG module 203 is provided at an arbitrary position on the trunk portion.
  • the wearable body 201 is used to be tied to the patient's wrist to monitor the patient's basic physiological sign parameter value and/or non-physiological sign parameter value.
  • Each electrode pad connector 204 is used to hold an electrode pad 205, and each electrode pad 205 is used to stick to a certain part of the patient's body to measure the basic physiological sign parameter value and/or non-physiological sign parameter value of the part or Impedance signal.
  • the above-mentioned ECG module 203 is provided with a defibrillation protection circuit.
  • the defibrillation protection circuit is used to protect the patient's heart from defibrillation to restore the normal heart beat when necessary.
  • the ECG module 203 and the wearable body 201 are independently installed, which reduces the volume of the wearable body 201 and is convenient to carry, and also avoids the strong current applied to the ECG module 203 to the wearable body 201
  • the signal inside causes interference.
  • the first type of sensor 21 includes at least one of an electrocardiogram sensor, a breathing sensor, a blood oxygen sensor, a blood pressure sensor, and a temperature sensor.
  • the first type of sensor 21 may include an electrocardiogram sensor, a respiration sensor, a blood oxygen sensor, a blood pressure sensor, and a temperature sensor, while simultaneously acquiring and monitoring ECG parameter values, respiratory parameter values, blood oxygen parameter values, Blood pressure parameter value, body temperature parameter value.
  • At least part of the electrode pads 205 of the plurality of electrode pads 205 sandwiched by the above-mentioned electrode pad connectors 204 constitute an ECG sensor, wherein the number of ECG sensors is plural, and each electrode pad 205 corresponds to an ECG sensor.
  • the electrode sheet 205 constituting the electrocardiographic sensor is attached to the corresponding part of the patient's body as described above, and the electrocardiographic parameter value is obtained, and the corresponding ECG data is obtained.
  • the breathing sensor is used to monitor breathing parameter values, such as respiration rate.
  • the breath sensor may also include at least one electrode pad 205 clamped by several electrode pad connectors 204.
  • the respiration sensor and the electrocardiogram sensor are integrated together and share the same electrode pad 205.
  • the blood oxygen (SPO2) sensor includes a blood oxygen probe 206 electrically connected to the wearable body 201.
  • the blood oxygen probe 206 may be a clamping structure for clamping on a patient's finger .
  • the blood oxygen parameter value is measured by the light intensity signal, for example, the blood oxygen concentration.
  • the blood pressure sensor may be disposed on the wearable body 201, for example, on the back of the wearable body 201, and used to monitor blood pressure parameter values, such as high pressure values and low pressure values.
  • the blood pressure sensor may be provided in a strap-type structure, bound to the patient's arm by the strap-type structure, and the blood pressure sensor and the wearable body 201 are connected by wire or wirelessly to monitor The blood pressure parameter value of is sent to the wearable body 201.
  • the arm bound by the blood pressure sensor is different from the arm worn by the wearable body 201, so as to avoid interference.
  • the temperature sensor can also be integrated with the ECG sensor, that is, share the same electrode pad 205. By attaching the electrode pad 205 to the corresponding part of the patient's body, the acquisition/monitoring of ECG parameter values and temperature parameters can be achieved simultaneously Value acquisition/monitoring.
  • the temperature sensor may also be provided in the ECG module 203 and include a body temperature probe led from the ECG module 203. Since the ECG module 203 is located close to the user's armpit, the cable length of the body temperature probe can be shortened , It is convenient to measure the temperature of the patient's armpit and further improve the wearing comfort.
  • the ECG module 203 includes an ECG processing circuit for processing the ECG parameter value acquired by the ECG sensor and sending it to the wearable body 201.
  • the ECG module 203 may further include a measurement circuit such as a blood pressure measurement processing circuit, a blood oxygen measurement processing circuit, and a temperature measurement processing circuit, which are used to process the parameter values acquired by the corresponding sensors before sending them to the wearable body 201.
  • the second type of sensor 22 includes at least one of an acceleration sensor and a pain sensor.
  • the second type of sensor 22 includes an acceleration sensor and a pain sensor.
  • the acceleration sensor is used to obtain the acceleration information of the patient reflecting the sleep parameter value and the motion parameter value, that is, the acceleration parameter value monitored by the acceleration sensor 22 can be used to obtain the patient's motion parameter value and sleep parameter value.
  • the acceleration value when the acceleration value is zero, the patient can be determined to be stationary.
  • the acceleration value changes the patient is reflected as movement, and the frequency of the acceleration value reflects the patient's movement pace, speed and other sports parameter values.
  • the sleep time and other sleep parameter values can be reflected.
  • acceleration sensors which are respectively installed in the wearable body 201 and the ECG module 203, which can effectively reduce the motion misdetection caused by arm movement and improve the statistical accuracy of the patient's exercise time and sleep time.
  • the pain sensor may include at least one of a humidity sensor, a sound sensor and the like. Because the patient sweats when he is in pain, and the more he sweats, the more he sweats, so the humidity value detected by the humidity sensor can also reflect the pain parameter value, that is, the pain level. For another example, when a patient is in pain, he usually yells because it is unbearable. When the voice content of the user is detected as a pain moan by the sound sensor, the pain parameter value, that is, the level of pain can be reflected according to the volume of the volume.
  • the processor 23 is provided in the wearable body 201.
  • the processor 23 obtains the patient's motion parameter value and sleep parameter value by receiving the acceleration value monitored by the acceleration sensor, and obtains by receiving the humidity value monitored by the humidity sensor and/or voice information of the sound sensor The patient's pain parameter value. Therefore, the non-physiological sign parameter value including/at least one of the sleep parameter value, the exercise parameter value, and the pain parameter value monitored/acquired by the second type sensor 22 refers to the indirect reflection of sleep monitored/acquired by the second type sensor 22 The parameter value of at least one of the parameter value, the motion parameter value, and the pain parameter value.
  • the mobile monitoring device 200 further includes a display screen 24, and the processor 23 is connected to the display screen 24 for controlling the display of the patient state recovery parameter value on the display screen 24. That is, the processor 23 controls the output of the patient state recovery parameter value to control the display of the patient state recovery parameter value on the display screen 24.
  • the display screen 24 is provided on the wearable body 201. Specifically, the display screen 24 is provided on the outer surface of the wearable body 201.
  • the wearable body 201 is a wristband device, which is used to be worn on the patient's wrist.
  • the display screen 24 is located away from the patient's wrist.
  • the back of the wearable body 201 is further integrated with a heart rate sensor for measuring heart rate/pulse rate after the wearable body 201 is worn on the wrist, wherein the heart rate sensor is a photoelectric sensor.
  • the heart rate/pulse rate measured by the heart rate sensor may be used as the ECG parameter value alone or in combination with the ECG parameter value measured by the ECG sensor as the final ECG parameter value.
  • FIG. 4 is a schematic diagram of a parameter interface displayed on the display screen 24 of the mobile monitoring device 200.
  • the control interface 24 displays a parameter interface T1 including at least one parameter value of the patient state recovery parameter value, for example, as shown in FIG. 4
  • the processor 23 controls the display screen 24 to display a parameter interface T1 including ECG parameter values, blood oxygen parameter values, breathing parameter values, and blood pressure parameter values.
  • the ECG parameter values in the figure are displayed by means of ECG curves
  • the blood oxygen parameter value is 98
  • the respiration rate is 20
  • the blood pressure is 120/80.
  • the processor 23 controls the display screen 24 to display a parameter interface including only blood pressure parameter values.
  • the processor 23 is further configured to control the switching of the parameter values displayed in the parameter interface in response to the user's operation or to control the switching of the parameter values displayed in the parameter interface T1 according to a preset time interval.
  • the parameter values displayed in the parameter interface can be switched according to the user's operation control or according to the preset time
  • the interval control switches the parameter value displayed in the parameter interface. For example, switch the blood pressure parameter value displayed on the current parameter interface to display the temperature parameter value.
  • the display screen 24 is a touch display screen, and the processor 23 controls the parameter values displayed in the switch parameter interface in response to a sliding touch operation input by the user on the display screen 24.
  • the mobile monitoring device 200 includes a mechanical switching button, and the processor 23 controls the parameter values displayed in the switching parameter interface in response to the pressing of the mechanical switching button.
  • the processor 23 when the patient state recovery parameter value displayed on the display screen 24 is a motion parameter value, the processor 23 also controls to display the motion sub-parameter value included in the motion parameter value in a circular manner, so The exercise sub-parameter values include at least one of the number of exercise steps, cadence, exercise distance, calories, exercise time, and exercise route.
  • the processor 23 switches the parameter value displayed in the parameter interface T1 to a motion parameter value
  • multiple motion sub-parameter values included in the motion parameter value are simultaneously displayed in the parameter interface, and the multiple motion sub-parameter values surround a circle .
  • the mobile monitoring device 200 further includes a communication unit 25, the processor 23 is connected to the communication unit 25, and is also used to establish a communication between the mobile monitoring device 200 and the target monitoring device 300 through the communication unit 25 Communication connection for sending the patient state recovery parameter value to the target monitoring device 300 through the communication unit 25, and outputting the patient state recovery parameter value through the target monitoring device 300; wherein, the target monitoring device 300 includes at least one of bedside monitoring equipment 301, department-level workstation equipment 302, and hospital-level data center/hospital-level emergency center management equipment 303.
  • the communication connection between the mobile monitoring device 200 and the target monitoring device 300 is a wireless communication connection.
  • the patient state recovery parameter value may be displayed by the target monitoring device 300, or may be further stored in the target monitoring device 300.
  • the communication unit 25 is provided in the wearable body 201.
  • the communication unit 25 includes a Bluetooth module
  • the mobile monitoring device 200 communicates with other mobile monitoring devices 200 through the Bluetooth module, and uses the wearable body 201 as the main communication device, and is responsible for data with the target monitoring device 300 Transmission, the wearable body 201 obtains the patient state recovery parameter value from the other mobile monitoring device 200 through the Bluetooth module, and sends it to the target monitoring device 300.
  • the wearable body 201 of the mobile monitoring device 200 only includes a communication unit 25 and a display screen 24.
  • the communication unit 25 includes a wireless communication module as a main communication device, a first type sensor 21 and a second type sensor 22 are all patch detection devices, and multiple patch detection devices also have Bluetooth modules, NFC modules, and other near-field communication modules, and send the acquired basic physiological sign parameter values and non-physiological sign parameter values to the wearable
  • the main body 201 is displayed on the display screen 24.
  • the communication unit 25 of the wearable main body 201 can also send the acquired patient recovery state data including the basic physiological sign parameter value and the non-physiological sign parameter value to the target monitoring device 300.
  • the display mode information is also sent to the target monitoring device 300 at the same time, so that the target The monitoring device 300 displays the patient state recovery parameter value according to the display mode information.
  • the display mode information defines the display position of the relevant data of the basic physiological sign parameter value and the non-physiological sign parameter value in the parameter interface for displaying the patient state recovery parameter, wherein the relevant data of the basic physiological sign parameter value is displayed in the parameter In the first area of the interface, the relevant data of the non-physiological sign parameter value is displayed in the second area of the parameter interface.
  • the target monitoring device 300 when receiving the patient state recovery parameter value, the target monitoring device 300 will display the parameter interface according to the display mode information, and display the relevant data of the basic physiological sign parameter value in the first area of the parameter interface, the non-physiological sign parameter The value-related data is displayed in the second area of the parameter interface.
  • the relevant data of the basic physiological sign parameter value includes real-time data of the basic physiological sign parameter value
  • the relevant data of the non-physiological sign parameter includes real-time data of the non-physiological sign parameter value
  • the relevant data of the non-physiological sign parameter value also includes change trend data of the non-physiological sign parameter value.
  • the change trend data of the non-physiological sign parameter value includes a plurality of historical data of non-physiological sign parameter values monitored at different times, and the non-physiological sign parameter values monitored at different times are arranged according to the monitoring time, A change trend is presented, which constitutes the change trend data.
  • the change trend data includes change trend data of multiple non-physiological sign parameter values monitored within a preset time period, for example, change trend data of multiple non-physiological sign parameter values monitored in the last week.
  • the real-time data of the basic physiological sign parameter value and the non-physiological sign parameter value may refer to the latest measurement Data of basic physiological sign parameter values and non-physiological sign parameter values.
  • the processor 23 when the target monitoring device 300 is a bedside monitor 301, the processor 23 also establishes a communication connection between the mobile monitoring device 200 and the target monitoring device 300 for the first time by the communication unit 25 During the process, a pairing operation with the target monitoring device 300 is performed, and after successful pairing with the target monitoring device 300, a communication connection between the mobile monitoring device 200 and the target monitoring device 300 is established.
  • FIG. 5 is a schematic diagram of the pairing prompt message displayed by the mobile monitoring device 200.
  • the processor 23 before performing the pairing operation with the target monitoring device, the processor 23 generates a pairing prompt message to prompt the user whether to perform pairing between the mobile monitoring device 200 and the target monitoring device 300, and selects “Yes” when the user At this time, the pairing operation with the target monitoring device 300 is performed.
  • the pairing prompt information may be text information, and the processor 23 controls the display screen 24 to display the pairing prompt information in the text form, for example, "please confirm whether to pair with the current monitoring device".
  • FIG. 6 is a schematic diagram of the pairing displayed by the mobile monitoring device 200.
  • the processor 23 performs a pairing operation with the target monitoring device 300, and controls the display screen 24 to display the pairing state schematic information currently in the pairing process.
  • the mobile monitoring device 200 shown in FIG. The information indicating that the target monitoring device 300 is pairing.
  • the processor 23 After the processor 23 has successfully paired the mobile monitoring device 200 with the target monitoring device 300, the processor 23 controls the mobile monitoring device 200 to resume displaying the parameter interface including the patient state recovery parameter value before the display.
  • the processor 23 is also used to control the synchronization of the real-time data and historical data of the patient state recovery parameter values detected by the mobile monitoring device 100 to the target monitoring after the mobile monitoring device 100 is successfully paired with the target monitoring device 200 Device 200. Therefore, after the mobile monitoring device 200 is successfully paired with the target monitoring device 300, the target monitoring device 300 will also display a parameter interface including the patient state recovery parameter value. Therefore, both the mobile monitoring device 200 and the target monitoring equipment display corresponding parameter interfaces at the same time.
  • the parameter interface displayed by the mobile monitoring device 200 and the parameter interface displayed by the target monitoring device are based on the ERAS (Patient Rehabilitation Guide) and display relevant patient state recovery parameter values.
  • the patient rehabilitation guide defines the basic physiological sign parameters and non-physiological sign parameters in the patient state recovery parameters that need to be detected during the patient recovery process, and selectively displays all or part of the patient in the parameter interface displayed by the target monitoring device 300
  • the parameter values of the patient state restoration parameters defined in the rehabilitation guide, and the parameter values of some patient state restoration parameters defined in the patient rehabilitation guide are selectively displayed on the parameter interface displayed by the mobile monitoring device 200.
  • the type/number of patient state recovery parameter values in the parameter interface displayed by the mobile monitoring device 200 is less than the type/number of patient state recovery parameter values in the parameter interface displayed by the target monitoring device 300.
  • the patient state recovery parameter value in the parameter interface displayed by the mobile monitoring device 200 is a part of the patient state recovery parameter value in the patient state recovery parameter value in the parameter interface displayed by the target monitoring device 300.
  • the parameter interface displayed by the mobile monitoring device 200 includes ECG parameter values, blood oxygen parameter values, respiratory parameter values, and blood pressure parameter values
  • the parameter interface displayed by the target monitoring device 300 may include ECG values Parameter value, blood oxygen parameter value, respiratory parameter value, blood pressure parameter value, body temperature parameter value, exercise parameter value, sleep parameter value, etc.
  • the communication unit 25 includes at least one of a Bluetooth module, a WMTS communication module, an NFC communication module, and a WIFI communication module.
  • the The mobile monitoring device 200 establishes a Bluetooth connection, a WMTS communication connection, or an NFC communication connection with the bedside monitoring device 301 through a Bluetooth module, a WMTS communication module, or an NFC communication module, and restores the patient state detected by the mobile monitoring device 200 to a parameter value
  • Both real-time data and historical data are synchronized to the bedside monitoring device 301.
  • the real-time data and historical data of the patient state recovery parameter values can be further synchronized to the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303 through the bedside monitoring device 301.
  • the mobile monitoring device 200 When the mobile monitoring device 200 is located outside the ward, the mobile monitoring device 200 establishes a WIFI communication connection with the department-level workstation equipment 302 and/or the hospital-level data center/hospital-level emergency center management equipment 303 through the WIFI module to move
  • the real-time data and historical data of the patient state recovery parameter values detected by the monitoring device 200 are synchronized to the department-level workstation equipment 302 and/or the hospital-level data center/hospital emergency center management equipment 303, and then through the department-level workstation equipment 302 and/or the hospital
  • the level data center/hospital level emergency center management device 303 synchronizes the real-time data and historical data of the patient state recovery parameter values to the bedside monitoring device 302.
  • the relevant data of the patient state recovery parameter values monitored by the mobile monitoring device 200 will be synchronized to the bedside monitoring device 302, the department-level workstation device 302 and/or
  • the hospital-level data center/hospital-level emergency center management equipment 303 enables the monitoring system 100 to store the data monitored by the mobile monitoring device 200 as a whole, which facilitates centralized management of patient information.
  • the mobile monitoring device 200 passes the Bluetooth module, WMTS communication module or NFC
  • the communication module establishes a Bluetooth connection, a WMTS communication connection or an NFC communication connection with the bedside monitoring device 301, which can effectively reduce power consumption and improve the endurance of the mobile monitoring device 100.
  • the processor 23 is further configured to control the display screen 23 to display the lock screen interface when the mobile monitoring device 200 has not received the user's operation for more than a preset duration, and in response to the user During any sliding operation of the screen, the mobile monitoring device 200 is unlocked, and the parameter interface is restored to be displayed.
  • the number of types of patient recovery parameter values included in the lock screen interface displayed by the mobile monitoring device 200 is less than the number of types of patient recovery parameter values in the parameter interface displayed after the mobile monitoring device 200 is unlocked.
  • the lock screen interface may be a simplified interface of the unlocked parameter interface, and only part of the patient recovery parameter values displayed in the unlocked parameter interface are displayed.
  • the lock screen interface may also only display time information.
  • the mobile monitoring device 200 further includes an input unit 26, and the processor 23 is further configured to set the current pain level of the user of the mobile monitoring device 200 in response to the pain level setting operation input through the input unit 26. And obtain the pain parameter value.
  • the pain parameter value may be a pain level value directly input by the doctor, nurse, or patient himself.
  • the input unit 26 may be a touch panel, which is integrated with the display screen 24 to form a touch display screen, and the pain level value may be input through an input box displayed on the display screen 24.
  • the input unit 26 may also be a mechanical key, and the doctor, nurse, or patient may input the pain level value by operating the mechanical key.
  • the monitoring device 300 includes a communication unit 31, a display screen 32 and a processor 33.
  • the processor 33 is configured to receive data related to the patient state recovery parameter value through the communication unit 31, and control the display screen 32 to display the received data related to the patient state recovery parameter value; wherein, the patient state recovery parameter value related data Including related data of basic physiological sign parameter values and non-physiological sign parameter values, the basic physiological sign parameter values include at least one of ECG parameter values, respiratory parameter values, blood oxygen parameter values, blood pressure parameter values, body temperature parameter values.
  • the non-physiological characteristic parameter values include at least one of sleep parameter values, exercise parameter values, and pain parameter values.
  • the communication unit 31 is used to establish a communication connection with the mobile monitoring device 200, and the processor 33 receives from the mobile monitoring device 200 through the communication unit 31 the relevant data of the patient state recovery parameter values acquired by the mobile monitoring device 200 as described above .
  • FIG. 8 a schematic diagram of the parameter interface T2 displayed by the monitoring device 300.
  • the processor 33 controls the display screen 32 to display the parameter interface T2 including the relevant data of the received patient state recovery parameter value as described above, wherein the relevant data of the non-physiological sign parameter value is displayed on the first page of the parameter interface T2 In an area A1, the relevant data of the basic physiological sign parameter values are displayed in the second area A2 of the parameter interface T2.
  • the first area A1 of the parameter interface T2 is the left area of the parameter interface T2, and the second area A2 is the right area of the parameter interface T2.
  • the sizes of the first area A1 and the second area A2 may be equal or unequal. In some embodiments, the size of the first area A1 is smaller than the size of the second area A2.
  • the related data of the basic physiological sign parameter value includes at least real-time data of the basic physiological sign parameter value
  • the related data of the non-physiological sign parameter value includes the real-time data of the non-physiological sign parameter value
  • the relevant data of the non-physiological sign parameter value also includes change trend data of the non-physiological sign parameter value.
  • the change trend data of the non-physiological sign parameter value includes a plurality of historical data of non-physiological sign parameter values monitored at different times, and the non-physiological sign parameter values monitored at different times are arranged according to the monitoring time, A change trend is presented, which constitutes the change trend data.
  • the change trend data includes change trend data of a plurality of non-physiological sign parameter values detected within a preset time period, for example, within the last week.
  • the first area A1 of the parameter interface T2 shows the exercise parameter value of exercise time (Exercise) and the historical trend of the exercise parameter value composed of multiple historical exercise events to the right of the exercise time data.
  • Each movement in the historical trend data of the movement parameter value also includes the target movement parameter value and the actual movement parameter value of each movement.
  • the black bars are the target movement parameter values, and correspond to The gray-white part of the column is the actual motion parameter value. Therefore, the historical trend data in FIG. 2 can also indicate the information of the achievement rate of each exercise time.
  • the first area A1 also displays sleep time (sleep time) as a sleep parameter value, and historical trend data of sleep parameter values composed of multiple historical sleep parameter values located to the right of the sleep time.
  • the historical trend data of sleep parameter values includes the sleep time of multiple sleeps.
  • the first area A1 also displays the pain parameter value of the pain level value, and the historical trend data of the pain parameter value composed of a plurality of historical pain parameter values to the right of the pain parameter value.
  • the historical trend data of the pain parameter value includes the pain level value obtained many times.
  • the exercise parameter value, sleep parameter value and pain parameter value are displayed in order from top to bottom.
  • the order of the movement parameter values, sleep parameter values and pain parameter values on the parameter interface may also be other orders, for example, the sleep parameter values, exercise parameter values and pain parameter values are displayed in order from top to bottom.
  • the data related to the basic physiological sign parameter value displayed in the second area A1 includes the real-time value and waveform of the basic physiological sign parameter value.
  • the left part of the second area A1 sequentially displays the electrocardiogram curve, the blood oxygen concentration curve, and the respiration rate curve from top to bottom.
  • the right side of the ECG curve corresponds to the real-time value of the ECG parameter value of the heart rate value ("80" shown in Figure 8) obtained from the last measurement, and the right side of the blood oxygen concentration curve corresponds to the latest time.
  • the measured blood oxygen concentration value (“90” shown in FIG. 8), the blood oxygen parameter value, corresponds to the right side of the respiration rate curve and displays the latest measured respiration rate value (as shown in FIG. 8). Shown "28") this breathing parameter value.
  • the blood pressure parameter value of arterial pressure (“120/80 (93)” shown in FIG. 8 is also displayed.
  • the second area A1 also displays historical monitoring data of multiple parameter values below the electrocardiogram curve, blood oxygen concentration curve, and respiration rate curve. For example, the figure shows blood measured at intervals of half an hour. Historical monitoring data of oxygen concentration value, respiratory rate value, blood pressure value.
  • the parameter interface T2 shown in FIG. 8 is only an example, and the number of patient state recovery parameter values displayed in the parameter interface T2 and the displayed position can be adjusted as needed.
  • FIG. 9 is a schematic diagram of the pairing prompt information displayed by the monitoring device 300.
  • the processor 33 is also used to receive the pairing request sent by the mobile monitoring device 200 during the first time the communication unit 31 establishes a communication connection with the mobile monitoring device 200, and generate a prompt message according to the pairing request, The user is prompted whether to agree to pair with the mobile monitoring device 200, and when the user selects "Yes", the pairing operation with the mobile monitoring device 200 is performed.
  • the pairing prompt information may be text information
  • the processor 33 may control the display screen 32 to display the text pairing prompt information, for example, "please confirm whether to pair with the current mobile monitoring device".
  • the processor 33 performs a pairing operation with the mobile monitoring device 200 when the user selects “Yes”, such as the “ok” option in FIG. 9, and controls the display screen 32 to display the information currently in the pairing state, for example, as shown in FIG. 10
  • the schematic information of the mobile monitoring device 200 and the target monitoring device 300 being paired is shown.
  • the processor 33 receives real-time data and historical data of the patient state recovery parameter values monitored by the mobile monitoring device 100, and displays the received patient state recovery parameters Parameter interface T2 for real-time data and historical data.
  • the processor 33 is also used to save the pairing information of the mobile monitoring device after the monitoring device 300 is successfully paired with the mobile monitoring device 200 for subsequent movement
  • the monitoring device 200 is located within the preset range of the monitoring device 300, automatic pairing is performed, and a communication connection is automatically established.
  • the processor 33 is also used to send the pairing information of the mobile monitoring device 200 to the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303 through the communication unit 32 to complete Pairing of the mobile monitoring device 200 with the department-level workstation equipment 302 and/or the hospital-level data center/hospital-level emergency center management equipment 303.
  • the bedside monitoring device 301 will also complete with the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management equipment 303 pairing.
  • the mobile monitoring device 200 moves outside the ward, it can establish a communication connection with the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303 through a WIFI network or the like.
  • the monitoring device 300 has a mobile monitoring mode and a normal mode
  • the display screen 32 displays the main interface in the normal mode
  • the processor 33 is further used to respond to the monitoring
  • the operation of the target button on the main interface of the device 300 controls the monitoring device 300 to switch to the mobile monitoring mode, and controls the display screen 32 to display the parameter interface T2 including the relevant data of the received patient state recovery parameter value.
  • the processor 33 responds to the operation of the target key on the main interface of the monitoring device 300 to control the display screen 32 to display the parameter interface T2 including the relevant data of the received patient state recovery parameter value.
  • the monitoring device 300 may only receive real-time data and historical data of the patient state recovery parameter values monitored by the mobile monitoring device 200, and the display screen 32 may not display the patient state recovery
  • the parameter interface of the parameter value when the doctor or nurse needs to check, the target display button 32 can be controlled by operating the target button, and the parameter interface T2 is displayed.
  • the target button may be the ERAS dashboard button K0 shown at the bottom of FIG. 8.
  • a number of main control buttons K1 are displayed at the bottom of the display screen 32 of the monitoring device 300 for controlling the monitoring device 300 to enter the corresponding function mode and controlling the display screen 32 to display the corresponding function interface.
  • the above keys may be virtual keys. In other embodiments, the above keys may also be mechanical keys.
  • the processor 23 of the mobile monitoring device 200 when the processor 23 of the mobile monitoring device 200 sends the patient state recovery parameter value to the target monitoring device 300 through the communication unit, it can also simultaneously send display mode information to all Scription target monitoring equipment 300.
  • the processor 33 is also used to automatically control the display parameter interface T2 according to the display mode information when the monitoring device 300 receives the patient state recovery parameter value.
  • the monitoring device 300 receives real-time data and historical data of the patient state recovery parameter values monitored by the mobile monitoring device 200, and also receives display mode information
  • the processor 33 controls the monitoring device 300 to automatically enter the mobile monitoring mode according to the display mode information, and controls the display screen 32 to display the parameter interface T2 including the relevant data of the received patient state recovery parameter value.
  • the monitoring device 300 After the monitoring device 300 is successfully paired with the mobile monitoring device 200, it automatically enters the display of the parameter interface T2, which facilitates the monitoring of the relevant data of the patient state recovery parameter value through the monitoring device 300.
  • the display mode information defines the display position of the relevant data of the basic physiological sign parameter value and the non-physiological sign parameter value in the parameter interface T2 for displaying the patient state recovery parameters, wherein the correlation of the basic physiological sign parameter value
  • the data is displayed in the first area A1 of the parameter interface T2
  • the relevant data of the non-physiological sign parameter values is displayed in the second area A2 of the parameter interface T2.
  • the monitoring device 300 when receiving the patient state recovery parameter value, the monitoring device 300 will display the parameter interface T2 according to the display mode information, and display the relevant data of the basic physiological sign parameter value in the first area A1 of the parameter interface T2.
  • the relevant data of the physical parameter values are displayed in the second area A2 of the parameter interface T2.
  • the communication unit 31 of the monitoring device 300 also includes at least one of a Bluetooth module, a WMTS communication module, and an NFC communication module.
  • the monitoring device 300 establishes a Bluetooth connection, a WMTS communication connection with the mobile monitoring device 200 through the communication unit 31 NFC communication connection.
  • the communication unit 31 of the monitoring device 300 further includes a WIFI module.
  • the monitoring device 300 When the monitoring device 300 is a bedside monitoring device 301, it also communicates with the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303 through the WIFI module Establish a WIFI communication connection, and receive the data related to the patient state recovery parameter value sent by the mobile monitoring device 200 through the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303, wherein the patient state recovery parameter value
  • the related data is sent by the mobile monitoring device 200 to the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303 via a WIFI communication connection outside the ward.
  • the mobile monitoring device 200 can send the patient status recovery to the department-level workstation device 302 and/or the hospital-level data center/hospital-level emergency center management device 303 through the WIFI communication connection
  • the relevant data of the parameter value is then forwarded by the department-level workstation equipment 302 and/or the hospital-level data center/hospital-level emergency center management equipment 303 to the bedside monitoring equipment 301 paired with the mobile monitoring device 200, which is implemented in multiple Data synchronization between devices.
  • the communication unit 31 further includes a connection interface for connecting with a corresponding sensor accessory
  • the processor 33 is further used for receiving data related to patient state recovery parameter values from the sensor accessory through the connection interface; the processor 33 also controls
  • the display screen 32 simultaneously displays the data related to the patient state recovery parameter value received from the mobile monitoring device 200 and the data related to the patient state recovery parameter received from the sensor accessory.
  • the connection interface may be an accessory interface matching the sensor accessory.
  • the processor 33 controls the parameter interface T2 displayed on the display screen 32 to include both the relevant data of the patient state recovery parameter value received by the mobile monitoring device 200 and the patient state recovery parameter value received from the sensor accessory related data.
  • FIG. 11 is a schematic diagram of a parameter interface T2' displayed by the monitoring device 300 in another embodiment.
  • the parameter interface T2 ′ shown in FIG. 11 also displays related data of the patient state recovery parameter value received from the sensor attachment, for example, venous pressure ( "8.5" shown in FIG. 11) the blood pressure parameter value and the like.
  • control is also performed In the parameter interface T2', the same type of related data of the patient state recovery parameter value received from the sensor accessory and the related data of the patient state recovery parameter value received from the mobile monitoring device 200 are simultaneously displayed.
  • the parameter interface T2' also displays the arterial pressure data "120/60” received from the mobile monitoring device 200 and the arterial pressure data "120/80" received from the sensor accessory.
  • the data of the pain parameter value includes the pain level.
  • the monitoring device 300 further includes an input unit 34, and the processor 33 is further configured to respond to the pain level setting operation input through the input unit 34. The level is set, and the pain parameter value is obtained.
  • the pain parameter value may be generated by the doctor, nurse, or even the patient through input setting of the monitoring device 300 through the input unit 34.
  • the input unit 34 may be a touch panel, and integrated with the display screen 32 to form a touch display screen.
  • the input unit 34 may also be a mechanical key.
  • the temperature parameter value of the temperature value (“37.2° C.” shown in FIG. 11) obtained from the latest measurement is also displayed.
  • the monitoring system 100 in the present application satisfies a variety of monitoring needs by monitoring the patient's basic physiological sign parameter values and non-physiological characteristic parameter values.
  • monitoring by the mobile monitoring device 200 allows the patient to perform activities outside the ward , While meeting the patient's activity needs.
  • the mobile monitoring device 200 and the bedside monitoring device 301 may be multi-parameter monitors.
  • the structure of the multi-parameter monitor please refer to the structure of the multi-parameter monitor or module assembly in FIG. 12 described below.
  • FIG. 12 is a system framework diagram of a multi-parameter monitor or module assembly.
  • the multi-parameter monitor or module assembly includes at least a parameter measurement circuit 112.
  • the parameter measurement circuit 112 includes at least one parameter measurement circuit corresponding to physiological parameters.
  • the parameter measurement circuit includes at least an electrocardiographic signal parameter measurement circuit, a respiratory parameter measurement circuit, a body temperature parameter measurement circuit, a blood oxygen parameter measurement circuit, a non-invasive blood pressure parameter measurement circuit, and At least one parameter measurement circuit in the invasive blood pressure parameter measurement circuit and the like, and each parameter measurement circuit is respectively connected to the externally inserted sensor accessory 111 through a corresponding sensor interface.
  • the sensor accessory 111 includes a detection accessory corresponding to the detection of physiological parameters such as electrocardiographic respiration, blood oxygen, blood pressure, and body temperature.
  • the parameter measurement circuit 112 is mainly used to connect the sensor accessory 111 to obtain the acquired physiological parameter signal, and may include at least two or more physiological parameter measurement circuits.
  • the parameter measurement circuit may be, but not limited to, a physiological parameter measurement circuit (module), a human body
  • the physiological parameter measurement circuit (module) or sensor acquires human physiological parameters and so on.
  • the parameter measurement circuit obtains the external physiological parameter sensor accessory through the extended interface to obtain the physiological sampling signal of the patient, and after the processing, the physiological data is obtained for alarm and display.
  • the extended interface can also be used to output the control signal about how to obtain physiological parameters output by the main control circuit to the external physiological parameter monitoring accessory through the corresponding interface to realize the monitoring and control of the patient's physiological parameters.
  • the parameter measurement circuit 112 may be the aforementioned ECG module 203; the sensor accessories 111 are sensor accessories including the aforementioned first type sensor 21 and second type sensor 21.
  • the sensor accessory 111 is an external sensor accessory that can be inserted through the sensor interface.
  • the multi-parameter monitor or module component may further include a main control circuit 113, which needs to include at least one processor 1131 and at least one memory 1132.
  • the main control circuit may also include a power management module 1133, a power IP module and an interface At least one of conversion circuits and the like.
  • the power management module is used to control the power on/off of the whole machine, the power-on sequence of each power domain inside the board, and battery charging and discharging.
  • the power IP module refers to correlating the schematic diagram of the power circuit unit that is frequently called repeatedly and the PCB layout, and curing into a separate power module, that is, converting an input voltage into an output voltage through a predetermined circuit, wherein the input voltage and The output voltage is different.
  • the power IP module may be single-channel or multi-channel.
  • the power IP module can convert an input voltage to an output voltage.
  • the power IP module can convert one input voltage to multiple output voltages, and the voltage values of the multiple output voltages can be the same or different, so as to meet the needs of multiple electronic components at the same time. Voltage demand, and the module has few external interfaces, working in the system is a black box decoupled from the external hardware system, improving the reliability of the entire power system.
  • the interface conversion circuit is used to convert the signal output by the main control minimum system module (that is, at least one processor and at least one memory in the main control circuit) into the input standard signal required by the actual external device, for example, supporting external VGA display
  • the function is to convert the RGB digital signal output from the main control CPU to a VGA analog signal, support external network functions, and convert the RMII signal to a standard network differential signal.
  • the multi-parameter monitor or module assembly may also include one or more of a local display 114, an alarm circuit 116, an input interface circuit 117, an external communication, and a power interface 115.
  • the main control circuit is used to coordinate and control each board, circuit and equipment in the multi-parameter monitor or module assembly.
  • the main control circuit is used to control the data interaction between the parameter measurement circuit 112 and the communication interface circuit, as well as the transmission of control signals, and send the physiological data to the display 114 for display, or it can be received from the touch screen or User control commands input by physical input interface circuits such as keyboards and keys, of course, can also output control signals on how to obtain physiological parameters.
  • the alarm circuit 116 may be an audible and visual alarm circuit.
  • the main control circuit completes the calculation of physiological parameters, and can send the calculation results and waveforms of the parameters to the host (such as the host with a display, PC, central station, etc.) through external communication and power interface 115, external communication and power interface 115
  • the host such as the host with a display, PC, central station, etc.
  • external communication and power interface 115 It can be one or a combination of LAN interfaces composed of Ethernet (Token), Token Ring (Token Ring), Token Bus (Token Bus), and the Backbone Network Fiber Distributed Data Interface (FDDI) as the three networks.
  • FDDI Backbone Network Fiber Distributed Data Interface
  • It can also be one or a combination of wireless interfaces such as infrared, Bluetooth, wifi, and WMTS communication, or one or a combination of wired data connection interfaces such as RS232 and USB.
  • the external communication and power interface 115 may also be one or a combination of two of a wireless data transmission interface and a wired data transmission interface.
  • the host computer can be any computer equipment such as the host computer of the monitor, the electrocardiograph, the ultrasound diagnostic apparatus, and the computer. By installing the matched software, a monitor device can be formed.
  • the host can also be a communication device, such as a mobile phone, a multi-parameter monitor, or a module component, which sends data to a mobile phone that supports Bluetooth communication through a Bluetooth interface, so as to realize remote transmission of data.
  • the local display 114 is the display screen 24, the input interface circuit 117 is the input unit 26, and the external communication and power interface 115 may be the aforementioned communication unit 25.
  • the local display 114 is the display screen 32, the input interface circuit 117 is the input unit 34, and the external communication and power interface 115 may be the aforementioned communication unit 31.
  • the multi-parameter monitoring module component can be set outside the monitor casing.
  • an independent external parameter module it can be inserted into the monitor host (including the main control board) to form a plug-in monitor as part of the monitor, or It can be connected to the host of the monitor (including the main control board) through a cable, and the external parameter module is used as an external accessory of the monitor.
  • parameter processing can also be built into the housing, integrated with the main control module, or physically separated within the housing to form an integrated monitor.
  • the mobile monitoring device 200 further includes a memory 27, which can be used to store the aforementioned relevant data of the patient state recovery parameter value.
  • the monitoring device 300 also includes a memory 35 that can be used to store data related to patient state recovery parameter values received by the monitoring device 300.
  • the memory 27 further stores program instructions, which are used by the processor 23 of the mobile monitoring device 200 to execute the foregoing functions after being called.
  • the memory 35 of the monitoring device 300 also stores program instructions, and the program instructions are used by the processor 33 of the monitoring device 300 to execute the foregoing functions after being called.
  • the memory 27, 35 may include high-speed random access memory, and may also include non-volatile memory, such as a hard disk, a memory, a plug-in hard disk, a smart memory card (Smart, Media, Card, SMC), and a secure digital (Secure Digital, SD) card, flash card (Flash Card), multiple disk storage devices, flash memory devices, or other volatile solid-state storage devices.
  • non-volatile memory such as a hard disk, a memory, a plug-in hard disk, a smart memory card (Smart, Media, Card, SMC), and a secure digital (Secure Digital, SD) card, flash card (Flash Card), multiple disk storage devices, flash memory devices, or other volatile solid-state storage devices.
  • the processor 23 and the processor 33 may be a central processing unit (Central Processing Unit, CPU), or other general-purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC ), field programmable gate array (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, etc.
  • the general-purpose processor may be a microprocessor or the processor may be any conventional processor or the like.
  • FIG. 13 is a flowchart of a patient state monitoring method in an embodiment.
  • the patient state method may be applied to the mobile monitoring device described above. As shown in FIG. 13, the method includes the following steps.
  • S131 Obtain the basic physiological sign parameter value through the first type sensor of the mobile monitoring device, where the basic physiological sign parameter value includes at least one of the ECG parameter value, the respiratory parameter value, the blood oxygen parameter value, the blood pressure parameter value, and the body temperature parameter value One kind.
  • S133 Obtain non-physiological sign parameter values through the second type sensor of the mobile monitoring device, where the non-physiological characteristic parameter values include at least one of sleep parameter values, exercise parameter values, and pain parameter values.
  • S135 Use the acquired basic physiological sign parameter value and non-physiological sign parameter value as the patient state recovery parameter value, and output the patient state recovery parameter value.
  • the obtained basic physiological sign parameter values and non-physiological sign parameter values are aggregated to form a patient state recovery parameter value.
  • step S131 and step S133 may be performed simultaneously or sequentially.
  • the mobile monitoring device further includes a display screen, and the above-mentioned "outputting the patient state recovery parameter value” includes: controlling to display the patient state recovery parameter value on the display screen of the mobile monitoring device.
  • the value of the patient state recovery parameter is displayed on the display screen of the mobile monitoring device.
  • controlling display of patient state recovery parameter values on the display screen of the mobile monitoring device includes: controlling the display screen to display a parameter interface including at least one of the patient state recovery parameter values; and responding to user operation control Switch the parameter value displayed in the parameter interface or control the parameter value displayed in the switch parameter interface according to the preset time interval.
  • the parameter values displayed in the parameter interface can be switched according to the user's operation control or according to the preset time interval Control to switch the parameter value displayed in the parameter interface. For example, switch the blood pressure parameter value displayed in the current parameter interface to the temperature parameter value for display, and so on.
  • the controlling displaying the patient state recovery parameter value on the display screen of the mobile monitoring device includes: displaying the patient state recovery parameter value on the display screen when the patient state recovery parameter value is the motion parameter value, controlling to display the motion elements included in the motion parameter value in a circular manner Parameters, the movement sub-parameter values include at least one of the number of movement steps, the step frequency, the movement distance, the calories, the movement time, and the movement route.
  • the mobile monitoring device also includes a communication unit
  • the above-mentioned "outputting the patient state recovery parameter value” may further include: establishing a communication connection with the target monitoring device through the communication unit; sending the patient state recovery parameter value to the target monitoring device, and passing The target monitoring equipment outputs patient state recovery parameter values; wherein, the target monitoring equipment includes at least one of bedside monitoring equipment, department-level workstation equipment, and hospital-level data center/hospital-level emergency center management equipment.
  • the above “sending the patient state recovery parameter value to the target monitoring device and outputting the patient state recovery parameter value through the target monitoring device” includes: when sending the patient state recovery parameter value to the target monitoring device, Send the display mode information to the target monitoring device, so that the target monitoring device displays the patient state recovery parameter value according to the display mode information.
  • the display mode information defines the display position of the relevant data of the basic physiological sign parameter value and the non-physiological sign parameter value in the display interface for displaying the patient state recovery parameter value, wherein the relevant data of the basic physiological sign parameter value is displayed in In the first display area of the display interface, the relevant data of the non-physiological sign parameter value is displayed in the second display area of the display interface.
  • the relevant data of the basic physiological sign parameter value includes real-time data of the basic physiological sign parameter
  • the relevant data of the non-physiological sign parameter includes real-time data of the non-physiological sign parameter
  • the relevant data of the non-physiological sign parameter value also includes the change trend data of the non-physiological sign parameter value.
  • the change trend data includes change trend data of multiple non-physiological sign parameter values detected in the last week.
  • the method further includes: performing the pairing operation with the target monitoring device during the first establishment of the communication connection between the mobile monitoring device and the target monitoring device; and After successfully pairing with the target monitoring device, establish a communication connection between the mobile monitoring device and the target monitoring device.
  • the method before “performing the pairing operation with the target monitoring device", the method further includes: generating pairing prompt information to prompt the user whether to perform pairing between the mobile monitoring device and the target monitoring device.
  • performing pairing operation with the target monitoring device includes: performing a pairing operation with the target monitoring device when the user selects Yes.
  • sending the patient state recovery parameter value to the target monitoring device includes: after the mobile monitoring device is successfully paired with the target monitoring device, controlling the real-time data and historical data of the patient state recovery parameter value detected by the mobile monitoring device Synchronize to the target monitoring device.
  • the communication unit of the mobile monitoring device includes at least one of a Bluetooth module, a WMTS communication module, an NFC communication module, and a WIFI communication module.
  • the mobile monitoring device passes the Bluetooth module,
  • the WMTS communication module or NFC communication module establishes a Bluetooth connection, WMTS communication connection or NFC communication connection with the bedside monitoring device;
  • the above "control synchronizes the real-time data and historical data of the patient status recovery parameter values detected by the mobile monitoring device to the target "Monitoring equipment” includes: controlling the synchronization of real-time data and historical data of patient state recovery parameter values detected by the mobile monitoring device to the bedside monitoring equipment through Bluetooth connection, WMTS communication connection or NFC communication connection.
  • the mobile monitoring device when the mobile monitoring device is located outside the ward, the mobile monitoring device establishes a WIFI communication connection with the department-level workstation equipment and/or the hospital-level data center/hospital-level emergency center management equipment through the WIFI module; the above “control will detect the mobile monitoring device
  • the real-time data and historical data of the patient's state recovery parameter values are synchronized to the target monitoring equipment, including: controlling the synchronization of the real-time data and historical data of the patient state recovery parameter values detected by the mobile monitoring device to the department-level workstation equipment through the WIFI communication connection And/or hospital-level data center/hospital emergency center management equipment, and then synchronize real-time data and historical data of patient status recovery parameter values to the bed through department-level workstation equipment and/or hospital-level data center/hospital emergency center management equipment Side monitoring equipment.
  • the above method further includes: controlling the display screen to display a lock screen when the mobile monitoring device has not received the user's operation for more than a preset time period; and responding to any sliding operation of the user on the display screen to restore the display Parameter interface.
  • the mobile monitoring device further includes an input unit
  • the above method further includes: in response to a pain level setting operation input through the input unit, setting the current pain level of the user of the mobile monitoring device.
  • FIG. 14 is a flowchart of a patient state monitoring method in another embodiment.
  • the patient state method may be applied to the mobile monitoring device 200 described above.
  • the mobile monitoring device 200 includes a communication unit and a display screen; as shown in FIG. 14 As shown, the method includes the following steps.
  • S141 Obtain basic physiological sign parameter values through the first type sensor of the mobile monitoring device, where the basic physiological sign parameter values include at least one of electrocardiogram parameter values, respiratory parameter values, blood oxygen parameter values, blood pressure parameter values, and body temperature parameter values One kind.
  • S143 Obtain non-physiological sign parameter values through the second type sensor of the mobile monitoring device, where the non-physiological characteristic parameter values include at least one of sleep parameter values, exercise parameter values, and pain parameter values.
  • the target monitoring equipment includes at least one of bedside monitoring equipment, department-level workstation equipment and hospital-level data center/hospital-level emergency center management equipment.
  • the patient state recovery parameter value acquired by the mobile monitoring device is sent to the target monitoring device for output, it will also be displayed on the display screen of the mobile monitoring device.
  • the above method may further include: establishing a communication connection with the target monitoring device through the communication unit.
  • FIG. 15 is a flowchart of a patient status monitoring method in still another embodiment.
  • the patient status method may be applied to the above-mentioned monitoring device 300, which includes a communication unit and a display screen; as shown in FIG. 15
  • the method includes the following steps.
  • S151 Receive related data of the patient state recovery parameter value through the communication unit.
  • S153 Control the display screen to display the received relevant data of the patient's state recovery parameter value; wherein, the patient's state recovery parameter value includes the relevant data of the basic physiological sign parameter value and the non-physiological sign parameter value, and the basic physiological sign parameter value includes the ECG parameter, At least one of breathing parameters, blood oxygen parameters, blood pressure parameters, and body temperature parameters, and non-physiological characteristic parameter values include at least one of sleep parameters, exercise parameters, and pain parameters.
  • step S151 may specifically include: establishing a communication connection with the mobile monitoring device through the communication unit, and receiving data related to the patient state recovery parameter value acquired by the mobile monitoring device from the mobile monitoring device through the communication unit.
  • control display screen displays the relevant data of the received patient state recovery parameter value includes: the control display screen displays a parameter interface including the relevant data of the received patient state recovery parameter value, wherein the non-physiological sign parameter value The relevant data is displayed in the first area of the parameter interface, and the relevant data of the basic physiological sign parameter values is displayed in the second area of the parameter interface.
  • the relevant data of the basic physiological sign parameter value includes real-time data of the basic physiological sign parameter value
  • the relevant data of the non-physiological sign parameter value includes real-time data of the non-physiological sign parameter
  • the relevant data of the non-physiological sign parameter value also includes the change trend data of the non-physiological sign parameter value.
  • the change trend data includes change trend data of multiple non-physiological sign parameter values detected within a preset time period before the current time, for example, changes of multiple non-physiological sign parameter values detected in the last week Trend data.
  • the method may further include: receiving a pairing request sent by the mobile monitoring device during the first time the communication unit establishes a communication connection with the mobile monitoring device; generating a prompt message according to the pairing request to prompt the user Whether to agree to pair with the mobile monitoring device; and when the user selects Yes, pair with the mobile monitoring device, and after the pairing is successful, establish a communication connection with the mobile monitoring device.
  • the method further includes: saving the pairing information of the mobile monitoring device after the monitoring device is successfully paired with the mobile monitoring device, so as to perform automatic pairing when the subsequent mobile monitoring device is within the preset range of the monitoring device.
  • the monitoring device is a bedside monitoring device placed in the ward
  • the method further includes: sending the pairing information of the mobile monitoring device to the department-level workstation device and/or the hospital-level data center/hospital-level emergency center In the management equipment, to complete the pairing of the mobile monitoring device and the department-level workstation equipment and/or the hospital-level data center/hospital-level emergency center management equipment.
  • the communication unit of the monitoring equipment includes at least one of a Bluetooth module, a WMTS communication module, and an NFC communication module.
  • the communication unit establishes a Bluetooth connection, a WMTS communication connection, or an NFC communication connection with the mobile monitoring device.
  • the monitoring device has a mobile monitoring mode and a normal mode, and the display screen displays the main interface in the normal mode.
  • the communication unit further includes a connection interface for connecting with a corresponding sensor accessory.
  • the above method further includes: receiving data related to the patient state recovery parameter value from the sensor accessory through the connection interface; "Relevant data of patient state recovery parameter values” includes: controlling the display screen to simultaneously display the relevant data of the patient state recovery parameter values received from the mobile monitoring device and the relevant data of the patient state recovery parameter values received from the sensor accessory.
  • the communication unit includes a WIFI module
  • the above-mentioned “receiving related data of patient state recovery parameter values acquired by the mobile monitoring device from the mobile monitoring device through the communication unit" also includes:
  • the pain parameter data includes a pain level
  • the monitoring device further includes an input unit.
  • the above method further includes: setting the pain level in response to the pain level setting operation input through the input unit, and acquiring the pain parameter data .
  • the patient state monitoring methods in the embodiments of the present application correspond to the aforementioned monitoring system 100, and the relevant steps and the functional operations performed by the monitoring system 100 can be referred to and correspond to each other, which will not be repeated here.
  • the present application also provides a computer-readable storage medium.
  • the foregoing computer-readable storage medium stores a plurality of program instructions for the processor 23 or the processor 33 to call and execute.
  • the present application can obtain the basic physiological sign parameter value and the non-physiological sign parameter value at the same time, can obtain the user's electrocardiogram, respiratory and other physiological conditions and sleep, exercise and other non-physiological states, and can more fully detect the patient's state.
  • the mobile monitoring device 200 can be a wearable monitoring device, it is used for the patient to move outside the ward after wearing, and can continuously monitor the state recovery parameter value of the patient, which satisfies the fact that the patient (such as sub-critically ill) moves outside the ward The need for condition monitoring.
  • any tangible, non-transitory computer-readable storage medium can be used, including magnetic storage devices (hard disks, floppy disks, etc.), optical storage devices (CD-ROM, DVD, Blu-ray disks, etc.), flash memory, and/or the like .
  • These computer program instructions can be loaded onto a general purpose computer, special purpose computer, or other programmable data processing equipment to form a machine, so that these instructions executed on a computer or other programmable data processing device can generate a device that implements a specified function.
  • Computer program instructions can also be stored in a computer-readable memory, which can instruct the computer or other programmable data processing device to operate in a specific manner, so that the instructions stored in the computer-readable memory can form a piece Manufactured products, including implementation devices that implement specified functions.
  • Computer program instructions can also be loaded onto a computer or other programmable data processing device, so that a series of operating steps are performed on the computer or other programmable device to produce a computer-implemented process that allows the computer or other programmable device to execute Instructions can provide steps for implementing specified functions.

Landscapes

  • Life Sciences & Earth Sciences (AREA)
  • Health & Medical Sciences (AREA)
  • Medical Informatics (AREA)
  • Biophysics (AREA)
  • Pathology (AREA)
  • Engineering & Computer Science (AREA)
  • Biomedical Technology (AREA)
  • Heart & Thoracic Surgery (AREA)
  • Physics & Mathematics (AREA)
  • Molecular Biology (AREA)
  • Surgery (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Public Health (AREA)
  • Veterinary Medicine (AREA)
  • Measuring And Recording Apparatus For Diagnosis (AREA)

Abstract

一种移动监测装置(200),包括第一类传感器(21)、第二类传感器(22)及处理器(23)。第一类传感器(21)用于获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种,第二类传感器(22)用于获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种,处理器(23)用于将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并控制输出病人状态恢复参数值。还涉及一种监护设备(300)、监护系统(100)及病人状态监测方法。

Description

移动监测装置、监护设备、监护系统及病人状态监测方法 技术领域
本申请涉及病人状态监测技术领域,尤其涉及一种移动监测装置、监护设备、监护系统及病人状态监测方法。
背景技术
传统的院内监护设备,通常包括针对严重病人的在病人床边设置的床边监护仪,用以对病人的状态进行监测,供医生了解病人的身体康复状态,以及提示病人可能存在的生命体征风险,对病人的康复以及意外的预防起到了重要的作用。现有的监护仪都是放置在病房中的床头处的病房级监护仪/床边监护仪,通常位置无法移动,对于某些病人来说,例如对于亚重症病人来说,既需要实时监测状态,又需要在一定范围内移动,例如,在病房外散步,则如何满足亚重症病人能够在病房外活动的同时进行状态监测,成为了需要解决的问题。
发明内容
本发明提供一种移动监测装置、监护设备、监护系统及病人状态监测方法,以解决上述问题。
本发明实施例提供一种移动监测装置,移动监测装置包括第一类传感器、第二类传感器及处理器。第一类传感器用于获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种。第二类传感器用于获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。处理器用于将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并控制输出病人状态恢复参数值。
本发明实施例还提供一种监护设备,监护设备包括通信单元、显示屏以及处理器。处理器,用于通过通信单元接收病人状态恢复参数值的相关数据,并控制显示屏显示接收的病人状态恢复参数值的相关数据;其中,病人状态恢复参数值的相关数据包括基本生理体征参数值和非生理体征参数值的相关数据,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。
本发明实施例还提供一种监护系统,监护系统包括移动监测装置和监护设备,移动监测装置包括第一类传感器、第二类传感器及处理器。第一类传感器用于获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种。第二类传感器用于获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。处理器用于将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并控制输出病人状态恢复参数值。监护设备包括通信单元、显示屏以及处理器。处理器,用于通过通信单元接收病人状态恢复参数值的相关数据,并控制显示屏显示接收的病人状态恢复参数值的相关数据。
本发明实施例还提供一种病人状态监测方法,应用于移动监测装置中,所述方法包括:通过移动监测装置的第一类传感器获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种;通过移动监测装置的第二类传感器获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种;以及将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并输出病人状态恢复参数值。
本发明实施例还提供一种病人状态监测方法,应用于监护设备中,监护设备包括通信单元和显示屏,所述方法包括:通过通信单元接收病人状态恢复参数值的相关数据;以及控制显示屏显示接收的病人状态恢复参数值的相关数据;其中,病人状态恢复参数值包括基本生理体征参数值和非生理体征参数值的相关数据,基本生理体征参数值包括心电参数、呼吸参数、血氧参数、血压参数、体温参数中的至少一种,非生理特征参数值包括睡眠参数、运动参数、疼痛参数中的至少一种。
附图说明
为了更清楚地说明本发明实施例中的技术方案,下面将对实施例中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本发明的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。
图1为一种院内使用的监护系统的示意图。
图2为一种移动监测装置的模块架构图。
图3为一种移动监测装置的结构示意图。
图4为一种移动监测装置的显示屏显示的参数界面的示意图。
图5为一种移动监测装置显示的配对提示信息的示意图。
图6为一种移动监测装置显示的配对示意图。
图7为一种监护设备的模块架构图。
图8为一种监护设备显示的参数界面的示意图。
图9为一种监护设备显示的配对提示信息的示意图。
图10为一种监护设备显示的配对示意图。
图11为一种监护设备显示的参数界面的示意图。
图12为一种多参数监护仪或模块组件的系统框架图。
图13为一种病人状态监测方法的流程图。
图14为一种病人状态监测方法的流程图。
图15为一种病人状态监测方法的流程图。
具体实施方式
本文参照了各种示范实施例进行说明。然而,本领域的技术人员将认识到,在不脱离本文范围的情况下,可以对示范性实施例做出改变和修正。例如,各种操作步骤以及用于执行操作步骤的组件,可以根据特定的应用或考虑与系统的操作相关联的任何数量的成本函数以不同的方式实现(例如一个或多个步骤可以被删除、修改或结合到其他步骤中)。
本发明的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别不同的对象,而不是用于描述特定顺序。此外,术语“包括”和“具有”以及它们任何变形,意图在于覆盖不排他的包含。例如包含了一系列步骤或单元的过程、方法、系统、产品或设备没有限定于已列出的步骤或单元,而是可选地还包括没有列出的步骤或单元,或可选地还包括对于这些过程、方法或设备固有的其他步骤或单元。
请参阅图1,为一种院内使用的监护系统100的示意图,利用监护系统100可以将监护仪的数据进行整体保存,集中管理病人信息和看护信息,两者进行关联存储,便于进行历史数据的保存和关联报警。在图1所示的监护系统100中,监护系统包括至少一个移动监测装置200以及至少一个监护设备300。至少一个监护设备300包括床边监护设备、科室级工作站设备和院级数据中心/院级急救中心管理设备中的至少一种。移动监测装置200具体可以为可穿戴式监测装置。
如图1所示,监护设备300包括床边监护仪301,其中,针对每个病床均可以提供一个床边监护仪301,该床边监护仪301可以是多参数监护仪或者插件式监护仪。另外,每 个床边监护仪301还可以与一个移动监测装置200进行配对传输,移动监测装置200提供简便、可携带的多参数监护仪或模块组件,可是穿戴在病人身体上对应病人进行移动式监护,通过移动监测装置200与床边监护仪301进行有线或无线通讯后可以将移动式监护产生的病人状态数据传输到床边监护仪301上进行显示。如图1所示,监护设备300还可包括科室级工作站设备302及院级数据中心/院级急救中心管理设备303,移动监测装置200通过移动式监护产生的病人状态数据传输至科室级工作站设备302供医生或护士查看,或通过床边监护仪301传输到院级数据中心/院级急救中心管理设备303进行存储和/或显示。
另外,移动监测装置200还可以直接通过设置在院内的无线网络节点N1将移动式监护产生的病人状态数据传输到科室级工作站设备302进行存储和显示,或者通过设置在院内的无线网络节点N1将移动式监护产生的病人状态数据传输到院级数据中心/院级急救中心管理设备303进行存储。可见,床边监护仪301上显示的病人状态参数对应的数据可以是源自直接连接到床边监护仪上的传感器附件,或者源自移动监测装置200,或者源自科室级工作站设备302、院级数据中心/院级急救中心管理设备303。
其中,每个移动监测装置200也可存储自身获取到的病人状态数据,床边监护仪301也可存储连接到床边监护仪上的传感器附件获取的病人状态数据,以及存储从移动监测装置200、科室级工作站设备302、院级数据中心/院级急救中心管理设备303等接收的病人状态数据。科室级工作站设备302、院级数据中心/院级急救中心管理设备303则可存储任何移动监测装置200发送过来的病人状态数据。
请参阅图2,为移动监测装置200的模块架构图。如图2所示,移动监测装置200包括第一类传感器21、第二类传感器22以及处理器23。处理器23与第一类传感器21、第二类传感器22连接。
第一类传感器21用于获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种。
第二类传感器22用于获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。
处理器23用于将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并控制输出病人状态恢复参数值。
其中,处理器23将获取到的基本生理体征参数值以及非生理体征参数值进行汇总后形成病人状态恢复参数值。
从而,本申请中,移动监测装置200可同时获取基本生理体征参数值和非生理体征参数值,能够获取用户的心电、呼吸等生理状况以及睡眠、运动等非生理状态,能够更加全面侦测病人的状态。
其中,移动监测装置200可为穿戴式监测装置,用于供病人穿戴后在病房外活动,同时能持续监测病人状态恢复参数值,满足了病人(例如亚重症病人)在病房外活动的同时进行状态监测的需求。
请一并参阅图3,为移动监测装置200的结构示意图。移动监测装置200还包括穿戴式主体201、参数测量线缆202、ECG(electrocardiogram,心电图)模块203和若干电极片连接器204。穿戴式主体201连接于上述参数测量线缆202的一端。上述参数测量线缆202从靠近上述穿戴式主体201的一端到远离上述穿戴式主体201的一端上依次串设有上述ECG模块203和上述若干个电极片连接器204。上述电极片连接器204用于夹持电极片205。更进一步地,在其中一些变形实施例中,上述参数测量线缆202可以采用一根电缆结构依次串设有上述ECG模块203和上述若干电极片连接器204构成的一线式参数测量线缆,也可以采用分叉式线缆结构构成。若上述参数测量线缆202采用分叉式线缆结构,则参数测量线缆202包含主干部和至若干分叉部,主干部的一端连接上述穿戴式主 体201,主干部的另一端连接若干分叉部,每个分叉部设置至少一种电极片连接器,在主干部上的任意位置设置上述ECG模块203。
具体地,上述穿戴式主体201用于绑在病人腕部以监测病人的基本生理体征参数值和/或非生理体征参数值。每个电极片连接器204用于夹持一片电极片205,每个电极片205用来贴到病人身体的某一部位以测量该部位的基本生理体征参数值和/或非生理体征参数值或阻抗信号。上述ECG模块203中设置有除颤防护电路,除颤防护电路用于在必要时为病人心脏除颤以恢复正常的心脏跳动时避免移动监测装置200受损的保护电路。本申请中,上述ECG模块203与上述穿戴式主体201独立设置,使得上述穿戴式主体201的体积减小,便于携带,同时也避免了施加在上述ECG模块203的强电流对上述穿戴式主体201内的信号造成干扰。
其中,本申请中,第一类传感器21包括心电传感器、呼吸传感器、血氧传感器、血压传感器以及温度传感器中的至少一种。在一些实施例中,第一类传感器21可同时包括心电传感器、呼吸传感器、血氧传感器、血压传感器以及温度传感器,而同时获取和监测心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值。
上述若干个电极片连接器204夹持的若干电极片205中至少部分电极片205构成心电传感器,其中,心电传感器的数量为多个,每个电极片205对应为一个心电传感器,通过上述的将构成心电传感器的电极片205贴放在病人身体的相应部位,而实现心电参数值的获取,而得到相应的ECG数据。
其中,呼吸传感器用于监测呼吸参数值,例如呼吸率。呼吸传感器也可包括若干个电极片连接器204夹持的至少一种电极片205。在一些实施例中,呼吸传感器和心电传感器整合在一起,共用相同的电极片205。
如图3所示,所述血氧(SPO2)传感器包括与穿戴式主体201电连接的血氧探头206,所述血氧探头206可为夹持式结构,用于夹持在病人的手指上,通过光强信号测量血氧参数值,例如,血氧浓度。
所述血压传感器可设置于穿戴式主体201上,例如设置于穿戴式主体201的背面,用于监测血压参数值,例如高压值以及低压值。
在一些实施例中,所述血压传感器可设置于绑带式结构中,通过绑带式结构绑缚于病人的胳膊上,且血压传感器与穿戴式主体201通过有线或无线连接,而将监测到的血压参数值发送至穿戴式主体201。其中,血压传感器所绑缚的手臂与穿戴式主体201穿戴的手臂不同,从而避免干扰。
所述温度传感器也可与心电传感器整合在一起,即共用相同的电极片205,通过将电极片205贴放在病人身体的相应部位,可同时实现心电参数值的获取/监测以及温度参数值的获取/监测。
在一些实施例中,温度传感器也可设置于ECG模块203中,并包括从ECG模块203引出的体温探头,由于ECG模块203的位置靠近用户的腋下,因此,可以缩短体温探头的线缆长度,方便测量病人腋下温度,进一步提高佩戴舒适性。
其中,所述ECG模块203中包括ECG处理电路,用于对心电传感器获取的心电参数值进行处理后发送给穿戴式主体201。所述ECG模块203中还可包括血压测量处理电路、血氧测量处理电路、温度测量处理电路等测量电路,用于对相应传感器获取的参数值进行处理后再发送给穿戴式主体201。
其中,所述第二类传感器22包括加速度传感器、疼痛传感器中的至少一种。在本实施例中,第二类传感器22包括加速度传感器和疼痛传感器。
所述加速度传感器用于获取病人的反映了睡眠参数值、运动参数值的加速度信息,即通过加速度传感器22监测的加速度值即可得出病人的运动参数值和睡眠参数值。例如,在加速度值为零时,即可确定病人为静止,在加速度值发生变化时,即反映了病人为运动, 并且加速度值的变化频率反映了病人运动的步频、速度等运动参数值,而通过统计加速度值为零的时间又可反映出睡眠时间等睡眠参数值。
其中,所述加速度传感器可为多个,分别设置于穿戴式主体201以及ECG模块203中,可以有效减少手臂运动带来的运动误检,提高病人运动时间和睡眠时间的统计准确率。
其中,疼痛传感器可包括湿度传感器、声音传感器等中的至少一种。由于病人疼痛时会出汗,且越疼汗越多,因此通过湿度传感器侦测的湿度值也可反映疼痛参数值,即,疼痛的级别。又例如,病人疼痛时通常会由于难以忍受而喊叫,通过声音传感器侦测用户的语音内容为疼痛呻吟声时根据音量的大小即可反映疼痛参数值,即,疼痛的级别。
其中,处理器23设置于所述穿戴式主体201中。在一些实施例中,处理器23通过接收加速度传感器监测的加速度值而得出病人的运动参数值和睡眠参数值,以及通过接收湿度传感器监测的湿度值和/或声音传感器的语音信息而得出病人的疼痛参数值。从而,第二类传感器22监测/获取到的包括睡眠参数值、运动参数值、疼痛参数值中的至少一种的非生理体征参数值指的是第二类传感器22监测/获取到间接反映睡眠参数值、运动参数值、疼痛参数值中的至少一种的参数值。
如图2所示,移动监测装置200还包括显示屏24,处理器23与显示屏24连接,用于控制在显示屏24上显示病人状态恢复参数值。即,处理器23控制输出病人状态恢复参数值为控制在显示屏24上显示病人状态恢复参数值。
其中,显示屏24设置于穿戴式主体201上,具体的,显示屏24为设置于穿戴式主体201的外表面上。
如图3所示,穿戴式主体201为腕带式装置,用于穿戴于病人的手腕上,当穿戴式主体201穿戴于病人手腕上后,显示屏24位于远离病人手腕一侧。
在一些实施例中,穿戴式主体201的背面还集成有心率传感器,用于在穿戴式主体201穿戴于手腕后测量心率/脉率,其中,心率传感器为光电式传感器。所述心率传感器测量得到的心率/脉率可单独作为心电参数值或者结合心电传感器测量得到的心电参数值作为最终的心电参数值。
请一并参阅图4,为移动监测装置200的显示屏24显示的参数界面的示意图。进一步的,处理器23控制在显示屏24上显示病人状态恢复参数值时,为控制显示屏24显示包括病人状态恢复参数值中的至少一种参数值的参数界面T1,例如,如图4所示,处理器23控制显示屏24显示包括心电参数值、血氧参数值、呼吸参数值、血压参数值的参数界面T1。其中,图中的的心电参数值为通过心电图曲线的方式展示,血氧参数值为98,呼吸率为20,血压为120/80。或者,在一些实施例中,处理器23控制显示屏24显示仅包括血压参数值的参数界面。
在一些实施例中,处理器23还用于响应用户的操作控制切换参数界面中所显示的参数值或根据预设的时间间隔控制切换所述参数界面T1中所显示的参数值。
即,当病人状态恢复参数值包括了若干参数值,而同一时间参数界面T1仅显示了部分参数值时,则可响应用户的操作控制切换参数界面中所显示的参数值或根据预设的时间间隔控制切换所述参数界面中所显示的参数值。例如,将当前参数界面中显示的血压参数值切换至显示体温参数值等。
在一些实施例中,显示屏24为触摸显示屏,处理器23为响应用户在显示屏24上输入的滑动触摸操作而控制切换参数界面中所显示的参数值。在一些实施例中,移动监测装置200包括机械切换按键,处理器23为响应机械切换按键的按压而控制切换参数界面中所显示的参数值。
在一些实施例中,在所述显示屏24上显示的病人状态恢复参数值为运动参数值时,处理器23还控制通过环形的方式显示所述运动参数值所包括的运动子参数值,所述运动子参数值包括运动步数、步频、运动距离、卡路里、运动时间、运动路线中的至少一种。
例如,处理器23将参数界面T1中显示的参数值切换为运动参数值时,将运动参数值包括的多个运动子参数值同时显示在参数界面中,且多个运动子参数值围绕成环形。
如图2所示,所述移动监测装置200还包括通信单元25,所述处理器23与通信单元25连接,还用于通过所述通信单元25建立移动监测装置200与目标监护设备300之间的通信连接,并用于将所述病人状态恢复参数值通过所述通信单元25发送所述目标监护设备300,并通过所述目标监护设备300输出所述病人状态恢复参数值;其中,目标监护设备300包括床边监护设备301、科室级工作站设备302和院级数据中心/院级急救中心管理设备303中的至少一种。在一些实施例中,移动监测装置200与目标监护设备300之间的通信连接为无线通信连接。
其中,病人状态恢复参数值可通过目标监护设备300显示,也可进一步存储于目标监护设备300中。
其中,通信单元25设置于穿戴式主体201中。
在一些实施例中,所述通信单元25包括蓝牙模块,移动监测装置200通过蓝牙模块与其他移动监测装置200通信,并采用穿戴式主体201作为主通讯设备,而负责与目标监护设备300进行数据传输,穿戴式主体201通过蓝牙模块从其他移动监测装置200获得病人状态恢复参数值,并发送给目标监护设备300。
在其中一个变形实施例中,移动监测装置200的穿戴式主体201只包括通信单元25和显示屏24,通信单元25包括作为主通讯设备的无线通讯模块,第一类传感器21和第二类传感器22均为贴片式检测设备,多个贴片式检测设备中也具有蓝牙模块、NFC模块等等近场通讯模块,并将获取的基本生理体征参数值以及非生理体征参数值发送到穿戴式主体201上,通过显示屏24进行显示,此外,还可以通过穿戴式主体201的通信单元25将获取到的包括基本生理体征参数值以及非生理体征参数值的病人恢复状态数据发送到目标监护设备300。
在一些实施例中,处理器23所述病人状态恢复参数值通过所述通信单元发送至所述目标监护设备300时,还同时发送显示模式信息至所述目标监护设备300,以使得所述目标监护设备300根据所述显示模式信息对所述病人状态恢复参数值进行显示。
其中,显示模式信息中定义了用于显示病人状态恢复参数的参数界面中基本生理体征参数值和非生理体征参数值的相关数据的显示位置,其中,基本生理体征参数值的相关数据显示于参数界面的第一区域,所述非生理体征参数值的相关数据显示于参数界面的第二区域。
从而,目标监护设备300在接收到病人状态恢复参数值时,将根据显示模式信息显示参数界面,且将基本生理体征参数值的相关数据显示于参数界面的第一区域,所述非生理体征参数值的相关数据显示于参数界面的第二区域。
其中,基本生理体征参数值的相关数据包括基本生理体征参数值的实时数据,非生理体征参数的相关数据包括非生理体征参数值的实时数据。即,移动监测装置200将实时获取到的基本生理体征参数值的数据和非生理体征参数值的数据发送给目标监护设备300后,实时获取到的基本生理体征参数值的数据和非生理体征参数值的数据将显示于参数界面的不同区域。
进一步的,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。其中,非生理体征参数值的变化趋势数据包括了的多个在不同时刻监测到的非生理体征参数值的历史数据,所述多个不同时刻监测到的非生理体征参数值根据监测时间排列,而呈现变化趋势,构成所述变化趋势数据。
其中,所述变化趋势数据包括预设时间段内监测到的多个非生理体征参数值的变化趋势数据,例如最近一周内监测到的多个非生理体征参数值的变化趋势数据。
其中,由于基本生理体征参数值的数据和非生理体征参数值的数据的获取是有时间间 隔的,所述基本生理体征参数值和非生理体征参数值的实时数据可以指的是最近一次测量得到的基本生理体征参数值和非生理体征参数值的数据。
在一些实施例中,当所述目标监护设备300为床边监护仪301时,所述处理器23还在通信单元25第一次建立移动监测装置200与目标监护设备300之间的通信连接的过程中,执行与目标监护设备300的配对操作,并在与目标监护设备300配对成功后,建立所述移动监测装置200与目标监护设备300之间的通信连接。
请一并参阅图5,为移动监测装置200显示的配对提示信息的示意图。如图5所示,处理器23在执行与目标监护设备的配对操作之前,产生配对提示信息,提示用户是否进行移动监测装置200与目标监护设备300之间的配对,并在用户选择“是”时,执行与目标监护设备300的配对操作。其中,所述配对提示信息可为文字信息,处理器23控制显示屏24显示所述文字形式的配对提示信息,例如“请确认是否与当前的监护设备进行配对”。
请一并参阅图6,为移动监测装置200显示的配对示意图。处理器23在用户选择“是”时,执行与目标监护设备300的配对操作,并控制显示屏24显示当前处于配对过程的配对状态示意信息,例如,如图6所示的移动监测装置200与目标监护设备300正在进行配对的示意信息。
其中,处理器23并在移动监测装置200与目标监护设备300配对成功后,控制移动监测装置200恢复显示之前的包括有病人状态恢复参数值的参数界面。
其中,所述处理器23还用于在移动监测装置100与目标监护设备200配对成功后,控制将移动监测装置100检测的病人状态恢复参数值的实时数据和历史数据均同步至所述目标监护设备200。从而,在移动监测装置200与目标监护设备300配对成功后,所述目标监护设备300也将显示包括有病人状态恢复参数值的参数界面。从而,移动监测装置200和目标监护设备同时均显示相应的参数界面。
其中,移动监测装置200显示的参数界面和目标监护设备显示的参数界面均为基于ERAS(病人康复指南)而显示有相关的病人状态恢复参数值。
其中,病人康复指南中定义了病人康复过程中需要检测的病人状态恢复参数中的基本生理体征参数和非生理体征参数,并选择性地在目标监护设备300显示的参数界面中显示全部或部分病人康复指南中定义的病人状态恢复参数的参数值,以及选择性地在移动监测装置200显示的参数界面中显示病人康复指南中定义的部分病人状态恢复参数的参数值。
其中,移动监测装置200显示的参数界面中的病人状态恢复参数值的类型/数量少于目标监护设备300显示的参数界面中的病人状态恢复参数值的类型/数量。
在一些实施例中,移动监测装置200显示的参数界面中的病人状态恢复参数值为目标监护设备300显示的参数界面中的病人状态恢复参数值中的部分病人状态恢复参数值。
例如,如图4所示,移动监测装置200显示的参数界面中包括心电参数值、血氧参数值、呼吸参数值、血压参数值,而目标监护设备300显示的参数界面则可包括心电参数值、血氧参数值、呼吸参数值、血压参数值、体温参数值、运动参数值、睡眠参数值等。
在一些实施例中,所述通信单元25包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种以及WIFI通信模组,当所述移动监测装置100位于病房内时,所述移动监测装置200通过蓝牙模组、WMTS通信模组或NFC通信模组与床边监护设备301建立蓝牙连接、WMTS通信连接或NFC通信连接,而将移动监测装置200检测的病人状态恢复参数值的实时数据和历史数据均同步至所述床边监护设备301。其中,病人状态恢复参数值的实时数据和历史数据并可进一步通过床边监护设备301同步至科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303。
当所述移动监测装置200位于病房外时,所述移动监测装置200通过WIFI模组与科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303建立WIFI通信连接,将移动监测装置200检测的病人状态恢复参数值的实时数据和历史数据同步到科室级工作 站设备302和/或院级数据中心/院级急救中心管理设备303,再通过科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303将病人状态恢复参数值的实时数据和历史数据同步到床边监护设备302。
从而,佩戴有移动监测装置200的病人是在病房内还是病房外,移动监测装置200监测的病人状态恢复参数值的相关数据均会同步到床边监护设备302、科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303,而使得监护系统100可以将移动监测装置200监测到的数据进行整体保存,方便集中管理病人信息。
其中,由于蓝牙模组、WMTS通信模组和NFC通信模组的功耗很低,所述移动监测装置100位于病房内时,所述移动监测装置200通过蓝牙模组、WMTS通信模组或NFC通信模组与床边监护设备301建立蓝牙连接、WMTS通信连接或NFC通信连接,能够有效降低功耗,提高移动监测装置100的续航能力。
在一些实施例中,所述处理器23还用于在移动监测装置200未接收到用户的操作的时间超过预设时长时,控制所述显示屏23显示锁屏界面,并在响应用户在显示屏的任意滑动操作时,对移动监测装置200进行解锁,而恢复显示所述参数界面。
其中,移动监测装置200显示的锁屏界面中包括的病人恢复参数值的类型数量少于移动监测装置200解锁后显示的参数界面中的病人恢复参数值的类型数量。
所述锁屏界面可为解锁后的参数界面的简化界面,仅显示有解锁后的参数界面显示的病人恢复参数值中的部分病人恢复参数值。
在一些实施例中,锁屏界面还可仅显示时间信息。
在一些实施例中,移动监测装置200还包括输入单元26,所述处理器23还用于响应通过输入单元26输入的疼痛等级设置操作,对移动监测装置200使用者当前的疼痛等级进行设置,而得到所述疼痛参数值。
即,在一些实施例中,所述疼痛参数值可为医生、护士或病人自己直接输入的疼痛等级值。
其中,所述输入单元26可为触摸板,与所述显示屏24整合成触摸显示屏,可通过显示屏24上显示的输入框进行疼痛等级值的输入。
在一些实施例中,所述输入单元26也可为机械按键,医生、护士或病人自己可通过操作机械按键而进行疼痛等级值的输入。
请一并参阅图7,为监护设备300的模块架构图。如图7所示,监护设备300包括通信单元31、显示屏32以及处理器33。处理器33用于通过通信单元31接收病人状态恢复参数值的相关数据,并控制显示屏32显示所述接收的病人状态恢复参数值的相关数据;其中,所述病人状态恢复参数值的相关数据包括基本生理体征参数值和非生理体征参数值的相关数据,所述基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种,所述非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。
其中,通信单元31用于与移动监测装置200建立通信连接,处理器33通过通信单元31从所述移动监测装置200接收如前所述的移动监测装置200获取的病人状态恢复参数值的相关数据。
请一并参阅图8,为监护设备300显示的参数界面T2的示意图。处理器33控制显示屏32显示如前所述的包括所述接收的病人状态恢复参数值的相关数据的参数界面T2,其中,所述非生理体征参数值的相关数据显示于参数界面T2的第一区域A1,所述基本生理体征参数值的相关数据显示于参数界面T2的第二区域A2。
其中,如图8所示,所述参数界面T2的第一区域A1为参数界面T2的左边的区域,第二区域A2为参数界面T2的右边的区域。其中,第一区域A1和第二区域A2的尺寸可相等或不相等,在一些实施例中,第一区域A1的尺寸小于第二区域A2的尺寸。
其中,基本生理体征参数值的相关数据至少包括基本生理体征参数值的实时数据,非生理体征参数值的相关数据包括非生理体征参数值的实时数据。
进一步的,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。其中,非生理体征参数值的变化趋势数据包括了的多个在不同时刻监测到的非生理体征参数值的历史数据,所述多个不同时刻监测到的非生理体征参数值根据监测时间排列,而呈现变化趋势,构成所述变化趋势数据。
其中,所述变化趋势数据包括预设时间段内,例如最近一周内检测到的多个非生理体征参数值的变化趋势数据。
如图8所示,所述参数界面T2的第一区域A1显示了运动时间(Exercise)这一运动参数值,以及位于运动时间右方的由多个历史运动事件构成的运动参数值的历史趋势数据。
其中,所述运动参数值的历史趋势数据中的每次运动还包括了每次运动的目标运动参数值以及实际运动参数值,例如,图8中,黑色的柱子为目标运动参数值,而对应柱子中的灰白色的部分则为实际运动参数值,从而,通过图2中的历史趋势数据,还能示意出每次运动时间的达成率这一信息。
所述第一区域A1还显示了睡眠时间(sleep time)这一睡眠参数值,以及位于睡眠时间右方的由多个历史睡眠参数值构成的睡眠参数值的历史趋势数据。睡眠参数值的历史趋势数据包括了多次睡眠的睡眠时间。
第一区域A1还显示了疼痛等级值这一疼痛参数值,以及位于疼痛参数值右方的由多个历史疼痛参数值构成的疼痛参数值的历史趋势数据。疼痛参数值的历史趋势数据包括了多次得出的疼痛等级值。
其中,所述运动参数值、睡眠参数值以及疼痛参数值从上至下依次排列显示。
显然,所述运动参数值、睡眠参数值以及疼痛参数值在参数界面的排列位置次序也可为其他次序,例如,睡眠参数值、运动参数值及疼痛参数值从上至下依次排列显示。
例如,第二区域A1显示的基本生理体征参数值的相关数据包括了基本生理体征参数值的实时数值以及波形。
例如,如图8所述,第二区域A1的左边部分从上到下依次显示了心电图曲线、血氧浓度曲线、呼吸率曲线。在心电图曲线的右方对应显示了最近一次测量得到的心率值(如图8中所示的“80”)这一心电参数值的实时值,在血氧浓度曲线的右方对应显示了最近一次测量得到的血氧浓度值(如图8中所示的“90”)这一血氧参数值,在呼吸率曲线的右方对应显示了最近一次测量得到的呼吸率值(如图8中所示的“28”)这一呼吸参数值。
如图8所示,在心率值、血氧浓度值以及呼吸率值的下方,还显示有动脉压(如图8中所示的“120/80(93)”)这一血压参数值。
其中,所述第二区域A1中在心电图曲线、血氧浓度曲线、呼吸率曲线的下方还显示有多个参数值的历史监测数据,例如,图中示意出了每间隔半小时测量得到的血氧浓度值、呼吸率值、血压值的历史监测数据。
其中,图8显示的参数界面T2仅仅是一个示例,参数界面T2中显示的病人状态恢复参数值的数量、显示的位置可以根据需要进行调整。
并在用户选择是时,与移动监测装置200进行配对,以及在配对成功后,建立与移动监测装置200的通信连接。
请一并参阅图9,为监护设备300显示的配对提示信息的示意图。如图10所示,处理器33还用于在通信单元31第一次与移动监测装置200建立通信连接的过程中,接收移动监测装置200发送的配对请求,并根据配对请求产生一提示信息,提示用户是否同意与移动监测装置200进行配对,并在用户选择“是”时,执行与移动监测装置200的配对操作。其中,所述配对提示信息可为文字信息,处理器33可控制显示屏32显示文字形式的配对 提示信息,例如“请确认是否与当前的移动监测装置进行配对”。
请一并参阅图10,为监护设备300显示的配对示意图。处理器33在用户选择“是”时,例如图9中的“ok”选项时,执行与移动监测装置200的配对操作,并控制显示屏32显示当前处于配对状态的信息,例如,如图10所示的移动监测装置200与目标监护设备300正在进行配对的示意信息。
如前所述,处理器33在监护设备300与移动监测装置200配对成功后,接收移动监测装置100监测的病人状态恢复参数值的实时数据和历史数据,并显示包括有接收的病人状态恢复参数值的实时数据和历史数据的参数界面T2。
其中,当监护设备300为放置于病房内的床边监护设备301时,处理器33还用于在监护设备300在与移动监测装置200配对成功后保存移动监测装置的配对信息,以在后续移动监测装置200位于监护设备300预设范围内时,进行自动配对,而自动建立通信连接。
在一些实施例中,处理器33还用于通过通信单元32将移动监测装置200的配对信息发送至科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303中,以完成移动监测装置200与科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303的配对。
从而,当移动监测装置200第一次与床边监护设备301进行配对时,则还会通过床边监护设备301完成与科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303的配对。当移动监测装置200移动到病房外时,则可通过WIFI网络等与科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303建立通信连接。
在一些实施例中,监护设备300具有移动监护模式和常规模式,显示屏32在常规模式下显示主界面,在监护设备300与移动监测装置200配对成功后,处理器33还用于响应在监护设备300的主界面上的目标按键的操作而控制监护设备300切换至移动监护模式,控制显示屏32显示包括接收的病人状态恢复参数值的相关数据的参数界面T2。
即,在一些实施例中,处理器33是响应监护设备300的主界面上的目标按键的操作才控制显示屏32显示包括接收的病人状态恢复参数值的相关数据的参数界面T2。在监护设备300与移动监测装置200配对成功后,监护设备300可仅仅是接收移动监测装置200监测的病人状态恢复参数值的实时数据和历史数据,而显示屏32可不显示具有所述病人状态恢复参数值的参数界面;当医生或护士需要查看时,可通过操作目标按键,而控制显示屏32开始显示参数界面T2。
请返回参考图8,目标按键可为图8底部显示的ERAS控制面板(ERAS dashboard)按键K0。
如图8所示,监护设备300的显示屏32的底部显示有若干主控制按键K1,用于控制监护设备300进入相应的功能模式并控制显示屏32显示相应的功能界面。
其中,上述按键可均为虚拟按键。在另一些实施例中,上述按键也可为机械按键。
在一些实施例中,如前所述,移动监测装置200的处理器23所述病人状态恢复参数值通过所述通信单元发送至所述目标监护设备300时,还可同时发送显示模式信息至所述目标监护设备300。
处理器33还用于在监护设备300在接收到病人状态恢复参数值时,根据显示模式信息自动控制显示参数界面T2。
即,在一些实施例中,在监护设备300与移动监测装置200配对成功后,监护设备300接收移动监测装置200监测的病人状态恢复参数值的实时数据和历史数据之外,还接收显示模式信息,处理器33根据显示模式信息控制监护设备300自动进入移动监护模式,并控制显示屏32显示包括接收的病人状态恢复参数值的相关数据的参数界面T2。
因此,在监护设备300与移动监测装置200配对成功后则自动进入参数界面T2的显示,方便了通过监护设备300进行病人状态恢复参数值的相关数据的查看。
如前所述,显示模式信息中定义了用于显示病人状态恢复参数的参数界面T2中基本生理体征参数值和非生理体征参数值的相关数据的显示位置,其中,基本生理体征参数值的相关数据显示于参数界面T2的第一区域A1,所述非生理体征参数值的相关数据显示于参数界面T2的第二区域A2。
从而,监护设备300在接收到病人状态恢复参数值时,将根据显示模式信息显示参数界面T2,且将基本生理体征参数值的相关数据显示于参数界面T2的第一区域A1,所述非生理体征参数值的相关数据显示于参数界面T2的第二区域A2。
其中,监护设备300的通信单元31也包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种,监护设备300通过通信单元31与移动监测装置200建立蓝牙连接、WMTS通信连接或NFC通信连接。
监护设备300的通信单元31还包括WIFI模组,监护设备300为床边监护设备301时,还通过WIFI模组与科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303建立WIFI通信连接,并通过科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303接收移动监测装置200发送的病人状态恢复参数值的相关数据,其中,病人状态恢复参数值的相关数据为移动监测装置200在位于病房外通过WIFI通信连接向科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303发送的。
从而,当穿戴有移动监测装置200的病人位于病房外时,移动监测装置200可通过WIFI通信连接向科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303发送病人状态恢复参数值的相关数据,然后,再由科室级工作站设备302和/或院级数据中心/院级急救中心管理设备303转发至与移动监测装置200配对的床边监护设备301,而实现在多个设备之间的数据同步。
在一些实施例中,通信单元31还包括连接接口,用于与相应的传感器附件连接,处理器33还用于通过连接接口从传感器附件接收病人状态恢复参数值的相关数据;处理器33并控制显示屏32同时显示从移动监测装置200接收的病人状态恢复参数值的相关数据以及从传感器附件接收的病人状态恢复参数的相关数据。所述连接接口可为与传感器附件匹配的附件接口。
即,在一些实施例中,处理器33控制显示屏32显示的参数界面T2中同时包括有移动监测装置200接收的病人状态恢复参数值的相关数据以及从传感器附件接收的病人状态恢复参数值的相关数据。
请一并参阅图11,为另一实施例中的监护设备300显示的参数界面T2’的示意图。如图11所示,相比图8所示的参数界面T2’,图11所示的参数界面T2’还显示有从感器附件接收的病人状态恢复参数值的相关数据,例如,静脉压(图11所示的“8.5”)这一血压参数值等。
在一些实施例中,当通过连接接口从传感器附件接收的病人状态恢复参数值的相关数据和从移动监测装置200接收的病人状态恢复参数值的相关数据中有相同类型的参数值时,还控制在参数界面T2’中同时显示相同类型的从传感器附件接收的病人状态恢复参数值的相关数据和从移动监测装置200接收的病人状态恢复参数值的相关数据。
例如,如图11所示,参数界面T2’还同时显示有从移动监测装置200接收的动脉压数据“120/60”以及从传感器附件接收的动脉压数据“120/80”。
在一些实施例中,疼痛参数值的数据包括疼痛等级,如图7所示,监护设备300还包括输入单元34,处理器33还用于响应通过输入单元34输入的疼痛等级设置操作,对疼痛等级进行设置,而获取到疼痛参数值。
即,在一些实施例中,疼痛参数值可为医生、护士甚至是病人自己通过监护设备300的输入单元34进行输入设置而生成的。
其中,输入单元34可为触摸板,并与显示屏32整合成触摸显示屏。输入单元34也 可为机械按键。
其中,如图11所示,在多个参数值的历史监测数据的下方,还显示有最近一次测量得到的温度值(如图11中所示的“37.2℃”)这一温度参数值。
从而,本申请中的监护系统100,通过监测病人的基本生理体征参数值和非生理特征参数值,满足了多种监护需求,另外,通过移动监测装置200进行监测,允许病人在病房外进行活动,同时满足了病人的活动需求。
其中,上述的移动监测装置200和床边监护设备301可均为多参数监护仪,其中多参数监护仪的结构请参阅下述的图12的多参数监护仪或模块组件的结构。
请参阅图12,为一种多参数监护仪或模块组件的系统框架图。多参数监护仪或模块组件至少包括参数测量电路112。参数测量电路112至少包括一个生理参数对应的参数测量电路,参数测量电路至少包含心电信号参数测量电路、呼吸参数测量电路、体温参数测量电路、血氧参数测量电路、无创血压参数测量电路、有创血压参数测量电路等等中的至少一个参数测量电路,每个参数测量电路分别通过相应的传感器接口与外部插入的传感器附件111连接。传感器附件111包括用于心电呼吸、血氧、血压、体温等生理参数检测所对应的检测附件。参数测量电路112主要是用来连接传感器附件111获得获取的生理参数信号的,可以包括至少两种以上生理参数的测量电路,参数测量电路可以是但不局限于生理参数测量电路(模块),人体生理参数测量电路(模块)或传感器获取人体生理参数等。具体的,参数测量电路通过扩展接口获得外部生理参数传感器附件获得有关病人的生理采样信号,并经过处理后得到生理数据,用以报警和显示。扩展接口还可用于将主控电路输出的关于如何获取生理参数的控制信号通过相应接口输出至外部生理参数监测附件,实现对病人生理参数的监测控制。
对于移动监测装置200来说,参数测量电路112可为上述的ECG模块203;该些传感器附件111即为包括前述的第一类传感器21和第二类传感器21的传感器附件。对于床边监护设备301来说,传感器附件111即为可通过传感器接口插入的外接的传感器附件。
多参数监护仪或模块组件还可以包括主控电路113,主控电路113需要包括至少一个处理器1131和至少一个存储器1132,当然,主控电路还可以包括电源管理模块1133、电源IP模块和接口转换电路等中的至少之一。电源管理模块用于控制整机开关机、板卡内部各电源域上电时序和电池充放电等。电源IP模块是指把经常重复调用的电源电路单元的原理图和PCB版图相关联,固化成单独的电源模块,即,将一输入电压通过预定的电路转换为一输出电压,其中,输入电压和输出电压不同。例如,将15V的电压转换为1.8V、3.3V或3.8V等。可以理解的是,电源IP模块可以是单路的,还可以是多路的。当电源IP模块为单路时,电源IP模块可以将一个输入电压转换为一个输出电压。当电源IP模块为多路时,电源IP模块可以将一个输入电压转换为多个输出电压,且多个输出电压的电压值可以相同,也可以不相同,从而能够同时满足多个电子元件的不同电压需求,并且模块对外接口少,在系统中工作呈黑盒与外界硬件系统解耦,提高了整个电源系统的可靠性。接口转换电路用于将主控最小系统模块(即主控电路中的至少一个处理器和至少一个存储器)输出的信号,转换为实际外部设备所要求接收的输入标准信号,例如,支持外接VGA显示功能,是将主控CPU输出的RGB数字信号转换为VGA模拟信号,支持对外网络功能,是将RMII信号转换为标准的网络差分信号。
此外,多参数监护仪或模块组件还可以包括本地显示器114、报警电路116、输入接口电路117、对外通讯和电源接口115中的一个或多个。主控电路用于协调、控制多参数监护仪或模块组件中的各板卡、各电路和设备。在本实施例中,主控电路用于控制参数测量电路112和通讯接口电路之间的数据交互、以及控制信号的传输,并将生理数据输送到显示器114上进行显示,也可以接收来自触摸屏或者键盘、按键等物理输入接口电路输入的用户控制指令,当然还可以输出的关于如何获取生理参数的控制信号。报警电路116可 以是声光报警电路。主控电路完成生理参数的计算,并通过对外通讯和电源接口115可将参数的计算结果和波形发送到主机(如带显示器的主机、PC机、中央站等等),对外通讯和电源接口115可以是以太网(Ethernet)、令牌环(Token Ring)、令牌总线(Token Bus)以及作为这三种网的骨干网光纤分布数据接口(FDDI)构成的局域网接口中的一个或其组合,还可以是红外、蓝牙、wifi、WMTS通讯等无线接口中的一个或其组合,或者还可以是RS232、USB等有线数据连接接口中的一个或其组合。对外通讯和电源接口115也可以是无线数据传输接口和有线数据传输接口中的一种或两种的组合。主机可以是监护仪的主机、心电图机,超声诊断仪,计算机等任何一个计算机设备,安装配合的软件,就能够组成一个监护设备。主机还可以是通讯设备,例如手机,多参数监护仪或模块组件通过蓝牙接口将数据发送到支持蓝牙通讯的手机上,实现数据的远程传输。
其中,对于移动监测装置200来说,本地显示器114即为显示屏24,输入接口电路117即为输入单元26、对外通讯和电源接口115可为前述的通信单元25。对于床边监护设备200来说,本地显示器114即为显示屏32,输入接口电路117即为输入单元34、对外通讯和电源接口115可为前述的通信单元31。
多参数监护模块组件可以设置在监护仪外壳之外,作为独立的外插参数模块,可以通过插入到监护仪的主机(包含主控板)形成插件式监护仪,作为监护仪的一部分,或者也可以通过电缆与监护仪的主机(包含主控板)连接,外插参数模块作为监护仪外置的一个配件。当然,参数处理还可以内置于外壳之内,与主控模块集成,或物理分离设置在外壳之内,形成集成监护仪。
其中,如图2所示,移动监测装置200还包括存储器27,所述存储器27可用于存储前述的病人状态恢复参数值的相关数据。如图7所示,监护设备300也包括存储器35,所述存储器35可用于存储监护设备300接收到的病人状态恢复参数值的相关数据。
在一些实施例中,所述存储器27中还存储有程序指令,所述程序指令用于供移动监测装置200的处理器23调用后执行前述的功能。所述监护设备300的存储器35中也存储有程序指令,所述程序指令用于供监护设备300的处理器33调用后执行前述的功能。
其中,所述存储器27、35可以包括高速随机存取存储器,还可以包括非易失性存储器,例如硬盘、内存、插接式硬盘,智能存储卡(Smart Media Card,SMC),安全数字(Secure Digital,SD)卡,闪存卡(Flash Card)、多个磁盘存储器件、闪存器件、或其他易失性固态存储器件。
处理器23和处理器33可以是中央处理单元(Central Processing Unit,CPU),还可以是其他通用处理器、数字信号处理器(Digital Signal Processor,DSP)、专用集成电路(Application Specific Integrated Circuit,ASIC)、现场可编程门阵列(Field-Programmable Gate Array,FPGA)或者其他可编程逻辑器件、分立门或者晶体管逻辑器件、分立硬件组件等。通用处理器可以是微处理器或者该处理器也可以是任何常规的处理器等。
请参阅图13,为一实施例中的病人状态监测方法的流程图,所述病人状态方法可应用于上述的移动监测装置中,如图13所示,所述方法包括如下步骤。
S131:通过移动监测装置的第一类传感器获取基本生理体征参数值,其中,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种。
S133:通过移动监测装置的第二类传感器获取非生理体征参数值,其中,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。
S135:将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并输出病人状态恢复参数值。其中,所述获取到的基本生理体征参数值以及非生理体征参数值进行汇总后形成病人状态恢复参数值。
其中,步骤S131和步骤S133可同时进行,也可先后进行。
在一些实施例中,移动监测装置还包括显示屏,上述“输出病人状态恢复参数值”,包括:控制在移动监测装置的显示屏上显示病人状态恢复参数值。
即,病人状态恢复参数值为在移动监测装置的显示屏进行显示。
进一步的,上述“控制在移动监测装置的显示屏上显示病人状态恢复参数值”包括:控制显示屏显示包括病人状态恢复参数值中的至少一种参数值的参数界面;以及响应用户的操作控制切换参数界面中所显示的参数值或根据预设的时间间隔控制切换参数界面中所显示的参数值。
从而,当病人状态恢复参数值包括了若干参数值,而同一时间参数界面仅显示了部分参数值时,则可响应用户的操作控制切换参数界面中所显示的参数值或根据预设的时间间隔控制切换所述参数界面中所显示的参数值。例如,将当前参数界面中显示的血压参数值切换至体温参数值进行显示,等等。
所述控制在移动监测装置的显示屏上显示病人状态恢复参数值,包括:在显示屏上显示病人状态恢复参数值为运动参数值时,控制通过环形的方式显示运动参数值所包括的运动子参数,运动子参数值包括运动步数、步频、运动距离、卡路里、运动时间、运动路线中的至少一种。
其中,移动监测装置还包括通信单元,上述“输出病人状态恢复参数值”,还可包括:通过通信单元建立与目标监护设备的通信连接;将病人状态恢复参数值发送至目标监护设备,并通过目标监护设备输出病人状态恢复参数值;其中,目标监护设备包括床边监护设备、科室级工作站设备和院级数据中心/院级急救中心管理设备中的至少一种。
在一些实施例中,上述“将病人状态恢复参数值发送至目标监护设备,并通过目标监护设备输出病人状态恢复参数值”,包括:将病人状态恢复参数值发送至目标监护设备时,还同时发送显示模式信息至目标监护设备,以使得目标监护设备根据显示模式信息对病人状态恢复参数值进行显示。
其中,显示模式信息中定义了用于显示病人状态恢复参数值的显示界面中基本生理体征参数值和非生理体征参数值的相关数据的显示位置,其中,基本生理体征参数值的相关数据显示于显示界面的第一显示区域,非生理体征参数值的相关数据显示于显示界面的第二显示区域。
其中,基本生理体征参数值的相关数据包括基本生理体征参数的实时数据,非生理体征参数的相关数据包括非生理体征参数的实时数据。
其中,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。在一些实施例中,变化趋势数据包括最近一周内检测到的多个非生理体征参数值的变化趋势数据。
其中,当目标监护设备为床边监护设备时,所述方法还包括:在第一次建立移动监测装置与目标监护设备之间的通信连接的过程中,执行与目标监护设备的配对操作;以及在与目标监护设备配对成功后,建立移动监测装置与目标监护设备之间的通信连接。
在一些实施例中,在“执行与目标监护设备的配对操作”之前,所述方法还包括:产生配对提示信息,提示用户是否进行移动监测装置与目标监护设备之间的配对。
上述“执行与目标监护设备的配对操作”,包括:在用户选择是时,执行与目标监护设备的配对操作。
进一步的,上述“将病人状态恢复参数值发送至目标监护设备”包括:在移动监测装置与目标监护设备配对成功后,控制将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至目标监护设备。
其中,移动监测装置的通信单元包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种以及WIFI通信模组,当移动监测装置位于病房内时,移动监测装置通过蓝牙模组、WMTS通信模组或NFC通信模组与床边监护设备建立蓝牙连接、WMTS通信连接 或NFC通信连接;上述“控制将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至目标监护设备”,包括:控制通过蓝牙连接、WMTS通信连接或NFC通信连接将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至床边监护设备。
其中,当移动监测装置位于病房外时,移动监测装置通过WIFI模组与科室级工作站设备和/或院级数据中心/院级急救中心管理设备建立WIFI通信连接;上述“控制将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至目标监护设备”,包括:控制通过WIFI通信连接将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据同步到科室级工作站设备和/或院级数据中心/院级急救中心管理设备,再通过科室级工作站设备和/或院级数据中心/院级急救中心管理设备将病人状态恢复参数值的实时数据和历史数据同步到床边监护设备。
在一些实施例中,上述方法还包括:在移动监测装置未接收到用户的操作的时间超过预设时长时,控制显示屏显示锁屏界面;以及响应用户在显示屏的任意滑动操作,恢复显示参数界面。
在一些实施例中,移动监测装置还包括输入单元,上述方法还包括:响应通过输入单元输入的疼痛等级设置操作,对移动监测装置使用者当前的疼痛等级进行设置。
请参阅图14,为另一实施例中的病人状态监测方法的流程图,所述病人状态方法可应用于上述的移动监测装置200中,移动监测装置200包括通信单元和显示屏;如图14所示,所述方法包括如下步骤。
S141:通过移动监测装置的第一类传感器获取基本生理体征参数值,其中,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种。
S143:通过移动监测装置的第二类传感器获取非生理体征参数值,其中,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。
S145:将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,将病人状态恢复参数值发送至目标监护设备,并通过目标监护设备输出病人状态恢复参数值;其中,目标监护设备包括床边监护设备、科室级工作站设备和院级数据中心/院级急救中心管理设备中的至少一种。
S147:控制在移动监测装置的显示屏上显示病人状态恢复参数值。
即,移动监测装置获取到的病人状态恢复参数值发送至目标监护设备进行输出时,还会在移动监测装置的显示屏上显示。
其中,在步骤S145之前,上述方法还可包括:通过通信单元建立与目标监护设备的通信连接。
其中,图14所示的病人状态监测方法与图13所示的病人状态监测方法的相关步骤的描述请参考图13的描述。图13相关的附加步骤等也可适用于图14所示的病人状态监测方法。
请参阅图15,为再一实施例中的病人状态监测方法的流程图,所述病人状态方法可应用于上述的监护设备300中,监护设备300包括通信单元和显示屏;如图15所示,所述方法包括如下步骤。
S151:通过通信单元接收病人状态恢复参数值的相关数据。
S153:控制显示屏显示接收的病人状态恢复参数值的相关数据;其中,病人状态恢复参数值包括基本生理体征参数值和非生理体征参数值的相关数据,基本生理体征参数值包括心电参数、呼吸参数、血氧参数、血压参数、体温参数中的至少一种,非生理特征参数值包括睡眠参数、运动参数、疼痛参数中的至少一种。
其中,步骤S151可具体包括:通过通信单元与移动监测装置建立通信连接,通过通 信单元从移动监测装置接收移动监测装置获取的病人状态恢复参数值的相关数据。
其中,上述“控制显示屏显示接收的病人状态恢复参数值的相关数据”,包括:控制显示屏显示一包括接收的病人状态恢复参数值的相关数据的参数界面,其中,非生理体征参数值的相关数据显示于参数界面的第一区域,基本生理体征参数值的相关数据显示于参数界面的第二区域。
其中,基本生理体征参数值的相关数据包括基本生理体征参数值的实时数据,非生理体征参数值的相关数据包括非生理体征参数的实时数据。
其中,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。在一些实施例中,变化趋势数据包括当前时刻之前的预设时间段内检测到的多个非生理体征参数值的变化趋势数据,例如最近一周内检测到的多个非生理体征参数值的变化趋势数据。
在一些实施例中,所述方法还可包括:在通信单元为第一次与移动监测装置建立通信连接的过程中,接收移动监测装置发送的配对请求;根据配对请求产生一提示信息,提示用户是否同意与移动监测装置进行配对;以及在用户选择是时,与移动监测装置进行配对,并在配对成功后,建立与移动监测装置的通信连接。
其中,所述方法还包括:在监护设备在与移动监测装置配对成功后保存移动监测装置的配对信息,以在后续移动监测装置位于监护设备预设范围内时,进行自动配对。
在一些实施例中,监护设备为放置于病房内的床边监护设备,所述方法还包括:将移动监测装置的配对信息发送至科室级工作站设备和/或院级数据中心/院级急救中心管理设备中,以完成移动监测装置与科室级工作站设备和/或院级数据中心/院级急救中心管理设备的配对。
其中,监护设备的通信单元包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种,通信单元与移动监测装置建立蓝牙连接、WMTS通信连接或NFC通信连接。
监护设备具有移动监护模式和常规模式,显示屏在常规模式下显示主界面,上述“控制显示屏显示一包括接收的病人状态恢复参数值的相关数据的参数界面”,包括:响应在监护设备的主界面上的目标按键的操作而控制监护设备而切换至移动监护模式;以及在移动监护模式下,控制显示屏显示包括接收的病人状态恢复参数值的相关数据的参数界面。
在一些实施例中,通信单元还包括连接接口,用于与相应的传感器附件连接,上述方法还包括:通过连接接口从传感器附件接收病人状态恢复参数值的相关数据;上述“控制显示屏显示接收的病人状态恢复参数值的相关数据”,包括:控制显示屏同时显示从移动监测装置接收的病人状态恢复参数值的相关数据以及从传感器附件接收的病人状态恢复参数值的相关数据。
其中,通信单元包括WIFI模组,上述“通过通信单元从移动监测装置接收移动监测装置获取的病人状态恢复参数值的相关数据”,还包括:
通过WIFI模组与科室级工作站设备和/或院级数据中心/院级急救中心管理设备建立WIFI通信连接,并通过科室级工作站设备和/或院级数据中心/院级急救中心管理设备接收移动监测装置发送的病人状态恢复参数值的相关数据,其中,病人状态恢复参数值的相关数据为移动监测装置在位于病房外通过WIFI通信连接向科室级工作站设备和/或院级数据中心/院级急救中心管理设备发送的。
在一些实施例中,疼痛参数的数据包括疼痛等级,监护设备还包括输入单元,上述方法还包括:响应通过输入单元输入的疼痛等级设置操作,对疼痛等级进行设置,而获取到疼痛参数的数据。
其中,本申请的各个实施例中的病人状态监测方法与前述的监护系统100对应,相关的步骤和监护系统100执行的功能操作可相互对应参照,在此不再赘述。
在一些实施例中,本申请还提供一种计算机可读存储介质。前述计算机可读存储介质中存储有多条程序指令用于供处理器23或处理器33调用执行。
其中,计算机可读存储介质中存储的多条程序指令被移动监测装置200的处理器23调用执行后,可执行图13-图14任一附图中所示的方法中的部分步骤或全部步骤或其中步骤的任意组合。计算机可读存储介质中存储的多条程序指令被监护设备300的处理器33调用执行后,可执行图15中所示的方法中的部分步骤或全部步骤或其中步骤的任意组合
从而,本申请可同时获取基本生理体征参数值和非生理体征参数值,能够获取用户的心电、呼吸等生理状况以及睡眠、运动等非生理状态,能够更加全面侦测病人的状态。另外,由于移动监测装置200可为穿戴式监测装置,用于供病人穿戴后在病房外活动,同时能持续监测病人状态恢复参数值,满足了病人(例如亚重症病人)在病房外活动的同时进行状态监测的需求。
本文参照了各种示范实施例进行说明。然而,本领域的技术人员将认识到,在不脱离本文范围的情况下,可以对示范性实施例做出改变和修正。例如,各种操作步骤以及用于执行操作步骤的组件,可以根据特定的应用或考虑与系统的操作相关联的任何数量的成本函数以不同的方式实现(例如一个或多个步骤可以被删除、修改或结合到其他步骤中)。
另外,如本领域技术人员所理解的,本文的原理可以反映在计算机可读存储介质上的计算机程序产品中,该可读存储介质预装有计算机可读程序代码。任何有形的、非暂时性的计算机可读存储介质皆可被使用,包括磁存储设备(硬盘、软盘等)、光学存储设备(CD-ROM、DVD、Blu Ray盘等)、闪存和/或诸如此类。这些计算机程序指令可被加载到通用计算机、专用计算机或其他可编程数据处理设备上以形成机器,使得这些在计算机上或其他可编程数据处理装置上执行的指令可以生成实现指定的功能的装置。这些计算机程序指令也可以存储在计算机可读存储器中,该计算机可读存储器可以指示计算机或其他可编程数据处理设备以特定的方式运行,这样存储在计算机可读存储器中的指令就可以形成一件制造品,包括实现指定功能的实现装置。计算机程序指令也可以加载到计算机或其他可编程数据处理设备上,从而在计算机或其他可编程设备上执行一系列操作步骤以产生一个计算机实现的进程,使得在计算机或其他可编程设备上执行的指令可以提供用于实现指定功能的步骤。
虽然在各种实施例中已经示出了本文的原理,但是许多特别适用于特定环境和操作要求的结构、布置、比例、元件、材料和部件的修改可以在不脱离本披露的原则和范围内使用。以上修改和其他改变或修正将被包含在本文的范围之内。
前述具体说明已参照各种实施例进行了描述。然而,本领域技术人员将认识到,可以在不脱离本披露的范围的情况下进行各种修正和改变。因此,对于本披露的考虑将是说明性的而非限制性的意义上的,并且所有这些修改都将被包含在其范围内。同样,有关于各种实施例的优点、其他优点和问题的解决方案已如上。然而,益处、优点、问题的解决方案以及任何能产生这些的要素,或使其变得更明确的解决方案都不应被解释为关键的、必需的或必要的。本文中所用的术语“包括”和其任何其他变体,皆属于非排他性包含,这样包括要素列表的过程、方法、文章或设备不仅包括这些要素,还包括未明确列出的或不属于该过程、方法、系统、文章或设备的其他要素。此外,本文中所使用的术语“耦合”和其任何其他变体都是指物理连接、电连接、磁连接、光连接、通信连接、功能连接和/或任何其他连接。
具有本领域技术的人将认识到,在不脱离本发明的基本原理的情况下,可以对上述实施例的细节进行许多改变。因此,本发明的范围应仅由以下权利要求确定。

Claims (61)

  1. 一种移动监测装置,其特征在于,移动监测装置包括:
    第一类传感器,用于获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种;
    第二类传感器,用于获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种;以及
    处理器,用于将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并控制输出病人状态恢复参数值。
  2. 如权利要求1所述的移动监测装置,其特征在于,移动监测装置还包括显示屏,处理器用于控制在显示屏上显示病人状态恢复参数值。
  3. 如权利要求2所述的移动监测装置,其特征在于,处理器控制显示屏显示包括病人状态恢复参数值中的至少一种参数值的参数界面,并响应用户的操作控制切换参数界面中所显示的参数值或根据预设的时间间隔控制切换参数界面中所显示的参数值。
  4. 如权利要求2或3所述的移动监测装置,其特征在于,在显示屏上显示的病人状态恢复参数值为运动参数值时,处理器控制通过环形的方式显示运动参数值所包括的运动子参数值,运动子参数值包括运动步数、步频、运动距离、卡路里、运动时间、运动路线中的至少一种。
  5. 如权利要求1所述的移动监测装置,其特征在于,移动监测装置还包括通信单元,处理器通过通信单元建立移动监测装置与目标监护设备之间的通信连接,并用于将病人状态恢复参数值通过通信单元发送至目标监护设备,并通过目标监护设备输出病人状态恢复参数值;其中,目标监护设备包括床边监护设备、科室级工作站设备和院级数据中心/院级急救中心管理设备中的至少一种。
  6. 如权利要求5所述的移动监测装置,其特征在于,处理器病人状态恢复参数值通过通信单元发送至目标监护设备时,还同时发送显示模式信息至目标监护设备,以使得目标监护设备根据显示模式信息显示相应的参数界面,以对病人状态恢复参数值进行显示。
  7. 如权利要求6所述的移动监测装置,其特征在于,显示模式信息中定义了参数界面中基本生理体征参数值和非生理体征参数值的相关数据的显示位置,其中,基本生理体征参数值的相关数据显示于参数界面的第一区域,非生理体征参数值的相关数据显示于参数界面的第二区域。
  8. 如权利要求7所述的移动监测装置,其特征在于,基本生理体征参数值的相关数据包括基本生理体征参数值的实时数据,非生理体征参数的相关数据包括非生理体征参数值的实时数据。
  9. 如权利要求8所述的移动监测装置,其特征在于,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。
  10. 如权利要求9所述的移动监测装置,其特征在于,变化趋势数据包括当前时刻之前的预设时间段内检测到的多个非生理体征参数值的变化趋势数据。
  11. 如权利要求5所述的移动监测装置,其特征在于,当目标监护设备为床边监护设备时,处理器还在通信单元第一次建立移动监测装置与目标监护设备之间的通信连接的过程中,执行与目标监护设备的配对操作,并在与目标监护设备配对成功后,建立移动监测装置与目标监护设备之间的通信连接。
  12. 如权利要求11所述的移动监测装置,其特征在于,处理器在执行与目标监护设备的配对操作之前,产生配对提示信息,提示用户是否进行移动监测装置与目标监护设备之间的配对,并在用户选择是时,执行与目标监护设备的配对操作。
  13. 如权利要求11所述的移动监测装置,其特征在于,处理器还用于在移动监测装置与目标监护设备配对成功后,控制将移动监测装置检测的病人状态恢复参数值的实时数 据和历史数据均同步至目标监护设备。
  14. 如权利要求13所述的移动监测装置,其特征在于,通信单元包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种以及WIFI通信模组,当移动监测装置位于病房内时,移动监测装置通过蓝牙模组、WMTS通信模组或NFC通信模组与床边监护设备建立蓝牙连接、WMTS通信连接或NFC通信连接,而将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至床边监护设备;当移动监测装置位于病房外时,移动监测装置通过WIFI模组与科室级工作站设备和/或院级数据中心/院级急救中心管理设备建立WIFI通信连接,将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据同步到科室级工作站设备和/或院级数据中心/院级急救中心管理设备,再通过科室级工作站设备和/或院级数据中心/院级急救中心管理设备将病人状态恢复参数值的实时数据和历史数据同步到床边监护设备。
  15. 如权利要求3所述的移动监测装置,其特征在于,处理器还用于在移动监测装置未接收到用户的操作的时间超过预设时长时,控制显示屏显示锁屏界面,并在响应用户在显示屏的任意滑动操作时,恢复显示参数界面。
  16. 如权利要求1-15任一项所述的移动监测装置,其特征在于,移动监测装置还包括输入单元,处理器还用于响应通过输入单元输入的疼痛等级设置操作,对移动监测装置使用者当前的疼痛等级进行设置,而得到疼痛参数值。
  17. 一种监护设备,其特征在于,监护设备包括:
    通信单元;
    显示屏;以及
    处理器,用于通过通信单元接收病人状态恢复参数值的相关数据,并控制显示屏显示接收的病人状态恢复参数值的相关数据;其中,病人状态恢复参数值的相关数据包括基本生理体征参数值和非生理体征参数值的相关数据,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种。
  18. 如权利要求17所述的监护设备,其特征在于,通信单元用于与移动监测装置建立通信连接,处理器通过通信单元从移动监测装置接收移动监测装置获取的病人状态恢复参数值的相关数据。
  19. 如权利要求17或18所述的监护设备,其特征在于,处理器控制显示屏显示一包括接收的病人状态恢复参数值的相关数据的参数界面,其中,非生理体征参数值的相关数据显示于参数界面的第一区域,基本生理体征参数值的相关数据显示于参数界面的第二区域。
  20. 如权利要求19所述的监护设备,其特征在于,基本生理体征参数值的相关数据包括基本生理体征参数值的实时数据,非生理体征参数值的相关数据包括非生理体征参数值的实时数据。
  21. 如权利要求20所述的监护设备,其特征在于,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。
  22. 如权利要求21所述的监护设备,其特征在于,变化趋势数据包括当前时刻之前的预设时间段内检测到的多个非生理体征参数值的变化趋势数据。
  23. 如权利要求18所述的监护设备,其特征在于,处理器还用于在通信单元第一次与移动监测装置建立通信连接的过程中,接收移动监测装置发送的配对请求,并根据配对请求产生一提示信息,提示用户是否同意与移动监测装置进行配对,并在用户选择是时,与移动监测装置进行配对,以及在配对成功后,建立与移动监测装置的通信连接。
  24. 如权利要求23所述的监护设备,其特征在于,监护设备为放置于病房内的床边监护设备,处理器还用于在监护设备在与移动监测装置配对成功后保存移动监测装置的配 对信息,以在后续移动监测装置位于监护设备预设范围内时,进行自动配对。
  25. 如权利要求24所述的监护设备,其特征在于,处理器还用于还将移动监测装置的配对信息发送至科室级工作站设备和/或院级数据中心/院级急救中心管理设备中,以完成移动监测装置与科室级工作站设备和/或院级数据中心/院级急救中心管理设备的配对。
  26. 如权利要求18所述的监护设备,其特征在于,通信单元包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种,通信单元与移动监测装置建立蓝牙连接、WMTS通信连接或NFC通信连接。
  27. 如权利要求19所述的监护设备,其特征在于,监护设备具有移动监护模式和常规模式,显示屏在常规模式下显示主界面,处理器还用于响应在监护设备的主界面上的目标按键的操作而控制监护设备切换至移动监护模式,并控制显示屏显示包括接收的病人状态恢复参数值的相关数据的参数界面。
  28. 如权利要求18所述的监护设备,其特征在于,通信单元还包括连接接口,用于与相应的传感器附件连接,处理器还用于通过连接接口从传感器附件接收病人状态恢复参数的相关数据;处理器并控制显示屏同时显示从移动监测装置接收的病人状态恢复参数的相关数据以及从传感器附件接收的病人状态恢复参数的相关数据。
  29. 如权利要求18所述的监护设备,其特征在于,通信单元包括WIFI模组,监护设备还通过WIFI模组与科室级工作站设备和/或院级数据中心/院级急救中心管理设备建立WIFI通信连接,并通过科室级工作站设备和/或院级数据中心/院级急救中心管理设备接收移动监测装置发送的病人状态恢复参数值的相关数据,其中,病人状态恢复参数值的相关数据为移动监测装置在位于病房外通过WIFI通信连接向科室级工作站设备和/或院级数据中心/院级急救中心管理设备发送的。
  30. 如权利要求17所述的监护设备,其特征在于,疼痛参数的数据包括疼痛等级,监护设备还包括输入单元,处理器还用于响应通过输入单元输入的疼痛等级设置操作,对疼痛等级进行设置,而获取到疼痛参数值。
  31. 一种监护系统,其特征在于,监护系统包括如权利要求1-16任一项所述的移动监测装置和如权利要求17-30任一项所述的监护设备。
  32. 一种病人状态监测方法,应用于移动监测装置中,其特征在于,所述方法包括:
    通过移动监测装置的第一类传感器获取基本生理体征参数值,基本生理体征参数值包括心电参数值、呼吸参数值、血氧参数值、血压参数值、体温参数值中的至少一种;
    通过移动监测装置的第二类传感器获取非生理体征参数值,非生理特征参数值包括睡眠参数值、运动参数值、疼痛参数值中的至少一种;以及
    将获取到的基本生理体征参数值以及非生理体征参数值作为病人状态恢复参数值,并输出病人状态恢复参数值。
  33. 如权利要求17所述的病人状态监测方法,其特征在于,移动监测装置还包括显示屏;所述输出病人状态恢复参数值,包括:
    控制在移动监测装置的显示屏上显示病人状态恢复参数值。
  34. 如权利要求33所述的病人状态监测方法,其特征在于,所述控制在移动监测装置的显示屏上显示病人状态恢复参数值包括:
    控制显示屏显示包括病人状态恢复参数值中的至少一种参数值的参数界面;以及
    响应用户的操作控制切换参数界面中所显示的参数值或根据预设的时间间隔控制切换参数界面中所显示的参数值。
  35. 如权利要求33或34所述的病人状态监测方法,其特征在于,所述控制在移动监测装置的显示屏上显示病人状态恢复参数值,包括:
    在显示屏上显示的病人状态恢复参数值为运动参数值时,控制通过环形的方式显示运动参数值所包括的运动子参数,运动子参数值包括运动步数、步频、运动距离、卡路里、 运动时间、运动路线中的至少一种。
  36. 如权利要求32所述的病人状态监测方法,其特征在于,移动监测装置还包括通信单元;所述输出病人状态恢复参数值,包括:
    通过通信单元建立与目标监护设备的通信连接;
    将病人状态恢复参数值发送至目标监护设备,并通过目标监护设备输出病人状态恢复参数值;其中,目标监护设备包括床边监护设备、科室级工作站设备和院级数据中心/院级急救中心管理设备中的至少一种。
  37. 如权利要求36所述的病人状态监测方法,其特征在于,将病人状态恢复参数值发送至目标监护设备,并通过目标监护设备输出病人状态恢复参数值,包括:
    将病人状态恢复参数值发送至目标监护设备时,还同时发送显示模式信息至目标监护设备,以使得目标监护设备根据显示模式信息显示相应的参数界面,以对病人状态恢复参数值进行显示。
  38. 如权利要求37所述的病人状态监测方法,其特征在于,显示模式信息中定义了用于显示病人状态恢复参数值的参数界面中基本生理体征参数值和非生理体征参数值的相关数据的显示位置,其中,基本生理体征参数值的相关数据显示于参数界面的第一区域,非生理体征参数值的相关数据显示于参数界面的第二区域。
  39. 如权利要求38所述的病人状态监测方法,其特征在于,基本生理体征参数值的相关数据包括基本生理体征参数的实时数据,非生理体征参数的相关数据包括非生理体征参数的实时数据。
  40. 如权利要求39所述的病人状态监测方法,其特征在于,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。
  41. 如权利要求40所述的病人状态监测方法,其特征在于,变化趋势数据包括当前时刻之前的预设时间段内检测到的多个非生理体征参数值的变化趋势数据。
  42. 如权利要求36所述的病人状态监测方法,其特征在于,当目标监护设备为床边监护设备时,所述方法还包括:
    在第一次建立移动监测装置与目标监护设备之间的通信连接的过程中,执行与目标监护设备的配对操作;以及
    在与目标监护设备配对成功后,建立移动监测装置与目标监护设备之间的通信连接。
  43. 如权利要求42所述的病人状态监测方法,其特征在于,执行与目标监护设备的配对操作之前,所述方法还包括:
    产生配对提示信息,提示用户是否进行移动监测装置与目标监护设备之间的配对;
    执行与目标监护设备的配对操作,包括:
    在用户选择是时,执行与目标监护设备的配对操作。
  44. 如权利要求42所述的病人状态监测方法,其特征在于,所述输出病人状态恢复参数值,进一步包括:
    在移动监测装置与目标监护设备配对成功后,控制将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至目标监护设备。
  45. 如权利要求44所述的病人状态监测方法,其特征在于,通信单元包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种以及WIFI通信模组,当移动监测装置位于病房内时,移动监测装置通过蓝牙模组、WMTS通信模组或NFC通信模组与床边监护设备建立蓝牙连接、WMTS通信连接或NFC通信连接;所述控制将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至目标监护设备,包括:
    控制通过蓝牙连接、WMTS通信连接或NFC通信连接将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至床边监护设备;
    当移动监测装置位于病房外时,移动监测装置通过WIFI模组与科室级工作站设备和/ 或院级数据中心/院级急救中心管理设备建立WIFI通信连接;所述控制将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据均同步至目标监护设备,包括:
    控制通过WIFI通信连接将移动监测装置检测的病人状态恢复参数值的实时数据和历史数据同步到科室级工作站设备和/或院级数据中心/院级急救中心管理设备,再通过科室级工作站设备和/或院级数据中心/院级急救中心管理设备将病人状态恢复参数值的实时数据和历史数据同步到床边监护设备。
  46. 如权利要求34所述的病人状态监测方法,其特征在于,所述方法还包括:
    在移动监测装置未接收到用户的操作的时间超过预设时长时,控制显示屏显示锁屏界面;以及
    响应用户在显示屏的任意滑动操作,恢复显示参数界面。
  47. 如权利要求32-46任一项的病人状态监测方法,其特征在于,移动监测装置还包括输入单元,所述方法还包括:
    响应通过输入单元输入的疼痛等级设置操作,对移动监测装置使用者当前的疼痛等级进行设置。
  48. 一种病人状态监测方法,应用于监护设备中,其特征在于,监护设备包括通信单元和显示屏,所述方法包括:
    通过通信单元接收病人状态恢复参数值的相关数据;以及
    控制显示屏显示接收的病人状态恢复参数值的相关数据;其中,病人状态恢复参数值包括基本生理体征参数值和非生理体征参数值的相关数据,基本生理体征参数值包括心电参数、呼吸参数、血氧参数、血压参数、体温参数中的至少一种,非生理特征参数值包括睡眠参数、运动参数、疼痛参数中的至少一种。
  49. 如权利要求48所述的病人状态监测方法,其特征在于,所述通信单元用于与移动监测装置建立通信连接,通过通信单元接收病人状态恢复参数值的相关数据,包括:
    通过通信单元从移动监测装置接收移动监测装置获取的病人状态恢复参数值的相关数据。
  50. 如权利要求48或49所述的病人状态监测方法,其特征在于,所述控制显示屏显示接收的病人状态恢复参数值的相关数据,包括:
    控制显示屏显示一包括接收的病人状态恢复参数值的相关数据的参数界面,其中,非生理体征参数值的相关数据显示于参数界面的第一区域,基本生理体征参数值的相关数据显示于参数界面的第二区域。
  51. 如权利要求50所述的病人状态监测方法,其特征在于,基本生理体征参数值的相关数据包括基本生理体征参数值的实时数据,非生理体征参数值的相关数据包括非生理体征参数的实时数据。
  52. 如权利要求51所述的病人状态监测方法,其特征在于,非生理体征参数值的相关数据还包括非生理体征参数值的变化趋势数据。
  53. 如权利要求52所述的病人状态监测方法,其特征在于,变化趋势数据包括当前时刻之前预设时间段内检测到的多个非生理体征参数值的变化趋势数据。
  54. 如权利要求49所述的病人状态监测方法,其特征在于,所述方法还包括:
    在通信单元第一次与移动监测装置建立通信连接的过程中,接收移动监测装置发送的配对请求;
    根据配对请求产生一提示信息,提示用户是否同意与移动监测装置进行配对;以及
    在用户选择是时,与移动监测装置进行配对,并在配对成功后,建立与移动监测装置的通信连接。
  55. 如权利要求54所述的病人状态监测方法,其特征在于,所述方法还包括:
    在监护设备在与移动监测装置配对成功后保存移动监测装置的配对信息,以在后续移 动监测装置位于监护设备预设范围内时,进行自动配对。
  56. 如权利要求54所述的病人状态监测方法,其特征在于,监护设备为放置于病房内的床边监护设备,所述方法还包括:
    将移动监测装置的配对信息发送至科室级工作站设备和/或院级数据中心/院级急救中心管理设备中,以完成移动监测装置与科室级工作站设备和/或院级数据中心/院级急救中心管理设备的配对。
  57. 如权利要求49所述的病人状态监测方法,其特征在于,通信单元包括蓝牙模组、WMTS通信模组、NFC通信模组中的至少一种,通信单元与移动监测装置建立蓝牙连接、WMTS通信连接或NFC通信连接。
  58. 如权利要求50所述的病人状态监测方法,其特征在于,监护设备具有移动监护模式和常规模式,显示屏在常规模式下显示主界面;所述控制显示屏显示一包括接收的病人状态恢复参数值的相关数据的参数界面,包括:
    响应在监护设备的主界面上的目标按键的操作而控制监护设备切换至移动监护模式;以及
    在移动监护模式下,控制显示屏显示包括接收的病人状态恢复参数值的相关数据的参数界面。
  59. 如权利要求49所述的病人状态监测方法,其特征在于,通信单元还包括连接接口,用于与相应的传感器附件连接,所述方法还包括:
    通过连接接口从传感器附件接收病人状态恢复参数值的相关数据;
    控制显示屏显示接收的病人状态恢复参数值的相关数据,包括:
    控制显示屏同时显示从移动监测装置接收的病人状态恢复参数值的相关数据以及从传感器附件接收的病人状态恢复参数值的相关数据。
  60. 如权利要求49所述的病人状态监测方法,其特征在于,通信单元包括WIFI模组;所述通过通信单元从移动监测装置接收移动监测装置获取的病人状态恢复参数值的相关数据,还包括:
    通过WIFI模组与科室级工作站设备和/或院级数据中心/院级急救中心管理设备建立WIFI通信连接,并通过科室级工作站设备和/或院级数据中心/院级急救中心管理设备接收移动监测装置发送的病人状态恢复参数值的相关数据,其中,病人状态恢复参数值的相关数据为移动监测装置在位于病房外通过WIFI通信连接向科室级工作站设备和/或院级数据中心/院级急救中心管理设备发送的。
  61. 如权利要求48所述的病人状态监测方法,其特征在于,疼痛参数的数据包括疼痛等级,监护设备还包括输入单元,所述方法还包括:
    响应通过输入单元输入的疼痛等级设置操作,对疼痛等级进行设置,而获取到疼痛参数的数据。
PCT/CN2018/125662 2018-12-29 2018-12-29 移动监测装置、监护设备、监护系统及病人状态监测方法 WO2020133426A1 (zh)

Priority Applications (4)

Application Number Priority Date Filing Date Title
CN201880099009.9A CN113015479B (zh) 2018-12-29 2018-12-29 移动监测装置、监护设备、监护系统及病人状态监测方法
PCT/CN2018/125662 WO2020133426A1 (zh) 2018-12-29 2018-12-29 移动监测装置、监护设备、监护系统及病人状态监测方法
CN202410306637.7A CN118303851A (zh) 2018-12-29 2018-12-29 移动监测装置、监护设备、监护系统及病人状态监测方法
US17/362,851 US20210321886A1 (en) 2018-12-29 2021-06-29 Portable monitoring apparatus, monitoring device, monitoring system and patient status monitoring method

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/CN2018/125662 WO2020133426A1 (zh) 2018-12-29 2018-12-29 移动监测装置、监护设备、监护系统及病人状态监测方法

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2018/125795 Continuation-In-Part WO2020133486A1 (zh) 2018-12-29 2018-12-29 移动监护设备、移动监护系统及监护体域系统

Related Child Applications (1)

Application Number Title Priority Date Filing Date
US17/362,851 Continuation-In-Part US20210321886A1 (en) 2018-12-29 2021-06-29 Portable monitoring apparatus, monitoring device, monitoring system and patient status monitoring method

Publications (1)

Publication Number Publication Date
WO2020133426A1 true WO2020133426A1 (zh) 2020-07-02

Family

ID=71129518

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2018/125662 WO2020133426A1 (zh) 2018-12-29 2018-12-29 移动监测装置、监护设备、监护系统及病人状态监测方法

Country Status (2)

Country Link
CN (2) CN118303851A (zh)
WO (1) WO2020133426A1 (zh)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115624320A (zh) * 2022-09-15 2023-01-20 浙江智柔科技有限公司 生理参数监测系统、方法、电子装置和存储介质

Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2011147493A (ja) * 2010-01-19 2011-08-04 Omron Healthcare Co Ltd 生体情報監視装置、警報値設定方法および警報値設定プログラム
CN103027671A (zh) * 2013-01-09 2013-04-10 王成 移动生理参数监测系统
CN105380593A (zh) * 2014-08-22 2016-03-09 深圳迈瑞生物医疗电子股份有限公司 用于患者活动监测的方法和系统以及便携式遥测装置
CN205729337U (zh) * 2016-02-01 2016-11-30 深圳大微医疗科技开发有限公司 一种便携式医疗监护装置
US20170143256A1 (en) * 2015-11-24 2017-05-25 Annu H. Navani System and method for measuring intensity of pain and emotional responses
CN107550487A (zh) * 2017-09-22 2018-01-09 成都比特律动科技有限责任公司 便携式心电监护系统
CN107788960A (zh) * 2017-11-19 2018-03-13 成都漫程科技有限公司 一种多功能便携式心电监护系统
CN108742594A (zh) * 2018-06-23 2018-11-06 苏强 一种穿戴式冠心病检测装置

Patent Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2011147493A (ja) * 2010-01-19 2011-08-04 Omron Healthcare Co Ltd 生体情報監視装置、警報値設定方法および警報値設定プログラム
CN103027671A (zh) * 2013-01-09 2013-04-10 王成 移动生理参数监测系统
CN105380593A (zh) * 2014-08-22 2016-03-09 深圳迈瑞生物医疗电子股份有限公司 用于患者活动监测的方法和系统以及便携式遥测装置
US20170143256A1 (en) * 2015-11-24 2017-05-25 Annu H. Navani System and method for measuring intensity of pain and emotional responses
CN205729337U (zh) * 2016-02-01 2016-11-30 深圳大微医疗科技开发有限公司 一种便携式医疗监护装置
CN107550487A (zh) * 2017-09-22 2018-01-09 成都比特律动科技有限责任公司 便携式心电监护系统
CN107788960A (zh) * 2017-11-19 2018-03-13 成都漫程科技有限公司 一种多功能便携式心电监护系统
CN108742594A (zh) * 2018-06-23 2018-11-06 苏强 一种穿戴式冠心病检测装置

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115624320A (zh) * 2022-09-15 2023-01-20 浙江智柔科技有限公司 生理参数监测系统、方法、电子装置和存储介质

Also Published As

Publication number Publication date
CN113015479A (zh) 2021-06-22
CN118303851A (zh) 2024-07-09
CN113015479B (zh) 2024-04-02

Similar Documents

Publication Publication Date Title
US20240268685A1 (en) Body-worn vital sign monitor
US8364250B2 (en) Body-worn vital sign monitor
US10420476B2 (en) Body-worn vital sign monitor
EP3684245B1 (en) Determining an orientation of a wearable device
US20110066009A1 (en) Body-worn vital sign monitor
US20110066050A1 (en) Body-worn vital sign monitor
US20110066045A1 (en) Body-worn vital sign monitor
CA3036168A1 (en) Leadless electrocardiogram monitor
US20210321886A1 (en) Portable monitoring apparatus, monitoring device, monitoring system and patient status monitoring method
JP6811595B2 (ja) 生体情報モニタ、生体情報ソフトウェア制御方法、及びプログラム
WO2020133426A1 (zh) 移动监测装置、监护设备、监护系统及病人状态监测方法
JP2016077710A (ja) 生体情報測定装置、生体情報表示方法、及びプログラム
US9486154B2 (en) Device and method for recording physiological signal
WO2020133347A1 (zh) 一种对患者的监护方法及装置
US11005575B2 (en) Wireless sensors in medical environments
CN103190888B (zh) 多参数遥测监护系统
WO2020133425A1 (zh) 监护设备、监护方法及计算机可读存储介质
US20190029635A1 (en) Patient monitor
US20220117561A1 (en) Monitoring device, method for setting reference baseline and readable storage medium
US20240099630A1 (en) Electrocardiogram Systems and Devices and Related Methods
WO2020133466A1 (zh) 监护设备、监护方法及计算机可读存储介质
WO2018211963A1 (ja) 情報表示装置およびプログラム
KR20210083415A (ko) 혈압을 모니터링하는 전자 장치 및 방법
JP2024116486A (ja) 携帯型医療機器および医療システム
CN111954161A (zh) 一种病房监护方法及设备、计算机可读存储介质

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 18945131

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

32PN Ep: public notification in the ep bulletin as address of the adressee cannot be established

Free format text: NOTING OF LOSS OF RIGHTS PURSUANT TO RULE 112(1) EPC (EPO FORM1205 DATED 10.11.2021)

122 Ep: pct application non-entry in european phase

Ref document number: 18945131

Country of ref document: EP

Kind code of ref document: A1