CN219895714U - Intraoperative monitoring system - Google Patents

Abstract

The utility model relates to an intraoperative monitoring system, which comprises a bed body, an external terminal and a communication module, wherein an image acquisition device is arranged on the bed body and is in communication connection with the external terminal through the communication module; the image acquisition device is used for shooting an operation process image corresponding to the object to be monitored and sending the operation process image to the external terminal; the external terminal is used for receiving the operation process image and displaying the operation process image. The intraoperative monitoring system can transmit the information of the surgical procedure to an external terminal in real time in the surgical procedure.

Description

Intraoperative monitoring system

Technical Field

The utility model relates to the technical field of medical treatment, in particular to an intraoperative monitoring system.

Background

When an object to be monitored performs an operation, medical staff needs to monitor physiological parameters of the object to be monitored in real time and the operation process, and the physiological parameters generally measured in an operating room comprise: electrocardiograph, heart rate, blood pressure, blood oxygen, body temperature, respiratory rate, etc.

However, during the surgical procedure, only medical personnel can determine vital signs of the subject to be monitored by means of the above-mentioned monitored physiological parameters, and learn about the progress and result of the surgery. The family members of the objects to be monitored cannot acquire the operation progress and the result in real time in the operation process, so how to transmit the operation process information in real time in the operation process becomes a technical problem to be solved in the current medical technical field.

Disclosure of Invention

In view of the foregoing, it is desirable to provide an intraoperative monitoring system capable of transmitting information of a surgical procedure in real time during the surgical procedure.

One embodiment of the present utility model provides an intraoperative monitoring system comprising: the bed body is provided with an image acquisition device, and the image acquisition device is in communication connection with the external terminal through the communication module;

the image acquisition device is used for shooting an operation process image corresponding to the object to be monitored and sending the operation process image to the external terminal;

and the external terminal is used for receiving the operation process image and displaying the operation process image.

In one embodiment, the intraoperative monitoring system further comprises a plurality of types of data acquisition devices arranged on the bed body, and each data acquisition device is connected with the communication module;

each data acquisition device is used for acquiring the physiological information of the object to be monitored and sending the physiological information to the external terminal.

In one embodiment, the physiological information includes at least one of heart rate, respiratory rate, electrocardiographic signals, blood oxygen, blood pressure, body temperature, and body position.

In one embodiment, the data acquisition device comprises at least one of a fiber optic sensing unit, a radar, a temperature sensor, and a heart pulse monitoring unit;

the optical fiber sensing unit is used for collecting the respiratory frequency and the heart rate of the object to be monitored;

the radar is used for acquiring electrocardiosignals and body positions of the object to be monitored;

the temperature sensor is used for acquiring the body temperature of the object to be monitored;

and the heart pulse monitoring unit is used for collecting blood oxygen and blood pressure of the object to be monitored.

In one embodiment, the intraoperative monitoring system further comprises:

and the alarm device is connected with each data acquisition device and is used for sending alarm information according to the abnormal physiological information acquired by the data acquisition devices.

In one embodiment, the bed body is further provided with a processor, and the input end of the processor is connected with the image acquisition devices and/or the data acquisition devices and is used for inputting surgical process images and/or physiological information; the output end of the processor is connected with an external terminal through a communication module and is used for outputting an image processing result and/or an information processing result.

In one embodiment, the external terminals include a first terminal and a second terminal;

the first terminal is used for receiving and displaying any one or more of the image processing results and the information processing results;

and the second terminal is used for receiving and displaying the operation process image and the physiological information of the object to be monitored.

In one embodiment, the intraoperative monitoring system further comprises: information inquiry equipment and a voice control device;

the output end of the voice control device is connected with the input end of the information inquiry equipment, the input end of the voice control device is used for receiving voice control instructions of a user, and the output end of the voice control device is used for outputting the voice control instructions to the information inquiry equipment;

the input end of the information inquiry equipment is used for receiving the voice control instruction and displaying inquiry information corresponding to the voice control instruction.

In one embodiment, the intraoperative monitoring system further comprises a monitoring terminal, wherein the monitoring terminal is in communication connection with the image acquisition device and the external terminal.

In one embodiment, the image capture device is a camera.

The intraoperative monitoring system provided by the embodiment of the utility model comprises a bed body, an external terminal and a communication module, wherein an image acquisition device is arranged on the bed body and is in communication connection with the external terminal through the communication module; the image acquisition device is used for shooting an operation process image corresponding to the object to be monitored and sending the operation process image to the external terminal; the external terminal is used for receiving the operation process image and displaying the operation process image. In this embodiment, through the bed body and the communication module that set up in the operating room and the image acquisition device that sets up on the bed body, can gather and send the outside terminal outside the operating room with the operating procedure image in the operating room for medical personnel who holds outside terminal or the family members of waiting to monitor the object can learn the operating procedure image in real time, so that medical personnel or the family members of waiting to monitor the object can be to knowing the operation condition in the operating room, can reduce the operation anxiety of the family members of waiting to monitor the object, and medical personnel can the minimum time notice the family members of waiting to monitor the object make follow-up arrangement under the critical condition.

Drawings

FIG. 1 is a schematic diagram of an intraoperative monitoring system in one embodiment;

FIG. 2 is a schematic diagram of an intraoperative monitoring system in another embodiment;

FIG. 3 is a schematic diagram of an intraoperative monitoring system in another embodiment;

FIG. 4 is a schematic diagram of an intraoperative monitoring system in another embodiment;

FIG. 5 is a schematic diagram of an intraoperative monitoring system in another embodiment;

FIG. 6 is a schematic diagram of specific content displayed by the first terminal in one embodiment;

FIG. 7 is a schematic diagram of an intraoperative monitoring system in another embodiment;

fig. 8 is a schematic structural diagram of an intraoperative monitoring system in another embodiment.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "coupled" as used herein includes both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present utility model, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the present utility model, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

Firstly, before the technical scheme provided by the embodiment of the utility model is specifically introduced, the technical background or technical evolution context based on the utility model is introduced. When a patient performs an operation, medical staff needs to continuously monitor physiological parameters of the patient in real time and the operation process. The medical staff can timely adjust the operation scheme according to the feedback of the physiological parameters of the patient so as to prevent uncontrollable events in the operation. Physiological parameters typically measured in an operating room include: electrocardiograph, heart rate, blood pressure, blood oxygen, body temperature, respiratory rate, etc.

However, during surgery, only medical personnel can determine the patient's physiological signs through the above-mentioned monitored physiological parameters, as well as learn about the progress and outcome of the surgery. The family members of the objects to be monitored cannot acquire the operation progress and result in real time in the operation process. Therefore, how to transmit the operation process information in real time during the operation process is a technical problem to be solved in the current medical technical field. In this regard, the present utility model provides an intraoperative monitoring system.

The technical scheme related to the embodiment of the utility model is described below in connection with the scene to which the embodiment of the utility model is applied.

Referring to fig. 1, one embodiment of the present utility model provides an intraoperative monitoring system 10, the intraoperative monitoring system 10 comprising: the bed body 100, the external terminal 200 and the communication module 300, wherein the image acquisition device 110 is arranged on the bed body 100, and the image acquisition device 110 is in communication connection with the external terminal 200 through the communication module 300.

The intraoperative monitoring system 10 is applied to an operating room, and the bed body 100 is a bed for bearing an object to be monitored in the operating room in the process of performing an operation. The external terminal 200 refers to a terminal outside an operating room, and the external terminal 200 may be a computer device, which may be, but is not limited to, an industrial computer, a notebook computer, a smart phone, a tablet computer, a portable wearable device, and the like. The present embodiment is not limited in the kind and structure of the external terminal 200 and the like as long as the functions thereof can be realized.

The communication module 300 may be a wireless communication module or a wired communication module. The present embodiment does not limit the kind of the communication module 300 as long as the functions thereof can be realized.

In an alternative embodiment, communication module 300 is a wireless communication module. The communication module 300 may be a bluetooth module, a routing module, or the like, which is not limited in this embodiment.

The intraoperative monitoring system 10 further includes an image acquisition device 110, the image acquisition device 110 being disposed on the bed 100.

In an alternative embodiment, the image capture device 110 is positioned at the head or tail of the bed 100.

The image capturing device 110 is used for capturing an operation process image corresponding to an object to be monitored, and transmitting the operation process image to the external terminal 200. When a medical staff performs an operation on an object to be monitored, the image acquisition device 110 disposed on the bed body 100 can acquire an operation process image corresponding to the object to be monitored in real time. Surgical procedure images refer to images that are capable of characterizing the progress of a surgical procedure. The surgical procedure image may include a surgical start image, a surgical in-image, a surgical suture image, and a surgical end image. The present embodiment is not limited to the specific kind and structure of the image pickup device 110.

The image pickup device 110 and the external terminal 200 are communicatively connected through the communication module 300. The image acquisition device 110 transmits the acquired surgical procedure image corresponding to the object to be monitored to the external terminal 200 through the communication module 300. The external terminal 200 is used to receive the surgical procedure image and display the surgical procedure image. That is, the external terminal 200 includes a display device, and the external terminal 200 displays the surgical procedure image on the display device after receiving the surgical procedure image, so that a medical staff holding the external terminal 200 or a family member of the object to be monitored determines the current surgical procedure from the surgical procedure image displayed on the display device.

The intraoperative monitoring system 10 provided by the embodiment of the utility model comprises a bed body 100, an external terminal 200 and a communication module 300, wherein an image acquisition device 110 is arranged on the bed body 100. The image pickup device 110 is communicatively connected to the external terminal 200 through the communication module 300. The image acquisition device 110 is used for shooting an operation process image corresponding to the object to be monitored and sending the operation process image to the external terminal 200; the external terminal 200 is used to receive the surgical procedure image and display the surgical procedure image. In this embodiment, through the bed body 100 and the communication module 300 which are disposed in the operating room, and the image acquisition device 110 which is disposed on the bed body 100, the operation process image in the operating room can be acquired and sent to the external terminal 200 outside the operating room, so that the medical staff holding the external terminal 200 or the family members of the object to be monitored can learn the operation process image in real time, so that the medical staff or the family members of the object to be monitored can learn the operation condition in the operating room, the operation anxiety of the family members of the object to be monitored can be reduced, and the medical staff can notify the family members of the object to be monitored in the shortest time to make subsequent arrangement in the critical situation. In addition, the image acquisition device 110 is arranged on the bed body 100, so that the operation process image can be acquired more clearly and without shielding.

In one embodiment, image capture device 110 is a camera. That is, a camera is provided on the bed 110, an operation process image of the object to be monitored is photographed by the camera, and the operation process image is transmitted to the external terminal 200 through the communication module 300.

In another embodiment, the image acquisition device 110 may also be a scanner.

Referring to fig. 2, in one embodiment, the intraoperative monitoring system 10 further includes a plurality of types of data acquisition devices 120 disposed on the bed 100, each data acquisition device 120 being connected to the communication module 300. Each data acquisition device 120 is configured to acquire physiological information of a subject to be monitored, and transmit the physiological information to the external terminal 200.

Various types of data acquisition devices 120 may be integrated on the bed 100. Optionally, a removable and detachable mattress is laid on the bed 100, and a plurality of types of data acquisition devices 120 are integrated in the mattress, and the mattress is loaded with an object to be monitored. The location of integration of the data acquisition device 120 in the mattress varies depending on the physiological information that the data acquisition device 120 is required to acquire. For example, the data acquisition device 120 needs to acquire an electrocardiographic signal of the object to be monitored, and then the data acquisition device 120 is integrated at a position on the mattress where the heart of the object to be monitored is located. The data acquisition devices 120 are detachably integrated on the mattress, so that the positions of the data acquisition devices 120 can be conveniently moved, and the data acquisition devices 120 can be replaced.

In an alternative embodiment, the mattress on the bed 100 has a thickness of 1cm-2cm and the exterior of the mattress is made of medical grade polypropylene material.

The data acquisition device 120 is a device for acquiring physiological information of an object to be monitored, the physiological information of the object to be monitored to be acquired is different, and the types of the data acquisition device 120 are different. The specific type of the data acquisition device 120 and the number of the data acquisition devices 120 in this embodiment are not limited, and the user can set the data acquisition device according to the actual application scenario. If the physiological information to be monitored of the object to be monitored is body temperature, the data acquisition device can be a temperature sensor.

After the physiological information of the object to be monitored is collected, each data collection device 120 transmits the collected physiological information to the external terminal 200 through the communication module 300, so that the medical staff holding the external terminal 200 or the family members of the object to be monitored can obtain the physiological information of the object to be monitored.

In this embodiment, the intraoperative monitoring system 10 further includes a data acquisition device 120, and the data acquisition device 120 can send the acquired physiological information of the object to be monitored to the external terminal 200 through the communication module 300, so that the medical staff holding the external terminal 200 or the family members of the object to be monitored can acquire the physiological information of the object to be monitored in real time.

In one embodiment, the physiological information includes at least one of heart rate, respiratory rate, electrocardiographic signals, blood oxygen, blood pressure, body temperature, and body position. That is, in the operation process, the physiological information required to monitor the object to be monitored may be any one or more of heart rate, respiratory rate, electrocardiosignal, blood oxygen, blood pressure, body temperature and body position, and the user may select according to the actual requirement.

In one embodiment, the plurality of types of data acquisition devices 120 corresponding to physiological information include at least one of a fiber optic sensing unit, a radar, a temperature sensor, and a heart pulse monitoring unit. That is, in the surgical procedure, the data acquisition device 120 corresponding to the physiological information of the object to be monitored may be any one or more of an optical fiber sensing unit, a radar, a temperature sensor, and a heart pulse monitoring unit, and the user may select the physiological information according to the need.

The optical fiber sensing unit is used for collecting the respiratory rate and the heart rate of the object to be monitored. The optical fiber sensing unit adopts an optical fiber sensing technology, the optical fiber sensing technology can monitor tiny static force and dynamic force, and can accurately sense the heart and respiratory chest abdomen vibration force of an object to be monitored in a static scene, so that the respiratory frequency and a heart attack chart, namely the heart rate, are obtained. The optical fiber sensing unit may be disposed at a position of the mattress corresponding to the heart of the subject to be monitored.

The radar is used for acquiring electrocardiosignals and body positions of the object to be monitored. The radar is millimeter wave radar, and the microwave radar technology can emit signals with the wavelength of millimeter magnitude. The millimeter wave radar can obtain the distance between the radar and the object to be monitored through the time delay generated by the emission signal and the reflection signal of the electromagnetic wave, the moving speed of the object to be monitored can be calculated through the frequency shift generated by the emission signal and the reflection signal of the electromagnetic wave, and the form of the object to be monitored can be obtained through the intensity of the emission signal of the electromagnetic wave, so that the body position of the object to be monitored can be obtained, and the situation that the object to be monitored keeps a posture for a long time to cause pressure sores can be prevented. The end-to-end reconstruction mapping from the input of radio frequency to the output of electrocardiogram can be realized by utilizing the millimeter wave technology and the deep learning technology, so that the electrocardiosignals of the monitored object can be brought.

The temperature sensor is used for collecting the body temperature of the object to be monitored.

The heart pulse monitoring unit is used for collecting blood oxygen and blood pressure of a subject to be monitored. The heart pulse monitoring unit monitors blood oxygen and blood pressure of the subject to be monitored based on a heart pulse monitoring technology of light sensation. The heart pulse monitoring unit may be arranged at a corresponding mattress position under the wrist of the subject to be monitored.

In this embodiment, different physiological information is collected by using the corresponding data collection device 120, so that accuracy and efficiency of collecting physiological information can be improved.

In one embodiment, as shown in FIG. 3, the intraoperative monitoring system 10 further includes an alarm device 400. The alarm device 400 is connected to each data acquisition device 120, and is configured to send alarm information according to abnormal physiological information acquired by the data acquisition devices 120.

The alarm device 400 is arranged in an operating room, and the alarm device 400 can be a warning bell or a warning lamp. The specific structure and kind of the alarm device 400 are not limited in this embodiment as long as the function thereof can be achieved.

After the data acquisition device 120 acquires the physiological information, the physiological information is transmitted to the alarm device 400, and the alarm device 400 determines whether the physiological information is abnormal or not and sends out alarm information when the physiological information is determined to be abnormal. For example, the data acquisition device 120 is a temperature sensor, the temperature sensor transmits the temperature information to the alarm device 400 after monitoring the temperature information of the object to be monitored, and the alarm device 400 compares the temperature information with a temperature threshold; if the temperature threshold value is exceeded, determining that the temperature information is abnormal, and sending out alarm information.

In an alternative embodiment, after the data acquisition device 120 acquires the physiological information, it determines whether the physiological information is abnormal, and if the physiological information is abnormal, the data acquisition device sends the physiological abnormal information to the alarm device 400, so that the alarm device 400 sends alarm information.

In this embodiment, the intra-operative monitoring system 10 is provided with the alarm device 400 connected to the data acquisition device 110, and when the physiological information acquired by the data acquisition device 110 is abnormal, the alarm device 400 can timely send out alarm information, so that medical staff in an operating room can timely acquire the physiological information abnormal message and make corresponding measures, for example, adjust an operation scheme, etc., so that the intra-operative monitoring system 10 provided by the embodiment of the utility model has higher applicability.

In one embodiment, as shown in fig. 4, a processor 130 is further disposed on the bed body 100, and an input end of the processor 130 is connected to the image acquisition device 110 and/or each data acquisition device 120, and is used for inputting surgical procedure images and/or physiological information; an output terminal of the processor 130 is connected to the external terminal 200 through the communication module 300 for outputting an image processing result and/or an information processing result.

The intraoperative monitoring system 10 further includes a processor 130, the processor 130 being disposed on the bed 100.

In an alternative embodiment, the processor 130 may be integrated into the mattress on the bed 100.

The processor 130 includes an input end and an output end, the input end of the processor 130 may be connected to the image collector 110, the input end of the processor 130 may also be connected to each data collector 120, and the input end of the processor 130 may also be connected to both the image collector 110 and each data collector 120.

The surgical procedure image acquired by the image acquisition device 110 is input to the processor 130 through an input of the processor 130. Upon receiving the surgical procedure image, the processor 130 performs an identification process on the surgical procedure image to determine a surgical procedure characterized by the surgical procedure image, i.e., an image processing result. The output terminal of the processor 130 transmits the image processing result to the external terminal 200 through the communication module 300. The image processing result, i.e., the current surgical procedure, is displayed on the display device of the external terminal 200. For example, the surgical procedure image is a surgical suture image, the "surgical status" is displayed on the display device of the external terminal: in stitching). Therefore, when the operation is about to end, the family members of the object to be monitored with the external terminal 200 can learn the operation progress in advance, and the waiting anxiety time of the family members can be relieved, so that the family members can receive the object to be monitored accurately in advance.

Physiological information collected by each data collection device 120 is input to the processor 130 via an input of the processor 130. After receiving the physiological information, the processor 130 analyzes and processes the physiological information to determine whether the vital sign of the object to be monitored is normal, i.e. the information processing result. The output terminal of the processor 130 transmits the information processing result to the external terminal 200 through the communication module 300. The information processing result, i.e., whether the vital sign of the current subject to be monitored is normal, is displayed on the display device of the external terminal 200.

In this embodiment, the processing of the processor 130 enables the external terminal 200 to receive the image processing result and/or the information processing result, so that a medical staff or family member holding the external terminal 200 can more clearly know the operation progress and vital signs of the object to be monitored, and the intra-operative monitoring system 10 has higher applicability.

In one embodiment, as shown in fig. 5, the external terminal 200 includes a first terminal 210 and a second terminal 220.

The first terminal 210 represents a terminal held by a family member of an object to be monitored. The first terminal 210 may be a smart phone, a portable wearable device, or the like. The first terminal 210 is configured to receive and display any one of the image processing result and the information processing result. That is, any one or more of the image processing result and the information processing result may be displayed on the display device of the first terminal 210, and the user may set himself according to the actual need.

The second terminal 220 represents a terminal that is held by a medical professional outside the operating room. The second terminal 220 may be a computer tablet, a computer, etc. The second terminal 220 is used for receiving and displaying the surgical procedure image and the physiological information of the object to be monitored. That is, the surgical procedure image and the physiological information of the object to be monitored in the surgical procedure may be displayed on the display device of the second terminal 220 in real time, so that the external medical staff can know the surgical state in the operating room and the vital signs of the object to be monitored in real time.

In the present embodiment, the external terminal 200 includes a first terminal 210 and a second terminal 220, and different contents are displayed for different terminals, so that the applicability of the system 10 is monitored intraoperatively.

In an alternative embodiment, a medical staff outside the operating room may acquire the operation state in the operating room and vital signs of the subject to be monitored, or the medical staff in the operating room may transmit the post-operation notes and nursing points, etc. to the first terminal 210 after the operation is finished, and display the post-operation notes and nursing points, etc., that is, the post-operation notes and nursing points, etc. may also be displayed on the display device of the first terminal 210. Specifically, the first terminal 210 may directly display the postoperative notice and the nursing gist, or may display a two-dimensional code, and the family members of the subject to be monitored may acquire the postoperative notice and the nursing gist by scanning the two-dimensional code.

The content that can be displayed on the display device of the first terminal 210 is shown in fig. 6. The specific time of the current procedure is displayed within the display box of the first procedure time in fig. 6; displaying the specific state of the current operation (in operation, suture or operation end) in the display frame of the second operation state and vital sign, and whether the vital sign of the object to be monitored is normal or not; and displaying corresponding two-dimensional codes in a display frame of the third notes and nursing points in the operation, or directly displaying specific notes and nursing points.

In an alternative embodiment, the first terminal 210 includes an alarm module, and when a critical situation occurs in the object to be monitored in the operation process, the first terminal 210 receives an alarm notification, and the alarm module sends out alarm information, so that the family members of the object to be monitored can interface with the medical staff in time for subsequent arrangement.

In an alternative embodiment, the first terminal 210 includes a processing module, where the first terminal 210 may further receive the surgical procedure image, and obtain an image processing result after the surgical procedure image is identified and processed by the processing module, that is, a specific state of the surgery corresponding to the surgical procedure image; and displays the processing result on the display device of the first terminal 210. In this embodiment, the processing module typically performs the identification process on the surgical procedure image using conventional image identification methods.

In an alternative embodiment, the processing module adopts methods such as deep learning training or template matching to perform recognition processing on the operation process image, so as to obtain an image processing result. If the processing module adopts a deep learning training method to identify and process the image of the operation process, and the image processing result is determined to be the image of the suture needle in the image of the operation process, the operation is in a suture stage, and the operation is about to be ended. The display device can display that the operation is in the suture stage, and the operation is about to be finished, so that the family members of the object to be detected can be given a prompt, and the anxiety of the operation of the family members of the object to be detected is reduced.

In one embodiment, as shown in fig. 7, the intraoperative monitoring system 10 further comprises: a kiosk 500 and a voice control device 510. The voice control device 510 includes an input and an output, as well as the information query apparatus 500. An output of the voice control device 510 is connected to an input of the information inquiry apparatus 500.

The input terminal of the voice control device 510 is used for receiving voice control instructions of a user. The voice control instruction refers to information of the medical staff in the operating room. The output terminal of the voice control device 510 is used for outputting voice control instructions to the information query apparatus 500. The input end of the information inquiry device 500 is used for receiving the voice control instruction and displaying inquiry information corresponding to the voice control instruction. In other words, after receiving the voice control instruction from the user, the input end of the voice control device 510 transmits the voice control instruction to the input end of the voice query device 500 through the output end of the voice control device 510, and after receiving the voice control instruction, the voice query device 500 searches the query information corresponding to the voice control instruction in the storage device and displays the query information. For example, the voice control instruction received by the voice control device 510 is "display of the record of the visit of the object to be monitored", and the information inquiry apparatus 500 directly displays the record of the visit of the object to be monitored according to the voice control instruction.

In this embodiment, other important indexes of preoperative inspection of the object to be monitored are stored in the storage device in advance, and a user (medical staff) can acquire required information through voice interaction with the voice control device 510 and the information query device 500, so that manual operation of the user is not required, convenience of the user is increased or decreased, and efficiency is improved. In addition, various data such as physiological information of the object to be monitored in the operation process can be stored in the storage device.

In one embodiment, as shown in FIG. 8, the intraoperative monitoring system 10 further includes a monitoring terminal 600. The monitoring terminal 600 is communicatively connected to both the image capture device 110 and the external terminal 200.

The monitoring terminal 600 is in communication connection with the control terminal of the image capturing device 110 and the control terminal of the external terminal 200, and the monitoring terminal 600 is used for monitoring the operation of the image capturing device 110 and the external terminal 200.

In the present embodiment, the image capturing device 110 and the external terminal 200 are monitored in the background by the monitoring terminal 600 to prevent the image capturing device 110 from malfunctioning or the communication between the image capturing device 110 and the external terminal 200 from malfunctioning, so that the applicability of the intraoperative monitoring system can be improved.

In an alternative embodiment, the monitoring terminal 300 is further communicatively connected to each data acquisition device 120, so as to monitor each data acquisition device 120, so as to prevent each data acquisition device 120 from malfunctioning, or communication between each data acquisition device 120 and the external terminal 200 from malfunctioning. In addition, the monitor 300 can also receive the physiological information of the object to be monitored collected by each data collection device 120, analyze and process the received physiological information to obtain an information processing result, and send the information processing result to the external terminal 200.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the utility model and are described in detail herein without thereby limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of the utility model should be assessed as that of the appended claims.

Claims (10)

1. An intraoperative monitoring system, characterized in that the intraoperative monitoring system (10) comprises: the bed comprises a bed body (100), an external terminal (200) and a communication module (300), wherein an image acquisition device (110) is arranged on the bed body (100), and the image acquisition device (110) is in communication connection with the external terminal (200) through the communication module (300);

the image acquisition device (110) is used for shooting an operation process image corresponding to an object to be monitored and sending the operation process image to the external terminal (200);

the external terminal (200) is used for receiving the operation process image and displaying the operation process image;

the intraoperative monitoring system (10) further comprises: an information inquiry apparatus (500) and a voice control device (510);

the output end of the voice control device (510) is connected with the input end of the information inquiry equipment (500), the input end of the voice control device (510) is used for receiving a voice control instruction of a user, and the output end of the voice control device (510) is used for outputting the voice control instruction to the information inquiry equipment (500);

the input end of the information inquiry equipment (500) is used for receiving the voice control instruction and displaying inquiry information corresponding to the voice control instruction.

2. The intraoperative monitoring system of claim 1, wherein the intraoperative monitoring system (10) further comprises a plurality of types of data acquisition devices (120) disposed on the bed (100), each data acquisition device (120) being connected to the communication module (300);

and each data acquisition device (120) is used for acquiring the physiological information of the object to be monitored and transmitting the physiological information to the external terminal (200).

3. The intraoperative monitoring system of claim 2, wherein a mattress is laid on the bed (100), and wherein a plurality of types of the data acquisition devices (120) are integrated in the mattress.

4. The intraoperative monitoring system of claim 2, wherein the physiological information comprises at least one of heart rate, respiratory frequency, electrocardiographic signal, blood oxygen, blood pressure, body temperature, and body position.

5. The intraoperative monitoring system of claim 4, wherein the data acquisition device (120) comprises at least one of a fiber optic sensing unit, a radar, a temperature sensor, and a heart pulse monitoring unit;

the optical fiber sensing unit is used for collecting the respiratory frequency and the heart rate of the object to be monitored;

the radar is used for acquiring the electrocardiosignals and the body positions of the object to be monitored;

the temperature sensor is used for detecting the temperature of the liquid, the body temperature of the object to be monitored is acquired;

the heart pulse monitoring unit is used for collecting the blood oxygen and the blood pressure of the object to be monitored.

6. The intraoperative monitoring system of any one of claims 2-5, wherein the intraoperative monitoring system (10) further comprises:

and the alarm device (400) is connected with each data acquisition device (120) and is used for sending alarm information according to the abnormal physiological information acquired by the data acquisition devices (120).

7. The intraoperative monitoring system according to claim 2, wherein a processor (130) is further arranged on the bed body (100), and an input end of the processor (130) is connected with the image acquisition device (110) and/or each data acquisition device (120) and is used for inputting the surgical procedure image and/or the physiological information;

the output end of the processor (130) is connected with the external terminal (200) through the communication module (300) and is used for outputting image processing results and/or information processing results.

8. The intraoperative monitoring system of claim 7, wherein the external terminal (200) comprises a first terminal (210) and a second terminal (220);

the first terminal (210) is configured to receive and display any one or more of the image processing result and the information processing result;

the second terminal (220) is used for receiving and displaying the operation process image and the physiological information of the object to be monitored.

9. The intraoperative monitoring system of claim 1, wherein the intraoperative monitoring system (10) further comprises a monitoring terminal (600), the monitoring terminal (600) being communicatively connected to both the image acquisition device (110) and the external terminal (200).

10. The intraoperative monitoring system of claim 1, wherein the image acquisition device (110) is a camera.