Medical device linkage methods, devices, equipment and storage media

By communicating with the insufflator and endoscope, the working mode is obtained and the image acquisition status is adjusted, which solves the high cost problem caused by the manual independent control of the endoscope and insufflator, and realizes automatic linkage of equipment and cost reduction.

CN115886899BActive Publication Date: 2026-07-03HANGZHOU HAIKANG HUIYING TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HANGZHOU HAIKANG HUIYING TECH CO LTD
Filing Date
2022-10-21
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Endoscopic equipment and insufflation machines require independent manual control, resulting in high labor costs.

Method used

By communicating with the insufflator and the endoscope, the working mode is obtained and the image acquisition status of the endoscope is adjusted according to the preset correspondence, so as to realize the linkage of the devices.

Benefits of technology

It reduces labor costs, enables automatic linkage between the insufflator and endoscope, and reduces the need for manual adjustments.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application provides a method, apparatus, device, and storage medium for linking medical devices, relating to the field of medical device technology. The specific implementation involves: acquiring the operating mode of the insufflator as a first operating mode; determining the first indicator content corresponding to the first operating mode based on a preset correspondence between various operating modes of the insufflator and various first indicator contents of the endoscope device; wherein different first indicator contents are used to characterize different image acquisition states of the endoscope probe of the endoscope device; and sending a first state control command to the endoscope host based on the first indicator content corresponding to the first operating mode, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe. Therefore, this solution can achieve linking of medical devices, thereby reducing labor costs.
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Description

Technical Field

[0001] This application relates to the field of medical device technology, and in particular to a method, apparatus, device, and storage medium for linking medical devices. Background Technology

[0002] With the widespread adoption of advanced medical equipment, endoscopic devices and insufflators are increasingly used in hospitals at all levels. An endoscope is a medical instrument used to collect images of the body, consisting of an endoscope unit and an endoscope probe. The endoscope probe connects to the endoscope unit to transmit the captured images. An insufflator is an important peripheral auxiliary device for laparoscopic surgery. It establishes and maintains pneumoperitoneum by introducing CO2 airflow into the body, separating the abdominal wall from the abdominal organs, thus providing sufficient field of vision and operating space for laparoscopic surgery.

[0003] In related technologies, both endoscopic equipment and insufflation machines require independent manual control, resulting in high labor costs. Summary of the Invention

[0004] The purpose of this application is to provide a method, apparatus, device, and storage medium for linking medical devices, thereby achieving linkage of medical devices and reducing labor costs. The specific technical solution is as follows:

[0005] In a first aspect, embodiments of the present invention provide a medical device linkage method applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, the method comprising:

[0006] The working mode of the insufflator is obtained as the first working mode;

[0007] Based on the preset correspondence between the various working modes of the insufflator and the various first index contents of the endoscope, the first index contents corresponding to the first working mode are determined; wherein, different first index contents are used to characterize different image acquisition states of the endoscope probe of the endoscope; the image acquisition state characterized by the first index contents corresponding to any working mode of the insufflator is the image acquisition state of the endoscope probe that is adapted when the insufflator is working in that working mode.

[0008] Based on the first indicator content corresponding to the first working mode, a first state control command is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe.

[0009] Optionally, each of the first indicators includes the parameter values ​​of each of the first specified parameters of the endoscope device, wherein the first specified parameter is a parameter used to adjust the image acquisition state of the endoscope probe;

[0010] The step of determining the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscopic device includes:

[0011] Based on the preset correspondence between the various working modes of the pneumoperitoneum machine and the various parameter values ​​of the first specified parameter of the endoscope device, the target parameter value of the first specified parameter corresponding to the first working mode is determined.

[0012] Optionally, the step of sending a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe, includes:

[0013] A first state control command carrying a target parameter value of the first specified parameter is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the first specified parameter of the endoscope device according to the target parameter value of the first specified parameter, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target parameter value of the first specified parameter.

[0014] Optionally, the first specified parameter includes brightness and contrast.

[0015] The endoscope host, in response to the first state control command, adjusts the first specified parameter of the endoscope device according to the target parameter value, including:

[0016] The endoscope host responds to the first state control command and obtains the current parameter value of each first specified parameter of the endoscope device;

[0017] For each first specified parameter of the endoscope device, if the target parameter value of the first specified parameter is greater than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is increased by a preset step size until the parameter value of the first specified parameter increases to the target parameter value of the first specified parameter, and then the adjustment stops.

[0018] If the target parameter value of the first specified parameter is less than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is reduced by a preset step size until the parameter value of the first specified parameter is reduced to the target parameter value, and then the adjustment stops.

[0019] Optionally, each of the first indicators includes each working mode of the endoscope device; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device;

[0020] The step of determining the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscopic device includes:

[0021] Based on the preset correspondence between the various working modes of the insufflator and the various working modes of the endoscope, the target working mode corresponding to the first working mode is determined.

[0022] Optionally, the step of sending a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe, includes:

[0023] A first state control command carrying the target working mode is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the working mode of the endoscope device according to the target working mode, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target working mode.

[0024] Optionally, acquiring the operating mode of the pneumoperitoneum machine as a first operating mode includes:

[0025] The working mode of the pneumoperitoneum machine is periodically acquired as the first working mode;

[0026] The method further includes:

[0027] The working mode of the endoscope device is periodically acquired as a second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0028] Based on the preset correspondence between the various working modes of the endoscope and the various second index contents of the insufflator, the second index contents corresponding to the second working mode are determined; wherein, different second index contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second index contents corresponding to any working mode of the endoscope is the airflow state that the insufflator is adapted to when the endoscope works in that working mode.

[0029] Based on the second indicator content corresponding to the second working mode, a second state control command is sent to the insufflator so that the insufflator responds to the second state control command and adjusts the airflow state of the insufflator.

[0030] Optionally, each of the second indicators of the pneumoperitoneum machine includes the parameter values ​​of each of the second specified parameters of the pneumoperitoneum machine, or each of the working modes of the pneumoperitoneum machine.

[0031] The second specified parameter is a parameter used to adjust the airflow state of the pneumoperitoneum machine; the airflow state is different in different working modes of the pneumoperitoneum machine.

[0032] Secondly, embodiments of the present invention provide another method for linking medical devices, applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, the method comprising:

[0033] The working mode of the endoscope device is obtained as a second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes;

[0034] Based on the preset correspondence between the various working modes of the endoscope and the various second index contents of the insufflator, the second index contents corresponding to the second working mode are determined; wherein, different second index contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second index contents corresponding to any working mode of the endoscope is the airflow state that the insufflator is adapted to when the endoscope works in that working mode.

[0035] Based on the second indicator content corresponding to the second working mode, a second state control command is sent to the insufflator so that the insufflator responds to the second state control command and adjusts the airflow state of the insufflator.

[0036] Thirdly, embodiments of the present invention provide a medical device linkage device applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, and the device includes:

[0037] The first acquisition module is used to acquire the working mode of the pneumoperitoneum machine as the first working mode.

[0038] The first determining module is used to determine the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscope device; wherein, different first indicator contents are used to characterize different image acquisition states of the endoscope probe of the endoscope device, and the image acquisition state characterized by the first indicator content corresponding to any working mode is the image acquisition state of the endoscope probe that is adapted when the insufflator is working in that working mode.

[0039] The first adjustment module is used to send a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host adjusts the image acquisition state of the endoscope probe in response to the first state control command.

[0040] Optionally, each of the first indicators includes the parameter values ​​of each of the first specified parameters of the endoscope device, wherein the first specified parameter is a parameter used to adjust the image acquisition state of the endoscope probe;

[0041] The first determining module is specifically used for:

[0042] Based on the preset correspondence between the various working modes of the pneumoperitoneum machine and the various parameter values ​​of the first specified parameter of the endoscope device, the target parameter value of the first specified parameter corresponding to the first working mode is determined.

[0043] Optionally, the first adjustment module is specifically used for:

[0044] A first state control command carrying a target parameter value of the first specified parameter is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the first specified parameter of the endoscope device according to the target parameter value of the first specified parameter, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target parameter value of the first specified parameter.

[0045] Optionally, the first specified parameter includes brightness and contrast.

[0046] The endoscope host, in response to the first state control command, adjusts the first specified parameter of the endoscope device according to the target parameter value, including:

[0047] The endoscope host responds to the first state control command and obtains the current parameter value of each first specified parameter of the endoscope device;

[0048] For each first specified parameter of the endoscope device, if the target parameter value of the first specified parameter is greater than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is increased by a preset step size until the parameter value of the first specified parameter increases to the target parameter value of the first specified parameter, and then the adjustment stops.

[0049] If the target parameter value of the first specified parameter is less than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is reduced by a preset step size until the parameter value of the first specified parameter is reduced to the target parameter value, and then the adjustment stops.

[0050] Optionally, each of the first indicators includes each working mode of the endoscope device; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device;

[0051] The first determining module is specifically used for:

[0052] Based on the preset correspondence between the various working modes of the insufflator and the various working modes of the endoscope, the target working mode corresponding to the first working mode is determined.

[0053] Optionally, the first adjustment module is specifically used for:

[0054] A first state control command carrying the target working mode is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the working mode of the endoscope device according to the target working mode, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target working mode.

[0055] Optionally, the first acquisition module is specifically used for:

[0056] The working mode of the pneumoperitoneum machine is periodically acquired as the first working mode;

[0057] The device further includes:

[0058] A periodic acquisition module is used to periodically acquire the working mode of the endoscope device as a second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0059] The second indicator content determination module is used to determine the second indicator content corresponding to the second working mode based on the preset correspondence between the various working modes of the endoscope device and the various second indicator contents of the insufflator; wherein, different second indicator contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second indicator content corresponding to any working mode of the endoscope device is the airflow state that the insufflator is adapted to when the endoscope device is working in that working mode.

[0060] The pneumoperitoneum machine adjustment module is used to send a second state control command to the pneumoperitoneum machine based on the second indicator content corresponding to the second working mode, so that the pneumoperitoneum machine responds to the second state control command and adjusts the airflow state of the pneumoperitoneum machine.

[0061] Fourthly, embodiments of the present invention provide another medical device linkage device applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, and the device includes:

[0062] The second acquisition module is used to acquire the working mode of the endoscope device as the second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0063] The second determining module is used to determine the second indicator content corresponding to the second working mode based on the preset correspondence between the various working modes of the endoscope device and the various second indicator contents of the insufflator; wherein, different second indicator contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second indicator content corresponding to any working mode of the endoscope device is the airflow state that the insufflator is adapted to when the endoscope device is working in that working mode.

[0064] The second adjustment module is used to send a second state control command to the pneumoperitoneum machine based on the second indicator content corresponding to the second working mode, so that the pneumoperitoneum machine responds to the second state control command and adjusts the airflow state of the pneumoperitoneum machine.

[0065] Fifthly, embodiments of the present invention provide an electronic device, including a processor, a communication interface, a memory, and a communication bus, wherein the processor, the communication interface, and the memory communicate with each other through the communication bus;

[0066] Memory, used to store computer programs;

[0067] When a processor executes a program stored in memory, it implements the steps of any of the above-described medical device linkage methods.

[0068] Sixthly, embodiments of the present invention provide a computer-readable storage medium storing a computer program, which, when executed by a processor, implements the steps of any of the above-described medical device linkage methods.

[0069] Beneficial effects of the embodiments in this application:

[0070] The solution provided in this application first obtains the working mode of the insufflator as the first working mode. Then, based on a preset correspondence between various working modes of the insufflator and various first indicator contents of the endoscopic device, the first indicator content corresponding to the first working mode is determined. Next, based on the first indicator content corresponding to the first working mode, a first state control command is sent to the endoscopic host, causing the endoscopic host to adjust the image acquisition state of the endoscopic probe in response to the first state control command. Since the image acquisition state represented by the first indicator content corresponding to the first working mode is the image acquisition state adapted to the endoscopic probe when the insufflator is working in that first working mode, adjusting the image acquisition state of the endoscopic probe based on the first indicator content corresponding to the first working mode allows the image acquisition state of the endoscopic probe of the endoscopic device to be adapted to the first working mode, thereby achieving linkage between the insufflator and the endoscopic device. Therefore, this solution can achieve linkage of medical devices to reduce labor costs.

[0071] Of course, implementing any product or method of this application does not necessarily require achieving all of the advantages described above at the same time. Attached Figure Description

[0072] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other embodiments can be obtained based on these drawings.

[0073] Figure 1 A flowchart of a medical device linkage method provided in an embodiment of the present invention;

[0074] Figure 2 This is another flowchart of the medical device linkage method provided in the embodiment of the present invention;

[0075] Figure 3 A flowchart of another medical device linkage method provided in an embodiment of the present invention;

[0076] Figure 4 An interactive interface diagram provided in an embodiment of the present invention;

[0077] Figure 5 This is a schematic diagram of the structure of a medical device linkage device provided in an embodiment of the present invention;

[0078] Figure 6 This is a schematic diagram of another medical device linkage device provided in an embodiment of the present invention;

[0079] Figure 7 This is a block diagram of an electronic device provided in an embodiment of the present invention. Detailed Implementation

[0080] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art based on this application are within the scope of protection of this application.

[0081] With the widespread use of advanced medical equipment, endoscopic devices and insufflators are increasingly being used in hospitals at all levels. Both endoscopic devices and insufflators require independent manual control, resulting in high labor costs. For example, during surgery, the parameters or operating modes of the endoscopic devices and insufflators often need to be manually adjusted, further contributing to the high labor costs.

[0082] Based on the above, in order to achieve linkage of medical devices and reduce labor costs, embodiments of the present invention provide a method, apparatus, device, and storage medium for linkage of medical devices.

[0083] Below, we will first introduce a medical device linkage method provided by an embodiment of the present invention.

[0084] This invention provides a medical device linkage method applied to an insufflator, which communicates with the endoscopic host of an endoscopic device. In specific applications, the insufflator and the endoscopic host can communicate via a designated serial port; wherein, the designated serial port is a communication port with a pre-established data transmission connection. For example, the designated serial port can be a COM (cluster communication port), such as an RS232 interface or an RS485 interface, conforming to MODBUS (a serial communication protocol).

[0085] Specifically, the executing entity of this medical device linkage method can be a medical device linkage device. For example, when this medical device linkage method is applied to an insufflator, the medical device linkage device can be a computer program running in the insufflator, which can be used to realize the linkage adjustment between the insufflator and the endoscope.

[0086] The medical device linkage method provided in this embodiment of the invention may include the following steps:

[0087] The working mode of the insufflator is obtained as the first working mode;

[0088] Based on the preset correspondence between the various working modes of the insufflator and the various first index contents of the endoscope, the first index contents corresponding to the first working mode are determined; wherein, different first index contents are used to characterize different image acquisition states of the endoscope probe of the endoscope; the image acquisition state characterized by the first index contents corresponding to any working mode of the insufflator is the image acquisition state of the endoscope probe that is adapted when the insufflator is working in that working mode.

[0089] Based on the first indicator content corresponding to the first working mode, a first state control command is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe.

[0090] The solution provided in this embodiment of the invention first obtains the working mode of the insufflator as the first working mode; then, based on the preset correspondence between various working modes of the insufflator and various first indicator contents of the endoscope device, it determines the first indicator content corresponding to the first working mode; then, based on the first indicator content corresponding to the first working mode, it sends a first state control command to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe. Since the image acquisition state represented by the first indicator content corresponding to the first working mode is the image acquisition state adapted to the endoscope probe when the insufflator is working in the first working mode, adjusting the image acquisition state of the endoscope probe based on the first indicator content corresponding to the first working mode can make the image acquisition state of the endoscope probe of the endoscope device adapted to the first working mode, thereby realizing the linkage between the insufflator and the endoscope device. It can be seen that this solution can realize the linkage of medical devices, thereby reducing labor costs.

[0091] The medical device linkage method provided by the embodiments of the present invention will be described below with reference to the accompanying drawings.

[0092] like Figure 1 As shown, the medical device linkage method provided in this embodiment of the invention is applied to an insufflator, which communicates with the endoscopic host of an endoscopic device. The method may include steps S101-S103:

[0093] S101, Obtain the working mode of the insufflator and set it as the first working mode;

[0094] It is understandable that, in order to achieve the linkage between the insufflator and the endoscope device, the working mode of the insufflator can be obtained first as the first working mode, so that the subsequent endoscope device can adjust its own working state according to the working mode of the insufflator, thereby achieving the linkage between the insufflator and the endoscope device. Exemplarily, the working mode of the insufflator may include an adult mode, a pediatric mode, an obesity mode, a user-defined mode, etc. The airflow states of the insufflator in different working modes are different, that is, the pressure value and the flow value of the insufflator are different. In practical applications, the insufflator can work according to the working mode set by the user, and each working mode of the insufflator has parameter values such as a preset output pressure threshold, a pressure initial value, a flow initial value, etc.

[0095] It should be noted that, in practical applications, a linkage switch can be set on the interaction interface of the insufflator to start the medical device linkage method when the linkage switch is turned on. At this time, obtaining the working mode of the insufflator can be obtaining the current working mode of the insufflator when the linkage switch is turned on, or periodically obtaining the working mode of the insufflator, etc. Exemplarily, if the current working mode of the insufflator is the adult mode when the linkage switch is turned on, then the adult mode is the first working mode.

[0096] S102. Determine the first index content corresponding to the first working mode according to the preset corresponding relationship between each working mode of the insufflator and each first index content of the endoscope device; wherein, different first index contents are used to represent different image acquisition states of the endoscope probe of the endoscope device, and the image acquisition state represented by the first index content corresponding to any working mode of the insufflator is the image acquisition state adapted to the endoscope probe when the insufflator works in this working mode.

[0097] In this embodiment, there is a preset corresponding relationship between each working mode of the insufflator and each first index content of the endoscope device. The preset corresponding relationship can be set by relevant technicians according to experience, and the present invention embodiment does not limit this corresponding relationship. It is understandable that, after obtaining the first working mode through step S101, in order to achieve the linkage between the insufflator and the endoscope device, the first index content corresponding to the first working mode can be determined according to the preset corresponding relationship between each working mode of the insufflator and each first index content of the endoscope device, so that the subsequent endoscope device can adjust its own working state according to the first index content, that is, adjust the image acquisition state of the endoscope probe of the endoscope device, so that the image acquisition state of the endoscope probe of the endoscope device can be adapted to the first working mode.

[0098] Optionally, in one implementation, each first indicator includes the parameter values ​​of the first specified parameter of the endoscope device, or the various operating modes of the endoscope device.

[0099] The first specified parameter is a parameter used to adjust the image acquisition state of the endoscope probe; the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0100] It is understood that, since the first specified parameter is a parameter used to adjust the image acquisition state of the endoscope probe, and the image acquisition state of the endoscope probe is different in different working modes of the endoscope device, the contents of each first indicator may include the parameter values ​​of the first specified parameter of the endoscope device, or the various working modes of the endoscope device.

[0101] For example, the first specified parameter may include parameters such as brightness, contrast, and saturation. Different values ​​of the first specified parameter result in different image acquisition states of the endoscopic probe. The various working modes of the endoscopic device may include laparoscopic mode, ventriculoscopy mode, hysteroscopy mode, user-defined mode, etc., and the endoscopic device has different image acquisition states corresponding to different working modes.

[0102] S103, based on the first indicator content corresponding to the first working mode, a first state control command is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe.

[0103] It is understandable that, since the image acquisition state represented by the first indicator content corresponding to the first working mode is the image acquisition state that the endoscope probe is adapted to when the insufflator is working in the first working mode, after determining the first indicator content corresponding to the first working mode through step S102, the working state of the endoscope device can be adjusted based on the first indicator content corresponding to the first working mode, so that the image acquisition state of the endoscope probe of the endoscope device can be adapted to the first working mode.

[0104] In this embodiment, since the insufflator and the endoscope communicate with each other, the insufflator can send a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode. This first state control command may carry the first indicator content, allowing the endoscope host to automatically adjust the image acquisition state of the endoscope probe according to the first indicator content, eliminating the need for manual adjustment. This achieves linkage between the insufflator and the endoscope, reducing labor costs. For example, if the first working mode is an adult mode and the first indicator content corresponding to this mode is user mode A, the insufflator sends a first state control command carrying user mode A to the endoscope host. This causes the endoscope host to adjust the working mode of the endoscope to user mode A, adjusting the image acquisition state of the endoscope probe to match the first working mode.

[0105] The solution provided in this embodiment of the invention first obtains the working mode of the insufflator as the first working mode; then, based on the preset correspondence between various working modes of the insufflator and various first indicator contents of the endoscope device, it determines the first indicator content corresponding to the first working mode; then, based on the first indicator content corresponding to the first working mode, it sends a first state control command to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe. Since the image acquisition state represented by the first indicator content corresponding to the first working mode is the image acquisition state adapted to the endoscope probe when the insufflator is working in the first working mode, adjusting the image acquisition state of the endoscope probe based on the first indicator content corresponding to the first working mode can make the image acquisition state of the endoscope probe of the endoscope device adapted to the first working mode, thereby realizing the linkage between the insufflator and the endoscope device. It can be seen that this solution can realize the linkage of medical devices, thereby reducing labor costs.

[0106] Optionally, in another embodiment of the present invention, the step S102 above, which determines the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscopic device, may include:

[0107] If each of the first indicators includes the parameter values ​​of the first specified parameter of the endoscope, then the target parameter value of the first specified parameter corresponding to the first working mode is determined according to the preset correspondence between the various working modes of the insufflator and the parameter values ​​of the first specified parameter of the endoscope.

[0108] It is understandable that if each of the first indicators includes the parameter values ​​of the first specified parameter of the endoscope, then the correspondence between each working mode of the insufflator and each of the first indicators of the endoscope is the correspondence between each working mode of the insufflator and each parameter value of the first specified parameter of the endoscope. In this case, the target parameter value of the first specified parameter corresponding to the first working mode can be determined according to the preset correspondence between each working mode of the insufflator and each parameter value of the first specified parameter of the endoscope.

[0109] For example, if the first specified parameter is brightness, that is, each of the first indicators includes each brightness value, then the target brightness value corresponding to the first working mode can be determined according to the preset correspondence between each working mode of the insufflator and each brightness value of the endoscope.

[0110] Accordingly, in this embodiment, step S103 above, which sends a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host adjusts the image acquisition state of the endoscope probe in response to the first state control command, may include:

[0111] A first state control command carrying the target parameter value of the first specified parameter is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the first specified parameter of the endoscope device according to the target parameter value of the first specified parameter, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target parameter value of the first specified parameter.

[0112] It is understood that if each of the first indicators includes the parameter values ​​of the first specified parameter of the endoscope device, then after determining the target parameter value of the first specified parameter corresponding to the first working mode, a first state adjustment command carrying the target parameter value of the first specified parameter can be sent to the endoscope host. For example, the first state adjustment command may be an instruction to control the increase or decrease of the parameter value of the first specified parameter, so that the endoscope host, in response to the first state adjustment command, increases or decreases the parameter value of the first specified parameter of the endoscope device according to the target parameter value of the first specified parameter, until the target parameter value of the first specified parameter is reached, thereby adjusting the image acquisition state of the endoscope probe to the image acquisition state represented by the target parameter value of the first specified parameter.

[0113] Alternatively, in one implementation, the first specified parameter includes brightness and contrast.

[0114] The endoscope host, in response to the first state control command, adjusts the first specified parameter of the endoscope device according to the target parameter value, which may include steps A1-A3:

[0115] A1, the endoscope host responds to the first state control command and obtains the current parameter value of each first specified parameter of the endoscope device;

[0116] In this implementation, the first specified parameters include brightness and contrast. In response to the first state control command, the endoscope host first obtains the current parameter value of each first specified parameter of the endoscope device, that is, obtains the current brightness value and contrast value of the endoscope device, so that the brightness value and contrast value of the endoscope device can be adjusted according to the relationship between the current parameter value and the target parameter value.

[0117] A2, for each first specified parameter of the endoscope device, if the target parameter value of the first specified parameter is greater than the current parameter value of the first specified parameter, then the parameter value of the first specified parameter is increased by a preset step size until the parameter value of the first specified parameter increases to the target parameter value of the first specified parameter, and then the adjustment stops;

[0118] A3. If the target parameter value of the first specified parameter is less than the current parameter value of the first specified parameter, then the parameter value of the first specified parameter is reduced by a preset step size until the parameter value of the first specified parameter is reduced to the target parameter value of the first specified parameter, and then the adjustment stops.

[0119] In this implementation, the preset step size can be set by the operator, for example, it can be 1, 5, 10, etc., and this embodiment of the invention is not limited to this. For example, if the target parameter value of the first specified parameter is a brightness value of 20 and a contrast value of 10, the preset step size is 1, and the current parameter value of the first specified parameter of the endoscope device is a brightness value of 10 and a contrast value of 5, then the brightness value and contrast value can be increased according to the preset step size until the brightness value increases to 20 and the contrast value increases to 10, at which point the adjustment stops.

[0120] As can be seen, through this solution, the parameter value of the first specified parameter of the endoscope can be adjusted according to the target parameter value of the first specified parameter corresponding to the determined first working mode, so that the parameter value of the first specified parameter of the endoscope matches the first working mode of the insufflator, thereby realizing the linkage between the insufflator and the endoscope.

[0121] Optionally, in another embodiment of the present invention, the step S102 above, which determines the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscopic device, may include:

[0122] If the contents of each first indicator include each working mode of the endoscope, then the target working mode corresponding to the first working mode is determined according to the preset correspondence between each working mode of the insufflator and each working mode of the endoscope.

[0123] It is understandable that if each of the first indicators includes each working mode of the endoscope, then the correspondence between each working mode of the insufflator and each of the first indicators of the endoscope is the correspondence between each working mode of the insufflator and each working mode of the endoscope. In this case, the target working mode corresponding to the first working mode can be determined according to the preset correspondence between each working mode of the insufflator and each working mode of the endoscope.

[0124] For example, if the working modes of the insufflator include mode A1, mode A2 and mode A3, and the working modes of the endoscope include mode B1, mode B2 and mode B3, the preset correspondence is: mode A1 corresponds to mode B1, mode A2 corresponds to mode B2, and mode A3 corresponds to mode B3. In this case, if the first working mode is mode A1, then the target working mode of the endoscope is mode B1.

[0125] Accordingly, in this embodiment, step S103 above, which sends a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host adjusts the image acquisition state of the endoscope probe in response to the first state control command, may include:

[0126] A first state control command carrying the target working mode is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the working mode of the endoscope device according to the target working mode, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target working mode.

[0127] It is understandable that if each of the first indicators includes each working mode of the endoscope device, then after determining the target working mode corresponding to the first working mode, a first state control instruction carrying the target working mode can be sent to the endoscope host. The first control instruction is used to instruct the endoscope host to adjust the current working mode of the endoscope device to the target working mode, thereby adjusting the image acquisition state of the endoscope probe to the image acquisition state represented by the target working mode.

[0128] As can be seen, this solution allows for the adjustment of the endoscope's operating mode according to the target operating mode corresponding to the determined first operating mode, so that the operating mode of the endoscope matches the operating mode of the insufflator, thereby achieving linkage between the insufflator and the endoscope.

[0129] Optionally, in another embodiment of the present invention, obtaining the working mode of the insufflator in step S101 above, as the first working mode, may include:

[0130] The operating mode of the insufflator is periodically acquired and used as the first operating mode;

[0131] It is understandable that by periodically acquiring the operating mode of the insufflator and using it as the first operating mode, the endoscopic device can promptly adjust its operating status according to the acquired operating mode when the insufflator's operating mode changes. It should be noted that the period for acquiring the insufflator's operating mode can be set by the operator according to needs, and this embodiment of the invention does not limit this.

[0132] Accordingly, in this embodiment, in Figure 1 Based on the illustrated embodiments, as Figure 2 As shown, the method may further include steps S201-S203:

[0133] S201, Periodically acquire the working mode of the endoscope device as the second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0134] In this embodiment, the cycle for acquiring the working mode of the endoscope can be the same as or different from the cycle for acquiring the working mode of the insufflator; both are reasonable. Based on the above-mentioned adjustment of the endoscope's working state using the acquired working mode of the insufflator, this embodiment can also acquire the endoscope's working mode as a second working mode, so that the insufflator can subsequently adjust its own working state according to the endoscope's working mode, achieving bidirectional linkage between the insufflator and the endoscope. Furthermore, the image acquisition state of the endoscope probe differs in different working modes, meaning the brightness, contrast, and other parameter values ​​of the endoscope probe differ. In practical applications, the endoscope can operate according to the working mode set by the user, and each working mode of the endoscope has preset brightness, contrast, saturation, and other parameter values.

[0135] S202, based on the preset correspondence between the various working modes of the endoscope and the various second index contents of the insufflator, determine the second index contents corresponding to the second working mode; wherein, different second index contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second index contents corresponding to any working mode of the endoscope is the airflow state that the insufflator is adapted to when the endoscope works in that working mode.

[0136] In this embodiment, there is a preset correspondence between the various working modes of the endoscope and the various second indicator contents of the insufflator. This preset correspondence can be set by relevant technical personnel based on experience, and this embodiment of the invention does not limit this correspondence. It is understood that after obtaining the second working mode through step S201, in order to achieve linkage between the endoscope and the insufflator, the second indicator contents corresponding to the second working mode can be determined based on the preset correspondence between the various working modes of the endoscope and the various second indicator contents of the insufflator. This allows the insufflator to subsequently adjust its working state according to the second indicator contents, that is, adjust the airflow state of the insufflator so that the airflow state of the insufflator can be adapted to the second working mode.

[0137] Optionally, in one implementation, each of the second indicators of the insufflator includes the parameter values ​​of each of the second specified parameters of the insufflator, or the various operating modes of the insufflator.

[0138] The second specified parameter is a parameter used to adjust the airflow state of the pneumoperitoneum machine; the airflow state is different in different working modes of the pneumoperitoneum machine.

[0139] It is understood that, since the second specified parameter is a parameter used to adjust the airflow state of the insufflator, and the airflow state is different in different working modes of the insufflator, the contents of each second indicator may include the parameter values ​​of the second specified parameter of the insufflator, or the various working modes of the insufflator.

[0140] For example, the second specified parameter may include parameters such as pressure and flow rate. Different values ​​of the second specified parameter result in different airflow states of the insufflator. The various working modes of the insufflator may include adult mode, pediatric mode, obesity mode, user-defined mode, etc., and the insufflator has different airflow states corresponding to different working modes.

[0141] S203, based on the second indicator content corresponding to the second working mode, a second state control command is sent to the insufflator so that the insufflator responds to the second state control command and adjusts the airflow state of the insufflator.

[0142] It is understandable that, since the airflow state represented by the second indicator content corresponding to the second working mode is the airflow state that the insufflator is adapted to when the endoscope is working in the second working mode, after determining the second indicator content corresponding to the second working mode through step S202, the airflow state of the insufflator can be adjusted based on the second indicator content corresponding to the second working mode so that the airflow state of the insufflator can be adapted to the second working mode.

[0143] In this embodiment, a second state control command can be sent to the insufflator. The second state control command can carry the second indicator content, so that the insufflator responds to the second state control command and automatically adjusts the airflow state of the insufflator according to the second indicator content, without the need for manual adjustment. This realizes bidirectional linkage between the insufflator and the endoscope, reducing labor costs.

[0144] For example, if the contents of each of the second indicators include the parameter values ​​of each of the second specified parameters of the insufflator, then according to the preset correspondence between each working mode of the endoscope and the parameter values ​​of each of the second specified parameters of the insufflator, a target parameter value of the second specified parameter corresponding to the second working mode is determined. After determining the target parameter value, a second state control command carrying the target parameter value of the second specified parameter is sent to the insufflator, so that the insufflator responds to the second state control command and adjusts the second specified parameter of the insufflator according to the target parameter value of the second specified parameter, thereby adjusting the airflow state of the insufflator to the airflow state represented by the target parameter value of the second specified parameter.

[0145] For example, if the various second indicators include various operating modes of the insufflator, then a target operating mode corresponding to the second operating mode is determined based on a preset correspondence between the various operating modes of the endoscope and the various operating modes of the insufflator. After determining the target operating mode, a second state control command carrying the target operating mode is sent to the insufflator, so that the insufflator responds to the second state control command and adjusts its operating mode to the target operating mode, thereby adjusting the airflow state of the insufflator to the airflow state represented by the target operating mode.

[0146] As can be seen, this solution, based on the above-mentioned adjustment of the working state of the endoscope by the obtained working mode of the insufflator, can also adjust the working state of the insufflator by the obtained working mode of the endoscope, thereby realizing the two-way linkage between the insufflator and the endoscope, and further reducing labor costs.

[0147] Corresponding to the above embodiments of the medical device linkage method, this embodiment of the invention also provides another medical device linkage method, applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, such as... Figure 3 As shown, the method may include steps S301-S303:

[0148] S301, Obtain the working mode of the endoscope device as the second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0149] For example, in practical applications, the interface of the insufflator can be equipped with a linkage switch to activate the medical device linkage method when the linkage switch is turned on. In this case, obtaining the operating mode of the endoscope can be done by acquiring the current operating mode of the endoscope when the linkage switch is turned on, or by periodically acquiring the operating mode of the endoscope, and so on. For example, if the current operating mode of the endoscope is laparoscopic mode when the linkage switch is turned on, then the laparoscopic mode is the second operating mode.

[0150] S302, based on the preset correspondence between the various working modes of the endoscope and the various second index contents of the insufflator, determine the second index contents corresponding to the second working mode; wherein, different second index contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second index contents corresponding to any working mode of the endoscope is the airflow state that the insufflator is adapted to when the endoscope works in that working mode.

[0151] S303, based on the second indicator content corresponding to the second working mode, a second state control command is sent to the insufflator so that the insufflator responds to the second state control command and adjusts the airflow state of the insufflator.

[0152] It should be noted that the contents of steps S302 and S303 are the same as those of steps S202 and S203 above, and will not be repeated here.

[0153] As can be seen, by adjusting the airflow state of the insufflator based on the second indicator content corresponding to the second working mode, this solution can make the airflow state of the insufflator match the second working mode, thereby realizing the linkage between the endoscope and the insufflator and reducing labor costs.

[0154] To better understand the content of the embodiments of the present invention, a specific example is described below.

[0155] Currently, both the endoscope host and the insufflator are manually controlled independently, resulting in high labor costs. To achieve intelligent linkage and adjustment between the endoscope and the insufflator, this example first connects the serial communication ports of the insufflator and the endoscope, enabling the endoscope host to communicate with the insufflator. Subsequently, by periodically acquiring the operating modes of the insufflator and the endoscope, both devices can adjust their operating states according to each other's modes, thus achieving intelligent linkage and adjustment between them.

[0156] Among them, the linkage algorithm that enables intelligent linkage adjustment between endoscopic equipment and insufflator (corresponding to the medical equipment linkage method mentioned above) is applied to insufflator. Figure 4 The interactive interface provided by the insufflator for user operation is demonstrated. This interface includes buttons for starting or stopping the linkage algorithm. In practical applications, a single click of this button activates the linkage algorithm, enabling intelligent linkage and adjustment between the endoscopic equipment and the insufflator.

[0157] In this example, the intelligent linkage adjustment between the endoscope and the insufflator includes adjusting the working state of the endoscope according to the working mode of the insufflator, and adjusting the working state of the insufflator according to the working mode of the endoscope.

[0158] (a) The procedure for adjusting the working status of the endoscope according to the working mode of the insufflator is as follows:

[0159] (1) Obtain the working mode of the pneumoperitoneum machine as the first working mode;

[0160] Each working mode of the pneumoperitoneum machine has preset parameter values ​​such as output pressure threshold, initial pressure value, pressure safety limit, control flow threshold, initial flow value, flow level, and flow safety threshold.

[0161] (2) Based on the correspondence between the preset working modes of the pneumoperitoneum machine and the brightness values ​​of the endoscope device (corresponding to the parameter values ​​of the first specified parameter mentioned above), determine the target brightness value corresponding to the first working mode.

[0162] (3) Send a first state control command carrying the target brightness value to the endoscope host so that the endoscope host responds to the first state control command to increase or decrease the current brightness value of the endoscope device until the target brightness value is reached and the adjustment ends.

[0163] The various operating modes of the insufflator and the first state control commands received by the endoscopic host are shown in Table 1 below:

[0164]

[0165] Table 1

[0166] In practical applications, users can select the working mode of the insufflator, and the brightness value of the endoscope changes according to the working mode. For example, if the adult mode is selected, the brightness of the endoscope remains at the default value of 20. If the working mode of the insufflator changes to the obesity mode, the brightness value of the endoscope will increase; if the working mode of the insufflator changes to the pediatric mode, the brightness value of the endoscope will decrease.

[0167] (II) The procedure for adjusting the working status of the insufflator according to the working mode of the endoscope equipment is as follows:

[0168] (1) Obtain the working mode of the endoscope device as the second working mode;

[0169] Each working mode of the endoscope equipment corresponds to preset parameter values ​​such as brightness, contrast, gain, saturation, and sharpness.

[0170] (2) Based on the pre-defined correspondence between the various working modes of the endoscope device and the various parameter values ​​of the insufflator (corresponding to the various parameter values ​​of the second specified parameter mentioned above), determine the target parameter value corresponding to the second working mode; wherein, the various parameters of the insufflator are pressure, flow rate and pressure relief method.

[0171] (3) Send a second state control command carrying the target parameter value to the insufflator so that the insufflator responds to the second state control command and controls the operation of the insufflator.

[0172] The various operating modes of the endoscope and the second-state control commands received by the insufflator are shown in Table 2 below:

[0173]

[0174] Table 2

[0175] In practical applications, users can select the operating mode of the endoscope equipment, and the various parameter values ​​of the insufflator change according to the operating mode. For example, if the standard mode is selected, the parameters of the insufflator remain at their default values, i.e., the pressure is controlled at 10 mmHg, the flow rate is controlled at 15 L / min, and the pressure relief method is manual. If the operating mode of the insufflator is changed to laparoscopic mode, the pressure and flow rate of the insufflator will increase, and the pressure relief method will change to automatic. If the operating mode of the insufflator is changed to ventriculoscopy mode, the pressure and flow rate of the insufflator will decrease, and the pressure relief method will change to automatic.

[0176] Additionally, it should be noted that the insufflator and the endoscope host communicate using the MOBDBUS communication protocol. The protocol signals for each parameter in this communication protocol can be set as shown in Table 3 below:

[0177]

[0178]

[0179] Table 3

[0180] As can be seen, this solution enables intelligent linkage between the endoscope host and the insufflator to control the pressure, flow rate, and depressurization method of the insufflator; it also enables intelligent linkage between the insufflator and the endoscope host to control the brightness of the endoscope; furthermore, it achieves bidirectional linkage, reducing manual operation costs.

[0181] Corresponding to the above embodiments of the medical device linkage method, this embodiment of the invention also provides a medical device linkage device applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, such as... Figure 5 As shown, the device includes:

[0182] The first acquisition module 510 is used to acquire the working mode of the pneumoperitoneum machine as the first working mode.

[0183] The first determining module 520 is used to determine the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscope device; wherein, different first indicator contents are used to characterize different image acquisition states of the endoscope probe of the endoscope device, and the image acquisition state characterized by the first indicator content corresponding to any working mode is the image acquisition state of the endoscope probe when the insufflator is working in that working mode.

[0184] The first adjustment module 530 is used to send a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host adjusts the image acquisition state of the endoscope probe in response to the first state control command.

[0185] Optionally, each of the first indicators includes the parameter values ​​of each of the first specified parameters of the endoscope device, wherein the first specified parameter is a parameter used to adjust the image acquisition state of the endoscope probe;

[0186] The first determining module is specifically used for:

[0187] Based on the preset correspondence between the various working modes of the pneumoperitoneum machine and the various parameter values ​​of the first specified parameter of the endoscope device, the target parameter value of the first specified parameter corresponding to the first working mode is determined.

[0188] Optionally, the first adjustment module is specifically used for:

[0189] A first state control command carrying a target parameter value of the first specified parameter is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the first specified parameter of the endoscope device according to the target parameter value of the first specified parameter, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target parameter value of the first specified parameter.

[0190] Optionally, the first specified parameter includes brightness and contrast.

[0191] The endoscope host, in response to the first state control command, adjusts the first specified parameter of the endoscope device according to the target parameter value, including:

[0192] The endoscope host responds to the first state control command and obtains the current parameter value of each first specified parameter of the endoscope device;

[0193] For each first specified parameter of the endoscope device, if the target parameter value of the first specified parameter is greater than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is increased by a preset step size until the parameter value of the first specified parameter increases to the target parameter value of the first specified parameter, and then the adjustment stops.

[0194] If the target parameter value of the first specified parameter is less than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is reduced by a preset step size until the parameter value of the first specified parameter is reduced to the target parameter value, and then the adjustment stops.

[0195] Optionally, each of the first indicators includes each working mode of the endoscope device; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device;

[0196] The first determining module is specifically used for:

[0197] Based on the preset correspondence between the various working modes of the insufflator and the various working modes of the endoscope, the target working mode corresponding to the first working mode is determined.

[0198] Optionally, the first adjustment module is further configured to:

[0199] A first state control command carrying the target working mode is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the working mode of the endoscope device according to the target working mode, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target working mode.

[0200] Optionally, the first acquisition module is specifically used for:

[0201] The working mode of the pneumoperitoneum machine is periodically acquired as the first working mode;

[0202] The device further includes:

[0203] A periodic acquisition module is used to periodically acquire the working mode of the endoscope device as a second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0204] The second indicator content determination module is used to determine the second indicator content corresponding to the second working mode based on the preset correspondence between the various working modes of the endoscope device and the various second indicator contents of the insufflator; wherein, different second indicator contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second indicator content corresponding to any working mode of the endoscope device is the airflow state that the insufflator is adapted to when the endoscope device is working in that working mode.

[0205] The pneumoperitoneum machine adjustment module is used to send a second state control command to the pneumoperitoneum machine based on the second indicator content corresponding to the second working mode, so that the pneumoperitoneum machine responds to the second state control command and adjusts the airflow state of the pneumoperitoneum machine.

[0206] Corresponding to the above-described other medical device linkage method embodiment, this embodiment of the invention also provides a medical device linkage device applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, such as... Figure 6 As shown, the device includes:

[0207] The second acquisition module 610 is used to acquire the working mode of the endoscope device as a second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device.

[0208] The second determining module 620 is used to determine the second indicator content corresponding to the second working mode based on the preset correspondence between the various working modes of the endoscope device and the various second indicator contents of the insufflator; wherein, different second indicator contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second indicator content corresponding to any working mode of the endoscope device is the airflow state that the insufflator is adapted to when the endoscope device is working in that working mode;

[0209] The second adjustment module 630 is used to send a second state control command to the pneumoperitoneum machine based on the second indicator content corresponding to the second working mode, so that the pneumoperitoneum machine responds to the second state control command and adjusts the airflow state of the pneumoperitoneum machine.

[0210] This application also provides an electronic device, such as... Figure 7 As shown, it includes:

[0211] Memory 701 is used to store computer programs;

[0212] When the processor 702 executes the program stored in the memory 701, it implements the steps of any of the above-described medical device linkage methods.

[0213] Furthermore, the aforementioned electronic device may also include a communication bus and / or a communication interface, with the processor 702, the communication interface, and the memory 701 communicating with each other via the communication bus.

[0214] The communication bus mentioned in the above electronic devices can be a Peripheral Component Interconnect (PCI) bus or an Extended Industry Standard Architecture (EISA) bus, etc. This communication bus can be divided into address bus, data bus, control bus, etc. For ease of illustration, only one thick line is used to represent it in the diagram, but this does not indicate that there is only one bus or one type of bus.

[0215] The communication interface is used for communication between the aforementioned electronic devices and other devices.

[0216] The memory may include random access memory (RAM) or non-volatile memory (NVM), such as at least one disk storage device. Optionally, the memory may also be at least one storage device located remotely from the aforementioned processor.

[0217] The processors mentioned above can be general-purpose processors, including central processing units (CPUs), network processors (NPs), etc.; they can also be digital signal processors (DSPs), application-specific integrated circuits (ASICs), field-programmable gate arrays (FPGAs), or other programmable logic devices, discrete gate or transistor logic devices, or discrete hardware components.

[0218] In another embodiment provided in this application, a computer-readable storage medium is also provided, which stores a computer program that, when executed by a processor, implements the steps of any of the above-described medical device linkage methods.

[0219] In another embodiment provided in this application, a computer program product containing instructions is also provided, which, when run on a computer, causes the computer to execute any of the medical device linkage methods described above.

[0220] In the above embodiments, implementation can be achieved entirely or partially through software, hardware, firmware, or any combination thereof. When implemented using software, it can be implemented entirely or partially in the form of a computer program product. The computer program product includes one or more computer instructions. When the computer program instructions are loaded and executed on a computer, all or part of the processes or functions described in the embodiments of this application are generated. The computer can be a general-purpose computer, a special-purpose computer, a computer network, or other programmable device. The computer instructions can be stored in a computer-readable storage medium or transmitted from one computer-readable storage medium to another. For example, the computer instructions can be transmitted from one website, computer, server, or data center to another website, computer, server, or data center via wired (e.g., coaxial cable, fiber optic, digital subscriber line (DSL)) or wireless (e.g., infrared, wireless, microwave, etc.) means. The computer-readable storage medium can be any available medium that a computer can access or a data storage device such as a server or data center that integrates one or more available media. The available medium can be a magnetic medium (e.g., floppy disk, hard disk, magnetic tape), an optical medium (e.g., DVD), or a semiconductor medium (e.g., solid state disk (SSD)).

[0221] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.

[0222] The various embodiments in this specification are described in a related manner. Similar or identical parts between embodiments can be referred to mutually. Each embodiment focuses on describing the differences from other embodiments. In particular, the apparatus embodiments are basically similar to the method embodiments, so the description is relatively simple; relevant parts can be referred to the descriptions of the method embodiments.

[0223] The above description is merely a preferred embodiment of this application and is not intended to limit the scope of protection of this application. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this application are included within the scope of protection of this application.

Claims

1. A medical device linkage method, characterized by, Applied to an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, the method includes: In response to the activation of the linkage switch in the interactive interface of the insufflator, the working mode of the insufflator is obtained as the first working mode. Based on a preset correspondence between various operating modes of the insufflator and various first indicator contents of the endoscope, the first indicator contents corresponding to the first operating mode are determined; wherein, different first indicator contents are used to characterize different image acquisition states of the endoscope probe of the endoscope; the image acquisition state characterized by the first indicator contents corresponding to any operating mode of the insufflator is the image acquisition state of the endoscope probe adapted when the insufflator is working in that operating mode; each first indicator content includes the parameter values ​​of each of the first specified parameters of the endoscope; the first specified parameter includes at least one of brightness, contrast, and saturation; Based on the first indicator content corresponding to the first working mode, a first state control command is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe according to a preset step size until the parameter value indicated by the first indicator content is reached.

2. The method of claim 1, wherein, The step of determining the first indicator content corresponding to the first working mode based on the preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscopic device includes: Based on the preset correspondence between the various working modes of the pneumoperitoneum machine and the various parameter values ​​of the first specified parameter of the endoscope, the target parameter value of the first specified parameter corresponding to the first working mode is determined.

3. The method of claim 2, wherein, Based on the first indicator content corresponding to the first working mode, a first state adjustment command is sent to the endoscope host, so that the endoscope host responds to the first state adjustment command and adjusts the image acquisition state of the endoscope probe according to a preset step size until the parameter value indicated by the first indicator content is reached, including: A first state control command carrying the target parameter value of the first specified parameter is sent to the endoscope host, so that the endoscope host responds to the first state control command and adjusts the first specified parameter of the endoscope device according to a preset step size and the target parameter value of the first specified parameter, so that the image acquisition state of the endoscope probe is adjusted to the image acquisition state represented by the target parameter value of the first specified parameter.

4. The method of claim 3, wherein, The first specified parameters include brightness and contrast; The endoscope host, in response to the first state control command, adjusts the first specified parameter of the endoscope device according to a preset step size and the target parameter value of the first specified parameter, including: The endoscope host responds to the first state control command and obtains the current parameter value of each first specified parameter of the endoscope device; For each first specified parameter of the endoscope device, if the target parameter value of the first specified parameter is greater than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is increased by a preset step size until the parameter value of the first specified parameter increases to the target parameter value of the first specified parameter, and then the adjustment stops. If the target parameter value of the first specified parameter is less than the current parameter value of the first specified parameter, the parameter value of the first specified parameter is reduced by a preset step size until the parameter value of the first specified parameter is reduced to the target parameter value, and then the adjustment stops.

5. The method according to any one of claims 1 to 4, characterized in that, The step of acquiring the working mode of the pneumoperitoneum machine, as the first working mode, includes: The working mode of the pneumoperitoneum machine is periodically acquired as the first working mode; The method further includes: The working mode of the endoscope device is periodically acquired as a second working mode; wherein, the image acquisition state of the endoscope probe is different in different working modes of the endoscope device. Based on the preset correspondence between the various working modes of the endoscope and the various second index contents of the insufflator, the second index contents corresponding to the second working mode are determined; wherein, different second index contents are used to characterize different airflow states of the insufflator, and the airflow state characterized by the second index contents corresponding to any working mode of the endoscope is the airflow state that the insufflator is adapted to when the endoscope works in that working mode. Based on the second indicator content corresponding to the second working mode, a second state control command is sent to the insufflator so that the insufflator responds to the second state control command and adjusts the airflow state of the insufflator.

6. The method according to claim 5, characterized in that, The second indicators of the pneumoperitoneum machine include the parameter values ​​of the second specified parameters of the pneumoperitoneum machine, or the various working modes of the pneumoperitoneum machine. The second specified parameter is a parameter used to adjust the airflow state of the pneumoperitoneum machine; the airflow state is different in different working modes of the pneumoperitoneum machine.

7. A medical equipment linkage device, characterized in that, An apparatus used in an insufflator, wherein the insufflator communicates with the endoscopic host of an endoscopic device, the apparatus comprising: The first acquisition module is used to acquire the working mode of the insufflator as the first working mode in response to the activation of the linkage switch in the interactive interface of the insufflator. The first determining module is used to determine the first indicator content corresponding to the first working mode based on a preset correspondence between the various working modes of the insufflator and the various first indicator contents of the endoscope device; wherein, different first indicator contents are used to characterize different image acquisition states of the endoscope probe of the endoscope device, and the image acquisition state characterized by the first indicator content corresponding to any working mode is the image acquisition state of the endoscope probe adapted when the insufflator is working in that working mode; each first indicator content includes the parameter values ​​of each of the first specified parameters of the endoscope device; the first specified parameter includes at least one of brightness, contrast and saturation. The first adjustment module is used to send a first state control command to the endoscope host based on the first indicator content corresponding to the first working mode, so that the endoscope host responds to the first state control command and adjusts the image acquisition state of the endoscope probe according to a preset step size until the parameter value indicated by the first indicator content is reached.

8. An electronic device, characterized in that, include: Memory, used to store computer programs; A processor, when executing a program stored in memory, implements the method of any one of claims 1-6.

9. A computer-readable storage medium, characterized in that, The computer-readable storage medium stores a computer program that, when executed by a processor, implements the method described in any one of claims 1-6.