CN212699898U - Remote drug delivery system - Google Patents
Remote drug delivery system Download PDFInfo
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- CN212699898U CN212699898U CN202020193755.9U CN202020193755U CN212699898U CN 212699898 U CN212699898 U CN 212699898U CN 202020193755 U CN202020193755 U CN 202020193755U CN 212699898 U CN212699898 U CN 212699898U
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- drug delivery
- delivery system
- injection pump
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Abstract
The utility model discloses a long-range drug delivery system, including radiography machine, long-range syringe pump and control terminal, the radiography machine is used for detecting perspective image, and long-range syringe pump is used for infusing treatment medicine to the human body to with control terminal communication connection, control terminal is used for the infusion speed and the infusion dosage of long-range syringe pump of remote control. The remote injection pump and the radiography machine are both arranged in the radiography room, and the control terminal is arranged outside the radiography room. The remote syringe pump may inject therapeutic drugs into the blood vessel and the contrast camera may detect a fluoroscopic image of the blood vessel after the therapeutic drugs are injected. The doctor can observe the perspective image outdoors, determine the administration condition of the therapeutic drug, and remotely adjust the infusion dosage and the infusion speed of the remote injection pump through the control terminal. Therefore, the doctor does not need to be in the radiation environment for a long time, and the injury of angiography to the doctor is reduced.
Description
Technical Field
The utility model relates to a be used for blood vessel to intervene treatment facility field, especially relate to a long-range drug delivery system.
Background
The blood vessel intervention operation is the main method for treating cardiovascular and cerebrovascular diseases and tumor diseases, in the operation process, firstly, radiography is needed to determine the condition of a focus, and then therapeutic drugs are injected directionally and slowly according to the condition of the focus, so that the therapeutic drugs are kept in a high-concentration state at the focus, and the curative effect is improved.
In the process of injecting the therapeutic drug, a fluoroscopic image of the lesion position needs to be detected for a long time by using a contrast machine, so that medical staff can observe the distribution condition of the therapeutic drug in the blood vessel in real time through the fluoroscopic image to effectively inject the therapeutic drug to the lesion.
Moreover, because the condition of the blood vessels in the focal region cannot be determined, whether the blood vessels of the focus are filled with the therapeutic drugs or not needs to be observed through the perspective image, and the drug administration is stopped at any time, so that the therapeutic drugs are prevented from entering the blood vessels of other healthy regions and damaging other parts of the human body due to the fact that excessive therapeutic drugs are injected. Therefore, in the whole vascular interventional operation process, medical staff can be in a radiation environment for a long time, which brings great harm to the medical staff.
SUMMERY OF THE UTILITY MODEL
For solving above technical problem, the utility model provides a long-range administration system, at the radiography in-process, the doctor can the long-range observation radiography machine detect and obtain perspective image, confirms the condition of dosing of treatment medicine to input dosage and the infusion speed of passing through the long-range injection pump of control terminal remote adjustment according to the condition of dosing.
The technical scheme is as follows:
a remote drug delivery system comprises a contrast machine, a remote injection pump and a control terminal, wherein the contrast machine is used for detecting perspective images, the remote injection pump is used for infusing therapeutic drugs into a human body and is in communication connection with the control terminal, and the control terminal is used for remotely controlling the infusion speed and the infusion dosage of the remote injection pump.
With reference to the first implementable manner, in a second implementable manner, the control terminal includes a monitor for displaying a fluoroscopic image detected by the contrast machine.
With reference to the first implementable manner, in a third implementable manner, the control terminal comprises a wired transmission interface, and the control terminal is in communication connection with a remote syringe pump through a data transmission line.
With reference to the first implementable manner, in a fourth implementable manner, the control terminal includes a wireless communication module, and the control terminal is in communication connection with the remote injection pump through the wireless communication module.
With reference to the third or fourth implementable manner, in a fifth implementable manner, the control terminal includes an input module for inputting instruction information for controlling the infusion speed and the infusion dosage.
With reference to the fifth implementable manner, in a sixth implementable manner, the control terminal comprises a display for displaying the infusion speed and the infusion dosage of the remote syringe pump.
In combination with the first implementable manner, in a seventh implementable manner, the control terminal includes an alarm, and the alarm is configured to receive alarm information sent by the remote injection pump and send a corresponding alarm signal.
Has the advantages that: adopt the utility model discloses a long-range drug delivery system can be according to the perspective image that the radiography machine detected, through the infusion dosage and the infusion speed of control terminal remote adjustment syringe pump, ensures that the treatment medicine reaches the pathological change position effectively to can avoid the doctor to be in the radiation environment for a long time, alleviate the injury that the radiation brought for the doctor.
Drawings
Fig. 1 is a schematic block diagram of the system of the present invention.
Detailed Description
The present invention will be further explained with reference to the following examples and drawings.
The system block diagram of the remote drug delivery system shown in fig. 1 includes a contrast machine for detecting a perspective image, a remote syringe pump for infusing therapeutic drugs into a human body and communicatively connected to a control terminal for remotely controlling the infusion speed and the infusion dosage of the remote syringe pump, and the control terminal.
Specifically, the remote injection pump and the contrast machine are both arranged in a contrast chamber, and the control terminal is arranged outside the contrast chamber. The remote injection pump can inject therapeutic drugs into the blood vessel, and the contrast machine can detect the perspective image of the blood vessel after the therapeutic drugs are injected into the blood vessel. The doctor can observe the perspective image outdoors, determine the administration condition of the therapeutic drug, and remotely adjust the infusion dosage and the infusion speed of the remote injection pump through the control terminal. Therefore, the doctor does not need to be in the radiation environment for a long time, and the injury of angiography to the doctor is reduced.
In this embodiment, it is preferable that the control terminal includes a monitor for displaying the perspective image detected by the contrast machine.
Specifically, the remote terminal may acquire a fluoroscopic image detected by the contrast machine and transmit the fluoroscopic image to the monitor for display, or the monitor may directly acquire the fluoroscopic image for display. The existing radiography machines are all provided with a video interface, such as an HDMI interface. The control terminal or monitor can be connected with the video interface of the contrast machine through a video transmission line to acquire the perspective image transmitted by the contrast machine. In this way, a doctor can observe a clear perspective image through a monitor outside the radiography room so as to accurately evaluate the physical condition of a patient.
In this embodiment, it is preferable that the control terminal includes a wired transmission interface, and the control terminal is communicatively connected with the remote syringe pump through a data transmission line.
Specifically, a matched wired transmission interface, such as an RS232 interface or an RJ45 interface, is arranged between the control terminal and the remote syringe pump, and the limited transmission interface between the control terminal and the remote syringe pump can be connected through a corresponding signal line, so as to realize the communication connection between the control terminal and the remote syringe pump.
In this embodiment, preferably, the control terminal includes a wireless communication module, and the control terminal is connected to the remote syringe pump through the wireless communication module.
Specifically, a wireless communication module matched with the control terminal, such as a Bluetooth module, is arranged between the control terminal and the remote injection pump, and the control terminal can be in communication connection with the remote injection pump through the wireless communication module. And 2 communication modes are set, so that when one communication mode fails, the other communication mode can be started to establish communication connection, and the normal operation of the whole system is ensured.
In this embodiment, preferably, the control terminal includes an input module, and the input module is used for inputting instruction information for controlling the infusion speed and the infusion dosage. Specifically, after the doctor has evaluated the physical condition of the patient, the infusion dosage and infusion speed of the therapeutic drug can be input through an input module, such as a key module. The control terminal can transmit the infusion dosage and the infusion speed input by the input module to the remote injection pump, and the remote injection pump adjusts the infusion dosage and the infusion speed according to the received infusion speed.
In this embodiment, it is preferable that the control terminal includes a display for displaying the infusion speed and the infusion dosage of the remote syringe pump. The doctor can know the set infusion speed and infusion dosage through the display, and errors are avoided.
In this embodiment, preferably, the control terminal includes an alarm, and the alarm is configured to receive alarm information sent by the remote syringe pump and send a corresponding alarm signal. In particular, most existing remote syringe pumps are provided with an alarm system on their own, which can detect the remaining liquid dose in the syringe pump, as well as system failures, and generate corresponding alarm information.
In this embodiment, the remote syringe pump can detect the liquid dosage and the system fault by using its own alarm system, and generate corresponding alarm information to send to the control terminal. The control terminal can control the alarm to send out an alarm signal according to the alarm information after receiving the alarm information so as to inform a doctor to process, and the alarm can be an audible and visual alarm.
Finally, it should be noted that the above description is only a preferred embodiment of the present invention, and those skilled in the art can make various similar representations without departing from the spirit and the scope of the present invention.
Claims (7)
1. A remote drug delivery system, characterized by: the remote injection system comprises a contrast machine, a remote injection pump and a control terminal, wherein the contrast machine is used for detecting perspective images, the remote injection pump is used for infusing therapeutic drugs into a human body and is in communication connection with the control terminal, and the control terminal is used for remotely controlling the infusion speed and the infusion dosage of the remote injection pump.
2. The remote drug delivery system of claim 1, wherein: the control terminal includes a monitor for displaying the fluoroscopic image detected by the contrast machine.
3. The remote drug delivery system of claim 1, wherein the control terminal comprises a wired transmission interface, the control terminal being communicatively connected to the remote syringe pump via a data transmission line.
4. The remote drug delivery system of claim 1, wherein: the control terminal comprises a wireless communication module, and the control terminal is in communication connection with the remote injection pump through the wireless communication module.
5. The remote drug delivery system according to claim 3 or 4, wherein: the control terminal comprises an input module, and the input module is used for inputting instruction information for controlling the infusion speed and the infusion dosage.
6. The remote drug delivery system of claim 5, wherein: the control terminal comprises a display used for displaying the infusion speed and the infusion dosage of the remote injection pump.
7. The remote drug delivery system of claim 1, wherein: the control terminal comprises an alarm which is used for receiving alarm information sent by the remote injection pump and sending a corresponding alarm signal.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202020193755.9U CN212699898U (en) | 2020-02-21 | 2020-02-21 | Remote drug delivery system |
Applications Claiming Priority (1)
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CN202020193755.9U CN212699898U (en) | 2020-02-21 | 2020-02-21 | Remote drug delivery system |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN114432530A (en) * | 2021-12-03 | 2022-05-06 | 中国人民解放军空军军医大学 | Automatic hydration treatment system used after nuclide treatment |
CN114432530B (en) * | 2021-12-03 | 2024-04-26 | 中国人民解放军空军军医大学 | Automatic hydration treatment system used after nuclide treatment |
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2020
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN114432530A (en) * | 2021-12-03 | 2022-05-06 | 中国人民解放军空军军医大学 | Automatic hydration treatment system used after nuclide treatment |
CN114432530B (en) * | 2021-12-03 | 2024-04-26 | 中国人民解放军空军军医大学 | Automatic hydration treatment system used after nuclide treatment |
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