CN114098718B - Multifunctional monitoring system for rapid rehabilitation patient - Google Patents

Abstract

The invention belongs to the technical field of rehabilitation monitoring, and particularly relates to a multifunctional monitoring system for a rapid rehabilitation patient, which comprises a patient end, a background end and a monitoring end; the background end is respectively communicated with the patient end and the monitoring end; the patient end comprises an acquisition unit and an input unit; the acquisition unit is used for acquiring rehabilitation data of a patient and sending the rehabilitation data to the background end, wherein the rehabilitation data comprises physical sign data, walking data and positioning; the background end is used for storing rehabilitation data, analyzing whether the patient is abnormal according to the physical sign data of the patient, and sending a first monitoring signal to the monitoring end if the patient is abnormal; the first monitored signal comprises the positioning of a patient, information of the patient and abnormal content; the input unit is used for inputting uncomfortable information and sending the uncomfortable information to the background end; the background end is also used for sending a second monitoring signal to the monitoring end after receiving the discomfort information; the second monitored signal includes patient location and patient information. The application can conveniently and accurately monitor postoperative rehabilitation.

Description

Multifunctional monitoring system for rapid rehabilitation patient

Technical Field

The invention belongs to the technical field of rehabilitation monitoring, and particularly relates to a multifunctional monitoring system for a rapid rehabilitation patient.

Background

In order to enable the patient to perform better physical recovery after the operation, later personnel can make a recovery plan for the patient who performs the operation according to own experience. The postoperative rehabilitation walking is an important content of a rehabilitation plan, namely, a patient walks according to the rehabilitation plan made by medical staff, so that the exercise capacity of the patient is gradually recovered.

At present, the rehabilitation walking of postoperative rehabilitation mainly guides the number of the activities of a patient every day according to experience by medical staff, then the medical staff records the walking number of the patient, and the physical sign data of the patient are measured through devices such as a sphygmomanometer, an oxygen finger clip and the like.

However, in such an operation mode, the acquisition quantity of the number of the activity steps of the first patient is not accurate enough; secondly, the monitoring mode of the patient physical sign is not real-time record of the activity, so that the timeliness is also insufficient; thirdly, when the medical staff performs statistical analysis on index data of patients, the index data are manually input one by one, and the operation is very troublesome; fourth, when there are many recovered patients, one medical staff needs to monitor a plurality of patients at the same time, and when a certain patient is untimely, it is difficult to monitor in time.

Therefore, a multifunctional monitoring system for rapidly recovering patients is needed, and the patients can be conveniently and accurately monitored in postoperative recovery.

Disclosure of Invention

The invention aims to provide a multifunctional monitoring system for a rapid rehabilitation patient, which can conveniently and accurately monitor postoperative rehabilitation of the patient.

The basic scheme provided by the invention is as follows:

the multifunctional monitoring system for the rapid rehabilitation patient comprises a patient end, a background end and a monitoring end; the background end is respectively communicated with the patient end and the monitoring end;

the patient end comprises an acquisition unit and an input unit; the acquisition unit is used for acquiring rehabilitation data of a patient and sending the rehabilitation data to the background end, wherein the rehabilitation data comprises physical sign data, walking data and positioning; the background end stores information of a patient corresponding to the patient end; the background end is used for storing rehabilitation data, analyzing whether the patient is abnormal according to the physical sign data of the patient, and sending a first monitoring signal to the monitoring end if the patient is abnormal; the first monitored signal comprises the positioning of a patient, information of the patient and abnormal content;

the input unit is used for inputting uncomfortable information and sending the uncomfortable information to the background end; the background end is also used for sending a second monitoring signal to the monitoring end after receiving the discomfort information; the second monitored signal includes patient location and patient information.

Basic scheme theory of operation and beneficial effect:

when a patient walks in a rehabilitation way, the patient end acquisition unit acquires the rehabilitation data of the patient and sends the rehabilitation data to the background end, and the background end stores the rehabilitation data. Because the rehabilitation data comprises physical sign data, walking data and positioning, the integrity, the accuracy and the timeliness of the postoperative rehabilitation training data of the patient can be ensured. When the rehabilitation data of the patient is required to be analyzed, the relevant data is directly extracted from the background end for analysis.

The background end also analyzes whether the patient is abnormal according to the physical sign data of the patient, and if so, the background end sends a first monitoring signal to the monitoring end; the first monitored signal includes a location of the patient, information of the patient, and content of the abnormality. After the medical staff receives the first monitored signal through the monitored end, the medical staff can know the position and the personal condition of the patient with abnormality at the first time, and can carry out corresponding nursing in time. In addition, when the patient feels uncomfortable during the rehabilitation process, the discomfort information can be input through the input unit and sent to the background end; the background receives the uncomfortable information and then sends a second monitored signal to the monitoring end; because the second monitored signal comprises the positioning of the patient and the information of the patient, the medical staff can arrive at the patient with conscious discomfort in time and can consult and care the patient in time.

In summary, the present application can be convenient, accurate to the patient carry out the recovered monitoring of postoperative.

Furthermore, the background end is also used for generating rehabilitation advice information according to the physical sign data and the walking data of the patient.

The beneficial effects are that: through the rehabilitation proposal information, medical staff can optimize and improve the walking rehabilitation scheme of the patient, so that the walking rehabilitation scheme meets the requirements of the patient better.

Further, the walking data includes stride frequency and stride length.

The beneficial effects are that: according to the step frequency and the stride, the physiological data of the patient, such as the height and weight, are combined, so that the walking state of the patient during rehabilitation can be known, and the state evaluation of the patient can be more accurately carried out.

The background end is further used for carrying out travel analysis according to the positioning data of the patient, if the travel analysis result is that a pre-stored dangerous area is about to pass, the background end analyzes the walking data of the patient, and if the step frequency of the patient is greater than the preset frequency or the step width is greater than the preset amplitude, the background end sends a stable signal to the patient end; the patient end comprises an intelligent foot ring, and the intelligent foot ring is used for continuously vibrating after receiving the steady signal; the intelligent foot ring is also used for inputting a confirmation signal after receiving the steady signal, wherein the confirmation signal is input through a button on the intelligent foot ring; the intelligent foot ring is also used for stopping vibrating after inputting a confirmation signal.

The beneficial effects are that: although a safer indoor space is usually selected in the rehabilitation area, a toilet, a boiled water room and other areas easy to fall down or dangerous areas with gradients basically exist. In these dangerous areas, special care is required when the patient walks, as the patient is already in the rehabilitation phase and may fall if walking too fast or stride too large. If a fall occurs in the rehabilitation stage, the rehabilitation effect is seriously affected. In this application, in order to avoid such a situation, the backend may perform path analysis according to the positioning data of the patient, and if the analysis result is about to pass through the dangerous area, it is necessary to know whether the current walking state of the patient is a state that is easy to fall. Therefore, the background end analyzes the walking data of the patient, if the step frequency of the patient is larger than the preset frequency or the step width is larger than the preset amplitude, the walking state of the patient at the moment is indicated to be an easy-to-fall state, and if the walking state is not corrected in time, the patient is at risk of falling in a dangerous area.

If the patient is adjusted, the patient is likely to not stop to process because of consistency of walking states only by the conventional voice prompt or the light prompt, but can directly continue to walk according to the original state until the patient feels comfortable, or walk while processing. The result of this is that the patient is still at a frequency or stride where he or she may fall while walking to the dangerous area. To avoid this, a steady signal is sent to the patient side in the system. The intelligent foot ring at the patient end can continuously vibrate after receiving the steady signal; when the feet are in continuous vibration sense, normal people feel uncomfortable. In this scheme, however, the patient is required to input a confirmation signal through a button on the intelligent foot ring in order to stop the vibration of the intelligent foot ring. Because the intelligent foot ring is worn at the ankle, to input a confirmation signal, the patient must make a half squat or even a deep squat, and the patient cannot continuously move during the half squat. Thus, the patient can be ensured to know the existence of the dangerous area in time after receiving the steady signal. Besides, the reminding mode breaks the consistency of patient walking, and is matched with other prompts (such as text or voice prompts for dangerous areas), so that when the patient starts walking again, the patient can walk with safe step frequency and stride.

By using the system, the patient can be ensured to pass through dangerous areas such as easy-to-fall areas and the like with safe step frequency and step length.

Further, when the background end sends a stable signal to the patient end, if the step frequency of the patient is greater than the preset frequency, the background end also generates a step frequency reminding signal and sends the step frequency reminding signal to the patient end, and if the step frequency of the patient is greater than the preset amplitude, the background end also generates a step frequency reminding signal and sends the step frequency reminding signal to the patient end; the patient end is also used for sending out corresponding voice reminding through the intelligent foot ring after receiving the step frequency reminding signal or the step reminding signal.

The beneficial effects are that: when the patient squats down and inputs a confirmation signal through the intelligent foot ring, the patient can know the condition of the patient to be noticed through the corresponding voice reminding. When the user walks again after getting up, corresponding adjustment can be performed, such as reducing the stride frequency or reducing the stride. So as to be able to walk steadily while passing through the dangerous area.

Further, an electronic map of a rehabilitation area is stored in the background end; the monitoring end is also used for marking the dangerous area on the electronic map.

The beneficial effects are that: during the use of the rehabilitation area, a new dangerous area or a temporary dangerous area may appear due to maintenance, construction and the like. By the arrangement, the nursing staff can timely mark when finding a new dangerous area, and the safety of patients is guaranteed.

Furthermore, the patient end is also used for inputting the walking destination and sending the walking destination to the background end, and the background end is also used for planning a path after receiving the walking destination, generating a walking line which does not pass through a dangerous area and feeding back the walking line to the corresponding patient end.

The beneficial effects are that: if the patient wants to move to a relatively far place, but is unfamiliar with the environment, the destination can be input through the patient end, and then the background end performs path planning on the patient, so that the patient can avoid dangerous areas in the walking process, and the safety in the walking process is ensured. Thus, even a patient unfamiliar with the regional environment can quickly find a safe walking route.

Further, the sign data includes heart rate, oxygen saturation, and blood pressure.

The beneficial effects are that: through the physical sign data, the physical state of the patient during rehabilitation can be accurately known.

Further, when the monitoring end user receives the first monitoring signal or the second monitoring signal, a monitoring prompt is sent out.

The beneficial effects are that: through the guardianship warning, can let medical personnel in time know the rehabilitation patient who has the abnormality.

Further, the monitoring reminding mode is voice plus text.

The beneficial effects are that: through the pronunciation, can let medical personnel notice the warning, through the characters, then can let medical personnel clear understanding the concrete content of warning.

Drawings

Fig. 1 is a logic block diagram of a first embodiment of the present invention.

Detailed Description

The following is a further detailed description of the embodiments:

example 1

As shown in fig. 1, the multifunctional monitoring system for rapid rehabilitation patients comprises a patient end, a background end and a monitoring end; the background end is respectively communicated with the patient end and the monitoring end. In this embodiment, the patient end includes an intelligent bracelet; the background end is a cloud server, and the monitoring end is a smart phone loaded with a corresponding APP.

The patient end comprises an acquisition unit and an input unit. The acquisition unit is used for acquiring rehabilitation data of a patient and sending the rehabilitation data to the background end, wherein the rehabilitation data comprises physical sign data, walking data and positioning. In this embodiment, the positioning data is directly collected by the positioning module of the smart band. In other embodiments, the positioning data of the patient can be acquired in real time after the special indoor positioning device is arranged and communicated with the intelligent bracelet through Bluetooth. The physical sign data includes heart rate, oxygen saturation and blood pressure. Through the physical sign data, the physical state of the patient during rehabilitation can be accurately known. In this embodiment, the physical sign data is directly collected through the smart bracelet, and in other embodiments, the physical sign data can be also collected through the corresponding detection sensor and then sent to the background through the smart bracelet in real time. In this embodiment, the walking data includes stride frequency and stride length. According to the step frequency and the stride, the physiological data of the patient, such as the height and weight, are combined, so that the walking state of the patient during rehabilitation can be known, and the state evaluation of the patient can be more accurately carried out.

The background end stores information of a patient corresponding to the patient end. During specific storage, medical staff can input and store the medical staff at the background end. The background end is used for storing rehabilitation data, analyzing whether the patient is abnormal according to the physical sign data of the patient, and sending a first monitoring signal to the monitoring end if the patient is abnormal; the first monitored signal includes a location of the patient, information of the patient, and content of the abnormality. The input unit is used for inputting uncomfortable information and sending the uncomfortable information to the background end; the background end is also used for sending a second monitoring signal to the monitoring end after receiving the discomfort information; the second monitored signal includes patient location and patient information.

And when the monitoring end user receives the first monitoring signal or the second monitoring signal, a monitoring prompt is sent out. Through the guardianship warning, can let medical personnel in time know the rehabilitation patient who has the abnormality. In this embodiment, the monitoring reminding mode is voice plus text. The voice prompt can enable medical staff to notice the prompt, and the text prompt can enable the medical staff to clearly know the specific prompt content. In this embodiment, the input unit is integrated on the smart band, and specifically, the input uncomfortable information may be set by means of a virtual button, which belongs to a common technical means in the art, and will not be described herein. The background end is also used for generating rehabilitation advice information according to physical sign data and walking data of the patient.

The specific implementation process is as follows:

when a patient walks in a rehabilitation way, the patient end acquisition unit acquires the rehabilitation data of the patient and sends the rehabilitation data to the background end, and the background end stores the rehabilitation data. Because the rehabilitation data comprises physical sign data, walking data and positioning, the integrity, the accuracy and the timeliness of the postoperative rehabilitation training data of the patient can be ensured. When the rehabilitation data of the patient is required to be analyzed, the relevant data is directly extracted from the background end for analysis.

The background end also analyzes whether the patient is abnormal according to the physical sign data of the patient, and if so, the background end sends a first monitoring signal to the monitoring end; the first monitored signal includes a location of the patient, information of the patient, and content of the abnormality. After the medical staff receives the first monitored signal through the monitored end, the medical staff can know the position and the personal condition of the patient with abnormality at the first time, and can carry out corresponding nursing in time. In addition, when the patient feels uncomfortable during the rehabilitation process, the discomfort information can be input through the input unit and sent to the background end; the background receives the uncomfortable information and then sends a second monitored signal to the monitoring end; because the second monitored signal comprises the positioning of the patient and the information of the patient, the medical staff can arrive at the patient with conscious discomfort in time and can consult and care the patient in time. After the medical care personnel receive the first monitored signal or the second monitored signal, the medical care personnel can send out a monitoring prompt in a voice and text mode, so that the medical care personnel can know the situation and collect corresponding nursing measures.

In addition, the background end in the application can also generate rehabilitation advice information according to the physical sign data and the walking data of the patient. Through the rehabilitation proposal information, medical staff can optimize and improve the walking rehabilitation scheme of the patient, so that the walking rehabilitation scheme meets the requirements of the patient better.

Example two

Unlike the first embodiment, in this embodiment, an electronic map of a rehabilitation area is stored in the background end; the monitoring end is also used for marking the dangerous area on the electronic map. During the use of the rehabilitation area, a new dangerous area or a temporary dangerous area may appear due to maintenance, construction and the like. By the arrangement, the nursing staff can timely mark when finding a new dangerous area, and the safety of patients is guaranteed.

The patient end also comprises an intelligent foot ring. The background end is also used for carrying out travel analysis according to the positioning data of the patient, if the result of the travel analysis is about to pass through a dangerous area, the background end analyzes the walking data of the patient, and if the step frequency of the patient is greater than a preset frequency or the step width is greater than a preset amplitude, the background end sends a stable signal to the patient end; the patient end comprises an intelligent foot ring, and the intelligent foot ring is used for continuously vibrating after receiving the steady signal; the intelligent foot ring is also used for inputting a confirmation signal after receiving the steady signal, wherein the confirmation signal is input through a button on the intelligent foot ring; the intelligent foot ring is also used for stopping vibrating after inputting a confirmation signal.

When the background end sends a stable signal to the patient end, if the step frequency of the patient is greater than the preset frequency, the background end also generates a step frequency reminding signal and sends the step frequency reminding signal to the patient end, and if the step frequency of the patient is greater than the preset amplitude, the background end also generates a step frequency reminding signal and sends the step frequency reminding signal to the patient end; the patient end is also used for sending out corresponding voice reminding through the intelligent foot ring after receiving the step frequency reminding signal or the step reminding signal.

The patient end is also used for inputting a walking destination and sending the walking destination to the background end, and the background end is also used for planning a path after receiving the walking destination, generating a walking line which does not pass through a dangerous area and feeding the walking line back to the corresponding patient end.

The specific implementation process is as follows:

although a safer indoor space is usually selected in the rehabilitation area, a toilet, a boiled water room and other areas easy to fall down or dangerous areas with gradients basically exist. In these dangerous areas, special care is required when the patient walks, as the patient is already in the rehabilitation phase and may fall if walking too fast or stride too large. If a fall occurs in the rehabilitation stage, the rehabilitation effect is seriously affected. In this application, in order to avoid such a situation, the backend may perform path analysis according to the positioning data of the patient, and if the analysis result is about to pass through the dangerous area, it is necessary to know whether the current walking state of the patient is a state that is easy to fall. Therefore, the background end analyzes the walking data of the patient, if the step frequency of the patient is larger than the preset frequency or the step width is larger than the preset amplitude, the walking state of the patient at the moment is indicated to be an easy-to-fall state, and if the walking state is not corrected in time, the patient is at risk of falling in a dangerous area.

If the patient is adjusted, the patient is likely to not stop to process because of consistency of walking states only by the conventional voice prompt or the light prompt, but can directly continue to walk according to the original state until the patient feels comfortable, or walk while processing. The result of this is that the patient is still at a frequency or stride where he or she may fall while walking to the dangerous area. To avoid this, a steady signal is sent to the patient side in the system. The intelligent foot ring at the patient end can continuously vibrate after receiving the steady signal; when the feet are in continuous vibration sense, normal people feel uncomfortable. In this scheme, however, the patient is required to input a confirmation signal through a button on the intelligent foot ring in order to stop the vibration of the intelligent foot ring. Because the intelligent foot ring is worn at the ankle, to input a confirmation signal, the patient must make a half squat or even a deep squat, and the patient cannot continuously move during the half squat.

And, because patient receives step frequency warning signal or stride warning signal after receiving, can send corresponding pronunciation warning through intelligent foot ring. When the patient squats down and inputs a confirmation signal through the intelligent foot ring, the patient can know the condition of the patient to be noticed through the corresponding voice reminding. When the user walks again after getting up, corresponding adjustment can be performed, such as reducing the stride frequency or reducing the stride. So as to be able to walk steadily while passing through the dangerous area. Thus, the patient can be ensured to know the existence of the dangerous area in time after receiving the steady signal. In addition, the reminding mode breaks through the continuity of patient walking, and when the patient starts walking again by matching with the corresponding voice reminding, the patient can walk with safe step frequency and step.

If the patient wants to move to a relatively far place, but is unfamiliar with the environment, the destination can be input through the patient end, and then the background end performs path planning on the patient, so that the patient can avoid dangerous areas in the walking process, and the safety in the walking process is ensured. Thus, even a patient unfamiliar with the regional environment can quickly find a safe walking route.

The foregoing is merely an embodiment of the present invention, and a specific structure and characteristics of common knowledge in the art, which are well known in the scheme, are not described herein, so that a person of ordinary skill in the art knows all the prior art in the application day or before the priority date of the present invention, and can know all the prior art in the field, and have the capability of applying the conventional experimental means before the date, so that a person of ordinary skill in the art can complete and implement the present embodiment in combination with his own capability in the light of the present application, and some typical known structures or known methods should not be an obstacle for a person of ordinary skill in the art to implement the present application. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the structure of the present invention, and these should also be considered as the scope of the present invention, which does not affect the effect of the implementation of the present invention and the utility of the patent. The protection scope of the present application shall be subject to the content of the claims, and the description of the specific embodiments and the like in the specification can be used for explaining the content of the claims.

Claims (10)

1. Multifunctional monitoring system for rapid rehabilitation patients, which is characterized in that: the system comprises a patient end, a background end and a monitoring end; the background end is respectively communicated with the patient end and the monitoring end;

the patient end comprises an acquisition unit and an input unit; the acquisition unit is used for acquiring rehabilitation data of a patient and sending the rehabilitation data to the background end, wherein the rehabilitation data comprises physical sign data, walking data and positioning;

the patient end comprises an intelligent foot ring, and the intelligent foot ring is used for continuously vibrating after receiving the steady signal; the intelligent foot ring is also used for inputting a confirmation signal after receiving the steady signal, wherein the confirmation signal is input through a button on the intelligent foot ring; the intelligent foot ring is also used for stopping vibrating after inputting a confirmation signal;

the background end stores information of a patient corresponding to the patient end; the background end is used for storing rehabilitation data, analyzing whether the patient is abnormal according to the physical sign data of the patient, and sending a first monitoring signal to the monitoring end if the patient is abnormal; the first monitored signal comprises the positioning of a patient, information of the patient and abnormal content;

the input unit is used for inputting uncomfortable information and sending the uncomfortable information to the background end; the background end is also used for sending a second monitoring signal to the monitoring end after receiving the discomfort information; the second monitored signal includes patient location and patient information.

2. The rapid rehabilitation patient multi-function monitoring system of claim 1, wherein: the background end is also used for generating rehabilitation advice information according to physical sign data and walking data of the patient.

3. The rapid rehabilitation patient multi-function monitoring system of claim 1, wherein: the walking data includes stride frequency and stride length.

4. The rapid rehabilitation patient multi-function monitoring system according to claim 3, wherein: the background end is also used for carrying out travel analysis according to the positioning data of the patient, if the travel analysis result is a dangerous area to be pre-stored, the background end analyzes the walking data of the patient, and if the step frequency of the patient is larger than the preset frequency or the step width is larger than the preset amplitude, the background end sends a steady signal to the patient end.

5. The rapid rehabilitation patient multi-function monitoring system of claim 4, wherein: when the background end sends a stable signal to the patient end, if the step frequency of the patient is greater than the preset frequency, the background end also generates a step frequency reminding signal and sends the step frequency reminding signal to the patient end, and if the step frequency of the patient is greater than the preset amplitude, the background end also generates a step frequency reminding signal and sends the step frequency reminding signal to the patient end; the patient end is also used for sending out corresponding voice reminding through the intelligent foot ring after receiving the step frequency reminding signal or the step reminding signal.

6. The rapid rehabilitation patient multi-function monitoring system of claim 4, wherein: an electronic map of a rehabilitation area is stored in the background end; the monitoring end is also used for marking the dangerous area on the electronic map.

7. The rapid rehabilitation patient multi-function monitoring system of claim 6, wherein: the patient end is also used for inputting a walking destination and sending the walking destination to the background end, and the background end is also used for planning a path after receiving the walking destination, generating a walking line which does not pass through a dangerous area and feeding the walking line back to the corresponding patient end.

8. The rapid rehabilitation patient multi-function monitoring system of claim 1, wherein: the physical sign data includes heart rate, oxygen saturation and blood pressure.

9. The rapid rehabilitation patient multi-function monitoring system of claim 1, wherein: and when the monitoring end user receives the first monitoring signal or the second monitoring signal, a monitoring prompt is sent out.

10. The rapid rehabilitation patient multi-function monitoring system of claim 9, wherein: the monitoring reminding mode is voice plus text.