CN112233758A

CN112233758A - Cerebral arteriosclerosis management cloud platform system and electronic intelligent medicine box

Info

Publication number: CN112233758A
Application number: CN202011100675.5A
Authority: CN
Inventors: 刘明
Original assignee: Beijing Fu Yun Cloud Data Technology Co ltd
Current assignee: Beijing Fu Yun Cloud Data Technology Co ltd
Priority date: 2020-10-15
Filing date: 2020-10-15
Publication date: 2021-01-15

Abstract

A cloud platform system and intelligent medicine box, the system includes the hygiene administrative department, patient use terminal and intelligent medicine box linked through the network, hygiene administrative department terminal, patient use terminal and intelligent medicine box all dispose the application program, characterized by that, the hygiene administrative department utilizes the application program that the terminal disposes to formulate the treatment scheme of the patient, follow-up visit plan and review plan, and utilize the medicine dispensing equipment to distribute the medicine for treating cerebral arteriosclerosis to the intelligent medicine box; the patient checks the re-diagnosis plan and the follow-up plan by using the configured application program, and reports the medicine taking effect; the intelligent medicine box runs an application program to remind a patient of taking medicine at regular time, and the intelligent medicine box further comprises a digital certificate authentication module which determines whether to open a medicine box cover according to an external digital certificate identification result of the patient or a caregiver. The invention ensures that the patient can take medicine according to the compliance through the coordination of the health management department, the patient and the intelligent medicine box, and the follow-up visit and the re-diagnosis are carried out in time.

Description

Cerebral arteriosclerosis management cloud platform system and electronic intelligent medicine box

Technical Field

The invention relates to a cerebral arteriosclerosis management cloud platform system and an intelligent medicine box, and belongs to the technical field of internet medical treatment.

Background

Cerebral arteriosclerosis is common in middle-aged and elderly people over 40 years old, more in men than women, and more common in people with cerebral arteriosclerosis, diabetes, hyperlipidemia, long-term smoking, drinking and mental stress. Brain function declines due to chronic inadequate blood supply to the brain for a long period of time. The disease can be asymptomatic before vascular complications and cerebral blood supply disturbance are caused. The following manifestations are common: neurasthenia syndrome, such as headache, dizziness, fatigue, inattention, hypomnesis, emotional lability, thought retardation, sleep disorder (insomnia or somnolence), etc., and fluctuation of disease condition; carotid atherosclerosis, occasionally TIA, can occur as if angina pectoris due to coronary arteriosclerosis, intermittent claudication of lower extremity atherosclerosis, and transient ischemic brain syndrome due to chronic cerebral insufficiency. The foreign scholars regard angina as a clinical symptom of coronary arteriosclerosis and TIA (except for cardiogenic) as a clinical symptom of cerebral arteriosclerosis. Fundus arteriosclerosis: the arteries become thin, the reflection is enhanced, and the severe ones are silver-silk-shaped and the crossed impression of arteries and veins. Positive metacarpal and mental reflex and sucking reflex, and can leave behind cerebral nerve damage, hemiplegia, hemiparesis, dysesthesia and other positioning signs

Whether patients with cerebral arteriosclerosis can take medicine regularly or not is the key to successful treatment. At present, the current situation and the main problems of the prevention and control of cerebral arteriosclerosis are as follows: for the health management sector: data can not be interconnected and communicated with patients, and supervision is difficult. For the patient: it is difficult to communicate timely with the health management department.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention aims to provide a cloud platform system and an intelligent medicine box, which ensure that a patient follows to take medicine through the cooperative cooperation of a health management department, the patient and the intelligent medicine box.

In order to achieve the purpose, the invention provides a cloud platform system which comprises a health management department, a patient terminal and an intelligent medicine box which are linked through a network, wherein the health management department terminal, the patient terminal and the intelligent medicine box are all provided with application programs; the patient checks the re-diagnosis plan and the follow-up plan by using the configured application program, reports the medicine taking effect, controls the pronunciation equipment to pronounce according to the medicine taking schedule, and controls, prepares and displays the medicines and the dosage of the medicines at the corresponding medicine taking time; the intelligent medicine box running application program regularly reminds a patient to take medicine according to the medicine taking schedule, and the application program configured by the intelligent medicine box also comprises a digital certificate authentication module which determines whether to open a medicine box cover according to an external digital certificate identification result of the patient or a caregiver.

Preferably, the health management department terminal comprises at least a physician terminal, a pharmacy terminal and an information management terminal, wherein the physician terminal is provided with an application program which comprises a patient treatment scheme making module, a medicine taking plan module, a patient follow-up visit plan making module, a re-diagnosis plan making module and a patient distribution to supervision authorities module, wherein the patient treatment scheme making module, the medicine taking plan module, the patient follow-up visit plan making module, the patient symptom making module, the detection data making module, the patient symptom determining module, the treatment scheme and the prescription making module are configured to record the patient symptoms, the detection data making module makes a detection sheet, the patient symptom is; the follow-up patient planning module is configured to determine a follow-up plan according to patient symptoms; the re-diagnosis plan making module determines a re-diagnosis plan and a prescription according to the symptoms of the patient; the terminal for the pharmacy receives the prescription of the doctor and distributes the cerebral arteriosclerosis medicines to the electronic intelligent medicine box according to the prescription medicine distribution equipment.

Preferably, the patient terminal is configured with an application program which comprises a patient module at least comprising a medicine taking module and a backlog module, wherein the medicine taking module is configured to be capable of checking a treatment scheme, modifying or checking medicine taking time, reminding a patient to take medicine when the medicine taking time is reached, and reminding the patient to measure blood pressure when the blood pressure time is measured and uploading a blood pressure value; the backlog module is configured to review the review plan and the follow-up plan, depending on whether the follow-up and follow-up modality is accepted for the offer selection.

Preferably, the operation process of the digital authentication module comprises:

after the external digital certificate disk is inserted into the interface of the intelligent medicine box, the password module A and the password module B perform bidirectional identity authentication based on the digital certificate to ensure the validity of a medicine taker; a private key SA of the cryptographic module A and a digital certificate of the cryptographic module B are prestored in the cryptographic module A, and the digital certificate of the cryptographic module B contains a public key PB of the cryptographic module B; the private key SB of the cryptographic module B and the digital certificate of the cryptographic module A are prestored in the cryptographic module B, the digital certificate of the cryptographic module A contains the public key PA of the cryptographic module A, the whole authentication process is considered to be successful only when the bidirectional authentication is successful, if the authentication is unsuccessful, the intelligent medicine box stops working, and if the authentication is successful, the medicine box cover is opened.

Preferably, the bidirectional identity authentication based on the digital certificate performed by the cryptographic module a and the cryptographic module B specifically includes:

step 1: the method comprises the following steps that a random number RA is generated and stored by a password module A, the password module A encrypts the RA by using a pre-stored public key PB of the password module B to obtain an encryption result PB (RA), and the password module A sends PB (RA) to the password module B;

step 2: the password module B decrypts the received PB (RA) by using a pre-stored private key SB of the password module B to obtain a random number RA; the cryptographic module B encrypts RA by using a pre-stored public key PA of the cryptographic module A to obtain an encrypted value PA (RA); the cryptographic module B sends the encrypted value PA (RA) to the cryptographic module A;

and 3, step 3: the password module A decrypts the received PA (RA) by using a pre-stored private key SA of the password module A, compares the PA (RA) decryption result with the RA value stored in the step 3-1, if the PA (RA) decryption result is the same as the RA value, the authentication is passed, the step 3-4 is carried out, and if the PA (RA) decryption result is not the same as the RA value, the authentication is failed;

and 4, step 4: the password module B generates and stores a random number RB, encrypts the RB by using a pre-stored public key PA of the password module A to obtain an encryption result PA (RB), and sends PA (RB) to the password module A;

and 5, step 5: the cipher module A decrypts the received PA (RB) by using a pre-stored private key SA of the cipher module A to obtain a random number RB; the cipher module A encrypts RB by using a pre-stored public key PB of the cipher module B to obtain an encrypted value PB (RB); the cryptographic module B sends the encrypted value PB (RB) to the cryptographic module B;

and 6, step 6: and the password module B decrypts the received PB (RB) by using a pre-stored private key SB of the password module B, compares the decryption result of the PB (RB) with the RB value stored in the steps 3-4, if the decryption result of the PB (RB) is the same with the RB value, the authentication is passed, and otherwise, the authentication fails.

Preferably, the medicine distribution equipment comprises a plurality of medicine distribution mechanisms, each distribution mechanism comprises a rotating shaft, a fixed shaft, a guide shaft and a belt pressing shaft which are arranged in parallel, the rotating shaft, the fixed shaft, the guide shaft and the belt pressing shaft are movably provided with two medicine packaging clamping frames, each clamping frame is provided with a first through hole, a second through hole, a third through hole and a sliding groove along a first direction, a groove is arranged along a second direction, and the first direction is vertical to the second direction; the rotating shaft, the fixed shaft, the guide shaft and the belt pressing shaft are respectively inserted into the first through hole, the second through hole, the third through hole and the sliding groove, the rotating shaft and the fixed shaft are respectively provided with a driving wheel and a driven wheel at the positions of the grooves, the driving wheel is fixed on the rotating shaft, the driven wheel is movably sleeved on the fixed shaft, and the driving wheel and the driven wheel are provided with a transmission belt; the transmission belt is provided with bulges at equal intervals, and the diameter of the through hole of the medicine package is the same as that of the bulges; the guide shaft is inserted into the third through hole, and a support wheel is arranged at the position of the groove; the pressing shaft is inserted into the sliding groove, the pressing wheel is arranged at the position of the groove of the pressing shaft, and the pressing shaft moves in the sliding groove so that the pressing wheel presses the medicine package on the supporting wheel, or a certain gap is kept between the pressing wheel and the supporting wheel, so that the medicine package passes through the gap; the medicine distribution mechanism further comprises a driving mechanism and a belt pressing mechanism, the driving mechanism comprises a first motor and a first transmission mechanism, and the first motor drives the rotating shaft to rotate through the first transmission mechanism, so that the conveying belt carries medicine packages to operate; the belt pressing mechanism comprises a second motor and a second transmission mechanism, and the second motor drives the belt pressing shaft to move in the sliding groove through a second rotating machine, so that the medicine package passes through or does not pass through.

Preferably, each drug dispensing mechanism dispenses a drug, the control system further comprising a sensor for reading drug information of the drug pack; the control system also comprises a metering module, a comparison module and a control module, wherein the metering module is used for metering and distributing the medicine amount distributed by the distribution mechanism according to the information provided by the sensor; the comparison module is used for comparing the dispensed medicine quantity with the medicine quantity recorded in the prescription, and when the dispensed medicine quantity is smaller than the medicine quantity recorded in the prescription, the control module controls the dispensing mechanism to continuously dispense the medicine until the dispensed medicine quantity reaches the medicine quantity recorded in the prescription.

Preferably, the cloud platform system is used for cerebral arteriosclerosis patient management.

In order to achieve the purpose, the invention further provides an intelligent medicine box in the cloud platform system, which comprises a processor, a light-emitting device, a sound device, a medicine box cover driving mechanism and a memory, wherein the memory stores an application program, the processor calls the application program to implement the function of the medicine taking module in the application program, when the medicine taking time is up, control signals are provided for the light-emitting device and the sound device, the light-emitting device converts the displayed light-emitting color to remind a patient to take medicine, and/or control signals are provided for the sound device, a loudspeaker of the sound device broadcasts sound to remind the patient to take medicine, the control signals are provided for an embedded processor of the medicine box to authenticate a user digital certificate, and after the authentication is qualified, the control signals are sent to a box cover control circuit to drive a cover control mechanism to open a box cover, so that the user takes out the medicine to be taken.

Compared with the prior art, the cloud platform system and the electronic intelligent medicine box provided by the invention ensure that the patient follows to take medicine through the cooperative coordination of the health management department, the patient or the caregiver and the intelligent medicine box.

Drawings

FIG. 1 is a schematic diagram of a cloud platform system provided by the present invention;

FIG. 2 is a schematic view of a pharmaceutical package provided by the present invention;

FIG. 3 is a schematic view of the internal structure of a medication dispensing apparatus provided by the present invention;

FIG. 4 is a schematic assembled component view of a medication package holding bracket according to the present invention;

FIG. 5 is a schematic view of an exploded view of a medication package holding bracket according to the present invention;

FIG. 6 is a circuit diagram of a control system of a medication dispensing apparatus provided by the present invention;

FIG. 7 is a block diagram of the control system of the intelligent medicine box provided by the present invention;

FIG. 8 is a block diagram of the present invention providing an external digital certificate tray;

fig. 9 is an input/output circuit diagram provided by the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In describing the present invention, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. The use of the terms "comprises" and/or "comprising," and the like, are intended to specify the presence of stated features, integers, and/or components, but do not preclude the presence or addition of one or more other features, integers, components, and/or groups thereof. The term "and/or" includes any and all combinations of one or more of the associated listed items. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

Fig. 1 is a schematic diagram of a cloud platform system provided by the present invention, and as shown in fig. 1, the cloud platform system provided by the present invention includes a health management department, a server, a patient terminal, and an intelligent medicine box linked via a network, the server is configured with a cloud database, the health management department terminal, the patient terminal, and the intelligent medicine box are all configured with an application program, the health management department uses the system configured by the terminal to make a patient treatment plan, a follow-up visit plan, and a re-diagnosis plan, and uses a medicine distribution device to distribute medicines to the intelligent medicine box according to a prescription, and further sends a medicine taking schedule determined according to the prescription to the patient terminal and the intelligent medicine box; the patient checks the re-diagnosis plan and the follow-up plan by using the configured application program, reports the medicine taking effect, controls the pronunciation equipment to pronounce according to the medicine taking schedule, and controls, prepares and displays the medicines and the dosage of the medicines at the corresponding medicine taking time; the intelligent medicine box running application program regularly reminds a patient to take medicine according to the medicine taking schedule, and the application program configured by the intelligent medicine box also comprises a digital certificate authentication module which determines whether to open a medicine box cover according to an external digital certificate identification result of the patient or a caregiver.

The health management department terminal at least comprises a physician terminal, a pharmacy terminal and an information management terminal, wherein the physician terminal is provided with an application program which comprises a patient treatment scheme making module, a medicine taking plan making module, a patient follow-up visit plan making module, a re-diagnosis plan making module and a patient distribution to supervision organization module, wherein the patient treatment scheme making module, the medicine taking plan making module, the patient follow-up visit plan making module, the patient symptom making module and the patient distribution management organization module are configured to record patient symptoms, issue a detection sheet, determine patient symptoms according to detection data and issue a treatment scheme and a prescription according to the patient symptoms; the follow-up patient planning module is configured to determine a follow-up plan according to patient symptoms; the re-diagnosis plan making module determines a re-diagnosis plan and a prescription according to the symptoms of the patient; the terminal for the pharmacy receives the prescription of the doctor and distributes the cerebral arteriosclerosis medicines to the electronic intelligent medicine box according to the prescription medicine distribution equipment.

In the invention, a terminal for a patient is configured with an application program which comprises a patient module at least comprising a medicine taking module and a backlog module, wherein the medicine taking module is configured to be capable of checking a treatment scheme, modifying or checking medicine taking time, reminding the patient to take medicine when the medicine taking time is reached, and reminding the patient to measure blood pressure when the blood pressure is measured and uploading a blood pressure value; the backlog module is configured to review the review plan and the follow-up plan, depending on whether the follow-up and follow-up modality is accepted for the offer selection.

In the present invention, in order to facilitate spraying of the medicine taking time on the medicine package according to the prescription of the doctor, the medicine for treating cerebral arteriosclerosis is packaged using the package shown in fig. 2.

Fig. 2 is a schematic view of a medicine package provided by the present invention, as shown in fig. 2, the package 100 is used for packaging medicines, and has a rectangular design, positioning holes 101 are equally spaced on two parallel sides, the positioning holes 101 are used for driving the package 100 to operate so as to dispense medicines by an intelligent prescription vending cabinet, and the packages 100 adjacent to each other are connected along a perforation seam 102 to form a string. The package 100 is preferably a single sealed bag joined to each other at a perforated seam 102. The package 100 is preferably painted with the dosing time when one side of the package is marked, coded or otherwise identified to indicate their respective information and the other side of the package is used to dispense the medication. Preferably, all information, such as a name of a medicine, a price, a functional indication, ingredients, properties, specifications, a usage, manufacturing company information, a production date, an expiration date, etc., is encoded using the bar code 102. It should be appreciated that the information described above may be marked with optically readable text in addition to the bar code 102. Preferably, the package 100 may also include information in the form of instructions to facilitate operation of the drug dispensing device. Preferably, the package 100 includes at least a paper layer onto which the dosing time is sprayed and a permeation prevention layer disposed within the paper layer. More preferably, the month, day and hour characters of the administration time are printed on the paper layer of the package in advance, and the figures of the administration time are sprayed by the spraying device, so that the medicine can be dispensed at an accelerated speed without spending much time due to the spraying service time.

Fig. 3 is a schematic diagram of an internal structure of a medicine dispensing device in the cloud platform system, which provides medicines to an intelligent medicine box according to a doctor's prescription. The drug dispensing device allows for monitoring and controlling the dispensing of the drug such that a pharmacist can directly access the drug dispensing device to dispense the drug to the smart cartridge according to the prescription.

The intelligent drug dispensing device has a body with a housing comprising a left side wall, a right side wall, a front panel 11, a rear panel 12, a top panel 13 and a bottom panel 14 defining an internal cavity, the front panel 11 having a door or access panel arranged for pivotal movement about a set of hinges to enable a pharmacist to access the interior of the internal cavity. The interior cavity is divided by partitions into M rows and N columns of rectangular parallelepiped spaces in a direction perpendicular to the base plate 14, each space being provided with a drug dispensing device comprising a housing comprising a left side wall, a right side wall, a front panel 15, a rear panel 16, a top panel 17 and a base plate 18 defining an interior cavity, the left or right side wall of each drug dispensing device having a door or access panel arranged for pivotal movement about a set of hinges to enable access to the interior of the drug dispensing device by authorised personnel. It will be appreciated that the housing and the partition of the medication dispensing apparatus and device may be constructed of any suitable material, such as a plastic or metal material, and further that the housing may be manufactured using any suitable construction method, such as injection molding, stamping, machining, and the like. Desirably, the back panel 12 of the device has an opening through which the power module 26 may be disposed. In the present invention, the medicine dispensing device is formed in a rectangular parallelepiped shape, and the medicine dispensing device is inserted into each rectangular parallelepiped space after the medicine to be dispensed is placed in the medicine dispensing device. The drug dispensing device is connected to the interface on the partition by an interface to provide power and control data to the drug dispensing device.

The housing may be constructed as a single piece of material or otherwise constructed from two or more pieces of material that are connected to one another. The front panel 11 of the device also has an opening 19 through which the pharmacist removes the smart cartridge 25 with the medicine dispensed, the opening 19 being opened or closed by a door. .

As shown in fig. 3, the medication dispensing apparatus is sized to accommodate a medication dispensing mechanism and a plurality of medication packages 100, the packages 100 being wound on spools 22.

Referring again to fig. 3, the drug dispensing apparatus further includes a control system in operative communication with each of the plurality of drug dispensing devices to regulate the plurality of drug dispensing devices to dispense the drug according to the doctor's prescription and deliver the drug to the smart cartridge. The plurality of dispensing devices are identical in composition and each comprise a drug dispensing mechanism 30 disposed within an internal chamber of the dispensing device, each drug dispensing mechanism 30 dispensing a drug to a drug output port 23, the drug having a drug package 100 as shown in figure 2. Each dispensing mechanism 30 is driven by a drive mechanism comprising a motor M2 (not shown in fig. 3) and a drug delivery mechanism 32, the motor M2 having a shaft with a drive member, such as a drive gear having a predetermined number of radially outwardly extending teeth. The motor M2 drives the rotary shaft 33 to rotate via the drug delivery mechanism 32, thereby causing the conveyor belt 42 to run the drug-loaded package 100.

As shown in fig. 3, the drug dispensing device has a chamber 24 for capturing the drug packages 100. The chamber 24 is defined by the front panel 11 of the medication dispensing apparatus, the front panels 15 of the plurality of medication dispensing devices and the left and right side walls of the medication dispensing apparatus.

As shown in fig. 3, the medicine dispensing mechanism 30 includes a rotating shaft 33 and a fixed shaft 34 which are arranged in parallel, the rotating shaft 33 and the fixed shaft 34 are movably provided with two medicine package holders 200, the two medicine package holders 200 are used for holding two sides of the medicine package 100, so that the medicine located in the middle is not damaged, and the information on the upper side of the medicine package is readable, and the medicine taking time can be sprayed from the lower side.

FIG. 4 is a schematic assembled component view of a medication package holding bracket according to the present invention; fig. 5 is an exploded view of the medication package holding bracket provided by the present invention. As shown in fig. 4 to 5, each holder 200 is provided with a first through-hole 201 and a second through-hole 202 in a first direction (axial direction of the rotary shaft 33), and a groove 203 in a second direction (axial direction perpendicular to the rotary shaft), the first direction and the second direction being perpendicular; the rotating shaft 33 is disposed in the first through hole 201 through a bearing, which can rotate in the bearing; the fixed shaft 34 is inserted into the second through hole 202, the rotating shaft 33 and the fixed shaft 34 are respectively provided with a driving wheel 35 and a driven wheel 36 at the position of the groove 203, the driving wheel 35 is fixed on the rotating shaft 33 through a mounting pad 220, the rotating shaft 33 rotates, and the driving wheels rotate in the same speed and the same direction. The driven wheel 36 is movably fitted on the fixed shaft 34 via a rotation wheel 221, the driven wheel 36 is fixedly connected with the rotation wheel 221, and the driven wheel 36 and the rotation wheel 221 rotate around the fixed shaft 34. The driving pulley 35 and the driven pulley 36 are connected by a transmission belt 42. Preferably, the driving belt 42 is provided with protrusions 43 at equal intervals, the diameter of the positioning holes of the medicine packages is the same as that of the protrusions 43, and the pitch of the positioning holes of the medicine packages 100 is the same as that of the protrusions.

According to an embodiment of the present invention, the holding frames 200 are further provided with locking devices 204, and after the medicine packages 100 are fixed on the two holding frames 200, the locking devices 204 fix the holding frames 200 on the fixing shaft 34.

According to an embodiment of the present invention, the clamping frame 200 is further provided with a third through hole 205 and a sliding slot 206, the dispensing mechanism further comprises a guide shaft 37 and a pinch shaft 39 which are arranged in parallel, the guide shaft 37 is inserted into the third through hole 205, a support wheel 38 is arranged at the position of the groove 203, the support wheel 38 is arranged on the guide shaft 37 through a mounting pad 219, and the guide shaft is fixed on the clamping frame; the tape pressing shaft 39 is inserted into the sliding groove 206, the tape pressing shaft 39 is provided with the tape pressing wheel 40 at the position of the groove 203, the tape pressing wheel 40 is arranged on the tape pressing shaft 37 through a mounting pad 218, and the tape pressing mechanism can drive the tape pressing shaft to move in the sliding groove 206 so that the tape pressing wheel 40 presses the medicine package on the supporting wheel 38 or a certain gap is kept between the tape pressing wheel 40 and the supporting wheel 38, so that the medicine package 100 passes through the gap.

Preferably, the distance between the fixed shaft 34 and the rotating shaft 33 is a first distance which is less than or equal to the length of one medicine package in the conveying direction of the conveyor belt 42, and the distance between the rotating shaft 33 and the guide shaft 37 is a second distance which is less than the first distance.

Preferably, the holder 200 includes a first plate 207 and a second plate 209 axially disposed along the fixed shaft 34 and extending in a direction perpendicular to the fixed shaft 34, with a groove 203 formed between the first plate 207 and the second plate 209. The first plate 207 is provided with a third plate 208 arranged perpendicularly thereto, the third plate extending in a direction perpendicular to the fixed shaft 34; the second plate 209 is provided with a fourth plate 210 arranged perpendicularly thereto, the fourth plate 210 extending in a direction perpendicular to the fixed shaft 34;

rectangular notches

212 and 213 are respectively arranged on two opposite sides of the third plate 208 and the fourth plate 210, when the third plate 208 and the fourth plate 210 are spliced together, the two rectangular notches form a first through hole 214, and the protrusions 43 on the transmission belt 42 extend out of the through holes 214. The fourth plate 210 has an "L" shape, and a fifth plate 211 extending in a third direction (perpendicular to the first direction and the second direction) is disposed at one end of the fourth plate 211, and a sliding groove 206 is disposed on the fifth plate 211.

According to the present invention, the holder 200 further includes a tape pressing plate 215, the tape pressing plate 215 is provided with a second through hole 216 corresponding to the first through hole 214 along the second direction, the tape pressing plate 215 and the fourth plate 210 are connected by a rotating mechanism 217, the tape pressing plate 215 holds the medicine package when in the open position, and the tape pressing plate 215, the third plate 208 and the fourth plate 210 clamp the edge of the medicine package 100 when in the closed position.

According to the present invention, the medicine dispensing mechanism further comprises a tape pressing mechanism including a motor M1 and a transmission mechanism 58, wherein the motor M1 drives the tape pressing shaft 39 to move on the chute 206 through the rotation mechanism 58, so that the tape pressing wheel 40 presses the medicine package 100 against the supporting wheel 38, or a gap is maintained between the tape pressing wheel 40 and the supporting wheel, so that the medicine package 100 passes through the gap. The motor M1 has a shaft with a drive member, such as represented by a drive gear having a predetermined number of radially outwardly extending teeth. One end of the tape pressing shaft 39 is provided with a rotating wheel having a predetermined number of teeth extending radially outward, the rotating wheel being directly engaged with the driving member.

According to one embodiment of the invention, the drug dispenser mechanism 30 further comprises a spray device disposed above or below the dispensing mechanism and interposed between the two belts 42 of the two gripper blocks 200. Preferably, the dispensing mechanism 30 further includes a fixing shaft (not shown), and the holder is further provided with a fifth through hole (not shown) in the first direction, and the fixing shaft is inserted into the fifth through hole; the spraying equipment at least comprises a spray head and a spray head driving mechanism, the spray head driving mechanism drives the spray head to move along the axial direction of the fixed shaft, and the control system controls the spraying equipment to spray the medicine taking time on the medicine package 100 while driving the distribution mechanism 30 to distribute the medicine package.

When the medicine package is installed, the pressing plates 215 of the two clamping frames are lifted, the first package of the string of medicine packages 100 passes through a gap formed between the pressing shaft 39 and the guide shaft 37 between the two package clamping frames 200, through holes on two sides of the package 100 are arranged on the bulges 43 on the conveying belts 42 of the two clamping frames 200, then the pressing plates 215 are put down, so that the clamping frames are fixed on the fixed shaft 34 through the locking devices 204, the medicine package string is fixed, and the medicine is dispensed by waiting for the command of the control system.

In the present invention, a sensor 41 is provided above the dispensing mechanism for reading information on the pharmaceutical product package 100, from which information the dose dispensed by the dispensing mechanism 30 can be metered.

Fig. 6 is a circuit diagram of a control system of a drug dispensing device according to the present invention, which comprises a controller 51, such as a CPU, as shown in fig. 6. The control system also includes an input output interface 52 for connection to a pharmacy control terminal. The control system also includes a touch screen display 53 for displaying information and for user input such as prescription, drug name, price, indications of function, ingredients, properties, specifications, usage, manufacturing enterprise information, date of manufacture, expiration date, etc. The control system also includes a communication subsystem 54 for wirelessly connecting with the pharmacy terminal. The control system further comprises a near field matching circuit 55 for linking the drug dispensing with the pharmacist's handheld terminal via a near field protocol. The control system further has a memory 50 for storing application programs and data, the CPU calls the programs to form a dispensing module configured to control the drug dispensing mechanism to dispense drugs to the smart cartridges according to the prescription; a spray module configured to spray a dosing time on the pharmaceutical packaging during dispensing of the pharmaceutical.

More specifically, as shown in fig. 6, the control system further includes a medicine dispensing mechanism controller including a motor driver 64, a motor driver 65 and a sensor 41, the processor control module sends signals to the motor driver 64 and the motor driver 65, calculates the medicine taking dose and the medicine taking time of each medicine according to the prescription, the CPU sends a control signal to the motor driver 65, so that the motor M1 drives the belt pressing mechanism 58 to operate, the belt pressing mechanism 58 drives the belt pressing shaft 39 to operate in the chute 206 to drive the belt pressing wheel 40 to move away from the support wheel 38, and a gap is formed between the belt pressing wheel 40 and the support wheel 38; meanwhile, the motor driver 64 sends a driving signal to the motor M2, the motor M2 drives the medicine conveying mechanism 32 to rotate, so that the driving wheel 35 rotates together, the conveying belt 42 drives the driven wheel 36 to rotate and drives the medicine packages 100 to operate, when the carried medicine packages operate to a proper position, the medicine conveying mechanism stops rotating, the spraying module enables the spraying mechanism to operate, namely, a control signal is sent to the motor driver 57, the motor M4 operates, the spraying heads of the spraying mechanism 66 are driven to spray one line of information on each medicine package, then, the motor M4 stops operating, the driving mechanism stops operating after carrying the medicine for a set time, the spraying heads of the spraying mechanism 66 are driven to spray one line of information on each medicine package, and the steps are repeated to spray the medicine taking time on the medicine packages. In the invention, the medicine taking time is sprayed on one surface of the medicine package. The sensor 41 detects the amount of the delivered medicine, and sends the measured information to the processor 51 for measurement, the dispensed amount is compared with the amount to be taken according to the prescription, when the prescribed amount is reached, a control signal is sent to the motor driver 65, so that the motor M1 drives the belt pressing mechanism 58 to operate, the belt pressing mechanism 58 drives the belt pressing shaft 39 to operate in the chute, so as to drive the belt pressing wheel 40 to be close to the supporting wheel 38, the belt pressing wheel 40 is in contact with the supporting wheel 38, and two sides of the medicine package at the rear in the string of medicine packages 100 are pressed tightly; meanwhile, the motor driver 64 sends a driving signal to the motor M2, the motor M2 continues to drive the medicine conveying mechanism 32 to rotate, the driving wheel 35 rotates together, the conveying belt 42 drives the driven wheel 36 to continue rotating and drives the front-side medicine package 100 to continue to run for a set time, and the front-side medicine package 100 continues to run because the rear-side package 100 of the adjacent medicine package 100 is pressed, so that the front-side package 100 is torn from the joint 101. The leading medication package 100 falls from the outlet 23 into the medication basket 63 of the medication basket delivery mechanism.

The control system further comprises a gate controller comprising a motor driver 59 and a sensor 61, the motor driver 59 being arranged to provide a drive signal to a motor M3 for driving operation of the gate control mechanism, the CPU being programmed to form a gate control module arranged to send a signal to the motor driver 59, the gate control module sending a control signal to the motor driver 59 after the processor 51 controls the dispensing mechanism to dispense a medicament into the cavity 24, the motor driver 59 sending a drive signal to motor M3, motor M3 driving the gate control mechanism 60 to open the door to the opening 19; after the sensor 61 detects that the medicine is taken away, the door control module sends a control signal to the motor driver 59 according to the information provided by the sensor 61, the motor driver 59 sends a driving signal to the motor M3, and the motor M3 drives the door control mechanism to close the door opening 19.

In the present invention, the sensor 41 communicates with the CPU to determine that the bar code 102, text or other readable information, is in a readable position. If the bar code 102, text or other readable information is not in a readable position, the CPU sends a control signal through the control motor driver 64 to drive the motor M2 to operate. The motor M2 then rotates in forward and reverse until the barcode 102 and/or text are in a readable position. The motor M2 is rotated in forward and reverse for a predetermined programmed amount of time. If after the time has elapsed, the barcode 102 and/or text remains unreadable, the drug dispensing device will notify the pharmacist that the package 100 is either empty or that there is a problem.

In accordance with the present invention, the medication dispensing apparatus may dispense any unreadable package 100 into the chamber 24 and attempt to read the next available package 100.

When the sensor 41 reads information from the text and/or barcode 102, the CPU communicates with the touch screen display 53 to visually display information about the medication within the medication package. After the drug dispensing device has dispensed the drug purchased by the user, the pharmacist is notified, for example by flashing a light bulb or touching the display 53.

Fig. 7 is a block diagram of a control system of an intelligent medicine box provided by the present invention, and as shown in fig. 7, the control system of the intelligent medicine box includes a CPU323, a main memory 315, a bridge device 314, an embedded processor 310, and a USB connector 320. The CPU323 is a processor that manages operation control of the intelligent cartridge and executes various programs loaded into the main memory 315. The various programs include an operating system OS that performs resource management of the smart cartridge, a driver that runs an application under the control of the OS, and a driver that performs operation control of various devices as hardware from software. The bridge circuit 314 is a device that relays reception and transmission of data performed between the CPU323, the main memory 315, and various devices. The embedded processor 310 is used to send the operation of the keyboard and pointing device to the CPU 323. The embedded processor 310 includes a function of starting/stopping the smart pill box in response to the on/off operation of the power button. In the invention, the CPU323 is connected with the main memory 315, the light-emitting device 321, the sound device 322, the communication subsystem 324 and the near field matching circuit 325 through the bridging device 314, the CUP323 application program further operates the light-emitting device 321 and the sound device 322, so that when the medicine taking time is reached, the patient is reminded of the medicine taking time by emitting light and sound, the corresponding medicine box is opened according to whether the password input by the patient on the external digital certificate disk is qualified or not, and when the password is successfully verified, the medicine box cover is opened, so that the patient takes out the medicine and takes the taken medicine. The sub-system 324 is used for remote communication between the intelligent medicine box and the patient terminal, the supervisor terminal, the health management department terminal, the disease control mechanism terminal and the like, and the near field matching circuit 325 is used for matching connection between the intelligent medicine box and the patient terminal, the supervisor terminal and the like through a near field protocol.

The control system of the smart medicine box further includes an input/output control circuit 311, a power supply circuit 318, a battery 317, a charging circuit 312, wherein a power supply line VBUS connected to the USB connector 320 is continued to the input/output control circuit 311. The input-output control circuit 311 is a switching circuit exclusively performing output of electric power to and input of electric power from the USB power line. The battery 317 is a secondary battery capable of repeated charge and discharge. The charging circuit 312 is a circuit that charges the battery 317 by using power input from the USB power line. When the smart medicine box is connected to the external power source, the power of the external power source is input to the charging circuit 317, and the charging circuit 312 charges the battery 18. Power supply circuit 318 outputs power from battery 317 to the circuitry of the intelligent pill box modules, circuits and devices.

The control system of the intelligent medicine box also comprises a password module B which is connected with the embedded processor 313 and is used for prestoring a public key and a private key.

According to one embodiment, the cartridge is preferably made of food grade material that is resistant to mold, moisture and contamination.

Fig. 8 is a block diagram of a control system of an external digital certificate tray provided by the present invention, and as shown in fig. 3, the control system of the external digital certificate tray includes a bridge device 414, an embedded processor 410, a USB connector 417, an input/output control circuit 411, a charging circuit 412, a battery 415, and a power supply circuit 416, where the embedded processor 410 is connected to the embedded processor 310 of the intelligent medicine box via a data line of the bridge device 410 and the USB connector 417, and the bridge device 314 of the intelligent medicine box. The input-output control circuit 411 is a switching circuit that exclusively performs output of electric power to and input of electric power from the USB power line. The battery 415 is a secondary battery capable of repeated charging and discharging. The charging circuit 412 is a circuit that charges the battery 415 by using power input from the USB power line. When the external digital certificate tray is connected with the smart medicine box, electric energy is input to the charging circuit 412, and the charging circuit 412 charges the battery 415. The power supply circuit 416 generates power from the battery 415 to be output to the modules and circuits of the external digital certificate tray.

The external digital certificate disk further comprises a cryptographic module a, which is connected to the embedded processor 411 and is used for prestoring a public key and a private key.

Fig. 8 is an exemplary diagram showing the structure of the input/output control circuit. The input/

output control circuits

411 and 311 have the same configuration, and the input/output control circuit 411 will be described as an example. As shown in fig. 8, the input/output control circuit 311 includes two

bus switches

161 and 162, and two backflow prevention circuits (diodes) D1 and D2. The bus switch 161 is provided on a power supply line in the input/output control circuit 311 to direct power generated by the power supply circuit 31 to the USB power supply line and to turn on or off the power supply line based on a control signal supplied from the embedded processor 310. A diode D1 to prevent reverse flow is provided at the output of the bus switch 161. In addition, the bus switch 162 is provided on a power supply line arranged in the input/output control circuit 311 to lead power input from the USB power supply line to the charging circuit 312, and to disconnect or cut off the power supply line based on a control signal (which is different from the control signal input to the bus switch 161) supplied from the embedded processor 310. A back flow prevention diode D2 is provided at the output of the bus switch 162. The input/output control circuit 311 forms a path from the power supply circuit 318 to the USB interface 320, the USB interface 417, the input/output control circuit 411 to the charging circuit 412, as indicated by arrows.

The working principle of the external digital certificate tray connected to the intelligent medicine box is explained below. When the external digital certificate disk is connected to the USB connector 320 of the intelligent medicine box, the USB data lines D + and D-connect the intelligent medicine box, so the bridge circuit 314 senses that the external digital certificate disk is connected to the USB connector 320. The bridge circuit 314, which has sensed that the external digital certificate tray is connected to the USB connector 320, generates an interrupt signal and sends it to the CPU 323. Thus, the OS in the main memory 315 recognizes that the external digital certificate tray is connected to the USB connector 320. Firstly, an instruction is sent to the embedded processor 310 to drive and control the input/output control circuit 311, so that the bus switch 161 is turned off, the bus switch 162 is turned on, and the intelligent medicine box provides electric energy for the external digital certificate tray. Then, an instruction is sent to the embedded processor 310 to perform digital certificate authentication (the authentication process is described later) with the external digital certificate disk, and after the authentication is qualified, the medicine box cover is opened to allow the patient to take the medicine.

In the invention, the process of authenticating the digital certificate module of the intelligent medicine box specifically comprises the following steps:

after the external digital certificate disk is inserted into the interface of the intelligent medicine box, the password module A and the password module B perform bidirectional identity authentication based on the digital certificate to ensure the validity of a medicine taker; a private key SA of the cryptographic module A and a digital certificate of the cryptographic module B are prestored in the cryptographic module A, and the digital certificate of the cryptographic module B contains a public key PB of the cryptographic module B; prestore cryptographic module B's private key SB and cryptographic module A's digital certificate in cryptographic module B, contain cryptographic module A's public key PA in cryptographic module A's the digital certificate, only when mutual authentication is all successful, just think whole authentication process is successful, if the authentication is unsuccessful, then medicine dispensing equipment reports to the police and safe intelligent medicine box stop work, if the authentication is successful, then opens the medicine box lid, specifically includes:

To achieve the above object, the present invention further provides a computer program that programs the above method into executable program code using a computer language. The present invention also provides a storage medium for storing the computer program, the storage medium including a network disk, an optical disk, and the like.

The cloud management platform system and the intelligent medicine box provided by the invention ensure that the patient can take medicine according to the compliance through the cooperative cooperation of the health management department, the patient and the intelligent medicine box, and the patient can follow up the visit and the return visit in time. Mainly used for the management of cerebral arteriosclerosis and/or patients thereof.

In the invention, after the operations of intervention, replacement, transplantation and the like, the rejection resistance, the thrombus agglomeration resistance and the like are mainly monitored, and the prescription is adjusted according to the monitoring result.

In the invention, after the patient takes the medicine for a period of time in compliance, the following steps are carried out on the patient at the time of patient re-diagnosis: drug metabolism genome detection, blood concentration monitoring, key index monitoring and/or drug resistance detection to evaluate the treatment effect of the patient, and adjusting the prescription according to the detection result.

The drug metabolism genome detection is to detect drug metabolizing enzyme and drug action target gene of a patient by utilizing the known genomics theory. If the variation of the drug enzymes in drug metabolism occurs, the significant change of the blood concentration can be caused, thereby changing the pharmacokinetics and pharmacodynamics of the drug. The individual difference of the patient to the medicine can be accurately judged through the medicine gene detection. The drug effect, toxicity and other reactions of drug metabolizing enzyme and action target spot in the patient to the drug are predicted, so that the drug testing is avoided at the cost of the body, and accurate individual drug use is realized.

The blood concentration monitoring is to monitor the blood concentration of a patient with chronic diseases after taking the medicine, guide the clinical selection of the optimal treatment scheme and the optimal treatment dosage suitable for different individuals, and realize the reasonable medication guidance of the patient. The blood concentration refers to the total concentration of the drug in the plasma after absorption, and includes drugs bound to plasma proteins or free in the plasma, and sometimes also refers to the concentration of the drug in whole blood. The intensity of the drug action is proportional to the concentration of the drug in the plasma, which varies with time in vivo. The phenomenon is often found in clinical practice, the medicine with the same dosage is used for different patients suffering from the same diseases, the curative effect is very different, and some patients are just cured by the medicine; some curative effects are common, and the disease condition is slightly improved; some have poor curative effect. The toxic and side effects of the traditional Chinese medicine are different in manifestation, and some of the traditional Chinese medicine have few side effects or are slight; some are severely poisoned. This is because there are individual differences (age, sex, body condition, heredity, race, etc.). Different people have large variation of effective drug dosage, but small variation of safe and effective blood concentration. Generally, the ratio is about 1 time. When the blood concentration is higher than the safe and effective range, the toxic and side effects, the expression and the degree of the toxic and side effects are less changed in different patients.

The key index monitoring of chronic diseases is to realize the evaluation of patients after taking medicines for treatment by monitoring vital sign indexes, biochemical detection indexes and image indexes of different chronic patients.

The drug resistance detection is to detect the drug resistance of antibiotics (also called drug resistance) when aiming at acute complications, select a reasonable treatment scheme and reasonable medicine application and avoid the complications causing more than two chronic diseases.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims

1. A cloud platform system comprises a health management department, a patient terminal and an intelligent medicine box which are linked through a network, wherein the health management department terminal, the patient terminal and the intelligent medicine box are all configured with application programs; the patient checks the re-diagnosis plan and the follow-up plan by using the configured application program, reports the medicine taking effect, controls the pronunciation equipment to pronounce according to the medicine taking schedule, and controls, prepares and displays the medicines and the dosage of the medicines at the corresponding medicine taking time; the intelligent medicine box running application program regularly reminds a patient to take medicine according to the medicine taking schedule, and the application program configured by the intelligent medicine box also comprises a digital certificate authentication module which determines whether to open a medicine box cover according to an external digital certificate identification result of the patient or a caregiver.

2. The cloud platform system of claim 1, wherein the health management terminal comprises at least a physician terminal and a pharmacy terminal and an information management terminal, the physician terminal is configured with an application program which comprises a patient treatment plan making module, a medicine taking plan making module, a patient follow-up plan making module, a re-diagnosis plan making module and a patient distribution to supervision authorities module, wherein the patient treatment plan making module, the medicine taking plan making module is configured to record patient symptoms, issue a detection sheet, determine patient symptoms according to detection data, issue a treatment plan and a prescription according to the patient symptoms; the follow-up patient planning module is configured to determine a follow-up plan according to patient symptoms; the re-diagnosis plan making module determines a re-diagnosis plan and a prescription according to the symptoms of the patient; the terminal for the pharmacy receives the prescription of the doctor and distributes the cerebral arteriosclerosis medicines to the electronic intelligent medicine box according to the prescription medicine distribution equipment.

3. The cloud platform system of claim 2, wherein the patient terminal is configured with an application program comprising a patient module including at least a medication taking module and a backlog module, the medication taking module is configured to view a treatment plan, modify or view medication taking time, remind a patient to take medication by the medication taking time, remind a patient to measure blood pressure by the blood pressure measuring time, and upload a blood pressure value; the backlog module is configured to review the review plan and the follow-up plan, depending on whether the follow-up and follow-up modality is accepted for the offer selection.

4. The cloud platform system of any of claims 1-3, wherein the digital authentication module is operable to:

5. The cloud platform system of claims 1-4, wherein the cryptographic module A and the cryptographic module B performing digital certificate-based two-way identity authentication specifically comprises:

6. The cloud platform system of claim 5, wherein the medicine dispensing device comprises a plurality of medicine dispensing mechanisms, each of the medicine dispensing mechanisms comprises a rotating shaft, a fixed shaft, a guide shaft and a belt pressing shaft which are arranged in parallel, two medicine package clamping frames are movably arranged on the rotating shaft, the fixed shaft, the guide shaft and the belt pressing shaft, each clamping frame is provided with a first through hole, a second through hole, a third through hole and a sliding groove along a first direction, a groove is arranged along a second direction, and the first direction is perpendicular to the second direction; the rotating shaft, the fixed shaft, the guide shaft and the belt pressing shaft are respectively inserted into the first through hole, the second through hole, the third through hole and the sliding groove, the rotating shaft and the fixed shaft are respectively provided with a driving wheel and a driven wheel at the positions of the grooves, the driving wheel is fixed on the rotating shaft, the driven wheel is movably sleeved on the fixed shaft, and the driving wheel and the driven wheel are provided with a transmission belt; the transmission belt is provided with bulges at equal intervals, and the diameter of the through hole of the medicine package is the same as that of the bulges; the guide shaft is inserted into the third through hole, and a support wheel is arranged at the position of the groove; the pressing shaft is inserted into the sliding groove, the pressing wheel is arranged at the position of the groove of the pressing shaft, and the pressing shaft moves in the sliding groove so that the pressing wheel presses the medicine package on the supporting wheel, or a certain gap is kept between the pressing wheel and the supporting wheel, so that the medicine package passes through the gap; the medicine distribution mechanism further comprises a driving mechanism and a belt pressing mechanism, the driving mechanism comprises a first motor and a first transmission mechanism, and the first motor drives the rotating shaft to rotate through the first transmission mechanism, so that the conveying belt carries medicine packages to operate; the belt pressing mechanism comprises a second motor and a second transmission mechanism, and the second motor drives the belt pressing shaft to move in the sliding groove through a second rotating machine, so that the medicine package passes through or does not pass through.

7. The cloud platform system of claim 6, wherein each drug dispensing mechanism dispenses a drug, the control system further comprising a sensor for reading drug information of the drug package; the control system also comprises a metering module, a comparison module and a control module, wherein the metering module is used for metering and distributing the medicine amount distributed by the distribution mechanism according to the information provided by the sensor; the comparison module is used for comparing the dispensed medicine quantity with the medicine quantity recorded in the prescription, and when the dispensed medicine quantity is smaller than the medicine quantity recorded in the prescription, the control module controls the dispensing mechanism to continuously dispense the medicine until the dispensed medicine quantity reaches the medicine quantity recorded in the prescription.

8. The cloud platform system of any of claims 1-7, being for cerebral arteriosclerotic disease and/or patient management thereof.

9. An intelligent medicine box in the cloud platform system of claims 1-8, comprising a processor, a light-emitting device, a sound device, a box cover driving mechanism, and a memory, wherein the memory stores an application program, the processor calls the application program to implement the function of the medicine taking module, when the medicine taking time is up, the processor provides control signals to the light-emitting device and the sound device, the light-emitting device and the sound device convert the displayed light-emitting color to remind the patient to take medicine, and/or provides control signals to the sound device, the speaker of the sound device broadcasts sound to remind the patient to take medicine, the embedded processor of the medicine box provides control signals to authenticate the user digital certificate, and after the authentication is passed, the control signals are sent to the box cover control circuit to drive the cover control mechanism to open the box cover, so that the user takes out the medicine to be taken and takes the medicine.