CN112258109B - Safe and efficient intelligent anesthesia medicine distribution charging method and system - Google Patents

Abstract

The invention discloses a safe and efficient intelligent anesthesia medicine delivery charging method and system. The method comprises the following steps: inputting first data information and performing pre-verification; searching and verifying the first data information; selecting the name, the quantity and the usage of the needed anesthetic drugs in a preset selection questionnaire and packaging the information into second data information; verifying the second data information according to a preset verification model and generating a medicine use risk probability, if the second data information is within a set threshold value range, passing the verification and returning a serial number with an anti-counterfeiting label; obtaining a driving signal according to the serial number; controlling the conveying mechanism to automatically send out the medicines according to the driving signal, sending fee deduction information to a hospital charging system for fee deduction, and feeding back fee deduction success information to the printing module after fee deduction is finished; the first data information and the second data information are synchronized to the anesthesia recording system while the automatic dispensing of the medication is successful. The invention is beneficial to the management and charging of the anesthetic.

Description

Safe and efficient intelligent anesthesia medicine distribution charging method and system

Technical Field

The invention relates to the field of medical systems, in particular to a safe and efficient intelligent anesthesia medicine delivery charging method and system.

Background

In the anesthesia department of a hospital, the conventional method for getting the anesthetic is relatively disordered, a patient or a family member of the patient directly goes to a pharmacy to get the anesthetic, or directly gets the drug in the anesthesia department, so that the management of the anesthetic is easy to be disordered, and the phenomena of multi-charge, wrong charge and charge leakage are easy to occur; meanwhile, if the medicines in a storage area at 4 ℃ are required to be taken out in advance and placed in a thermostatic chamber of an operation room at present, the medicines are degraded and the medicine efficacy is reduced. Therefore, there is a need to develop a safe and efficient intelligent anesthesia medicine delivery charging method and system.

Disclosure of Invention

The invention aims to provide a safe and efficient intelligent anesthesia medicine delivery charging system to overcome the defects in the prior art.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows:

a safe and efficient intelligent anesthesia medicine delivery charging method comprises the following steps:

the method comprises the steps that first data information is input through an input module and pre-verified, and the first data information is sent to a first verification module after the pre-verification is passed, wherein the first data information at least comprises a job number, a password, a patient name and a hospitalization number of an anesthesia department doctor;

the first verification module searches and verifies the first data information in a verification database, returns verification passing information if the first data information passes the verification, returns verification error information if the first data information does not pass the verification, and stores the verification error information in a feedback database in the form of an information feedback table;

selecting the name, the quantity and the usage of the needed anesthetic drugs in a preset selection questionnaire through a selection module, packaging the information into second data information, and sending the second data information to a second verification module;

the second verification module verifies the second data information according to a preset verification model to generate a medicine use risk probability, if the medicine use risk probability is within a set threshold value range, the verification is passed and a serial number with an anti-counterfeiting label is returned, otherwise, the verification fails to prompt that an error exists;

inputting the serial number with the anti-counterfeiting label into a preset driving model for comparison to obtain a driving signal;

the corresponding amount of medicines are automatically sent out by controlling the conveying mechanism through a driving signal, meanwhile, fee deduction information is sent to a hospital charging system through a fee deduction module for fee deduction, fee deduction success information is fed back to the printing module after fee deduction is completed, and the fee deduction information comprises medicine fee deduction amount and a patient hospitalization number;

the first data information and the second data information are synchronized to the anesthesia recording system while the delivery mechanism is successfully delivering the drug automatically.

Further, the step of performing pre-verification on the first data information specifically includes: and carrying out format verification and verification on the first data information, and carrying out pre-verification on the first data information by capturing an information feedback table in a feedback database of the cloud platform.

Further, the specific steps of the first verification module searching and verifying the first data information in the verification database are as follows:

verifying the work number password of the anesthesia department doctor, if the work number password passes the verification, continuing to execute the verification, otherwise, returning feedback information of the error of the work number password, and storing the work number password which fails in the verification in a database;

and verifying whether the patient name and the hospitalization number exist in a medical record system of the hospital, if so, verifying the first data information and continuing to execute, otherwise, returning feedback information that the patient name or the hospitalization number does not exist, and storing the patient name or the hospitalization number which fails in verification in a database.

Further, the preset step of establishing the selected questionnaire comprises the following steps:

when the system is established for the first time, the anesthetic drugs are sequenced according to the sequence of the use frequency in the hospital in unit time to form a selection questionnaire, and the selection questionnaire is sent to all automatic drug-dispensing cabinets;

and updating the selection questionnaire of the automatic dispensing cabinet within a set time according to the anesthetic use frequency of the single automatic dispensing cabinet.

Further, the preset verification model is established by the following steps:

establishing corresponding relations between the name of each medicine and the type of applicable diseases, the number of the medicines, the limited dosage of patients and the usage and the standard usage to form a pre-model;

importing the patient illness condition corresponding to the patient name and the hospitalization number into the pre-model to form a verification model;

after the verification model is established, the name, the quantity and the usage of the anesthetic in the second data information are led into the verification model for comparison, and the drug use risk probability of the anesthetic is calculated according to a risk evaluation algorithm in the verification model.

Further, the preset driving model is established by the following steps:

numbering each medicine storage area of each automatic medicine dispensing cabinet, numbering the medicine storage areas in each medicine storage area, and numbering the medicine storage units in each medicine storage area;

establishing a one-to-one correspondence between each medicine storage unit and the medicine name;

establishing a one-to-one corresponding relation between each medicine storage unit and a conveying mechanism for driving the medicines in the medicine storage units to act so as to form a driving model;

and returning the serial number with the anti-counterfeiting label after the second verification module passes the verification, wherein the serial number is consistent with the serial number of the medicine storage unit, and the medicine storage unit corresponding to the serial number is obtained when the serial number of the anti-counterfeiting label is input into the driving model so as to generate a driving signal for driving a driving mechanism of the medicine storage unit to act.

Further, the synchronizing of the second data information into the anesthesia recording system while the delivery mechanism is successfully delivering the drug automatically further comprises: if the used ampoule is not shot by the camera module within a set time, alarm information is sent out in the anesthesia recording system.

The invention also provides a system for realizing the safe and efficient intelligent anesthesia medicine delivery charging method, which comprises the following steps:

the input module is used for inputting first data information, pre-verifying the first data information and sending the first data information to the first verification module after the pre-verification is passed, wherein the first data information at least comprises a job number, a password, a patient name and a hospitalization number of an anesthesia department doctor;

the first verification module is used for searching and verifying the first data information in the verification database, returning verification passing information if the first data information passes the verification, returning verification error information if the first data information does not pass the verification, and storing the verification error information in the feedback database in the form of an information feedback table;

the selection module is used for selecting the name, the quantity and the usage of the needed anesthetic drugs in a preset selection questionnaire, packaging the information into second data information and sending the second data information to the second verification module;

the second verification module is used for verifying the second data information according to a preset verification model to generate a medicine use risk probability, if the medicine use risk probability is within a set threshold value range, the verification is passed and a serial number with an anti-counterfeiting label is returned, otherwise, the verification fails to prompt that an error exists;

the driving module is used for inputting the serial number with the anti-counterfeiting label into a preset driving model to be compared so as to obtain a driving signal;

the conveying mechanism is used for automatically sending out the corresponding amount of medicines according to the driving signal;

the fee deduction module is used for sending fee deduction information to a hospital charging system for fee deduction while the medicines are sent out, wherein the fee deduction information comprises medicine fee deduction amount and a patient hospitalization number, and fee deduction success information is fed back to the printing module after fee deduction is finished;

the printing module is used for printing the medication voucher;

the camera module is used for sending alarm information in the anesthesia recording system if the used ampoule is not shot within a set time;

the automatic medicine dispensing cabinet is characterized in that the input module, the selection module, the second verification module, the verification model, the driving module, the driving model, the conveying mechanism, the fee deducting module, the printing module and the camera module are all arranged in the automatic medicine dispensing cabinet, at least one automatic medicine dispensing cabinet is arranged in each operating room of a hospital, and the first verification module, the verification database, the feedback database, the hospital charging system and the anesthesia recording system are all arranged in the cloud platform.

Further, each of the automatic medicine dispensing cabinets includes: the medicine storage cabinet comprises a cabinet body, wherein at least one medicine storage area is arranged in the cabinet body, a plurality of layers of medicine storage areas are arranged in each medicine storage area, a plurality of medicine storage units are arranged in each medicine storage area, and a conveying mechanism for conveying medicines is arranged at the end part of each medicine storage unit; the lower extreme of the cabinet body is equipped with out the medicine mouth, and every medicine save area all communicates through independent passageway and play medicine mouth, cabinet body upper end is equipped with the touch-control screen, input module and selection module all integrate in the touch-control screen, one side of touch-control screen still is equipped with retrieves mouthful and print module, camera module locates in retrieving mouthful.

Further, the medicine save area includes normal atmospheric temperature save area and 4 ℃ save area, the below in normal atmospheric temperature save area is located to 4 ℃ save area, is equipped with the insulating layer between normal atmospheric temperature save area and 4 ℃ save area, and normal atmospheric temperature save area and 4 ℃ save area all communicate through independent passageway and play medicine mouth the both sides of the cabinet body still are equipped with the heat dissipation window.

Compared with the prior art, the invention has the advantages that: the safe and efficient intelligent anesthesia medicine delivery charging method and system provided by the invention can monitor the anesthetic medicine, the quantity and the usage selected by a doctor, can avoid the occurrence of medicine taking errors through anti-counterfeiting design, and can transmit information to a hospital charging system for fee deduction through a fee deduction module after the medicine is successfully taken out; meanwhile, as each operating room is provided with at least one automatic medicine dispensing cabinet, the medicines can be taken and used at any time, and the risks of medicine degradation and medicine efficiency reduction caused by the fact that the medicines which need to be used in a 4 ℃ storage area are placed in a thermostatic chamber of the operating room for a long time can be avoided.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic diagram of the safe and efficient intelligent anesthesia medicine dispensing charging system of the present invention.

Fig. 2 is a perspective view of the automatic medicine dispensing cabinet of the present invention.

Fig. 3 is a schematic structural view of each medicine storage area in the automatic medicine dispensing cabinet.

Fig. 4 is a flow chart of the safe and efficient intelligent anesthesia medicine dispensing charging method of the present invention.

Fig. 5 is a flow chart of the setup of the verification model preset in the present invention.

Fig. 6 is a flow chart of the establishment of the preset driving model in the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings so that the advantages and features of the present invention can be more easily understood by those skilled in the art, and the scope of the present invention will be more clearly and clearly defined.

Referring to fig. 4, the embodiment discloses a safe and efficient intelligent charging method for drug delivery in an anesthesia department, which includes the following steps:

step S1: the first data information is input through the input module 100, pre-verified and sent to the first verification module after passing the pre-verification, and the first data information at least comprises a job number, a password, a patient name and a hospital number of an anesthesia department doctor.

On one hand, the pre-verification is to perform format check verification on the first data information, that is, whether the input data conforms to the basic format, for example: whether the hospital number conforms to the data format specified by the hospital or not is also subjected to pre-verification on the first data information by capturing an information feedback table in the feedback database 220 of the cloud platform 20, that is, the data in the first data information should not be stored in the information feedback table in the feedback database 220.

Step S20: the first verification module 210 searches and verifies the first data information in the verification database 200, returns verification passing information if the first data information passes verification, returns verification error information if the first data information does not pass verification, and stores the verification error information in the feedback database in the form of an information feedback table.

The specific steps of the first verification module 210 for loading books to search and verify the first data information in the verification database are as follows:

firstly, verifying the work number password of the anesthesia department doctor, if the work number password passes the verification, continuing to execute the verification, otherwise, returning the feedback information of the error work number password, and storing the work number password which fails in the verification in a data feedback table in a feedback database;

and then, verifying whether the patient name and the hospitalization number exist in a medical record system of the hospital, if so, passing the verification of the first data information and continuing to execute, otherwise, returning feedback information that the patient name or the hospitalization number does not exist, and storing the patient name or the hospitalization number which fails in the verification in a data feedback table in a feedback database.

The following table 1 is a basic format of the data feedback table, that is, the verification failure types (wrong work number and password, wrong name and hospitalization number) and specific information are stored, when the data feedback table is used for the first time, the information in the table is empty, after the data feedback table is continuously used, the table information is continuously filled, and through the pre-verification step, the workload of searching and verifying in the verification database of the whole hospital by the first verification module 210 can be reduced.

TABLE 1

Verifying the failed speciesClass I	Verifying failed content	Number of times	Remarks for note
				Password error of job number	Zhao san, 111111	1
Wrong name and hospital number of patient	Zhang San 9898765	1
				……	……	……	……

Step S30: the selection module 101 selects the name, quantity and usage of the needed anesthetic drugs in a preset selection questionnaire, packages the information into second data information, and sends the second data information to the second verification module 102.

The preset selection questionnaire establishing step comprises the following steps: when the automatic medicine dispensing cabinet is established for the first time, the anesthetic medicines are sequenced according to the sequence of the use frequency in the hospital in unit time to form a selection questionnaire, and the selection questionnaire is sent to all the automatic medicine dispensing cabinets 10; in the subsequent use, the selection questionnaire of the automatic dispensing cabinet 10 is updated within a set time according to the anesthetic use frequency of the single automatic dispensing cabinet 10. Because the number of the narcotics is large, 2-3 pages appear on the selected page when the narcotic is actually used, and in order to be capable of timely putting the most common narcotic on the first page, the invalid operation caused by returning to turn the page and searching can be avoided by the method when the narcotic is selected. Table 2 below is the initial table for the selected questionnaire and table 3 below is the updated table for a single automated drug cabinet 10 due to the higher frequency of intravenous anesthetic use in that automated drug cabinet 10.

TABLE 2 initial selection questionnaire

Vasoactive agents	Local anesthetic
		Analgesic drug	Muscle relaxing medicine
Intravenous anesthetic	……

TABLE 3 updated selection questionnaire

Intravenous anesthetic	Local anesthetic
		Analgesic drug	Muscle relaxing medicine
Vasoactive agents	……

Step S40: the second verification module 102 verifies the second data information according to a preset verification model 103 to generate a medicine use risk probability, if the medicine use risk probability is within a set threshold range, the verification is passed and a serial number with an anti-counterfeiting label is returned, otherwise, the verification fails, and an error is presented.

The steps of establishing the preset verification model are (shown in fig. 5):

step S410: establishing corresponding relations between the name of each medicine and the type of applicable diseases, the number of the medicines, the limited dosage of patients and the usage and the standard usage to form a pre-model;

step S420: importing the patient illness condition corresponding to the patient name and the hospitalization number into the pre-model to form a verification model;

step S430: after the verification model is established, the name, the quantity and the usage of the anesthetic in the second data information are led into the verification model for comparison, and the drug use risk probability of the anesthetic is calculated according to a risk evaluation algorithm in the verification model.

Referring to table 4, in order to establish a verification model, the risk assessment algorithm may be adjusted according to actual needs.

TABLE 4 verification model

Step S50: and inputting the serial number with the anti-counterfeiting label into a preset driving model 105 for comparison to obtain a driving signal.

The steps of establishing the preset driving model are (shown in fig. 6):

step S510: each medicine storage area of each automatic medicine dispensing cabinet is numbered (S1\ S2\ S3 … …), the medicine storage areas in each medicine storage area are numbered (S1-1 … … \ S2-1 … … \ S3-1 … …), and the medicine storage units in each medicine storage area are numbered (S1-1-1 … … \ S2-1-1 … … \ S3-1-1 … …).

Step S520: a one-to-one correspondence between each medication storage unit 192 and the name of the medication is established.

Step S530: a one-to-one correspondence between each drug storage unit 192 and the delivery mechanism 193 driving the action of the drug within that drug storage unit is established to form the drive model 105.

And after the second verification module 102 passes the verification, returning a serial number with the anti-counterfeiting label, wherein the serial number is consistent with the serial number of the medicine storage unit, and when the serial number of the anti-counterfeiting label is input into the driving model 105, obtaining the medicine storage unit 192 corresponding to the serial number so as to generate a driving signal for driving the driving mechanism of the medicine storage unit 192 to act.

Referring to table 5, a driving model 105 is created.

TABLE 5 drive model

Step S60: the corresponding amount of medicines are automatically sent out by controlling the conveying mechanism through a driving signal, meanwhile, fee deduction information is sent to a hospital charging system through a fee deduction module for fee deduction, fee deduction success information is fed back to the printing module after fee deduction is completed, and the fee deduction information comprises medicine fee deduction amount and a patient hospitalization number;

step S70: the first data message and the second data message are synchronized to the anesthesia recording system 240 while the delivery mechanism 193 is successfully delivering the drugs automatically, so that the anesthesia recording system 240 can record the drug name, quantity, usage and user in time for management.

Step S80: if the used ampoule is not photographed by the camera module 190 within a set time (the set time can be specified according to actual requirements or set according to requirements of a supervision department), an alarm message is sent out in the anesthesia recording system 240 to remind that the ampoule is not recovered, so that medical staff can be reminded to recover in time or verify whether the ampoule is used or not.

Example two

Referring to fig. 1 to fig. 3, the present embodiment provides a safe and efficient intelligent anesthesia department drug delivery charging system, which includes the following modules: the input module 100 is used for inputting first data information, pre-verifying the first data information, and sending the first data information to the first verification module after the pre-verification is passed, wherein the first data information at least comprises a job number, a password, a patient name and a hospital number of an anesthesiologist; the first verification module 210 is configured to search and verify the first data information in the verification database 200, return verification passing information if the first data information passes verification, return verification error information if the first data information does not pass verification, and store the verification error information in the feedback database 220 in the form of an information feedback table; the selection module 101 is used for selecting the name, the quantity and the usage of the needed anesthetic drugs in a preset selection questionnaire, packaging the information into second data information, and sending the second data information to the second verification module 102; the second verification module 102 is configured to verify the second data information according to a preset verification model 103 to generate a drug use risk probability, if the drug use risk probability is within a set threshold range, the verification is passed and a serial number with an anti-counterfeit label is returned, otherwise, the verification fails, which indicates that an error exists; the driving module 104 is used for inputting the serial number with the anti-counterfeit label into a preset driving model to be compared so as to obtain a driving signal; a delivery mechanism 106 for automatically delivering a corresponding amount of the drug in accordance with the drive signal; the fee deduction module 107 is used for sending fee deduction information to the hospital charging system 230 for fee deduction while the medicines are sent out, wherein the fee deduction information comprises the amount of the medicine fee deduction and the number of the patient in hospital, and fee deduction success information is fed back to the printing module after the fee deduction is finished; a printing module 180 for printing the medication voucher; the camera module 190 is configured to send an alarm message in the anesthesia recording system 240 if the used ampoule is not photographed within a set time; the input module 100, the selection module 101, the second verification module 102, the verification model 103, the driving module 104, the driving model 105, the conveying mechanism 106, the fee deducting module 107, the printing module 180 and the camera module 190 are all arranged in the automatic medicine dispensing cabinet 10, each anesthesia department of the hospital is provided with at least one automatic medicine dispensing cabinet 10, and the first verification module 210, the verification database 200, the feedback database 220, the hospital charging system 230 and the anesthesia recording system 240 are all arranged in the cloud platform 20.

Each automatic medicine dispensing cabinet 10 in the present embodiment includes: the medicine storage cabinet comprises a cabinet body 110, wherein at least one medicine storage area is arranged in the cabinet body 110, a multi-layer medicine storage area 191 is arranged in each medicine storage area, a plurality of medicine storage units 192 are arranged in each medicine storage area 191, and a conveying mechanism 193 for conveying medicines is arranged at the end part of each medicine storage unit 192; the lower extreme of cabinet body 110 is equipped with out medicine mouth 150, and every medicine save area all communicates with a medicine mouth 150 through independent passageway, cabinet body 110 upper end is equipped with touch-control screen 120, input module 100 and selection module 101 are all integrated in touch-control screen 120, one side of touch-control screen 120 still is equipped with retrieves mouthful 170 and print module 180, and camera module 190 locates in retrieving mouthful 170, and cabinet body 110 is inside to be equipped with the recovery cavity that corresponds with retrieving mouthful 170, and the ampoule after the mainly used deposits the use adopts camera module 190 to shoot it, information such as the two-dimensional code that can scan or bar code to whether in time discover to retrieve.

A door (not shown) having a lock is provided at the rear side of the cabinet 110, and when the system of the automatic medicine dispensing cabinet 10 finds that the medicine is insufficient or less than a set value, a specialist (pharmacy staff) can open the lock to replenish the medicine into each medicine storage area 191 in the cabinet 110, and after the replenishment is completed, the number of the available medicines is updated in the system of the automatic medicine dispensing cabinet 10.

In this embodiment, a drug instruction query button is further integrated on the interface of the selection module 101 of the touch screen 120, and medical staff can query the instruction by clicking the button, so that the drugs can be used more regularly, and the drug administration beyond the instruction can be avoided.

If medical personnel are careless or the maloperation leads to getting more the medicine, through the module of returning the medicine of newly-increased on touch-control screen 120, medical personnel are through clicking the module of returning the medicine, the hasp that the back door can be opened through special personnel (drugstore personnel) to the module of returning the medicine, the medicine of getting more put in the corresponding storage medicine district 191 in the cabinet body 110 can, after successful, the module of returning the medicine notifies the module of deducting the fee, the medicine that the module of deducting the fee will return, quantity and expense give hospital charging system 230, hospital charging system 230 returns the expense that corresponds to patient's card.

In this embodiment, the medicine storage area includes a normal temperature storage area 130 and a 4 ℃ storage area 140, the 4 ℃ storage area 140 is disposed below the normal temperature storage area 130, a heat insulation layer (not shown) is disposed between the normal temperature storage area 130 and the 4 ℃ storage area 140, the normal temperature storage area 130 and the 4 ℃ storage area 140 are both communicated with the medicine outlet 150 through independent channels, and heat dissipation windows 160 are disposed on two sides of the cabinet body 11. The normal temperature storage area 130 is used for storing some anesthetics such as vasoactive drugs, local anesthetics, analgesics, etc., and the 4 ℃ storage area 140 is used for storing some anesthetics such as muscle relaxants, intravenous anesthetics, etc.

The embodiment can monitor the narcotic selected by a doctor, the quantity and the usage, can avoid taking the drug by anti-counterfeiting design, transmits information to a hospital charging system by a fee deducting module for fee deduction after the drug is successfully taken out, and simultaneously monitors the drug use condition by adopting an anesthesia recording system to avoid the drug abuse and the incapability of monitoring; meanwhile, as each operating room is provided with at least one automatic medicine dispensing cabinet, the medicines can be taken and used at any time, and the risks of medicine degradation and medicine efficiency reduction caused by the fact that the medicines which need to be used in a 4 ℃ storage area are placed in a thermostatic chamber of the operating room for a long time can be avoided.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, various changes or modifications may be made by the patentees within the scope of the appended claims, and within the scope of the invention, as long as they do not exceed the scope of the invention described in the claims.

Claims (8)

1. A safe and efficient intelligent anesthesia medicine dispensing charging method is characterized by comprising the following steps:

the method comprises the steps that first data information is input through an input module and pre-verified, and the first data information is sent to a first verification module after the pre-verification is passed, wherein the first data information at least comprises a job number, a password, a patient name and a hospitalization number of an anesthesia department doctor;

the first verification module searches and verifies the first data information in a verification database, returns verification passing information if the first data information passes the verification, returns verification error information if the first data information does not pass the verification, and stores the verification error information in a feedback database in the form of an information feedback table;

selecting the name, the quantity and the usage of the needed anesthetic drugs in a preset selection questionnaire through a selection module, packaging the information into second data information, and sending the second data information to a second verification module;

the second verification module verifies the second data information according to a preset verification model to generate a medicine use risk probability, if the medicine use risk probability is within a set threshold value range, the verification is passed and a serial number with an anti-counterfeiting label is returned, otherwise, the verification fails to prompt that an error exists;

inputting the serial number with the anti-counterfeiting label into a preset driving model for comparison to obtain a driving signal;

the corresponding amount of medicines are automatically sent out by controlling the conveying mechanism through a driving signal, meanwhile, fee deduction information is sent to a hospital charging system through a fee deduction module for fee deduction, fee deduction success information is fed back to the printing module after fee deduction is completed, and the fee deduction information comprises medicine fee deduction amount and a patient hospitalization number;

the first data information and the second data information are synchronized into an anesthesia recording system when the conveying mechanism successfully and automatically sends out the medicine;

the specific steps of the first verification module for searching and verifying the first data information in the verification database are as follows: verifying the work number password of the anesthesia department doctor, if the work number password passes the verification, continuing to execute the verification, otherwise, returning feedback information of the error of the work number password, and storing the work number password which fails in the verification in a database; verifying whether the patient name and the hospitalization number exist in a medical record system of the hospital or not, if so, verifying the first data information and continuing to execute, otherwise, returning feedback information that the patient name or the hospitalization number does not exist, and storing the patient name or the hospitalization number which fails in verification in a database;

the preset verification model is established by the following steps: establishing corresponding relations between the name of each medicine and the type of applicable diseases, the number of the medicines, the limited dosage of patients and the usage and the standard usage to form a pre-model; importing the patient illness condition corresponding to the patient name and the hospitalization number into the pre-model to form a verification model; after the verification model is established, the name, the quantity and the usage of the anesthetic in the second data information are led into the verification model for comparison, and the drug use risk probability of the anesthetic is calculated according to a risk evaluation algorithm in the verification model.

2. The safe and efficient intelligent anesthesia medicine delivery charging method of claim 1, wherein the step of pre-verifying the first data information specifically comprises: and carrying out format verification and verification on the first data information, and carrying out pre-verification on the first data information by capturing an information feedback table in a feedback database of the cloud platform.

3. The safe and efficient intelligent anesthesia medicine delivery billing method of claim 1, wherein the pre-configured selection questionnaire is established by the steps of:

when the system is established for the first time, the anesthetic drugs are sequenced according to the sequence of the use frequency in the hospital in unit time to form a selection questionnaire, and the selection questionnaire is sent to all automatic drug-dispensing cabinets;

and updating the selection questionnaire of the automatic dispensing cabinet within a set time according to the anesthetic use frequency of the single automatic dispensing cabinet.

4. The safe and efficient intelligent anesthesia medicine delivery billing method of claim 1, wherein the preset driving model is established by the steps of:

numbering each medicine storage area of each automatic medicine dispensing cabinet, numbering the medicine storage areas in each medicine storage area, and numbering the medicine storage units in each medicine storage area;

establishing a one-to-one correspondence between each medicine storage unit and the medicine name;

establishing a one-to-one corresponding relation between each medicine storage unit and a conveying mechanism for driving the medicines in the medicine storage units to act so as to form a driving model;

and returning the serial number with the anti-counterfeiting label after the second verification module passes the verification, wherein the serial number is consistent with the serial number of the medicine storage unit, and the medicine storage unit corresponding to the serial number is obtained when the serial number of the anti-counterfeiting label is input into the driving model so as to generate a driving signal for driving a driving mechanism of the medicine storage unit to act.

5. The safe and efficient intelligent anesthesia medicine delivery billing method of claim 1, wherein the synchronizing of the second data information into the anesthesia recording system while the delivery mechanism is successfully delivering the medicine automatically further comprises: if the used ampoule is not shot by the camera module within a set time, alarm information is sent out in the anesthesia recording system.

6. A system for implementing the safe and efficient intelligent anesthesia medicine delivery charging method of any one of claims 1-5, comprising:

the input module is used for inputting first data information, pre-verifying the first data information and sending the first data information to the first verification module after the pre-verification is passed, wherein the first data information at least comprises a job number, a password, a patient name and a hospitalization number of an anesthesia department doctor;

the first verification module is used for searching and verifying the first data information in the verification database, returning verification passing information if the first data information passes the verification, returning verification error information if the first data information does not pass the verification, and storing the verification error information in the feedback database in the form of an information feedback table;

the selection module is used for selecting the name, the quantity and the usage of the needed anesthetic drugs in a preset selection questionnaire, packaging the information into second data information and sending the second data information to the second verification module;

the second verification module is used for verifying the second data information according to a preset verification model to generate a medicine use risk probability, if the medicine use risk probability is within a set threshold value range, the verification is passed and a serial number with an anti-counterfeiting label is returned, otherwise, the verification fails to prompt that an error exists;

the driving module is used for inputting the serial number with the anti-counterfeiting label into a preset driving model to be compared so as to obtain a driving signal;

the conveying mechanism is used for automatically sending out the corresponding amount of medicines according to the driving signal;

the fee deduction module is used for sending fee deduction information to a hospital charging system for fee deduction while the medicines are sent out, wherein the fee deduction information comprises medicine fee deduction amount and a patient hospitalization number, and fee deduction success information is fed back to the printing module after fee deduction is finished;

the printing module is used for printing the medication voucher;

the camera module is used for sending alarm information in the anesthesia recording system if the used ampoule is not shot within a set time;

the automatic medicine dispensing cabinet is characterized in that the input module, the selection module, the second verification module, the verification model, the driving module, the driving model, the conveying mechanism, the fee deducting module, the printing module and the camera module are all arranged in the automatic medicine dispensing cabinet, at least one automatic medicine dispensing cabinet is arranged in each operating room of a hospital, and the first verification module, the verification database, the feedback database, the hospital charging system and the anesthesia recording system are all arranged in the cloud platform.

7. The system of claim 6, wherein each of the automated drug dispensing cabinets comprises: the medicine storage cabinet comprises a cabinet body, wherein at least one medicine storage area is arranged in the cabinet body, a plurality of layers of medicine storage areas are arranged in each medicine storage area, a plurality of medicine storage units are arranged in each medicine storage area, and a conveying mechanism for conveying medicines is arranged at the end part of each medicine storage unit; the lower extreme of the cabinet body is equipped with out the medicine mouth, and every medicine save area all communicates through independent passageway and play medicine mouth, cabinet body upper end is equipped with the touch-control screen, input module and selection module all integrate in the touch-control screen, one side of touch-control screen still is equipped with retrieves mouthful and print module, camera module locates in retrieving mouthful.

8. The system of claim 6, wherein the medicine storage area comprises a normal temperature storage area and a 4 ℃ storage area, the 4 ℃ storage area is arranged below the normal temperature storage area, a heat insulation layer is arranged between the normal temperature storage area and the 4 ℃ storage area, the normal temperature storage area and the 4 ℃ storage area are both communicated with the medicine outlet through independent channels, and heat dissipation windows are arranged on two sides of the cabinet body.

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