RU2546404C1 - Simulated operation room - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: simulated operation room is presented in the form of a single software-hardware complex comprising a control unit accommodating a visualisation system and a coupler connected to PC, an endosurgical unit, a patient's simulation unit. There is provided an anaesthesia unit comprising a drug administration simulator in the form of a data input system implemented in the form of a sensor monitor, and an anaesthesia-respiratory simulator comprising an artificial pulmonary ventilation control panel and an anaesthetic evaporation simulator. The endosurgical unit, patient's simulation unit and anaesthesia unit are connected by a two-way connection to the control unit.

EFFECT: simulated operation room provides the real-time optimisation of the surgeon's, assistant's, anaesthesiologist's and surgical nurse's practical skills by complete dipping into a situation simulated for educational purposes.

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Description

The invention relates to medicine and is intended for the comprehensive training of the operating team working in a team and the development of practical skills of endosurgical operations based on the use of a simulator that allows all specialists of the operating team to interact, including anesthetists, by completely immersing students in a specific situation simulated for training purposes .

Known neonatal imitation training complex containing a set of interconnected elements of a computer-medical information system and modules: diagnostic, imitation, surgical, resuscitation (utility model patent RU 103958). However, this complex allows you to practice individual manipulations outside the context of the operational process, the complex does not allow for the implementation of the feedback “doctor’s action - patient’s reaction”, and does not foster the clinical thinking of students.

The closest technical solution is a hybrid medical simulator of laparoscopy, made in the form of a single software and hardware complex, including a control module, consisting of a visualization system and an interface unit connected to a computer, an endosurgery module, a patient simulator module (patent for utility model RU 128762). However, this simulator does not allow to develop the practical skills of the operating surgical team together with the anesthetist, does not provide a single holistic approach to the training of surgeons, anesthetists, surgical sisters working in the operating room in collaboration, a single team.

The objective of the claimed invention is the creation of a simulator that provides comprehensive training for the operating team working in a team by developing the practical skills of surgeons, anesthetists and surgical sisters in real time and independent clinical thinking by solving situational problems in the interaction of the entire operating team in conditions as close as possible to real ones, including the location of the operating team relative to the patient simulator module and the surgical field.

The task is achieved in that the surgical operating room simulator, made in the form of a single software and hardware complex containing a control module, including a visualization system and an interface unit connected to a computer, an endosurgery module, a patient simulator module, according to the invention, additionally contains an anesthetic module, In this, the endosurgery module, the patient simulator module and the anesthesia module are connected by two-way communication with the control module. The anesthesia module contains a drug input simulator in the form of an information input system presented on a touch monitor, and an anesthesia-respiratory apparatus simulator containing an artificial lung ventilation control panel and an anesthetic vaporizer simulator.

In FIG. 1 presents a structural diagram of the inventive simulator.

In FIG. 2 shows a general view of a simulator of anesthesia-respiratory apparatus.

The simulator contains: a control module 1, including a visualization system 2 and an interface unit 3 connected to a computer 4, an endosurgery module 5, containing simulators of endosurgical instruments 6 and a device for tracking instruments 7, a patient simulator module 8, an anesthesia module 9, including an anesthetic respiratory simulator apparatus 10 and drug input simulator 11.

An anesthesia module 9, containing an anesthesia-respiratory apparatus simulator (NDA) 10 and a drug injection simulator 11, simulates the anesthetic management of an operation on a patient simulator module 8 and allows you to work out the actions of an anesthetist in regular and emergency situations during the interaction of the entire operating team. The simulator of anesthesia-respiratory apparatus 10 includes a control panel 12 for artificial lung ventilation (IVL) and an anesthetic vaporizer simulator 13 connected to the control unit of the anesthesia-respiratory apparatus 14. On the ventilation panel 12 are handles for supplying gases (air, oxygen, nitrous oxide) with sensors for tracking their rotation 16, a handle for setting ventilation parameters with a sensor for tracking its rotation 17, indicators for the amount of gas supplied and parameters for ventilation 18, buttons for selecting parameters for ventilation 19. Evaporator simulator anesthetic Ov 13 is made in the form of a real evaporator equipped with a sensor that tracks the position of the dosing valve 20. The drug input simulator 11 is connected to the control unit of the anesthesia-respiratory apparatus 14 and includes a list of drugs and its dosages presented on the touch monitor 15.

Anesthesia module 9 provides anesthetic support for a training operation at all its stages: at the preoperative stage (allows risk assessment and the choice of anesthesia method based on a medical history), during the operation (ensuring pain relief and patient safety), the postoperative stage (stabilization of the patient's condition after surgery, recovery after anesthesia).

The endosurgery module 5 contains simulators of endosurgical instruments 6, the instrument tracking device 7. The instrument tracking device 7 determines its position in space. The module allows the surgeon to develop individual practical skills and conduct a surgical training operation according to a specific scenario in stages and in full, and the surgeon manipulates imitators of endosurgical instruments 6.

The control module 1 includes a computer 4, a visualization system (monitors) 2 and an interface unit 3 connected to a computer. Endosurgery module 5, anesthesia module 9, and patient simulator module 8 are connected by two-way communication with control module 1 via interface unit 3.

The interface unit 3 provides information exchange between all modules and the software part of the computer 4, realizing a single information network.

The patient simulator module 8 allows you to simulate the reaction (condition) of the patient being operated on, depending on the selected scenario, medical history, and actions taken by a team of doctors. The patient simulator module is made in the form of a mannequin equipped with systems for simulating signs of human activity, a system for resuscitation, for example: cardiopulmonary resuscitation (CPR), intubation, mechanical ventilation (mechanical ventilation), administration of drugs, defibrillation, as well as systems, mimicking the symptoms of urination, hemorrhage, tears, sweat, hyperemia, seizures. The patient simulator module allows you to put into practice the knowledge of such medical procedures as diagnostic: auscultation, pulse, pressure measurement, checking the pupillary reflex, etc .; resuscitation: ensuring airway patency, cardiopulmonary resuscitation, drug therapy, defibrillation, while the actions of doctors are monitored by sensors and processed by a software algorithm in a computer. Based on these data, a model of the patient’s current state is built.

The simulator works as follows.

A team of specialists represented by an anesthesiologist, surgeon, assistant and operating sister take their places in the “operating room”, respectively, relative to the patient simulator module and the surgical field.

After the simulator is turned on, the training direction is selected using a software algorithm, for example, an exercise to perform an endosurgical operation and a variant of a clinical case, including information about the patient’s history, analyzes and complaints. Based on this information, the operating team makes a decision on the surgical intervention, plans its actions and proceeds with the implementation of the training surgical operation.

An anesthesiologist, having studied the patient information (examination data, tests, medical history), selects drugs and their doses in order to perform anesthesia in the drug injection simulator 11 on the touch monitor 15, intubates the patient simulator and sets it in the NDA simulator 10 using the feed handles gases 16, ventilator buttons for selecting ventilator parameters 19 and ventilator for adjusting ventilator parameters 17 ventilation mode, while the set values are displayed on the indicators of the amount of supplied gases and steam meters of mechanical ventilation 18. In the simulator of the anesthetics evaporator 13, the number of volatile anesthetics supplied is set by rotating the metering valve 20. The data specified by the IVL control panel 12, the anesthetics vaporizer simulator 13 and the drug injection simulator 11 are processed by the NDA control unit 14 and transferred from the anesthesia module 9 to the control module 1, where they are processed by the computer software algorithm 4.

The data specified by the anesthesia module 9 affect the current state of the patient simulator module 8, for example, incorrect actions of the anesthesiologist when introduced into anesthesia do not allow surgical intervention and are reflected in the patient simulator state: tachycardia, arterial hypotension, death.

In the case of correct anesthesia, the control module 1 gives a signal with its output to the monitor of the visualization system 2 about the loss of consciousness by the patient and the complete suppression of all types of sensitivity.

Then the surgeon, using the module of endosurgery 5, begins to carry out a training surgical intervention using simulators of endosurgical instruments 6. The visualization system 2 displays a virtual anatomical picture of the area being operated, generated by the computer algorithm 4. The surgeon carries out all stages of the operation in accordance with the selected exercise, the surgeon’s assistant controls the endoscopic camera, providing a visual overview for the surgeon, the nurse submits the tools to the surgeon, and is also responsible for the preparation UWC to work and the setting of the operating equipment.

All manipulations of the imitators of endosurgical instruments 6 are recorded by the instrument tracking device 7, the data are transmitted to the control module 1, processed by the computer software algorithm 4 and used to generate a virtual picture of the operated area. Actions taken by doctors are analyzed by the computer software 4 and reflected on the condition of patient simulator 8, control signals for the patient’s state are sent to visualization system 2 and patient simulator 8. Improper actions of doctors can lead to an emergency.

The imaging system 2 dynamically displays vital indicators of the respiratory and cardiovascular systems of patient simulator 8, the degree of blood oxygen saturation, body temperature, ECG and other important indicators. The patient’s current state is simulated in patient simulator module 8 using vital signs (breathing, pulse, pupil reaction, etc.), systems that simulate symptoms of hemorrhage, tears, sweat, hyperemia, etc., while control signals of the patient’s current state are transmitted from control module 1 to patient simulator module 8.

Consider the work of the simulator and the operating team during a surgical operation in case of an emergency, such as “ventricular fibrillation of the heart”. An anesthesiologist diagnoses ventricular fibrillation by observing in the visualization system 2 a decrease in the patient's cardiovascular system, as well as ventricular fibrillation or flutter, confirmed by ECG. An anesthetist notifies the surgeon. The surgeon completes his actions by performing the necessary surgical measures, for example, stops bleeding if any, and removes the imitators of endosurgical instruments 6 from the instrument tracking device 7 (removes the instruments from the patient). A nurse prepares a real defibrillation apparatus for work. The anesthesiologist performs defibrillation, while he tightly presses the electrodes of the defibrillation apparatus to the contact pads of the system to carry out resuscitation measures of the patient simulator module 8, and attempts to defibrillate until the pulse appears and the patient's life is restored. During defibrillation, as well as in reality, safety precautions must be observed. Other resuscitation measures are also carried out, for example, indirect cardiac massage or drug administration, necessary to restore and stabilize the patient’s condition, after which the surgeon and assistant begin further surgical operations. Possible errors during defibrillation, for example, interruptions in cardiac massage or the complete absence of resuscitation between the defibrillator discharges, applying a low or too high voltage discharge, applying a discharge against the background of small-wave fibrillation without taking measures that increase myocardial energy, the time between the beginning of ventricular fibrillation and the beginning of resuscitation measures, computers 4 are recorded and are included in the statistics for subsequent error analysis.

When you enter a drug that causes an allergic reaction during a "surgical operation", an anaphylactic shock simulation algorithm is launched. Signs of anaphylaxis (tachycardia, tachypnea, low blood pressure) are simulated by the patient simulator module 8 and the symptoms are displayed in the imaging system 2. The anesthesiologist proceeds to stop the shock by choosing the necessary drugs and dosage in the drug simulator 11.

During the "operation", the nurse submits the instruments. It picks up the instruments of the surgeon and his assistant at their request, if necessary, connects the imitators of endosurgical instruments to the corresponding control units, according to the surgeon and the anesthetist, sets up the equipment.

After the surgeon and the assistant to the surgical operation have completed, the anesthesiologist stops administering drugs for anesthesia, while he closes the dosing valve 20 of the simulator of the anesthetic vaporizer 13 and cancels the injection of drugs in the drug simulator 11, the signal to stop the flow of anesthetics and drugs is transmitted to control module 1. The current state of the patient changes, the functions of the central nervous system, reflexes are restored, the patient regains consciousness, in the visualization system 2 is displayed I increase the pulse and pressure, in the patient simulator module 8, the pupil reflex is restored.

After the completion of the training surgical operation, students can evaluate, analyze the results of their work (each individually and the whole team) by looking at the statistics in the computer program 4.

The inventive simulator of the surgical operating room allows the training process to a whole new level. By combining the modules into a single hardware and software system, the boundaries and training opportunities of highly qualified medical personnel are expanding, which cannot be achieved with the help of existing highly specialized simulators. The informational relationship of the endosurgery, anesthesia and patient simulator modules due to the two-way communication with the control module opens up flexible simulation capabilities for real-time simulation of various clinical situations during a training medical operation. A significant advantage of this simulator compared to existing analogues is that it allows for comprehensive training of doctors as part of the operating team, in which students are in a constantly changing clinical situation that requires professional knowledge and skills from each specialist and the ability to respond quickly in case of complications , skills to carry out diagnostic, resuscitation and other medical procedures, teamwork skills.

Claims (1)

A surgical operating room simulator, made in the form of a single software and hardware complex containing a control module, including a visualization system and an interface unit connected to a computer, an endosurgery module, a patient simulator module, characterized in that the simulator further comprises an anesthesia module including a drug input simulator in the form of an information input system implemented in the form of a touch monitor, and an anesthesia-respiratory apparatus simulator containing an artificial valve control panel yatsii and lung simulator anesthetic evaporator, wherein the module endosurgery, the simulator module and patient anesthesia module connected two-way communication with the control module.

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