RU187284U1 - Educational anatomical model of the human heart - Google Patents

Abstract

The training anatomical model of the human heart is designed to conduct and position diagnostic, ablating and implantable electrodes, pacemakers, cardioverter-defibrillators and devices in the process of training doctors of cardiovascular surgeons, cardiologists, students and to improve the skills of specialists in the field of interventional cardiology. The task to which the technical solution of the proposed model is aimed is to create not only an “anatomical”, externally replicating structure of a real heart, but the maximum possible “physiological” model that allows you to tactfully train in the application of interventional techniques in cardiology. To do this, on the external wall of the model in the projection of each camera "heart" placed additional opening elements that provide access to interconnected passable channels between the right and left atria, I’m waiting for the right atrium and ventricle, between the left atrium and the ventricle, between the coronary sinus and the right atrium, between the right ventricle and the pulmonary trunk, between the left ventricle and the aorta. In addition, the inner surface of the right ventricle and the right atrium at the sites of electrode implantation is made of elastic material imitating the density and topography of the endocardium. The technical effect is the ability to implement a practical procedure for the introduction (implantation) and fixation of the electrode and other medical device about the appointment, in the heart, both without use and with the use of radiological equipment.

Description

The utility model relates to medicine, namely to technical teaching aids in the field of cardiovascular surgery, in particular arrhythmology and interventional electrophysiology.

The model is designed to conduct and position diagnostic, ablative and implantable electrodes, pacemakers, cardioverter-defibrillators and devices during the training of doctors, cardiovascular surgeons, cardiologists, students and to improve the skills of specialists in the field of interventional cardiology.

Since the development of manual practical skills in surgical arrhythmology and interventional electrophysiology is significantly complicated by the impossibility of direct tactile contact with the patient’s heart, the urgency of creating a simulation training model of the heart, which allows practicing the whole range of medical manipulations used in cardiovascular surgery, is obvious.

To date, in the context of the constant expansion of the arsenal of technical means - simulators for the training and professional development of specialists, in particular in the field of cardiology, many educational anatomical models of the heart have been developed.

The specifics of the subject of study are due to the design differences of various known models, however, common to all is the lack of communication between the internal chambers and blood vessels of the heart (for example, 3D Scientific and Honglian models, Internet resource https://www.3bscientific.ru)

The use of such models in teaching practice is enough to teach a person to navigate in the main "markers" of topographic anatomy of the heart under normal conditions and for various pathologies, but not at all enough to train specialists in the field of cardiovascular surgery to use modern arrhythmology and interventional technologies X-ray heart surgery.

To develop skills for various manipulations in the framework of interventional arrhythmology, cardiology, the following requirements for the model of conditions must be observed:

- providing visual control of the position of the electrode and other medical devices (stent graft, balloon counterpulsator, bougie, conductor, transeptal needle, etc.) in the heart, including under x-ray control.

- compliance with the actual density and elasticity parameters used to create materials, in particular structures such as the endocardium, oval fossa, valves, for transmitting tactile sensations when conducting, positioning and implanting the electrode.

- providing communication between the right and left atrium, which is necessary to perform an electrophysiological examination of the left atrium and eliminate its arrhythmogenic foci.

- providing communication between the vena cava, coronary sinus, right atrium, right ventricle and pulmonary trunk; pulmonary veins, left atrium, left ventricle and aorta, which is necessary for performing interventional procedures.

- durability of the structure, since when using the model in the simulator mode, the probability of damage to individual parts is high.

For the prototype of the proposed utility model, a training anatomical model of the human heart (Adult Heart Model, model of the heart of an adult) was taken http://www.medicalexpo.ru/prod/shanghai-honglian-medical-instrument/product-77220-745818.html.

This 3D model is made of polymeric materials and compares favorably with similar ones by the exact transmission of the external and internal anatomical structures of the heart, access to which is provided by the opening viewing window.

However, as well as analogues, this model is not intended and does not provide the opportunity to develop skills in delivering the electrode and other medical devices to the necessary heart chamber, their correct positioning and fixing, because the design of this model has the functional disadvantages of other known analogues.

The task that the technical solution of the proposed model is aimed at is the creation of not only an “anatomical”, outwardly copying structure of a real heart, but the maximum possible “physiological” model that allows you to tactfully train in the application of interventional technologies in cardiology.

The problem is solved in that the proposed training anatomical model of the human heart, represented by a copy of the vascular system of the heart, relief printed on the outer surface, having on the front wall a removable element for access to the inner chambers of the heart, communicating with the blood vessels of the heart, of which the upper, lower hollow and pulmonary vein is made internally passable, characterized in that on the outer surface of the model in the projection of each chamber of the "heart" there are additional opening elements that provide up to dull to passable interconnected channels between the right and left atria, between the right atrium and ventricle, between the left atrium and the ventricle, between the coronary sinus and the right atrium, right ventricle and between the pulmonary trunk, between the left ventricle and the aorta.

In addition, the inner surface of the right ventricle and the right atrium at the sites of implantation of the electrodes is made of elastic material that simulates the density and relief of the endocardium.

The proposed utility model allows using the following technical effect: the possibility of implementing a practical procedure for the introduction (implantation) and fixation of the electrode and other medical devices in the heart, both without and using x-ray equipment.

The proposed utility model meets the criterion of "novelty", as the patent information research conducted did not reveal the source of scientific, technical and patent information that would discredit the novelty of the proposed model.

The proposed utility model meets the criterion of industrial applicability, since it can be used to teach students and specialists how to conduct and position diagnostic, ablative and implantable electrocardiostimulators, cardioverter defibrillators and devices for cardiac resynchronization therapy.

The utility model is illustrated by graphic material.

In FIG. 1 shows a block diagram of the messages between the simulated inner chambers and blood vessels of the heart, where:

1. the channel between the right and left atria,

2. the channel between the right atrium and ventricle,

3. the channel between the left atrium and the ventricle,

4. the channel between the coronary sinus and the right atrium,

5. the channel between the right ventricle and the pulmonary trunk,

6. The channel between the left ventricle and the aorta.

The proposed utility model is made using 3D printing technology, in accordance with the anatomical dimensions of the human heart.

The right atrium and ventricle, as well as the left atrium and ventricle, are interconnected by passable channels (2, 3), which communicate through the atrioventricular (atrioventricular) openings.

Due to the hole (1) in the oval fossa, the right and left atria are connected to each other. The coronary sinus and right atrium are connected through the channel (4). Due to the channel (5), the right ventricle and the pulmonary trunk are connected; due to the channel (6), the left ventricle and the aorta are connected.

Myocardium is made of dense material (polymer material for 3D printing), which allows you to maintain the shape of the heart model and facilitates its use as a training model.

Claims (1)

Educational anatomical model of the human heart, represented by a copy of the human vascular system, embossed on the outer surface, having a removable element on the front wall for accessing the inner chambers of the heart, communicating with the blood vessels of the heart, of which the superior, inferior vena cava and pulmonary veins are made inside passable the fact that on the outer surface of the model in the projection of each camera of the "heart" there are additional opening elements that provide access to the passable canals that communicate with each other between the right and left atria, between the right atrium and ventricle, between the left atrium and ventricle, between the coronary sinus and the right atrium, between the right ventricle and pulmonary trunk, between the left ventricle and the aorta, while the inner surface of the chambers of the right ventricle and the right atrium the implantation sites of the electrodes are made of an elastic material that simulates the density and relief of the endocardium.

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