RU2233632C1 - Vascular cannula - Google Patents

Abstract

FIELD: instruments used in medicine, in particular, artificial blood circulation equipment.

SUBSTANCE: apparatus has elongated body with at least two ends. Part adjoining one of said ends makes connecting part of cannula and part adjoining other end makes working part of cannula. Through channel is formed in elongated body so that working fluid is delivered therein from end adjoining connecting part of cannula and discharged from end adjoining working part of cannula. The latter is made spiral-shaped. Ratio of spiral diameter and its pitch provides for rotational speed of working fluid and its progressive speed ratio as √2:1.

EFFECT: provision for creating physiologic spiral blood flow in case of using artificial blood circulation, said spiral blood flow maximally approximating natural one, effective overcoming of vascular resistance and optimal conditions for micro hemocirculation and transcapillary exchange.

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Description

The invention relates to medical instruments and can be used in medicine, mainly with cardiopulmonary bypass.

In general, medical cannulas are hollow tubes of simple or complex configuration with a blunt head working part. Depending on the purpose and scope of application, cannulas are distinguished: anatomical, neurosurgical, ophthalmic, otorhinolaryngological, dental, urological, vascular and others.

Vascular cannulas are intended for intravenous infusions produced by venesection, including blood transfusion, as well as for connecting a cardiopulmonary bypass to the patient's arterial and venous vessels during cardiopulmonary bypass. Vascular cannulas of various configurations are known. Thus, the end vascular cannula is known, which is made in the form of a glass tube, the working part of which has a drawn narrowed end and interception in the form of a groove (neck of the cannula). The working part of the cannula is inserted into the incision of the vessel wall - arteries or veins and fixed in the vessel using a thread ligature, tightened in the neck of the cannula. The end of the glass tube, opposite the working part of the cannula, is its connecting part, on which hoses are put on from the heart-lung machine, or dropper [Big Medical Encyclopedia / Ed. A.N. Bakuleva, t. 12, - M .: Publishing House. "Great Soviet Encyclopedia". 1959, p. 167]. This vascular cannula is the closest analogue of the proposed cannula and is taken as a prototype of the invention for the greatest number of features similar to it. The disadvantage of the prototype is that when using this cannula to connect blood vessels to the cardiopulmonary bypass, it provides only the translational movement of blood in the vessels and does not provide the formation of a helical blood flow in the vessels of the circulatory system. At the same time, studies of blood circulation biomechanics conducted in recent years have experimentally shown that in the bloodstream, as well as throughout the cardiovascular system, the blood movement is not translational, as previously thought, but rotational-translational in nature, with the direction of rotation of the flow of blood in the large and small circles of blood circulation - the opposite [V.N. Zakharov et al. Biogidromechanics of blood movement in the cavities of the heart and great vessels ”(preprint) - Novosibirsk: Institute of Bioorganic Chemistry, Siberian Branch of the USSR Academy of Sciences, 1 989 and S.N. Bagaev, V.N. Zakharov, V.A. Orlov “Physical mechanisms of transport systems of a living organism” (preprint) - Novosibirsk: “Publishing House of the SB RAS”, 1999]. The helical blood flow has a left swirl in a large circle of blood circulation and a right swirl in a small circle.

The prerequisites for the formation of rotational-translational movement of blood are that the muscle elements of the myocardium of the ventricles of the heart and blood vessels have a spiral packing, their cavities are funnel-shaped chambers with asymmetry of entry and exit. The blood flow entering the main arterial bed during systole of the ventricles of the heart initially has a rotational-translational motion. Since, just as in the myocardium, smooth myocytes of arterial vessels are spirally packed, stretching of the walls of blood vessels receiving a systolic discharge of blood leads to tension of smooth muscle elements and a spiral wave of their excitation. Further, the addition of the forces of elastic deformation of the elastic skeleton and the active contraction of smooth myocytes in the walls of the arteries creates a twisting wave in them, which ensures the preservation of the swirling blood flow when it enters the blood vessel, and supports, along with the translational component of the blood movement, its rotational component. Over the period of one cardiac cycle, the reduction and relaxation of the active elements of the walls of the vessels occurs alternately, and this process extends from the heart to the periphery of the main arterial vessels. One cardiac cycle corresponds to one vascular arterial cycle. The activity of each section of the main arterial vessel is similar to the activity of the ventricle of the heart, since there are phases of spiral contraction and relaxation of the muscle layer of blood vessels, and in general, the activity of the heart and blood vessels is synchronized so much that in essence this whole system is a “distributed heart”, providing a single cardiovascular cycle. It was also established (by means of radiopaque original studies) that in the initial sections of the arterial bed of the circulatory system, the rotational energy of the blood flow is approximately two times greater than its translational energy, which provides optimal conditions for cardiac output, while the ratio of the rotational speed of the helical blood flow to its translational speeds - like √2: 1. The functional role of the rotational component of the blood movement is to overcome the distributed resistance of the vessels, the value of which is determined by the viscous friction and the length of the vascular arteries. In the cardiovascular system, as much rotational energy is generated as is necessary to overcome vascular resistance along the bloodstream. Therefore, it is extremely important during cardiopulmonary bypass not only to continuously pump blood under pressure through the circulatory system, as was previously accepted and accompanied by many complications, but to provide pulsed rotational-translational movement of blood in the arterial bed, causing active pulsed arterial work. The spiral contraction of the arteries maintains the necessary level of rotational energy in the spiral flow of blood, providing effective overcoming of vascular resistance.

The invention solves the problem of creating such a vascular cannula, which would provide rotational-translational movement of blood in the circulatory system during cardiopulmonary bypass.

The problem is solved by the fact that the proposed cannula, including an elongated body having at least two ends, while the area adjacent to one of the named ends is the connecting part of the cannula, and the area adjacent to the second of these ends is the working part of the cannula moreover, a through channel is made in the said elongated body, so that a fluid enters it from the end of the cannula, to which its connecting part is adjacent, and leaves the end of the cannula, to which its working Part B, which in turn is formed in a spiral shape.

The fluid for the vascular cannula may be blood, a blood substitute, or a mixture thereof. If such a cannula is used for purposes other than cardiopulmonary bypass, various medicines, ointments, etc. can be used as a fluid.

For the convenience of connecting the cannula to the patient’s vessel, its working part can be located at an angle to its connecting part, and this angle can be sharp, straight or blunt.

The connecting part of the vascular cannula, with which it is connected to the hose of the heart-lung machine, can be made cylindrical or conical in shape. Said hose can be connected to the cannula by putting it on the outside of its connecting part without additional means, or using known additional adapter fittings with different diameters of the working parts, one of which is included in the connecting part of the cannula, and the second in the hose [Big Medical Encyclopedia / Ed. A.N. Bakuleva, v. 12. - M.: Publishing. “The Great Soviet Encyclopedia”, 1959, p. 166, Fig. 11].

: 1 является оптимальным. Поэтому целесообразно выбирать такое соотношение диаметра спирали и ее шага, чтобы соблюдалось указанное соотношение величин вращательной и поступательной скоростей винтового потока крови в начальном отделе артериального русла.As mentioned above, studies of the circulatory system showed that the ratio of rotational and translational velocities as

: 1 is optimal. Therefore, it is advisable to choose a ratio of the diameter of the spiral and its pitch so that the indicated ratio of the rotational and translational velocities of the helical blood flow in the initial section of the arterial bed is observed.

A general view of the proposed vascular cannula is shown in figure 1. The cannula has a connecting part 1, a working part 2, and a through channel 3. The working part of the cannula 2 is made in the form of a spiral. Figure 2 shows a General view of the cannula with a working part located at right angles to the connecting part, and the working part of it is made in the form of a left-handed spiral. Such cannulas are intended for vessels of a large circle of blood circulation, primarily for connecting to arterial vessels, where there is a helical blood flow with a left swirl direction. Figure 3 shows a General view of the cannula with a working part located at right angles to the connecting part, and its working part is made in the form of a right-handed spiral. Such cannulas are intended for vessels of the pulmonary circulation, where there is a helical blood flow with the right direction of swirl.

The cannula works as follows. First of all, it must be connected to a blood vessel by introducing the end of its working part 2 into the vessel through an incision in its wall. Through hoses connected to the connecting part of the cannula 1, blood, a blood substitute, or their mixture (hereinafter referred to as blood) enters the through channel of the cardiopulmonary bypass into the through channel of the cannula 3. In the connecting part of the cannula 1, the blood moves translationally, and in the working part 2, passing along the channel of the spiral 3, it acquires a rotational-translational motion, the nature of which is preserved in the arteries downstream due to the active interaction of the blood vessel wall and the environment. Arteries make up for the loss of energy of rotational motion and provide the optimal ratio of rotational and translational speeds in the helical blood flow.

It was established that a previously unknown property for a swirling fluid flow in conical channels to create a traction force in a screw flow, which is due to the existence of rotational energy in the screw flow. In general, the cardiovascular system is a cone-shaped channel in which there is a swirling flow of blood. Due to the rotational component of the blood movement, the distributed resistance of the vessels, the magnitude of which is determined by viscous friction, is overcome, the mechanism of pushing blood through the vessels in a spiral is “triggered”, i.e. directly the walls of the vessels begin to work, pushing the blood. The flow of blood in the circulatory system is as close to natural as possible. As a result, many complications observed during traditional cardiopulmonary bypass, the reasons for which are a violation of the blood flow, the lack of feedback between blood flow in the arteries and their active work, are eliminated.

The proposed vascular cannula provides the creation of a physiological helical blood flow during cardiopulmonary bypass, which is as close to natural as possible. The optimal ratio of rotational and translational components of the helical movement of blood provides an effective overcoming of vascular resistance and optimal conditions for microhemocirculation and transcapillary exchange.

Ultimately, through the use of the proposed vascular cannula during cardiopulmonary bypass, the transport function of the cardiovascular system as a whole is realized, since high efficiency of blood transportation in the vessels is achieved.

Claims (8)

1. The cannula, including an elongated body having at least two ends, while the area adjacent to one of the named ends is the connecting part of the cannula, and the area adjacent to the second of the named ends is the working part of the cannula, and in the said elongated body is made through the channel so that it enters the fluid from the end adjacent to the connecting part of the cannula, and leaves the end adjacent to the working part of the cannula, characterized in that its working part is made in the form of alcohol or in such a way that the ratio of the size of the diameter of the spiral and the size of its pitch provides the ratio of the rotational velocity of the fluid to the magnitude of its translational velocity as

. 2. The cannula according to claim 1, characterized in that the connecting part of the cannula is connected to a source of fluid. 3. The cannula according to claim 1 or 2, characterized in that the fluid is blood. 4. The cannula according to claim 1 or 2, characterized in that the fluid is a blood substitute. 5. The cannula according to claim 1 or 2, characterized in that the fluid is a mixture of blood and blood substitute. 6. Cannula according to any one of claims 1 to 5, characterized in that its working part is made in the form of a right-handed spiral. 7. The cannula according to any one of claims 1 to 5, characterized in that its working part is made in the form of a left-handed spiral. 8. The cannula according to any one of claims 1 to 7, characterized in that its working part is at an angle to the connecting part.

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