SU1581323A1 - Lacertus blood circulation apparatus - Google Patents

Abstract

The invention relates to medical equipment, is used in the secondary blood circulation apparatus and allows to increase the accuracy of selection of the diseased heart unloading mode by providing intensive outflow of a part of blood from the aorta to the systole phase and separate control of the pressure unloading values. For this, parallel to the pumping device 5, serially connected to the cardiac synchronizer 1, the phasing device 2, the control unit 3 and the drive 4 of the pumping device, a switch 9 of streams is connected via tees 10.11, the control input of which is electrically connected to the output of the metering device 2. 1 or .

Description

The invention relates to medical technology, in particular to assisted circulatory machines.

The purpose of the invention is to improve the accuracy of selecting the mode of unloading of the affected heart by ensuring intensive outflow of a portion of blood from the aorta into the systole phase and separately adjusting the values of the unloading by pressure and flow.

The drawing shows a block diagram of the auxiliary blood circulation apparatus.

The device consists of a cardiosynchronizer 1, a phasing device 2, a control unit 3, a drive 4, a pumping device

5, the inlet and outlet cannulas 6 and 7, the tube 8, the switch 9 of the flow of the tube and the tees 10 and 11, the tube 8 being connected to the input cannula 6 and the entrance of the pumping device 5 and to the output cannula 7 and the output of the pumping device 5, and a flow switch 9 is mounted on the tube 8, the control input of which is connected to the output of the phasing device 2.

The device works as follows.

Cardiosynchronous isolator 1 from the input electrocardiogram (ECS) highlights informative features characterized by

with

1C

with

The activity of the patient's heart and generates pulses that arrive at the phasing device 2 and set, - the duration of the period of the current heartbeat cycle. Phasing device 2 performs phase control of the pumping device operation and generates output pulses that are phase-shifted with respect to a sync pulse (for example, an R-wave EX), which are fed to control unit 3.

The latter forms the parameters and the shape of the electrical signal, which through the actuator 4 controls the pressure in the working chamber of the pumping device 5.

When connecting the pumping device 5 to the patient's body only through and the output cannula 6 and 7, the process of the auxiliary blood circulation proceeds as follows. In the heart systole phase, the pumping device 5 draws blood from the left atrium through the inlet cannula 6. In the diastole phase of the heart, the blood is expelled from the pumping device 5 through the exit cannula 7 into the aorta, whereby the pressure in the aorta rises, which favorably affects the maintenance of coronary blood flow. In the diastole phase, the heart is only partially filled with blood, in connection with the fact that part of the blood from the atria took the pumping device into the heart systole phase. This volume of blood is discharged into the systole phase of the heart in the aorta. Since there is pressure in the aorta during this phase, the heart releases blood, increasing the pressure in the aorta even more, i.e. pressure is applied to the heart. By changing the performance of the pumping device, we thereby change the discharge of the heart according to the flow rate, which is determined by the ratio of the flow of blood flowing through the pumping device to the total flow of blood passing through the total peripheral resistance. By increasing the discharge of the heart according to the flow rate, we thereby decrease the volume of blood ejected by the heart. At the same time, the mean pressure in the aorta during the cardiac systole, i.e. pressure unloading increases slightly (up to 20%). Consequently, the discharge of the natural heart by pressure and

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five

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The flow rate is interdependent and cannot be adjusted separately, and the amount of unloading suppression does not exceed 20%.

To increase the degree of pressure of the natural heart by pressure, i.e. increasing the efficiency of the auxiliary blood circulation, as well as ensuring the possibility of separate regulation of pressure unloading and discharge unloading, a shunt is inserted in the tube connection circuit of the pumping device to the cardiovascular system in the form of a tube 8 installed between the inlet and outlet of the pumping device 5 flow, which is controlled by a signal from the output of the phasing device. 2. B. phase of the release of blood from the pumping device, i.e., into the natural heart diastole phase, “switch 9 pinches tube 8, therefore there is no blood flow through it into this phase. In the filling phase of the pump device 5, i.e. In the heart systole phase, the switch 9 partially opens the lumen of the tube 8 and part of the blood from the aorta is taken through this tube by the pumping device 5, and the blood pressure in the aorta decreases in the heart ejection phase, therefore, the pressure relief value of the heart increases. By adjusting the degree of lumen of the tube 8 into the heart systole phase, we regulate the pressure relief of the heart regardless of the control of the discharge flow rate, thereby providing the possibility of creating an optimal mode for the speedy recovery of the affected heart.

Claims (1)

Invention Formula The auxiliary blood circulation device containing a cardio-synchronizer serially connected, a phasing device, a control unit, a pump device drive and a pump device connected by a hydraulic input to the input and output to an output cannula, in order to increase the accuracy of the discharge mode of the affected heart by providing intensive outflow of part of blood from the aorta into the systole phase and the paouch adjustment of the values pressure and flow discharges, a switch flow is introduced into it, connected in parallel to the pumping device via tees, installed in the input and output cannulas, and the control input of the flow switch is electrically connected to the output of the phasing device. F eleven To patient