SU858843A1 - Device for controlling heart prosthesis - Google Patents

Description

(54) DEVICE FOR HEART PROSTHESIS MANAGEMENT

Claims (1)

The invention relates to medical technology and can be used in replacing the natural heart. A heart control device is known, which contains a pressure servo-mechanism coupled to a heart prosthesis with a pneumotrack, a rhythm generator, and a waveform transducer 13. The disadvantages of the known device include the fact that the use of a blood pressure sensor in the atrium leads to thrombus formation at the installation site and, as a result, to a distortion of the measurement result and a decrease in the accuracy of controlling the performance of the prosthesis under the substitution of the body's needs. The lack of prosperity is also the inability to control the performance of the prosthetic heart due to the simultaneous change in the shock output and the heart rate. The purpose of the invention is to maintain the COf of the circulatory tonus of the circulatory system by introducing a functional physiological relationship between heart rate and stroke output. The goal is achieved by the fact that the device for controlling the heart prosthesis, containing a servo-mechanism of pressure, connected to the heart prosthesis, pneumotrack, rhythm generator, forward wave transducer, is equipped with a flow sensor, a current percussion surge meter, a memory unit and a functional transducer. in the pneumotrack of the ventricle of the prosthetic heart and is connected to the input of the current, shock output meter, the output of which is connected through the memory unit to the input of the functional device an educator whose output is connected to the input of a rhythm generator. 3 The drawing shows a block diagram of the left cannula of the prosthetic heart control device. The device comprises a servo-mechanism of pressure, communicating with the left heart prosthesis 2 through a flow sensor 3, a current shock output meter 4, a memory unit 5, a functional transducer 6, a rhythm generator 7, and a waveform transducer 8. The device works as follows. The signal from the rhythm generator 7 through the transducer 8 of the waveform enters the electrical input of the servo-mechanism 1 pressure. At the pneumatic output of the pressure servo-mechanism 1, a pneumatic signal of pressure of a given shape and duration is formed. When the pressure changes at the entrance to the prosthesis 2 of the heart, the filling volume of its blood chamber changes, which leads to a change in the diastolic gas flow rate in the pneumatic section of the heart prosthesis, which is removed by means of the flow sensor 3. The signal from the flow sensor 3 to diastole is fed to the input of the meter 4 of the current impact surge and from the output of the meter to the memory block 5, which converts the discrete electrical signal corresponding to the current value of the shock surge to a smoothly varying analog voltage. This voltage connects to the input of the functional transducer 6, which is a device that allows you to set a physiological functional relationship between the values of the shock output and the frequency of reduction of the heart prosthesis. The output voltage from the transducer 6 is fed to the control input of the rhythm generator 7 and changes the heart rate in accordance with the physiological dependence existing in the body. And since the device is equipped with a guaranteed systole-assisted automaton, the performance of the prosthetic heart in a pneumatic stationary mode will be determined by the body's atrial pressure (diastolic filling or shock output) set by the body and the physiologically associated heart rate. Thus, the prosthetic heart control device allows automatic selection of performance depending on the amount of venous inflow. At the same time, by maintaining the physiological correspondence between the shock release and the frequency of contractions, there is no violation of the vascular tone of the circulatory system. Claims A heart control device comprising a pressure servo connected to a heart prosthesis with a pneumatic path, a rhythm generator, a waveform converter, characterized in that, in order to maintain the vascular topus of the circulatory system by introducing a functional physiological relationship between heart rate and shock output, it is equipped with a flow sensor, a current impact surge meter, a memory unit and a functional transducer, with the flow sensor t.anovlen in pnevmotrakte prosthetic heart ventricle and connected to the input of the current stroke volume meter, which output is via the storage unit connected to the input of a functional transducer whose output is coupled to the input of the rhythm generator. Sources of information taken into account in the examination 1. NASA Report, TNO-6171, 1971. K i / cmovHuift / dQ $ ff9H (// i (i / ffrfff (/ mJlfy Qiftfjicenufi