DE8015055U1 - Device for measuring at least two pneumatic lung parameters and measuring methods for this - Google Patents

Description

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Dr S gerwerk Aktiengesellschaft Molsllnger Allee 53-55. 2400 L 0 b e c k

Device for measuring at least two pneumatic Lunq parameters

The invention relates to a device for measuring at least two pneumatic lung parameters, namely the linear part of the airway resistance R ₁ , the square part of the airway resistance R_, the compliance C and the residual alveolar pressure P. in particular in connection with a ventilator, this device being input signals from a pressure sensor and a flow meter from the breathing air duct and in which a time-controlled integrator forms a corresponding volume signal from the flow signal, and in which the desired pneumatic lung parameters are also determined from these signals.

For people to be monitored, especially for patients ventilated with a ventilator, a continued and rapid determination of pneumatic lung parameters required. For this purpose, for example in DE-OS 25 13 676 an electronic device for automatic measurement and display of the flow resistance R of the air in the bronchial passages and the elasticity E of the pulmonary tissue based on measured values the breathing air flow and the change in endothoracic pressure.

A respiratory analyzer in which the breathing gas flow through time integration from differential pressure signals and other pneumatic parameters, such as absolute Tracheal or bronchial pressure can be measured is described in DE-OS 27 19 900.

DE-OS 24 13 988 and DE-OS 25 22 774 explain methods for researching intrathoracic respiratory mechanics, and thus for the determination of pneumatic lung parameters.

Finally, DE-AS 19 33 472 contains a respiration or. Anesthetic ventilator with pneumatic lung parameters can be put together in the form of a curve from measured instantaneous values.

Another prior art device according to DE-OS 23 37 061 relates to a respiratory volume measuring device in connection with a breathing pressure transducer, which triggers a controlled display and / or alarm device, which responds to a variable that depends on the ratio of respiratory pressure to respiratory volume.

Because of the strong spread of the measured values in the breathing air flow, the previously known devices the calculated or displayed pneumatic lung parameters are too imprecise for many monitoring purposes. The invention is based on the task of designing a device of the type specified at the outset in such a way that that a rapid determination of the desired, pneumatic lung parameters with high accuracy is made possible.

This task is solved by that a scanning device is provided, which at time intervals associated signals for Pressure, plow and volume are scanned as triples of measured values and at least two within each breathing cycle stores such measured value triples in a periodically erasable memory device, and that a computing device is provided which is connected to the scanning device and the memory device is connected, the desired from the stored measured value triples Lung parameters are calculated from linear systems of equations known per se, and that this computing device is connected to a display and / or control device which displays the lung parameters and / or outputs to control a ventilator.

In the practical version of the measuring device, the pressure and flow sensors generated signals measured, and by integration from the flow measurement or by direct Measurement is used to determine the volume. The quantities forming a triplet of measured values are electrical Voltages are available and are scanned accordingly.

To assign the triple measured values with regard to the In the inspiration or expiration phase, the measuring device expediently checks the flow curve · Is the flow equals 0 for a while and suddenly becomes> 0, then becomes

• · · ·> till ··· 4

The beginning of expiration is assumed, and then, in the expiratory phase, the required levels are generally assumed The highest possible number of measured value triples p, V, V is stored, with values also increasing in terms of amount Must be included in the course of the plow. These serve to identify and differentiate between inspiration and Expiratory phase. Typically, the maximum amount of the flow occurs in the expiratory phase approx. 50 ms after Bx * the beginning of the inspiration. The sampling period, i.e. the time span in which the measured value triples are stored, must be at least equal to the time constant of the lungs.

If, for example, the values for R ₁ , R ₂ , C and P _{Q are to be} determined, then from the linear system of equations

^p i ⁺ 1 * i ⁺ 2 * 1 i I * i ~ C ο ~ i * ο i = 1,2,3,4

be assumed in which the equation coefficients can be formed from four triples of measured values (ρ, V and V). The system of linear equations can only be solved if not two of the quantities p, V and V are linearly dependent.

In this direct determination, all measurement errors are also processed, and In addition, the calculation fails if one of the three quantities p, V and V is constant. Stores however, if a plurality, in particular a plurality of triples of measured values, is used, the above can be done linear system of equations in the minimum condition of the

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i - serial number of the sample

η »number of sampled value triples (p, V, V)

Mean V is the instantaneous value of the flow

V is the volume of the inflated lungs at the end of inspiration ⁰

ρ is the instantaneous value of the pressure in front of the mouth

P is the residual alveolar pressure
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R _{1 is} the linear part of the airway resistance R _{2 is} the quadratic part of the airway resistance

C the compliance, i.e. the reciprocal of the elasticity of the lungs.

After the required number of triples of measured values has been stored, the optimum values for R ^, R ₂ , C and P, which are optimal in terms of measurement technology, are calculated and displayed using the specified system of equations of η stored measured value triples. _{The measuring device can display the values of R 1} , R ₃ , C and P valid for this breath after each breath.

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The plow is preferably measured in the expiratory branch, but the measurement is also in the inspiratory branch or possible in the common breathing air duct.

The measuring device is functional even if the patient is not connected to a ventilator and only inhales and exhales through a measuring tube, if this is ensured by appropriate valve control becomes that at the beginning of expiration ρ> 0 and ρ decreases, while | v | increases. The applicability of the measuring device is also given when the patient is in Spontaneous or IMV or SIMV ventilation status, as well as PEEP.

In simpler embodiments of the measuring device, only two pneumatic lung parameters, preferably the linear part of the airway resistance R and the compliance C ₁₁ , omitting the square part of the airway resistance R and the alveolar part

Residual pressure P can be determined,
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The measurement does not affect p, V or V either during the inspiration or during the expiration phase. In addition, it is not necessary to have an end-expiratory or an end-inspiratory plateau for p, V or V is reached; the presence of a linear exhalation resistance is also not a prerequisite for the applicability of the measuring device, which can also be used for non-linear expiratory resistance.

The accuracy of the measurement result increases with the number of scanned triples of the measured values. This number must be so be greater, the greater the measurement errors in the individual

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The determinants ρ, V and V are.

The drawing shows a block diagram of the measuring device according to the invention.

A flow sensor is located in an expiratory branch 1 determined by a corresponding valve arrangement 2, the output signal of which is determined in a measured value unit as flow variable V and integrated into a Volume size V is transformed.

A pressure sensor is located in a common breathing air duct 4 5 is provided, the output variable of which is also fed to the measured value unit 3 and determined as ρ. In the measured value unit 3 thus has the quantities p, V and V available at any point in time. The scanning is carried out by Signals from a computing device 6 equipped with a microprocessor, which by monitoring the absolute values of the flow also determines the beginning of the desired measurement phase (inspiration or expiration).

The measured value triples scanned by a scanning device 7 in the measuring phase, a maximum of about 250 measured value triples, are stored in an erasable storage device. At the end of each measuring phase, the measured value triples are transferred from the storage device 8 to the computing device 6, and there are due to linear Systems of equations based on the method of the least sum of the squares of errors are optimal values of the values to be determined pneumatic lung parameters R ^, R-, C and P calculated and displayed in a display device 9.

The expiration branch 1 and an inspiration branch 10 of the common breathing air duct 4 are in the present case connected to a ventilator 11.

Claims (3)

claims 1. Device for measuring at least two of the following pneumatic lung parameters, namely the linear part of the airway resistance R ₁ , the square part of the airway resistance R2 »compliance C and the residual alveolar pressure P ₀ , in particular in connection with a ventilator, this device Input signals are supplied from a pressure sensor and a flow meter from the breathing air duct and in which a time-controlled integrator forms a corresponding volume signal from the flow signal, and in which the desired pneumatic lung parameters are also determined from these signals, characterized in that for receiving the input signals in A scanning device (7) is provided for the inspiration or expiration part of the breathing cycle, to which a periodically erasable storage device (8) is connected to store the input signals, and a computing unit (6) with both the scanning device g (7) and with the storage device (8), and that the computing unit (6) is connected to a display and / or control device (9) for forwarding the calculated lung parameters. 2. Device according to claim 1, characterized in that that as a controllable integrator for volume determination from the flow signal a volume measuring device is provided. 3. Device according to claim 1, characterized draws that the arithmetic unit (6) with a microprocessor is equipped.