RU2033750C1 - Apparatus to measure parameters of respiratory interchange of gasses - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: apparatus to measure parameters of respiratory interchange of gasses has oxygen concentration sensor, heating member 4, electronic-optical system of excitation and recording system. Oxygen concentration sensor sensitive member is made of thin aluminum plate, on which luminescent layer is applied. The layer is made of 10-20 mcm thick oxidized film with added organic complexes of platinum group metals. Recording system has photodetector 8 and air stream speed sensor 12, that are connected with processor through amplification and conversion units 9 and 10 correspondingly. Apparatus allows to measure instant values of oxygen concentrations in inhaling and exhaling air and to determine factor of used by organism oxygen at least during one breathing cycle. EFFECT: apparatus to measure parameters of respiratory interchange of gasses is used in medicine. 4 cl, 1 dwg

Description

 The invention can be used in systems of functional diagnostics of external respiration and blood circulation and allows to measure instantaneous values of oxygen concentration in the inhaled and exhaled air and to determine the oxygen utilization by the body for at least one respiratory cycle.

 A device for measuring gas exchange parameters is known (Japanese application N 63-21495, 1988, class A 61 B 5/08), comprising an oxygen concentration sensor, the function of which is performed by a gas analyzer, and a recording system.

 However, this device does not allow to monitor changes in oxygen concentration during one phase of exhalation. The accuracy of the measurements meets the requirements, but the measurement time is at least 5 s.

 It is also known a device for measuring the intensity of gas exchange in humans and animals, containing an oxygen concentration sensor and a recording system. The oxygen concentration in the inhaled and exhaled air is measured using an oxygen analyzer on a solid electrolyte heated to the required temperature. However, gas analyzers of this type have a low speed due to the mechanism of oxygen diffusion in a solid electrolyte and cannot be used for dynamic monitoring of oxygen concentration.

 The purpose of the invention is the creation of a device for measuring respiratory gas exchange parameters, for example, the oxygen utilization coefficient, which makes it possible to measure this parameter in each respiratory cycle, as well as to study the dynamics of changes in oxygen concentration in the exhalation phase. This ensures the required measurement accuracy, speed, eliminates pneumatic resistance to air flow during breathing.

 The device is based on the principle of measuring gas concentration by quenching luminescence.

 The invention consists in the following.

 A device for measuring respiratory gas exchange parameters contains an oxygen concentration sensor. The sensitive element of the sensor is made in the form of a thin plate of aluminum, on which a luminescent layer with a thickness of 10-20 μm is applied, which provides a short time for oxygen diffusion into the luminescent layer, and, as a result, the sensor performance is better than 0.2 s.

 The luminescent layer consists of an oxide film with introduced organic complexes of platinum group metals, which is due to the value of their spectral and luminescent characteristics. Organic complexes of metals of the platinum group are organometallic compounds whose molecules include metal atoms, organic fragments (ligands) and counterions.

Optimum results are obtained if Ru (bpy) ₃ Cl ₂ or Ru (Ph ₂ Phen) ₃ Cl _{2 is} introduced into the oxide film as organic complexes of the metals of the platinum group, since they, to a greater extent, satisfy the spectral-luminescent and environmental-economic characteristics to a greater extent , than others.

 The specific organic complex is selected depending on the range of measurement of oxygen concentration.

 The oxygen concentration sensor can be located in the housing and facing the luminescent layer to the electron-optical excitation system and a photodetector.

 In direct contact with the sensitive element of the oxygen concentration sensor is a heating element, which helps to stabilize the characteristics of the sensitive element and prevents it from fogging in contact with exhaled air.

The electron-optical excitation system can be made, in particular, in the form of a illuminator connected to a stabilizing device. As an illuminator, you can use any optical system that can cause luminescence. When choosing a more advanced illuminator from the point of view of radiation stability, the need for a stabilizing device disappears. A luminous flux with a radiation wavelength of λ _{1 is} directed to the surface of the sensor element. The luminescence λ ₂ excited by this luminous flux is perceived by the photodetector. In addition to the photodetector, the recording system also includes an air flow rate sensor and a processor. A photodetector and an air flow rate sensor are connected to the processor, in which the signals received from them are processed through the amplification and digitalization units.

 This arrangement of the device provides the required measurement accuracy and speed. The elimination of pneumatic resistance to air flow is facilitated by the above specific features of the sensor.

 The invention differs from the prototype in the sensitive element of the sensor, the presence of an electron-optical excitation system and the design of the recording system.

 The drawing shows a schematic diagram of a device for measuring the parameters of respiratory gas exchange.

In the housing 1, through which flows of inhaled (direction A) and exhaled air (direction B) pass, there is an oxygen concentration sensor 2 with a sensing element in the form of an aluminum plate with a luminescent layer 3 of a thickness of 15 μm. Luminescent layer 3 contains an oxide film into which organic complexes of platinum group metals are introduced, for example, Ru (bpy) ₃ Cl ₂ . It is known that in exhaled air the oxygen concentration is 15% and in atmospheric 21%. It has been experimentally established that the Ru (bpy) ₃ Cl ₂ complex has optimal characteristics for measuring oxygen concentration in this range. When changing the measuring range of the oxygen concentration, for example, in studies in pressure chambers, the optimal characteristics are the complexes of metals of the platinum group of a different composition, for example, Ru (Ph ₂ Phen) ₃ Cl ₂ .

 A luminescent coating can be made, for example, in accordance with the method of manufacturing the indicator coating (part No. 4812470/25, 1990).

 The sensor is located in the wall of the housing so that it does not resist air flow.

Directly in contact with the sensor element of the sensor 2 is a heating element, consisting of a heater 4, for example a nichrome spiral, and a control device 5, for example, a temperature controller Ш 4524. Thanks to the heating element, the sensor element is maintained with an accuracy of ± 0.5 ^о С in the temperature range 35-40 ^о С. On the opposite side of the casing there is an electron-optical excitation system and a recording system. The electron-optical excitation system comprises a illuminator 6, for example an incandescent lamp, and a stabilizing device 7, for example, B5-49.

 The recording system includes a photodetector 8, for example, a PMT-68, blocks 9 and 10 for amplifying and converting information into digital form, respectively, for example, an ADC-14, a processor 11, for example, based on DVK-2, and an air flow rate sensor 12 , for example, pneumotachovulimeter PT03-01. It is installed directly behind the oxygen concentration sensor.

 Another design embodiment of the device is also possible, for example, a lighting system and a photodetector can be placed in a separate housing, which can be connected by optical fibers to the sensor housing.

 The device operates as follows.

A luminous flux with a radiation wavelength corresponding to the absorption band used in the sensor element of the luminescent layer (for example, 450 nm for the luminescent layer Ru (bpy) ₃ Cl ₂ ) is directed from the illuminator 6 to the sensor element of the sensor 2 with a luminescent layer 3. The intensity of this flux is stabilized using device 5. The luminescence excited by the light flux with a radiation wavelength of 650 nm and intensity I (t), which depends on the oxygen concentration above layer 3, is perceived by the photodetector 8, The sky signal from which is sent through block 9 to the processor 11. The signal from the air flow rate sensor 12 through block 10 also arrives at the processor.

1

где t текущее время.Processing the signals received by the processor takes place in several stages. According to the Stern-Volmer equation, the instantaneous values of oxygen concentration in the exhaled air flow are found on the first measured values of I (t) and the value of the quenching constant K, which was previously determined when calibrating the sensitive element of the coated sensor
P (t)

1

where t is the current time.

P(t)·V(t)·S·dt где t₁, t₂ моменты времени, соответствующие началу и окончанию выдоха;
S площадь поперечного сечения воздушного потока.Next, the difference between the value of the oxygen concentration in the patient’s air P ₀ and its values in the exhaled air P (t) is calculated
Δ PP ₀ P (t). And finally, taking into account the air velocity V, measured using the sensor 12, the amount of oxygen used in the breathing process is determined
Q

P (t) · V (t) · S · dt where t ₁ , t ₂ moments of time corresponding to the beginning and end of exhalation;
S is the cross-sectional area of the air flow.

 Instantaneous values of the oxygen concentration in the stream of air exhaled by the patient can be represented graphically in the form of an oxygen barogram of the respiratory cycle on the display and at the same time calculate the coefficient of oxygen utilization by the body.

 The proposed device allows you to measure the parameters of respiratory gas exchange, in particular the coefficient of oxygen utilization in each respiratory cycle, as well as to study the dynamics of changes in oxygen concentration in the expiratory phase. The measurement accuracy is not worse than ± 2%, the response time is 0.1 s, there is practically no pneumatic resistance to air flow during breathing.

Claims (4)

 1. DEVICE FOR MEASURING RESPIRATORY GAS EXCHANGE PARAMETERS, comprising an oxygen concentration sensor with a sensing element in contact with the heating element, and a recording system, characterized in that it is equipped with an electron-optical excitation system, the oxygen element of the oxygen concentration sensor is made in the form of a thin plate from aluminum, on which a luminescent layer with a thickness of 10 to 20 μm is deposited from an oxide film with introduced trischelate organic metal complexes of the group otherwise, and the recording system contains a photodetector and an air flow velocity sensor, each of which is connected to a processor through an amplification and conversion unit.  2. The device according to claim 1, characterized in that the electron-optical excitation system is made in the form of a illuminator connected to a stabilizing device. 3. The device according to claim 1, characterized in that Ru (bpy) ₃ Ci _{2 is} introduced into the oxide film as a trischelate organic complex of the metal of the plate group. 4. The device according to claim 1, characterized in that Ru (Ph ₂ Phen) ₃ Cl _{2 is} introduced as the trischelate organic complex of the metal of the platinum group.