RU2682931C1 - Intraoperative thoracic blood flow analyzer - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention relates to medical equipment. Intraoperative thoracic blood flow analyzer comprises housing (1) with holder (2), head (3), module for monitoring blood oxygen saturation and module for monitoring the pressure force of a sensor for blood oxygen saturation. Head is fixed in the holder with the possibility of reciprocating motion. Module for monitoring blood oxygen saturation consists of sensor head (4) located at the distal end and a signal processing unit coming from the sensor. Sensor pressure control module consists of strain gauge sensor (5) and a signal processing unit from the sensor. Module for stabilizing the pressure of the sensor consists of permanent magnet (8) and electromagnet (11). Permanent magnet is fixed at the proximal end of the head. Electromagnet is fixed in the holder. Magnets are aligned with each other and the holder and are directed towards each other with like poles. Device is configured to control the current in the winding of the electromagnet based on the signal from the module monitoring the force of the pressure sensor oxygen saturation of blood. Strain gauge is located in the distal part of the head behind the blood oxygen saturation sensor.EFFECT: increase in the accuracy of measuring blood oxygen saturation during pulmonary pneumonectomy is achieved.3 cl, 2 dwg

Description

The invention relates to medicine, in particular to the surgical treatment of lung cancer, and can be used to measure blood oxygenation in pulmonary pneumonectomy.

Surgical treatment of lung cancer is characterized by the volume and invasiveness of surgical intervention. Despite the continuous improvement of the technique of operations, preoperative preparation and postoperative management of patients, the emergence of more advanced methods of processing the stump of the main bronchus, the use of the latest medical equipment, the frequency of development of bronchopleural fistulas after pneumonectomy remains quite high. (Sardak V.G., Polous Yu.M. "A method for the treatment of bronchial fistulas." 1987).

Enhanced mediastinal lymphatic dissection, accompanied by a high level of circulatory disturbance of the trachea and bronchi, has finally established itself in oncological practice, which, according to some authors, negatively affects the healing process of the stump of the main bronchus.

This is due, to a greater extent, to the fact that bronchopleural fistulas after pneumonectomy are related to the biological rather than the technical nature of this complication.

An important role in the development of bronchopleural fistula after pneumonectomy is played by a violation of blood circulation in the area of surgical intervention with extended and combined lung operations.

The treatment of bronchopleural fistulas with pleural empyema is still an urgent task: the effectiveness of repeated operations is insufficient (Ots ON, “Surgical treatment of the pathology of the operated lung”. 1993), their relapse rate and mortality after repeated operations are high, the level of “surgical aggression” is high »When performing repeated operations. Bronchopleural fistulas after pneumonectomies and loboectomies remain one of the most serious complications, significantly lengthening the length of stay of patients in the hospital and leading to new complications, on which the fate of the patient depends.

The problem of bronchopleural fistulas is a high mortality rate, which is caused by a formidable complication, and according to the literature is 25-71.2%. (Dobrovolsky S.R., Grigorieva S.P. "Combined resection in surgery for lung cancer." 1992). Surgical treatment of bronchopleural fistulas after pneumonectomy is often unsuccessful due to the occurrence of pleural empyema.

Repeated general anesthesia with prolonged mechanical ventilation, surgical trauma exacerbate the course of postoperative disease and worsen the prognosis. Relapse of the fistula after resection of the stump of the main bronchus occurs in more than half of cases, mortality is 48.5% (Abdumuradov K.A. “Retoracotomy in the treatment of acute complications after lung operations”. 1993).

However, the emergence of a large number of bronchoscopic methods for closing the bronchopleural fistula after pneumonectomy did not lead to the development of a unified prophylaxis, tactics and prognosis of this formidable complication. In addition, the above methods do not lead to satisfactory results and require certain material costs and conditions.

Thus, despite numerous studies and developments, there are currently problems of prognosis and prevention of primary failure of the stump of the main bronchus after extended, combined anatomically lung resections.

A known method of non-invasive measurement of blood oxygen saturation according to patent RU No. 2173082 C1 АВВ 5/00, АВВ 5/145, publ. 09/10/2001, based on the determination of the reflection coefficient of optical radiation, including irradiation of skin and biological tissue with monochromatic radiation with wavelengths λ1 = 650 ± 30 nm; λ3 = 830 ± 80 nm, photorecording a signal scattered by biological tissue using two channels operating in the bands λ1 and λ2, respectively, in which, after photorecording, the Doppler signal in the band is selected through the first channel

f1 = 2nvr / λl,

and on the second - in the strip

f2 = 2nvr / λ2,

where vr is the velocity of red blood cells in the studied section of the microcirculation system, n is the optical refractive index of the medium, amplitude detection of Doppler signals is performed, the variable (pulse or respiratory) and the constant parts of the signal are extracted along the first and second channels, and the variable is normalized to the constant component of the signal each channel, after which a part in phase with the signal of the first channel is extracted from the signal of the second channel, and the ratio of the signal of the first channel with the selected part is calculated Igna second channel.

The prototype of the claimed invention is the Intraoperative thoracic blood flow analyzer according to patent No. 166192, АВВ 5/1455, А61В 5/026, publ. 11/20/2016 Bull. 32, comprising a blood oxygen saturation sensor, consisting of a red and infrared radiation source and a photodetector, and a signal processing unit from this sensor, characterized in that the intraoperative thoracic blood flow analyzer comprises a pressure oxygen saturation sensor pressure control module, consisting of from the strain measurement sensor from this sensor and the signal processing unit coming from the strain measurement sensor, while the radiation sources and the photodetector are located one hundred ONU from the object of study on the distal end of the movable rod formed in the housing for linear displacement and mechanical contact with the strain measuring sensor, whose output is connected to the processing unit of the deformation of the probe signal.

The disadvantage of the prototype is the low accuracy of measuring oxygen saturation of blood during pneumonectomy of the lungs, due to the presence of measurement error associated with tremor of the hands of the operating staff.

The technical result, to which the claimed invention is directed, is to increase the accuracy of measuring oxygen saturation of the blood with pneumonectomy of the lungs.

The technical result is achieved by the fact that in the intraoperative thoracic blood flow analyzer, comprising a body with a holder, a head mounted in the holder with the possibility of reciprocating movement, a module for monitoring blood oxygen saturation, consisting of a blood oxygen saturation sensor located on the distal end of the head and a signal processing unit, coming from this sensor, as well as a module for monitoring the pressure force of the blood oxygen saturation sensor, consisting of a strain gauge and a processing unit and the signal coming from this sensor, new is that a stabilization module for the pressure force of the blood oxygen saturation sensor is introduced into it, consisting of a permanent magnet fixed to the proximal end of the head and fixed to the electromagnet holder, aligned with each other and the holder and directed towards each other poles of the same name, with the ability to control the current in the electromagnet winding based on a signal from the pressure monitoring module of the pressure sensor of saturation of blood oxygen, while the strain gauge is located n in the distal part of the head behind the oxygen saturation sensor. In the intraoperative thoracic blood flow analyzer, head movement is determined in the range of 5 ± 1 mm on both sides of the mid-position, which is sufficient to solve the problems posed by the authors. With an increase in the range of movement of the head, a significant increase in the nonlinearity of the change in the pressure value will be observed, which prevents the obtaining of a technical result. In the intraoperative thoracic blood flow analyzer, the signal processing units from the sensors are implemented as part of a microcontroller.

The invention is illustrated in FIG. 1 - FIG. 2, where FIG. 1 is a general view of the device, FIG. 2 - model of the movable head.

Here: 1 - housing, 2 - holder, 3 - head, 4 - blood oxygen saturation sensor, 5 - strain gauge, 6 - radio transmitter, 7 - induction power system for head elements, 8 - permanent magnet, 9 - accelerometer, 10 - microcontroller 11 - an electromagnet, 12 - a rechargeable battery, 13 - an amplifier, 14 - an induction battery charge module, 15 - a connector, 16 - a radio receiver, 17 - a display.

Intraoperative thoracic blood flow analyzer, consists of a housing 1 with a holder 2 and mounted in the holder of the head 3 with the possibility of reciprocating motion. At the distal end of the head there is a blood oxygen saturation sensor 4. In addition, a strain gauge 5, a radio transmitter 6, a part of the induction power supply system 7 of the head elements, a permanent magnet 8 and an accelerometer 9 are located in the head to determine excessively sharp accelerations of the device at the moment of contact with tissues body, because with a sharp contact of the head with tissues, the operation of the device may be incorrect. The microcontroller 10, the electromagnet 11, the battery 12, which feeds all the components of the device during its operation, the amplifier 13 for amplifying the signal fed to the electromagnet, the induction charge module 14 of the battery, part of the induction power supply system 7 head elements, connector 15 for connecting the device to the bedside monitor, a radio 16 receiving signals from sensors located in the head, a display 17 for displaying messages about the status of the device.

The device is used as follows: during pneumonectomy, after complete resection of the lung, a photometric oxygen saturation sensor 4 is installed on the site of the sutured tissue of the bronchus stump and is gradually pressed with increasing force to the tissues of the bronchus. The magnitude of the clamping force of the photometric sensor is measured by the strain gauge 5. At the moment the required initial clamping force is reached, a message is displayed on the display that the device has entered the operating mode and its operation has begun. The signal from the strain gauge enters the microcontroller 10, where it is processed. Next, the processed signal is amplified in the amplifier 13 and sent to an electromagnet 11, which interacts with a permanent magnet 8. The impact occurs with such a force that at each moment of time the force of pressing the head 3 against the bronchial tissue is in the range 0.7 ... 0.8 N / cm ² , which ensures the correct operation of the photometric sensor 4 and does not violate the blood flow in the study area. Such constancy of the pressure force of the head is achieved due to the fact that with an excess pressure of the head on the fabric, the current in the electromagnet winding is weakened, and the magnets repel each other with less force, which leads to the head entering the holder, compensating for the excess pressure on the fabric . With insufficient pressure of the head on the tissue site, the current in the winding increases, and the magnets repel with more force, so that the head extends from the holder, compensating for the insufficient pressure on the fabric. The signal from the photometric sensor 4, reflected from the boundaries of the test tissue and proportional to the absorption of radiation, enters the processing unit of this signal, which is part of the microcontroller 10. The device is connected to a standard, bedside monitor, which displays the oxygenation index of the blood and the pulse wave graph.

By the presence of pronounced pulsations of the blood flow and oxygenation rate, more than 80% judge the functional state of the bronchus stump and the viability of the surgical suture.

The proposed intraoperative thoracic blood flow analyzer with the ability to stabilize the clamping force of the optical sensor used in pneumonectomy is realizable and functional, allows to expand the diagnosis and reduce the incidence of bronchopleural fistula after surgery by adequately determining the degree of tissue oxygen saturation and to determine in advance the possible failure of the bronchus stump and background development of postoperative fistula.

Claims (3)

1. Intraoperative thoracic blood flow analyzer, comprising a housing with a holder, a head mounted in the holder with the possibility of reciprocating movement, a module for monitoring blood oxygen saturation, consisting of a blood oxygen saturation sensor located at the distal end of the head and a signal processing unit from this sensor, as well as a module for controlling the pressure force of the blood oxygen saturation sensor, consisting of a strain gauge sensor and a signal processing unit from this sensor, exl characterized in that a stabilization module for the pressure force of the blood oxygen saturation sensor is introduced, consisting of a permanent magnet fixed in the proximal end of the head and fixed in the electromagnet holder, coaxial to each other and to the holder and directed to each other by the same poles, with the possibility of controlling the current in the winding an electromagnet based on a signal from the pressure force control module of the blood oxygen saturation sensor, while the strain gauge is located in the distal part of the head behind the sensor blood oxygen saturation. 2. Intraoperative thoracic blood flow analyzer according to claim 1, characterized in that the head movement is determined in the range of 5 ± 1 mm on both sides of the mid-position. 3. The intraoperative thoracic blood flow analyzer according to claim 1, characterized in that the signal processing units from the sensors are implemented as part of a microcontroller.

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