RU166192U1 - Intraoperative Thoracic Bleeding Analyzer - Google Patents

Abstract

1. Intraoperative thoracic blood flow analyzer containing a blood oxygen saturation sensor, consisting of a red and infrared radiation source and a photodetector, and a signal processing unit coming from this sensor, characterized in that the intraoperative thoracic blood flow analyzer contains a saturation sensor pressure control module blood oxygen, consisting of a strain measurement sensor from this sensor and a signal processing unit coming from a strain measurement sensor, while and radiation and a photodetector arranged on one side of the object of investigation 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 a signal processing unit of this sensor deformatsii.2 measurement. An intraoperative thoracic blood flow analyzer according to claim 1, characterized in that the length of the movable stem is determined by the anatomical features of the human chest. 3. The intraoperative thoracic blood flow analyzer according to claim 1, characterized in that the source and receiver of the blood oxygen saturation sensor are located at an angle to each other to obtain the maximum signal-to-noise ratio.

Description

The utility model relates to medicine, in particular to the surgical treatment of lung oncology, 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 belong 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 techniques for closing the bronchopleural fistula after pneumonectomy did not lead to the development of a single prevention, 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.

, а по второму - в полосе

, где ν_r - значение скорости движения эритроцитов в исследуемом отделе системы микроциркуляции, n - оптический показатель преломления среды, производят амплитудное детектирование доплеровских сигналов, выделяют переменную (пульсовую или дыхательную) и постоянные части сигнала по первому и второму каналам, производят нормировку переменной к постоянной составляющей сигнала по каждому из каналов, после чего из сигнала второго канала выделяют часть, синфазную с сигналом первого канала, и вычисляют отношение сигнала первого канала с выделенной частью сигнала второго канала.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 λ ₁ = 650 ± 30 nm; λ ₃ = 830 ± 80 nm, photorecording a signal scattered by biological tissue using two channels operating in the λ ₁ and λ ₂ bands, respectively, in which, after photorecording, the Doppler signal in the band is selected through the first channel

, and in the second - in the strip

, where ν _r is the value of 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, the variable is normalized to constant component of the signal for 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 signal ratio of the first channel with part of the signal of the second channel.

The disadvantage of this method is the complexity of the hardware and software implementation of the determination of oxygen consumption by the tissue and selection of various departments of the microcirculation system.

The prototype of the claimed utility model is a gynecological blood oxygenation meter RU 121721 C2 A61B 5/145, A61B 5/02, publ. 11/10/2012, containing a red radiation source connected to the first current source, an infrared radiation source connected to the second current source, a photodetector made in the form of a photodiode, and a current-voltage converter connected to the photodetector, a voltage amplifier with a logarithmic conversion characteristic, the input of which is connected to the output of the current-voltage converter, the first synchronous detector connected in series, the first input of which is connected to the output of the amplifier voltages with a logarithmic conversion characteristic, a first high-pass filter and a first AC voltage amplifier connected in series to a second synchronous detector, the first input of which is connected to the output of a voltage amplifier with a logarithmic conversion characteristic, a second high-pass filter and a second AC voltage amplifier, as well as a shaper antiphase pulses with a frequency of 200-2000 Hz, the first output of which is connected to the control input of the first synchronous detector, and the second the output is to the control input of the second synchronous detector, and connected by its output to the indicator and its first and second inputs to the outputs of the first and second AC amplifiers, respectively, of the function calculation unit

,

,

и

- коэффициенты экстинкции восстановленного гемоглобина на длинах волн излучения соответственно в красном и инфракрасном диапазонах излучения;

и

- двойные амплитуды переменного напряжения на выходах соответственно первого и второго усилителей напряжения переменного тока;

и

- коэффициент экстинкции оксигемоглобина на длинах волн соответственно в красном и инфракрасном диапазонах излучения, отличающийся тем, что он дополнительно содержит формирователь опорных напряжений с регуляторами "Амплитуда токов", "Баланс токов" и "α", а также регулируемый источник переменного напряжения частотой 1-2 Гц и коммутатор, при этом первый и второй выходы формирователя опорного напряжения подключены соответственно к первому и второму входам коммутатора, первый и второй управляющие входы которого соединены соответственно с первым и вторым выходами формирователя противофазных импульсов частотой 200-2000 Гц, первый и второй выходы коммутатора подключены к управляющим входам соответственно первого источника тока и второго источника тока, выход регулируемого источника переменного напряжения частотой 1-2 Гц подключен к входу "α" формирователя опорных напряжений, упомянутый блок вычисления функции выполнен в виде последовательно соединенных мультиплексора, аналого-цифрового преобразователя и микропроцессора, при этом первый и второй входы мультиплексора являются соответственно первым и вторым входами упомянутого блока вычисления функции, третий и четвертый входы мультиплексора соединены с выходами первого и второго синхронных детекторов соответственно, управляющие входы аналого-цифрового преобразователя и мультиплексора соединены соответственно с первым и вторым управляющими выходами микропроцессора.where: S is the saturation coefficient;

and

- extinction coefficients of reduced hemoglobin at radiation wavelengths, respectively, in the red and infrared ranges of radiation;

and

- double amplitudes of the alternating voltage at the outputs of the first and second amplifiers of the AC voltage, respectively;

and

- the extinction coefficient of oxyhemoglobin at wavelengths, respectively, in the red and infrared ranges of radiation, characterized in that it further comprises a voltage shaper with regulators "Amplitude of currents", "Balance of currents" and "α", as well as an adjustable source of alternating voltage with a frequency of 1- 2 Hz and a switch, while the first and second outputs of the reference voltage driver are connected respectively to the first and second inputs of the switch, the first and second control inputs of which are connected respectively to the first and second outputs of the antiphase pulse shaper with a frequency of 200-2000 Hz, the first and second outputs of the switch are connected to the control inputs of the first current source and the second current source, respectively, the output of an adjustable AC voltage source with a frequency of 1-2 Hz is connected to the input "α" of the reference voltage shaper , said function calculation unit is designed as a series-connected multiplexer, analog-to-digital converter and microprocessor, while the first and second inputs of the multiplexer are respectively, the first and second inputs of the said function calculation unit, the third and fourth inputs of the multiplexer are connected to the outputs of the first and second synchronous detectors, respectively, the control inputs of the analog-to-digital converter and the multiplexer are connected respectively to the first and second control outputs of the microprocessor.

The disadvantage of the prototype presented is the difficulty of its use in pneumonectomy of the lungs, associated with the need to isolate the studied area of the bronchus and place it in the lumen between the sources and the radiation receiver.

The technical result, which is claimed by the claimed utility model, is to improve its design, which allows to measure the saturation of the blood sample with oxygen by the reflection method for pneumonectomy of the lungs.

The technical result is achieved by the fact that in the intraoperative thoracic blood flow analyzer containing a photometric sensor for oxygen saturation of the blood, consisting of red and infrared radiation sources, a photodetector and a signal processing unit coming from this sensor, it is new that the radiation sources and receiver are located at one side of the investigated area of the bronchus and work on reflection, and the meter contains a control module for the deformation of the studied area of the bronchus, consisting of a sensor and measuring the contact force photometric sensor to the test site and the deformation signal processing unit, wherein the photometric sensor is mounted at the distal end of the movable rod formed in the housing to contact a sensor measuring the deformation of the test area, whose output is connected to a signal processing unit.

In the intraoperative thoracic blood flow analyzer, the length of the movable stem is determined by the anatomical features of the human chest.

The source and receiver of the oxygen saturation sensor for blood to obtain the maximum signal to noise ratio are located at an angle to each other.

The essence of the utility model is illustrated in FIG. one.

Intraoperative thoracic blood flow analyzer is a photometric transducer 7 mounted on a movable rod 6, mounted using a retainer 3 and a holder 5 in the housing 4 with the possibility of linear movement until contact with the strain gauge 2,

In FIG. 2 shows a model of the distal portion of a moving rod with a photometric transducer.

At the distal end of the movable rod 6 there are elements of a blood oxygen saturation sensor containing radiation sources in the red and infrared light ranges 9, a photodetector 10, which can be located at an angle of 160 ° to reduce losses caused by light scattering, which allows you to get the maximum length of the focused area measurements in 8 ... 10 mm. The supply and signal wires from the red and infrared radiation sources and a photodetector pass inside and exit through channel 8 for connection to a control and processing unit (not shown in the figures).

The device is used as follows: during pnevmonectomy, after complete resection of the lung, a photometric oxygen saturation sensor is installed on the site of the sutured tissue of the bronchus stump. The magnitude of the pressing force of the photometric sensor is set within 0.7 ... 0.8 N / cm ² . The signal from the photometric sensor, reflected from the boundaries of the investigated tissue and proportional to the absorption of radiation, enters the information processing unit (not shown in the figures).

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 used in pnevmonectomy is feasible and efficient, 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 postoperative fistula.

Claims (3)

1. Intraoperative thoracic blood flow analyzer containing a blood oxygen saturation sensor, consisting of a red and infrared radiation source and a photodetector, and a signal processing unit coming from this sensor, characterized in that the intraoperative thoracic blood flow analyzer contains a saturation sensor pressure control module blood oxygen, consisting of a strain measurement sensor from this sensor and a signal processing unit coming from a strain measurement sensor, while and radiation and a photodetector arranged on one side of the object of investigation 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. 2. The intraoperative thoracic blood flow analyzer according to claim 1, characterized in that the length of the movable stem is determined by the anatomical features of the human chest. 3. The intraoperative thoracic blood flow analyzer according to claim 1, characterized in that the source and receiver of the blood oxygen saturation sensor are located at an angle to each other to obtain the maximum signal-to-noise ratio.

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