RU2699735C1 - Method for digital and visual monitoring of intratracheal pressure by a bed monitor during artificial pulmonary ventilation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to intensive care, and can be used in artificial pulmonary ventilation (APV). Transducer for invasive monitoring and an infusion line are used. Latter is shortened to 50–60 cm. Distal end of the infusion line is inserted through the sanative port on the respiratory circuit adapter and the intubation or tracheostomy tube into the trachea, and the proximal one is connected to a transducer located as close to the patient's bed and strictly as the trachea. On a bedside monitor with an invasive pressure monitoring option, a sweep speed of 25 mm/s and a measurement scale of 0–20 mm Hg are set. After the system is reset, the intratracheal pressure is measured and visual observation of the pressure curve is monitored on the monitor. Herewith, three pressure values in the trachea are measured: maximum (Ppeak), minimum (PEEP) and average.

EFFECT: method enables accurate and affordable measurement of maximum (Ppeak), minimum (PEEP) and average intratracheal pressure in the APV process, as well as a visual analysis of the tracheal pressure curve by using a bedside monitor technique with an invasive pressure monitoring option, a transducer for invasive monitoring and an infusion line.

1 cl, 1 dwg, 1 tbl, 1 ex

Description

The invention relates to medicine, namely to intensive care and can be used during artificial lung ventilation (mechanical ventilation).

Mechanical ventilation is one of the most commonly used methods of intensive care. The selection of the optimal ventilation parameters is mainly done by analyzing the numbers determined by the pressure sensors of the ventilation device (peak pressure at the inspiratory height (Rpik), plateau pressure (Rplato), positive pressure at the end of exhalation (PDKV), auto PDKV) and calculation of a number of derivative indicators (ventilation pressure (Drivingpressure), compliance, elasticity and aerodynamic resistance of the respiratory system). At the same time, the sensors are located in the ventilator and, therefore, measure the pressure in the respiratory circuit, which differs from the true pressure in the patient's respiratory system.

A known method of measuring intratracheal pressure, which more accurately reflects the dynamics of pressure in the respiratory system during mechanical ventilation. However, only expensive and inaccessible ventilation devices of expert class have this option. In addition, for the implementation of monitoring, it is necessary to purchase additional consumables that are not universal and can be used with only one model of the ventilator (A.S. Goryachev, I.A.Savin. Basics of ventilator. Moscow, 2017). This limits the widespread use of informative monitoring of intratracheal pressure in mechanical ventilation in the practice of intensive care units.

However, all beds in the intensive care unit are equipped with bedside monitors, most of which have the option of invasive pressure measurement. It is widely used for invasive monitoring of arterial and central venous pressures.

The authors propose a method for digital and visual monitoring of intratracheal pressure for bedside monitors during mechanical ventilation.

The technical result of the proposed method is the ability in the process of mechanical ventilation to accurately measure the maximum (Rpeak), minimum (PEEP) and average intratracheal pressures, the determination of Rplato and autoPDKV, visual analysis of the tracheal pressure curve to detect flow hunger during an inspiratory attempt of the patient in PS mode and the correct calculation of such derived parameters like ventilation pressure (drivingpressure), compliance, elasticity of the respiratory system and aerodynamic drag.

The technical result is achieved by the fact that instead of expensive and inaccessible ventilation devices of expert class, for accurate measurement of intratracheal pressure indicators, visual analysis of the pressure curve and the correct calculation of the characteristics of the respiratory system and ventilation parameters, bedside monitors available in any intensive care unit with the option of invasive pressure monitoring are used.

To implement the method, a standard transducer is used for invasive monitoring of arterial and venous pressures and a small volume infusion line designed to connect the syringe dispenser to the intravascular catheter. In cases where arterial and / or venous pressure is already monitored, only the infusion line. This makes the proposed method not only affordable in any intensive care unit, but also low cost.

The highway is shortened to 50-60 cm, which reduces the air volume in it to 0.22-0.26 ml. The small volume of the trunk, the density of its wall and the only connection with the transducer minimize the possible damping.

Another factor that can affect the accuracy of the measurement is the natural frequency of the transduction system. But its influence on the accuracy of measuring intratracheal pressure is ruled out due to the low respiration rate and slow increase in pressure during inspiration. Small measurements of tracheal pressure during mechanical ventilation also contribute to measurement accuracy. (VV Kuzkov. M.Yu. Kirov. Invasive monitoring of hemodynamics in intensive care and anesthesiology. Arkhangelsk. 2015).

The distal end of the infusion line through the reorganization port on the respiratory circuit adapter and the endotracheal or tracheostomy tube are inserted into the trachea, and the proximal end is connected to the transducer located as close to the patient's bed and strictly at the level of the trachea. To ensure the tightness of the transduction system at the place of entry of the infusion line into the rehabilitation port, several layers of adhesive tape are fixed on it.

On the monitor, a sweep speed of 25 mm / s and a measurement scale of 0-20 mm Hg are set. After zeroing the system, it becomes possible to measure tracheal pressure and visually observe the pressure curve on the monitor screen. 3 indicators of pressure in the trachea are measured: maximum (Rpik), minimum (PEEP) and average. At the selected sweep speed on the monitor screen, you can simultaneously observe the schedule of 1.5-2 respiratory cycles.

Visual analysis of the ascending part of the pressure curve during ventilation in the pressure support (PS) mode through the endotracheal tube makes it possible to assess the sufficiency of the support pressure to overcome the resistance of the latter and reliably eliminate “flow hunger” during an inspiratory attempt by the patient (Fig.).

Along with this, after successively activating the keys of the ventilator to keep the breath in and out on the monitor screen, the numbers Rplato and auto PDKV are determined, respectively. Determination of the last two indicators makes it possible to calculate such derivative parameters as ventilation pressure (drivingpressure), compliance, elasticity of the respiratory system and aerodynamic drag.

To confirm the differences in the results of pressure measurements by the sensors of the ventilator in the respiratory circuit and the intratracheal pressure determined by the bedside monitor, 21 patients were studied. We tested 3 types of ventilators: Puritanbennett 840, Hamilton C3, MedicalcareAvea. Tracheal pressure was measured with a nihonkohden monitor. Before the study, the ventilators were tested with the subsequent activation of the options for compensating for loop compliance, leakage and correction of the endotracheal tube resistance.

The values of Rpik, PDKV, Rplato and autoPDKV, determined by the ventilator and the bedside monitor, were simultaneously recorded.

To measure Rplato and auto PDKV, the inspiration and expiration delay keys were activated for 2-3 seconds. with the subsequent "freezing" of the image of the pressure curves on the monitor of the ventilator. The pressure value was determined by the value in the middle of the delay interval. To translate mmHg Art. in cm of water. Art. used a coefficient of 1.33.

All hardware pressure indicators (regardless of the type of ventilator) exceeded those measured by a bedside monitor in the trachea. At the same time, the differences were not only unidirectional, but also comparable in degree. In this regard, we considered it possible to combine all patients into one group for a statistical analysis of the data obtained (table).

X (95% DI) - average value (95% confidence interval).

As can be seen from the table, hardware-based pressure monitoring to a different extent, but statistically reliable overestimated all the indicators determined.

From a practical point of view, it is important that the differences in the average value of the plateau reached 2.6 cm of water. Art. Therefore, the use of hardware Rplato for calculating ventilation pressure will significantly overestimate the determined indicator, which will lead to incorrect determination of ventilation pressure and the choice of the optimal maximum permissible concentration.

A slight difference in the hardware and tracheal indices of auto-PEEP is due to the fact that most patients did not have it.

However, in 5 patients who underwent mechanical ventilation in the mode of “dropping” airway pressure (APRV), which involves the artificial creation of auto-PDKV, its value in the trachea was on average 2.8 cm of water. Art. (2,4-3,1) lower than the hardware indicator. Given the direct correlation between the value of auto-PDCV and atelectotrauma, during mechanical ventilation in the APRV mode, the revealed differences become practically significant.

In addition, given that, in patients with acute bronchial asthma or chronic obstructive bronchitis, mechanical minimization of auto-PDCV plays a key role in mechanical ventilation, and its correct determination in these categories of patients is of fundamental importance. It should be noted that the greater the absolute value of the pressure indicator, the more its hardware monitoring distorts. So, the greatest pressure difference was observed when measuring peak pressure.

This is confirmed by the results of hardware and intratracheal pressure monitoring in patients with intraperitoneal hypertension.

Clinical example.

Patient K., 54 years old, with a diagnosis of destructive pancreatitis. Mechanical ventilation is carried out in volume control mode. In connection with intra-abdominal hypertension (pressure in the bladder - 23 cm water column), esophageal pressure is monitored. It, at the end of exhalation, was 20 cm of water. Art.

To achieve zero transpulmonary pressure, a hardware PDKV was installed - 20 cm of water. Art.

At the same time, the peak reached 34 cm of water. Art. (in the trachea - 27.8, the difference - 6.2) PDKV-20 cm of water. Art. (in the trachea - 16.8, the difference - 3.2), plateau - 29 cm of water. Art. (in the trachea - 25.2, the difference - 3.8), auto-PDKV - 2.2 cm of water. Art. (in the trachea - 0, the difference - 2.2).

The revealed difference of the determined indicators significantly exceeded the average pressure difference presented in table 1.

Thus, the inventive method is superior in accuracy to pressure monitoring with a ventilator, provides a correct calculation of the derivative parameters of the respiratory system and ventilator, a visual analysis of the pressure curve, is available in any intensive care unit and requires minimal material costs.

Claims (1)

A method for digital and visual monitoring of intratracheal pressure with a bedside monitor during artificial lung ventilation, including the use of a transducer for invasive monitoring and an infusion line, the latter being shortened to 50-60 cm, the distal end of the infusion line through a rehabilitation port on the respiratory circuit adapter and an endotracheal or tracheostomy tube injected into the trachea, and the proximal - connected to a transducer located as close to the patient’s bed as possible at the level of the trachea, on a bedside monitor with the option of invasive pressure monitoring, a sweep speed of 25 mm / s and a measurement scale of 0-20 mm RT are set. Art., after zeroing the system, the intratracheal pressure is measured and the pressure curve is visually observed on the monitor screen, while 3 indicators of pressure in the trachea are measured: maximum (Rpik), minimum (PEEP) and average.

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