RU2175250C1 - Method of gas supply to body cavity - Google Patents

Abstract

FIELD: medical techniques, particularly, methods of supply of gas to body cavities for building up and maintaining of excessive pressure in body cavities. SUBSTANCE: volumetric rate of gas is additionally regulated with the help of electric control member by signal corresponding to measured volumetric rate which is compared with value set in conditions of initial filling and in subsequent pressure drop in rising from 1 to 15 l/min. In so doing, optimal volumetric rate corresponding to those restoring intracavitary pressure in its drop. Under conditions of maintenance of intracavitary pressure, working volumetric rate is determined depending on rate of said pressure drop and optimal volumetric rate. EFFECT: higher accuracy in maintenance of intracavitary pressure due to taking into account of pressure losses along gas supply route. 3 cl, 2 dwg

Description

 The invention relates to medical equipment, and in particular to methods of supplying gas to the body cavity, and is intended to create and maintain excess pressure in the body cavity in order to facilitate visualization of the state of the internal surface and contents of the cavity during laparoscopic operations and other medical procedures.

 A known method of supplying gas to the abdominal cavity and a device for its implementation. The method of insufflation of gas in the body cavity is that gas from a high pressure source is supplied through a system of valves, its pressure is reduced to 50 mm Hg. and then fed into the element in which the inlet valve, the outlet valve, and between them the volume for gas, the value of the intracavitary static pressure is determined by extrapolating the data of the rate of gas outflow from this volume. In this case, the valves are used to fill and empty the gas volume when it is supplied to the body cavity. The device for implementing this method comprises a gas supply line, a high pressure reducer, an adjustable safety valve, a switchable valve, then the supply line is divided into two branches on which the first and second valves are located, and between them a gas volume is provided, as well as a logic device for calculating the pressure in the body cavity at least at two points of pressure drop in the above gas volume and for monitoring the first and second valves, the pressure indicator, controlled by a logical device, transforms a pressure value into an electric signal and a device for injecting gas directly into the body cavity. These method and device are described in US patent N 5152745, M. cl. A 61 M 13/00, published on 6/10/1992.

 This method and device does not provide the necessary accuracy of maintaining intracavitary pressure during unexpected pressure surges due to the impossibility of compensating for the pressure drop on the elements of the gas supply line due to a significant limitation of the pressure at the inlet of the switched valve, as well as due to the final value of the volume for gas, which ultimately correct intracavitary pressure, which leads to an increased risk for the patient during surgical interventions.

 Closest to the proposed invention is a method of supplying gas to the body cavity, which consists in the fact that gas from a high pressure source is supplied through a high pressure reducer, a safety valve and an electromagnetic valve to a gas supply line, then to an electrically operated valve, a chamber, a throttle with a sensor differential pressure, another solenoid valve, while at the outlet of the gas supply line before it is fed into the body cavity, there is a pressure sensor whose signal corresponding to the internal Tnom pressure, and converted into an electrical direct via the microprocessor to the input of the above electric control valve, the flow is then introduced through the safety valve into the body cavity.

 A device for implementing this method comprises a high pressure gas source, a gas supply line, a high pressure reducer, safety valves, an electromagnetic valve, an element for controlling flow with an electrically operated valve, a chamber, a throttle with a differential pressure sensor for determining the presence of gas outflow from the above element for flow control, an outlet valve, as well as an outlet pressure sensor, a converter of its signal corresponding to intracavitary pressure to electric sky signal, the output transducer via a microprocessor connected to the input of the electric control valve, a power supply, the output gas feed line. Information about this invention was published on 06/13/1995 in US patent N 5423741, A 61 M 13/00.

 The disadvantages of this method and device for supplying gas to the body cavity are insufficient compensation for parasitic pressure losses on the gas supply line due to a significant pressure limitation before the gas is supplied to the electric controlled element and the feedback circuit from the output pressure sensor through the microprocessor to the electric input the controlled element works as a means for filling the chamber of a given volume without taking into account losses on the elements of the gas supply line, and then the gas is supplied through an additional electromagnet total valve into the body cavity. This leads to low accuracy of maintaining intracavitary pressure due to its regulation due to the use of finite gas portions determined by the chamber volume and insufficient compensation for pressure losses on the gas supply line.

 The basis of the invention is the task of increasing the accuracy of maintaining excessive intracavitary pressure by taking into account pressure losses in the gas supply path, which reduces the risk for the patient, as well as simplifying the design.

 The achievement of the above technical result is ensured by the fact that in the method of supplying gas to the body cavity by supplying gas from a high pressure source to the gas supply line, then to an electric controlled element for regulating the gas flow, then measuring the volumetric flow rate and then measuring the excess intracavitary pressure at the line outlet gas supply, its comparison with the maximum permissible value and supply to the input of the above element, according to the invention using an electric controlled electric the volume flow rate of the gas is additionally regulated using a signal corresponding to the measured volume flow rate, which is compared with the value set in the initial filling mode and with the subsequent decrease in excess intracavitary pressure in the increasing order in the range from 1 to 15 l / min, and the optimal volume flow is determined the flow rate corresponding to the restoration of excess intracavitary pressure during its decline, and in the mode of maintaining excessive intracavitary pressure, the working volume flow is determined lyayut depending on the speed of fall of pressure and the optimum volume flow, then the signal is fed to the input of said member; and also at the output of the gas supply line, the dynamic pressure of the gas flow is additionally measured, the corresponding signal is compared with the maximum allowable value and sent to the input of the above element.

 According to the invention, in the mode of maintaining excessive intracavitary pressure, the rate of change of pressure is determined, and with a multiple decrease in the rate of change of pressure, the working gas volumetric flow rate is chosen to be several times smaller than the optimal gas volumetric flow rate.

 The presence of an element that allows you to adjust the volumetric flow rate of the gas flow, the measurement of this flow rate, its comparison with the set value or the determined decay rate of the intracavitary pressure and the supply of this signal to the input of the above element (the so-called feedback on the volumetric flow rate) provide a quick response to change intracavitary pressure by selecting the volumetric flow rate necessary to quickly fill the cavity without creating unnecessary pressure surges, and thereby compensate for losses detecting in the gas supply path. This leads to an increase in the rate of pressure recovery and the accuracy of maintaining intracavitary pressure and, ultimately, a lower risk for the patient.

 The method of pressure recovery during unexpected pressure surges (greater than a certain threshold value), which reflects the dependence of the used volumetric flow rate on the pressure drop rate, also allows for the change in losses in the gas supply path, linking the pressure drop rate to the preset working volumetric flow rate, which reduces the possibility gas blowing during pressure recovery, and, therefore, to increase the accuracy of maintaining pressure, and thereby reduce the risk to the patient.

 Measurement of dynamic, and not only static pressure at the outlet of the gas supply line, its comparison with the maximum allowable value, and the supply of an element to the inlet that allows you to adjust the volumetric flow rate (the so-called feedback on the dynamic pressure of the gas flow) allow by limiting the dynamic pressure of the flow to reduce the risk for the patient without limiting the pressure at the inlet of the electric gearbox and without introducing additional stages of control, as is done in the prototype, which simplifies the entire product i.

 As the above analysis shows, the distinguishing features used in the claimed solution give the object positive properties that are not inherent in the well-known analogue and prototype, therefore, the claimed solution has significant differences.

 The method of supplying gas to the body cavity is illustrated in FIG. 1 and 2. In FIG. 1 shows a schematic diagram of an insufflation device; FIG. 2 is a diagram explaining a method of operating the device.

 The device shown to explain the gas supply method consists of a high pressure gas source 1, a high pressure reducer 2, safety valves 3 and 8, an electromagnetic valve 4, an electric controlled reducer 5, a flow sensor 6, a pressure sensor 7, a microprocessor module 9 with integrated into it by digital converters of the signals of the sensors 6 and 7 and the gas supply line 10 into the body cavity.

The method of supplying gas to the body cavity is as follows. On the microprocessor module 9 set the desired value of the excess intracavitary static pressure, usually not exceeding 25 mm RT. Art., and pre-set the maximum gas volumetric flow rate at a given time in the range from 1 to 15 l / min, choosing either the average volumetric flow rate in this range, or guided by medical indications. The volumetric flow rate of 1 l / min provides the necessary filling rate with minimal leaks, and 15 l / min is determined by the level of safety by the dynamic pressure, which we control before supplying gas directly to the body cavity, and, on the other hand, the transmittance of the standard means for supplying flow into the body cavity. Gas from the high pressure source 1 through the high pressure reducer 2, the solenoid valve 4 is supplied to an electrically controlled reducer 5, and during the supply of this portion of gas, the reducer gradually increases the pressure at its outlet until a predetermined volumetric flow rate through flow sensor 6, or until the dynamic pressure measured by the pressure sensor 7 does not exceed the maximum allowable value of 70 mm Hg, which provides an additional level of protection for the patient from overpressure. This filling phase is shown in the time diagram (Fig. 2) as 0-t ₁ . If during the time 0-t _{1 the} specified excess atmospheric intracavitary pressure P _{0 is} not reached, the gas supply cycle is continued in the respective filling phases until the required excess intracavitary pressure P ₀ is obtained. In this case, the volume flow rate set in the microprocessor 9 changes depending on the difference between the measured value of the intracavitary pressure and the value set by the operator in order to ensure a minimum excess of the set pressure.

At time t ₁ corresponding to the end of the filling phase, the gearbox 5 closes. In the measurement phase t ₁ -t ₂ is determined by the static pressure in the body cavity obtained for the first portion of the gas supply (t ₁ -t ₂ does not exceed 0.5 s, which corresponds to the time of establishment of the static pressure in the body cavity). Then begins the mode of tracking and maintaining pressure at a given level P ₀ + Δ using the built-in microprocessor unit 9 system for tracking the rate of change of excess intracavitary pressure. If the pressure drops (for example, at time t ₈ ), then begin to increase the volumetric flow rate set on the microprocessor module 9 to a predetermined maximum flow rate until the set value of the static intracavitary pressure is restored. In the microprocessor module 9, the last obtained volumetric flow rate is stored, which is taken as the optimal volumetric gas flow rate Q ₀ . If, for example, at time t ₁₂ a pressure drop is obtained greater than a predetermined threshold value, then the process of its restoration depends on the length of the decay time of the intracavitary pressure, that is, on the rate of change of the above pressure. For example, if t ₁₁ -t _{12 is} less than or equal to 1 s, then pressure is restored at the optimum volumetric flow rate Q ₀ . If the time interval t ₁₁ -t ₁₂ is approximately 2 s, then the volume flow rate 1/2 Q _{0 is} automatically set in the microprocessor 9. If the pressure recovery time is about 4 s, then the gas volumetric flow rate is 1/4 Q ₀ . This ensures quasi-continuous stabilization of excess intracavitary pressure.

 If the decrease in excess intracavitary pressure is significantly greater than the specified threshold value, then the pressure recovery process is similar to the gas supply process in the initial filling mode.

 Thus, pressure stabilization is achieved by controlling the volumetric flow rate, i.e. The main function in this case is the feedback between the flow sensor 7 and the reducer 5, carried out using a digital converter, which accelerates the response to changes in excess intracavitary pressure, taking into account changes in pressure losses in the gas supply path.

 The proposed method of gas insufflation into the body cavity passed technical tests in clinics of St. Petersburg and demonstrated high reliability, fast pressure stabilization and high accuracy of pressure maintenance, set by the threshold value.

Claims (3)

 1. The method of supplying gas to the body cavity by supplying gas from a high pressure source to the gas supply line to an electric controlled element for regulating the gas flow, then measuring the volumetric flow rate and then measuring the excess intracavitary pressure, comparing it with the maximum allowable value and supplying a signal corresponding to the difference of these pressures at the input of the above electric element, characterized in that the electric gas control element further regulate the volumetric gas flow with the signal corresponding to the measured volumetric flow rate, which is compared with the value specified in the initial filling mode and at the first pressure drop in ascending order in the range from 1 to 15 l / min, and the optimal volumetric flow rate corresponding to the restoration of excess intracavitary pressure is determined the first decline, and in the mode of maintaining excessive intracavitary pressure, the working volumetric gas flow rate is determined depending on the rate of decline of this pressure and the optimal volumetric flow yes, then this signal is fed to the input of said member and the outlet gas feed line additionally measured dynamic pressure gas stream, a corresponding signal is compared with a maximum value and is directed to the input of said member.  2. The method according to claim 1, characterized in that in the mode of maintaining excessive intracavitary pressure, the rate of change of excess intracavitary pressure is determined.  3. The method according to claim 1, characterized in that in the mode of maintaining excess intracavitary pressure with a multiple decrease in the rate of change of excess intracavitary pressure, the working gas volumetric flow rate is chosen to be a multiple of less than the optimal gas volumetric flow rate.

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