EA023035B1 - Method and device for controlling inspiration trigger and breathing machine - Google Patents

Abstract

A method and a device for controlling an inspiration trigger and a breathing machine. The control method comprises detecting a parameter value in an air passage in an expiration process (S102); judging whether the parameter value reaches an inspiration trigger value changing with the autonomous expiration cycle of a patient (S104); and determining, according to a judgment result, whether to switch from expiration to inspiration (S106). Through the control method and device, the inspiration trigger can be conveniently controlled, thereby reducing ineffective inspiration work of the patient without incurring a false trigger.

Description

FIELD OF THE INVENTION

The present invention relates to the field of mechanical ventilation apparatus, in particular to a method and apparatus for controlling a trigger of inspiration and a mechanical ventilation apparatus.

BACKGROUND OF THE INVENTION

In certain ventilation modes of a ventilator, such as a pressure-assisted ventilation (P8U) mode, a pressure trigger mechanism or a flow trigger mechanism are usually used to determine the switching time from exhalation to inhalation in order to realize synchronization between aspiration (t ie air release) of the artificial lung ventilation apparatus and spontaneous inhalation of the patient. Regardless of whether a pressure trigger or a flow trigger is used, exhalation to inhale switching is triggered as soon as the controlled airway pressure or flow reaches a preset threshold value, which is the so-called trigger sensitivity.

Since a flow trigger usually requires less effort (less patient effort to inhale) than a pressure trigger, a flow trigger is considered preferable, especially in the case of Auto-PEEP, pediatric lung ventilation, and non-invasive ventilation. The downstream trigger sensitivity is usually set manually according to the principle that the trigger sensitivity is as low as possible in order to avoid false triggering of the trigger.

Trigger false triggering occurs from time to time during lung ventilation for reasons such as interference with flow measurement, gas leakage, flow fluctuations caused by leakage, patient vibration due to heart activity, and patient movement. To avoid false triggering, a higher trigger sensitivity is usually used. Thus, impaired trigger sensitivity is used, since the higher trigger sensitivity used will increase the patient's effort to trigger the inspiration trigger and even lead to ineffective inspiration.

Therefore, it is necessary to develop a trigger mechanism that can eliminate the false triggering of the trigger, but does not increase the patient's effort to trigger the inspiration trigger. Kekrioszek Εκρτίΐ (U200) artificial lung ventilation apparatus uses a spontaneous trigger mechanism based on multiple information in which several different trigger mechanisms are triggered at different expiration periods, that is, more trigger criteria are used along with improved expiration, and if any of the data is satisfied trigger criteria trigger is triggered, as a result, the sensitivity of the trigger becomes higher and higher.

Although the possibility of false triggering of the trigger can be reduced without increasing the patient's effort to trigger the inspiration trigger by limiting the sensitivity of the trigger in the early phase of exhalation and by increasing the sensitivity of the trigger at the end of exhalation, the Kekrioshek EkrgN (U200) mechanical ventilation scheme is very inconvenient, for example: (1) many trigger criteria are used to define a trigger, which increases the number of calculations on the one hand; (2) on the other hand, a fixed threshold value is automatically provided to each trigger criterion, and it is very difficult to ensure the rationality of these threshold values; and (3) in order to determine the current specific period within the expiration, there are several complex definition standards that are manually configured in the mechanism.

As for the contradiction in setting the sensitivity of the inspiration trigger in related technologies, effective solutions have not yet been provided.

Summary of the invention

The present invention has been proposed in connection with the problem of setting an impaired sensitivity of an inspiration trigger. In this regard, the aim of the present invention is to provide a method and device for controlling an inspiratory trigger and a ventilator for solving this problem.

In order to accomplish the above object, there is provided a method for controlling an inspiration trigger according to one aspect of the present invention. This control method includes monitoring the value of the parameter in the respiratory tract during expiration; assessment of the achievement by the value of the parameter of the value of the trigger of inspiration, which varies with the cycle of spontaneous expiration of the patient; and determining whether to switch from exhalation to inhalation according to the result of the evaluation.

Additionally, the parameter value in the airways contains airway pressure; or airway flow.

Additionally, monitoring the value of the parameter in the airway contains monitoring the change in the value of the parameter in the airway and evaluating the achievement of the value of the parameter of the trigger value includes assessing the achievement of the change in the value of the parameter in the airway sensitivity of the trigger.

Additionally, determining whether to switch from exhalation to inspiration according to the result of the evaluation includes determining a point in time to switch from exhalation to inspiration by means of a pressure trigger mechanism or a flow trigger.

Additionally, before evaluating whether a parameter value has reached a trigger value, methods

- 1 023035 also include receiving parameter information entered by the user; and obtaining a trigger value according to the parameter information.

To accomplish the above, an inspiratory trigger control device according to another aspect of the present invention is provided. The control device includes a control module configured to control the value of the parameter in the respiratory tract during expiration; an evaluation module for evaluating whether a parameter value has reached a trigger value; and a determining module for determining whether to switch from exhalation to inhalation according to the evaluation result.

Additionally, the parameter value in the airways contains airway pressure; or airway flow.

Additionally, the inspiration trigger control device also includes a receiving module adapted to receive parameter information entered by a user; and a receiving module adapted to obtain a trigger value according to the parameter information.

To accomplish the above objectives, there is provided an artificial lung ventilation apparatus according to another aspect of the present invention. The artificial lung ventilation apparatus comprises the above inspiration trigger control device.

Using an innovative method that includes monitoring the value of the parameter in the respiratory tract during exhalation, assessing the achievement of the value of the parameter of the value of the trigger of inspiration, which varies with the spontaneous exhalation cycle of the patient, and determining the need to switch from exhalation to inspiration according to the result of the assessment, the problem of setting the sensitivity of the trigger is impaired inspiration in the related art and thus achieved the task of effectively controlling the inspiration trigger.

A brief description of the graphic materials

The graphic materials presented here provide a further understanding of the present invention and form part of this application. Illustrative embodiments and their description of the present invention are used to explain the present invention without undue limitation, where:

in FIG. 1 is a flowchart of a method for controlling an inspiration trigger according to an embodiment of the present invention;

in FIG. 2 is a flowchart of a flow trigger in P8U mode according to an embodiment of the present invention;

in FIG. 3 is a schematic diagram of a false trigger waveform according to an embodiment of the present invention;

in FIG. 4 is a schematic diagram of a trigger sensitivity based on obtaining information about a patient's spontaneous expiration time according to an embodiment of the present invention;

in FIG. 5 is a flowchart of a method for controlling an inspiration trigger according to a preferred embodiment of the present invention;

in FIG. 6 is a schematic diagram of an inspiration trigger control device according to an embodiment of the present invention.

Detailed Description of a Preferred Embodiment

It should be noted that the embodiments and features of the embodiments in the present invention can be combined with each other without forming contradictions. The present invention will be described in detail in combination with embodiments and with reference to graphic materials.

In FIG. 1 is a flowchart of a method for controlling an inspiration trigger according to an embodiment of the present invention.

As shown in FIG. 1, the method includes the following steps: 8102, 8104, and 8106.

At step 8102, the value of the parameter in the respiratory tract is monitored during expiration.

At step 8104, it is judged if the parameter value has reached the trigger value.

In addition, monitoring the value of the parameter in the airways contains monitoring the change in the value of the parameter in the airways and evaluating the achievement of the value of the parameter of the trigger value includes assessing the achievement of the sensitivity of the trigger by changing the value of the parameter in the airway.

At step 8106, the necessity of switching from exhalation to inhalation is determined according to the evaluation result.

Preferably, determining whether to switch from exhalation to inspiration according to the result of the evaluation comprises determining a point in time to switch from exhalation to inspiration by means of a pressure trigger mechanism or a flow trigger.

Preferably, the airway parameter value comprises airway pressure; or airway flow.

Preferably, before evaluating whether a parameter value has reached a trigger value, the method also comprises receiving parameter information entered by a user; and getting the value

- 2 023035 triggers according to the parameter information.

When the ventilator is ventilating the patient’s lungs, to ensure synchronization of aspiration of the ventilator with spontaneous inhalation of the patient, it is necessary to control the pressure or flow in the airways and determine if the change in pressure or flow has reached a certain trigger sensitivity in the exhalation phase, so that to conclude that the patient began to inhale, and therefore, determine the need to switch from exhalation to inhalation in an artificial ventilation apparatus soft.

Using the mechanism for determining the expiratory time of a patient in the present invention, the flow trigger sensitivity is continuously adjusted during inspiration to monotonically decrease the flow sensitivity of the trigger simultaneously with the exhalation process, thereby eliminating false triggering of the trigger and ineffective inspiratory effort of the patient to improve the synchronization of human and machine inspiration.

The mechanism of the self-regulating inspiratory trigger provided by the present invention is applicable to the PFU mode, the constant positive airway pressure mode (CPAP), the controlled assisted ventilation mode (A / C), the synchronized intermittent forced ventilation mode (§1MU), etc. . in invasive and non-invasive ventilation.

The following is an explanation of preferred embodiments of the present invention.

The purpose of the innovative technical scheme is to solve the dilemma of setting the trigger sensitivity in the traditional flow trigger mechanism, that is, a higher trigger sensitivity can reduce the possibility of false triggering of the trigger, but can also increase the patient’s effort to trigger the inspiration trigger, leading to a relatively significant delay in inspiration, even ineffective inspiratory effort of the patient; on the contrary, the low sensitivity of the trigger can reduce the patient’s effort to trigger the inspiratory trigger, but lead to a false trigger.

In P8U mode, for example, the classical waveforms of flow and pressure during ventilation are shown in FIG. 2. There are two obvious characteristics in the initial breath of the patient, ie decreased airway pressure and increased flow. When using the flow trigger mechanism, if the controlled flow is higher than the set trigger sensitivity for the flow, switching from exhalation to inhalation, called a trigger, is performed.

In order to avoid false triggering of the trigger, the relatively high sensitivity of the trigger in the flow is usually set due to the waste of effort of inspiration of the patient. As shown in FIG. 3, the waveform of the usual false trigger response does not contain an obvious characteristic of the patient's inspiration, namely, a decrease in airway pressure. Thus, according to the understanding of the characteristic of a false trigger waveform in practice, the flow trigger mechanism provided by this patent combined the reduction in airway pressure as a criterion for determining the switch from exhalation to inhalation, i.e., the trigger is triggered when the flow is higher than the set trigger sensitivity by flow, and airway pressure below a certain fixed threshold. Thus, a lower sensitivity of the flow can be set without false triggering, thus you can save the effort of inspiration of the patient.

By combining a reduction in airway pressure, although most false triggers can be avoided on the assumption that the trigger has sufficient sensitivity, false triggering can also be caused by a set lower sensitivity. Given this fact, the present patent provides a mechanism for self-regulating flow trigger, based on obtaining information about the patient's spontaneous expiration time, in order to completely resolve the contradiction of setting the flow sensitivity.

The essence of this technology is depicted in FIG. 4. This idea comes from the understanding that the respiratory cycle (or exhalation cycle) of a patient with the ability to spontaneously trigger inspiration is stable for a certain period. Therefore, the flow sensitivity of the trigger can be set according to the predicted inspiratory time of the patient, that is, the lower sensitivity of the trigger is set at the moment when the patient is most likely to take a breath, but the higher sensitivity of the trigger is set before this point. In this case, the prediction of the start time of the patient's inspiration is based on obtaining information about the expiration time in the previous several breathing cycles during ventilation.

As shown in FIG. 4, the limiting period of the TEISH trigger, during which the trigger is not detected, is usually present at the beginning of each exhalation, this strategy is used in many existing mechanical ventilation devices, that is, switching from exhalation to inhalation is not allowed in this period. The period TE1eagp indicates the spontaneous expiration time of the patient, determined from at least one previous ventilation cycle. For exhalation in the period after the TEish period, but before the TE1eagp period, the trigger sensitivity along the flow monotonically increases. In this case, three curves of monotonic decrease in sensitivity, i.e. a linear curve, an exponential curve, and a sectional curve are depicted, for example, in FIG. 2-4 respectively.

As for curve 1 in FIG. 4, namely, the curve of a linear decrease in sensitivity, the sensitivity of the trigger during ί (TENT <GOTE1eat), i.e. ΙΤδ (ί), calculated by the formula (1)

1T $ (1) ЩТ85С1- | (1Т88е1-ГГ8т1п) / (TE1еагг-1 ТЕПт)] * (1’ТЭП1Т1) (р

As for curve 2, namely, the curve of the exponential decrease in sensitivity, the sensitivity of the trigger during ί (TENT <GOTE1eat), i.e. ΙΤδ (ί), calculated by the formula (2)

ΓΓ8 (ί) = ΓΤ5δεΙ- (ΓΓ88εί-ΓΓ8ηιϊη) * exp [(1-TE1еат) / £] (2) where the time constant τ of the exponential function exp [] in formula (2) is constant, which may differ depending on situations .

As for curve 3, namely, the curve of sectional decrease in sensitivity, the sensitivity of the trigger during ί (TENT <GOTE1eat), i.e. 1T8 (b), calculated by the formula (3)

ГГ8 (1) = ГГ88еТЭИш <I <Т8 ЕГ8 (() = 1Т8ггйп, 1> ТB (3) where ТБ is a moment near the end of the period TE1еат and can be constant depending on the situation.

The block diagram of the present technical scheme is shown in FIG. 5, where the calculation in process 1 is represented by the above formulas (1), (2) or (3). The period TE1eat in each ventilation of process 2 is updated by the formula (4)

TE1eagp (1) = 4 * TE1eat (1-1) + (1 -4) * ΤΕί (4) where TE1eagi (1) indicates the patient's spontaneous expiration time, updated by receiving information from the current ventilation cycle, and TE1 indicates the current expiration time, α is a constant from 0 to 1 and preferably equal to 0.8.

It should be noted that the steps depicted in the flowcharts of graphic materials can be performed by a set of instructions executed by a computer in a computer system. Although the logical order is shown in the flowchart, the steps depicted or illustrated may, in a particular case, be performed in a manner different from it.

An inspiration trigger control device is provided according to an embodiment of the present invention.

In FIG. 6 is a schematic diagram of an inspiration trigger control device according to an embodiment of the present invention.

As shown in FIG. 6, the device comprises a monitoring module 602, an evaluation module 604, and a determining module 606.

The control module 602 is designed to control the value of the parameter in the respiratory tract during expiration; evaluation module 604 is designed to determine whether the value of the trigger reaches the value of the parameter, and determining module 606 is designed to determine whether to switch from exhalation to inspiration according to the evaluation result.

Preferably, the parameter value in the airways comprises the value of the pressure in the airways or the flow in the airways.

Preferably, the inspiration trigger control device also comprises a receiving module adapted to receive parameter information entered by a user; and a receiving module adapted to obtain a trigger value according to the parameter information.

An embodiment of the present invention also provides a ventilator comprising the above inspiration trigger control device.

As can be seen from the above description, the present invention has implemented a simple inspiration trigger control. In addition, the present invention solved the problem of asynchronization between a person and a machine caused by an established impaired trigger sensitivity in a conventional flow trigger mechanism, such as delaying inspiration, ineffective inspiratory effort of a patient, and false triggering. Thus, the trigger mechanism according to the invention can ensure that the patient’s effort to trigger the inspiratory trigger can be reduced as much as possible, but without causing a false trigger. In addition, the present invention does not require a change in the installation interface of the traditional downstream trigger mechanism, namely, the user still sets the highest sensitivity of the trigger downstream. In addition, the calculation of the technical scheme of the present invention is small.

Obviously, a person skilled in the art will understand that the corresponding modules or steps of the present invention, as mentioned above, can be implemented using a conventional computing device and can be integrated into a single computing device or distributed over a network consisting of several computing devices. Optionally, the modules or steps may be implemented using program codes executed by a computing device, and therefore, may be stored in a storage device for execution by a computing device, or integrated into respective integrated circuit modules, or several modules or steps integrated into a single integrated module schemes. Thus, the present invention is not limited to any particular hardware and software configuration.

The above descriptions are only preferred embodiments of the present invention, which are not used to limit the present invention. It will be apparent to those skilled in the art that the present invention may be subjected to various modifications and changes. Any changes, equivalents, improvements, etc. within the scope of the principle of the present invention are also within the scope of protection of the present invention.

Claims (6)

CLAIM 1. A method of controlling an inspiratory trigger, including controlling a parameter value, such as pressure or airway flow during expiration; determining the moment when the specified parameter reaches the value of the trigger parameter of the inspiration trigger, which can be set according to the predicted patient inspiratory time during the patient's spontaneous exhalation cycle; switching the ventilator from expiration to inspiration, if the parameter reaches the value of the trigger parameter of the inspiration trigger. 2. The method according to claim 1, characterized in that they control the change in the value of the specified parameter in the airways, while determining whether this parameter reaches the value of the trigger response parameter provides for determining whether the specified parameter reaches the sensitivity of the trigger in the airways. 3. The method according to claim 1, characterized in that before determining the achievement by the specified parameter in the airways of the value of the trigger response parameter, the method further includes receiving the value of the specified parameter in the airways and receiving the value of the trigger response parameter according to the obtained value of the specified parameter in the airways. 4. An inspiration trigger control device comprising a control module configured to control a parameter value, such as pressure or airway flow during expiration; an evaluation module configured to determine when the indicated parameter reaches the value of the trigger response parameter; and a determining module, configured to switch from exhalation to inspiration, if the parameter reaches the value of the trigger parameter of the inspiration trigger, and the inspiration trigger control device is configured to set the parameter of the trigger response according to the predicted patient inspiratory time during the patient's spontaneous exhalation cycle. 5. The device according to claim 4, characterized in that it further comprises a receiving module, configured to receive the value of the specified parameter in the airways; and the receiving module, configured to obtain the value of this trigger response parameter according to the obtained value of the specified parameter in the airways. 6. An artificial lung ventilation apparatus comprising an inspiratory trigger control device according to any one of claims 4 to 5.