专利摘要:
The invention provides positive pressure ventilation ("VPP") systems and methods that deliver a patient a range of pressures for treatment when the patient is determined to be asleep, and a standby pressure for use when the patient is determined as being awake, the standby pressure being adapted for the comfort of the patient. The standby pressure is adapted to be lower than the lower limit of the pressure range and may be a therapeutic or subtherapeutic pressure. The VPP systems and methods described herein advantageously allow the adaptation of the pressure range for an effective treatment of sleep-disordered breathing while allowing adjustment of the sleep pressure for patient comfort. This can advantageously increase both the efficacy of the treatment of TRSs and the observance of treatment by the patients.
公开号:FR3019468A1
申请号:FR1552566
申请日:2015-03-26
公开日:2015-10-09
发明作者:Andrew Gordon Gerred；David Robin Whiting
申请人:Fisher and Paykel Healthcare Ltd；
IPC主号:

专利说明:

[0001] BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to systems for the treatment of obstructive apnea in patients with obstructive sleep apnea. sleep by providing positive pressure ventilation to a patient, in particular, methods enabling the device to adjust the treatment pressure in response to respiratory disorders during sleep and in the awake state of the patient. STATE OF THE ART [0002] A major therapeutic strategy for obstructive sleep apnea includes the supply of respiratory gases to the patient throughout the duration of his sleep. These treatments may be referred to collectively as Positive Pressure Ventilation (PPV). Variations of this therapy include those with different inspiration and expiration pressures, commonly referred to as bi-VPP or two-level PPV, or with continuous treatment adjustment in response to respiratory events.
[0002] SUMMARY OF THE INVENTION [0003] The systems, methods and devices described herein have innovative aspects, none of which are indispensable or solely responsible for their desirable characteristics. Some of the advantageous, non-limiting features of the scope of the claims will be summarized below. The present description describes a positive pressure ventilation system that delivers gas to a patient when he is asleep, the gas being under a pressure that is in a range of sleep pressures, and under a pressure of 40.degree. different standby when the patient is awake, the standby pressure being lower than the minimum pressure in the range of sleep pressures. This can advantageously improve the comfort of the device for a patient, which can increase the compliance of the positive pressure ventilation therapy. Increased compliance in general improves the results of therapy for the patient. In a first aspect, there is provided a positive pressure ventilation system which includes a flow generator adapted to deliver gas under pressure to a patient. The positive pressure ventilation system also includes a user interface adapted to deliver the gas under pressure to the patient and a conduit for the gas to pass from the flow generator to the user interface. The positive pressure ventilation system also includes a sensor adapted to measure the patient's breathing. The positive pressure ventilation system also includes a control system adapted to detect sleep breathing disorders, based at least in part on an analysis of data acquired by the sensor; determine a sleep state of the patient, based at least in part on an analysis of data acquired by the sensor; controlling the flow generator to deliver a pressure between a low pressure and a high pressure when the sleep state is determined to be the asleep state, the delivered pressure being based at least in part on the fact that sleep are detected; and controlling the flow generator to provide a sleep pressure different from the low pressure if the sleep state is determined to be the awake state, the sleep pressure is selected by a user. In some embodiments of the first aspect, the standby pressure is a therapeutic pressure. In some embodiments of the first aspect, the standby pressure is lower than the low pressure. In some embodiments of the first aspect, the regulator is further adapted to regulate the flow generator to provide a pressure that increases with time at a first pressure ramp rate when the pressure that is provided by the Flow generator is the standby pressure and sleep state is determined as the sleeping state or if sleep breathing disorders are detected. In another embodiment, the first pressure ramp rate is adjustable by the user. In some embodiments of the first aspect, the regulator is further adapted to adjust the flow generator to provide a pressure that lowers over time at a second pressure ramp rate when the pressure supplied by the generator flow is between the low pressure and the high pressure and the state of sleep is determined as the awake state. In another embodiment, the second pressure ramp rate is adjustable by a user. In some embodiments of the first aspect, the low pressure and the high pressure are adjustable by a user. In some embodiments of the first aspect, the sensor is one of a flow sensor, a pressure sensor, a sound sensor, a motion sensor, or a plethysmograph sensor. In the second aspect, there is provided a method for providing positive pressure ventilation therapy to a patient. The method includes receiving an input from a user to set a sleep pressure, detecting a presence of sleep disordered breathing; determining a patient's sleep state; if the state of sleep is determined to be the sleeping state, the supply of gases having a sleep pressure that is set between a low sleep pressure and a high sleep pressure, the sleep pressure depending at least in part the presence of sleep disordered breathing; and if the state of sleep is determined to be the awake state, the supply of gas having the standby pressure, the standby pressure being different from the low sleep pressure. In some embodiments of the second aspect, the standby pressure is a therapeutic pressure. In some embodiments of the second aspect, the sleep pressure is lower than the low sleep pressure. In some embodiments of the second aspect, the method further includes raising a pressure of the gas delivered at a first ramp rate when the pressure being delivered is at the standby pressure and the condition of the sleep is determined to be the sleeping state where sleep breathing disorders are detected. In another aspect, the method includes receiving input from a user to adjust the first ramp rate. In some embodiments of the second aspect, the method includes lowering a pressure of the delivered gas at a second ramp rate when the pressure that is delivered is between the low sleep pressure and the sleep pressure. elevated and the state of sleep is determined to be the waking state. In another aspect, the method includes receiving input from a user to adjust the second ramp rate. In some embodiments of the second aspect, the method includes receiving input from a user to adjust low sleep pressure and high sleep pressure. In some embodiments of the second aspect, detecting a presence of sleep-disordered breathing includes analyzing values from a sensor, the sensor comprising at least one flow sensor, a pressure sensor, a sensor, and a sensor. sounds, a motion sensor or a plethysmograph. In a third aspect, there is provided a user interface which is communicatively coupled to a control system of a positive pressure ventilation apparatus. The user interface includes a standby pressure node adapted to receive standby pressure data indicative of standby pressure. The user interface includes a low pressure node adapted to receive lower limit data indicative of a lower limit of a range of pressures. The user interface includes a high pressure node adapted to receive upper limit data indicative of an upper limit of the pressure range. The user interface communicates the idle pressure, the lower limit of the pressure range and the upper limit of the pressure range to the control system, and the control system instructs the positive pressure ventilation apparatus to deliver a breathing gas having the standby pressure if a sleep state is determined to be the awake state, the standby pressure is different from the lower limit of the pressure range. In some embodiments of the third aspect, the standby pressure is less than the lower limit of the pressure range. In some embodiments of the third aspect, the user interface further includes a ramp rate node adapted to receive ramp rate data indicative of a pressure ramp rate. In another embodiment of the third aspect, the control system switches from standby pressure to pressure in the pressure range at the pressure ramp rate.
[0003] BRIEF DESCRIPTION OF THE DRAWINGS [0016] In all the drawings, the reference numbers may be reused to indicate a general correspondence between the reference elements. The drawings are given to illustrate illustrative embodiments described herein and should not be construed as limiting the scope of the description. [0017] FIG. 1 illustrates a VPP system for providing VPP therapy to a patient, the VPP system including a flow generator, a regulator, a patient interface and a conduit connecting the patient interface and the flow generator. [0018] FIG. 2 shows a block diagram of an exemplary VPP system adapted to deliver a standby pressure when a patient is awake and a range of pressures when the patient is asleep, the minimum pressure in the range being different standby pressure. FIG. Figure 3 shows a graph of pressure for a patient versus time, the graph showing different events and the responses to events. [0020] FIG. 4 is a process diagram of an exemplary method of providing a patient with standby pressure and a range of pressures when the patient is asleep, the minimum pressure in the range being different from the standby pressure.
[0004] DETAILED DESCRIPTION OF THE INVENTION [0021] Certain embodiments and examples of systems and methods for providing positive pressure ventilation are described herein. The systems and methods generally include providing a range of pressures for treating sleep disordered breathing when a patient is determined to be asleep and a sleep pressure when the patient is determined to be awake. The pressure range and the sleep pressure may include therapeutic and / or subtherapeutic pressures. Those skilled in the art will appreciate that the description extends beyond the specifically described embodiments and / or specifically described uses and obvious modifications and their equivalents. It should therefore be understood that the scope of the invention is not limited by any of the particular embodiments described herein. As used herein, the term sleep disordered breathing has a broad meaning and should have its ordinary and obvious meaning to the ordinary person skilled in the art and includes at least one of a group of disorders characterized by abnormal breathing pattern (eg, breaks in breathing). Respiratory sleep disorders include, for example and without limitation, obstructive sleep apnea, upper airway resistance syndrome, Cheyne-Stokes respiration, and the like. As used herein, the term "therapeutic pressure" has a broad meaning and should have its ordinary and obvious meaning to those of ordinary skill in the art and includes at least one pressure adapted to be effective in the treatment of respiratory disorders of the present invention. sleep. Subtherapeutic pressure, by comparison, is a pressure that is less than the pressure that is effective for the treatment of sleep-disordered breathing. The fact that a pressure is therapeutic may depend on the patient and / or time. For example, a pressure of 10 cm H2O may be a therapeutic pressure at a given time for a particular patient because it reduces or eliminates in that patient sleep breathing disorders at that time and, by extension, any lower pressure. at 10 cm H2O would be subtherapeutic pressure for this patient at that time. [0024] Positive pressure ventilation ("VPP") systems may be adapted to deliver a continuously adjustable pressure adapted for treating sleep breathing disorders ("TRS"). It is possible to use a pressure algorithm that analyzes the breathing of a patient to determine a pressure to deliver to the patient.
[0005] The pressures to be delivered to the patient, or the pressures determined by the pressure algorithm for delivery to the patient may be forced to enter a range of pressures. Pressures in the pressure range, however, may be uncomfortable for a patient who is awake or awake during treatment. In some VPP systems, the minimum pressure of the pressure range can then be delivered when the patient is determined to be awake to reduce discomfort to the patient. In this situation are at stake conflicting interests, likely to reduce or prevent effective treatment of TRS. First, it is desirable to adjust the pressure range for effective treatment of TRSs. It is desirable, for example, to restrict the degree of adjustment of the pressure (for example by reducing the size of the pressure range). Restricting the degree of pressure variability may reduce the likelihood of TRS events due at least in part to inappropriately applied subtherapeutic pressures. Restricting the degree of pressure variability can also reduce or prevent large temporary oscillations in pressure and reduce or avoid undesirable or inappropriate increases in pressure. In the second place, it is desirable to adjust the lower limit of the pressure range for patient comfort when awake. In general, the lower the pressure, the more comfortable the treatment is for a patient when awake.
[0006] Accordingly, it may be desirable to set the lower limit of the treatment range to a relatively low pressure setting or setting of the lowest available pressure (e.g., about 4 cm H2O). However, comfortable pressure may not effectively treat TRS. Adjusting the lower limit of the pressure range so that it is comfortable for the patient can then make the pressure algorithm less effective in the treatment of TRS. Therefore, if the lower limit of the pressure range is adapted to be comfortable for the patient when awake, there may be confusion or conflict for the clinician, physician, or user on how to adjust this. pressure. For example, there may be a conflict or confusion as to whether the lower limit should be set for comfort when the patient is awake or if it needs to be adjustable to a higher value in order to provide effective therapy when 'he is asleep. As a result, VPP systems and methods are provided in which an additional parameter, the standby pressure, is used to address these issues. The VPP systems and methods described herein provide a pressure treatment range for use when the patient is determined to be asleep, and a standby pressure for use when the patient is determined to be awake, the standby pressure being adapted for the patient. patient comfort. The standby pressure is adapted to be less than or equal to the lower limit of the pressure range and may be a therapeutic or subtherapeutic pressure. The standby pressure may differ depending at least in part on the patient's preference. The VPP systems and methods described herein advantageously allow a physician, clinician or user to tailor the pressure range for effective treatment of the TRS while allowing adjustment of the sleep pressure for patient comfort. This can advantageously increase both the efficacy of the TRS treatment and the patient's compliance with the treatment. Positive Pressure Ventilation Apparatus Fig. 1 is a diagram illustrating an exemplary VPP system adapted to deliver breathing gases at specified pressures as described herein. The system includes an apparatus 200 for providing a supply of respiratory gases, a supply conduit 202 and a patient interface 204. The pressure of the respiratory gases supplied by the apparatus 200 may vary depending on conditions detected by the system. The system may vary the pressure delivered in response to sleep disordered breathing, the pressure change being constrained to fall within the lower and upper limits. The system can deliver a standby pressure when a patient is determined to be awake, the standby pressure being less than or equal to the lower limit of the pressure range. The system includes the supply duct 202 which extends from an outlet of the gas supply apparatus to the patient interface 204. The supply duct 202 is adapted to deliver respiratory gases under pressure at the patient interface 204. The patient interface 204 includes a surplus flow outlet port 206 for permitting controlled leakage from the patient interface 204. The controlled leak allows the continuous introduction of new delivered gases by the feeding apparatus 200 within the patient interface 204. The patient interface 204 may include any of a number of types of patient interfaces for VPP delivery, for example, nasal mask. , facial mask, mouth mask, oral interface, nose pads, nasal mask or nasal cannula. The excess flow discharge port 206 may be disposed directly on the patient interface 204, or adjacent the patient interface 204 on a connection between the patient interface 204 and the supply conduit 202 or through the wall of the supply tube 202, near the patient interface 204. A wide variety of patient interfaces and ducts are known in the art. The power supply apparatus 200 includes a flow generator 209. The flow generator 209 may comprise a fan 210 driven by an electric motor 212. The air is sucked through an inlet 214 into the housing of the Apparatus 200 through the ventilator 210. The pressurized air leaves the ventilator 210 to be delivered to the patient via the supply conduit 202 and the user interface 204. In some embodiments, adjustable flow generators may collect on a ventilator 210. gas source under high pressure, and regulate a flow of gas from the high pressure source. The apparatus 200 may include a humidifier 216, for example in the form of a passage humidifier where the air passing through the chamber of the humidifier is charged with a certain amount of water vapor to from a water tank 218. The water tank 218 can be heated by a heater 220.
[0007] The humidifier 216 may be integrated with the flow generator housing 209 or be a separate optional component. The heating device 220 and the motor 212 are supplied with electricity by a current source 222. The intensity of the current arriving at the motor 212 and the intensity of current arriving at the heating device 220 can be regulated by the system. 224. The control system 224 is also supplied with electricity by the power source 222. The control system 224 can be adapted to receive an input of a user interface 226. For example, the control system 224 may receive input from the user for setting the pressure range and / or the idle pressure, as well as other parameters related to the operation of the apparatus 200. The control system 224 may also include a communication port 228 for connection to an external data source or other external system. The external data source or the external system may, for example, include a communication interface, such as a modem or a router, or be an interface with an external memory, such as a smart card, a reader of - 9 - disk, flash memory or the like. For general use, the communication port 228 may be a data communication port according to any of the many standards available, for example, a universal serial bus (USB) port. A USB interface (or similar) can be used to connect a wide range of peripheral devices. As described in more detail with reference to FIG. 2, the control system 224 may include a controller such as a computer processor (for example a microcomputer integrated with registered control programs). In some embodiments, the control system 224 may comprise a fixed electronic circuit executing a programmed functionality, or a programmed logic circuit (such as an FPGA) executing the programmed functionality. In addition, the control system 224 may include non-temporary storage means such as a computer memory adapted to store executable instructions which, when executed, cause the controller to perform programmed functions. Examples of programmed functions include determining a set pressure value, determining the sleep state of the patient, detecting sleep disordered breathing, or other functions for controlling the device 200. The apparatus 200 may include one or more sensors. Said one or more sensors may include a flow sensor 230 and may also include a pressure sensor 232 downstream of the fan 210. The flow sensor 230 may be placed upstream or downstream of the fan 210. Said one or more sensors may include, for example and without limitation, the flux sensor 230, the pressure sensor 232, a sound sensor, a motion sensor, a plethysmograph, and the like. The control system 224 may be adapted to receive data acquired by said one or more sensors. Based at least in part on the acquired data, the control system 224 can be adapted to detect a state of the patient's sleep. Also, based at least in part on acquired data, the control system 224 can be adapted to detect sleep-disordered breathing. When the patient is asleep, the control system 224 may use a pressure algorithm to determine an appropriate or targeted pressure of respiratory gases to deliver to the patient, the pressure determined by the pressure algorithm being based at least in part on possible detected events of sleep disordered breathing. When the patient is determined to be awake, the control system 224 may be adapted to control the apparatus 200 to deliver the sleep pressure. The pressure algorithm may be adapted to determine a target pressure of the delivered respiratory gases, the target pressure being based at least in part on the present and / or previously delivered pressure and on the presence of respiratory disorders. some sleep. In some embodiments, the pressure algorithm may increase the pressure of respiratory gases delivered when sleep-disordered breathing is detected. In some cases, the pressure may continue to increase (for example, in discrete or continuous pressure increments) while respiratory sleep disturbances persist. In some cases, the pressure may decrease (for example, by separate or continuous pressure decrements) while sleep-disordered breathing is absent. The pressure algorithm can be limited to a range of pressures. For example, the control system 224 can deliver a minimum pressure and a maximum pressure to the pressure algorithm, so that the pressure algorithm is restricted to output pressures falling within the inclusive range of minimum and maximum pressures. The range of pressures may include therapeutic pressures, subtherapeutic pressures, or both therapeutic and subtherapeutic pressures. The pressure range can be adapted so that the minimum and maximum pressures frame a determined, targeted or optimal pressure. For example, when it is determined that a pressure of about 12 cm H2O is an effective therapeutic pressure for a patient, the lower limit of the pressure range can be set at 9 cm H20 and the upper limit of the range of pressures can be set at 15 cm H2O. By setting this range, the control system 224 allows the pressure algorithm to respond to changes in the patient's condition that deserve or require different pressures but restricts or prevents the device 200 from providing a sub- and / or over-treatment. For example, when the pressure algorithm determines that an appropriate pressure or optimal pressure for a patient is about 12 cm H2O, this value may change depending on whether the patient sleeps on their backs or on one side. Other factors may affect appropriate or therapeutic pressure, including, for example and without limitation, alcohol consumption, sleep states, physical characteristics of a patient, and the like. When the patient is awake, the control system 224 can be adapted to control the device 200 to deliver respiratory gases at a standby pressure that is less than or equal to the lower limit of the pressure range used by the patient. pressure algorithm. The standby pressure may be adapted to be more comfortable for the patient than pressures in the pressure range. An increase in patient comfort may increase adherence to positive pressure ventilation therapy, which increases the effectiveness of treatment. Standby pressure may be therapeutic pressure or subtherapeutic pressure. The standby pressure may be adjustable and / or selected by a patient, physician, user, clinician or the like. The control system 224 may be adapted to control the apparatus 200 to effect a transition between the supply of respiratory gases under the standby pressure and the supply of respiratory gases in the pressure range. When a change in the sleep state of a patient is determined by the control system 224, the control system 224 may use a transition function to raise or lower the pressure between the idle pressure and the pressure range. , depending on whether the patient wakes up or goes to sleep. Positive Pressure Ventilation Control System [0042] FIG. 2 is a block diagram of a VPP control system 224 adapted to control a VPP apparatus (e.g., apparatus 200 described with reference to FIG 1) for providing a standby pressure when a patient is awake and a range of pressures when the patient is asleep, the lower limit of the pressure range being higher than the idle pressure. The control system 224 may be adapted to receive a sensor input 302 and / or the user interface 204, to determine a sleep state of a patient, to detect sleep breathing disorders, to determine a targeted pressure on the patient. the base at least in part of the input received from the sensors and / or the user, and / or to control the flow generator for delivering respiratory gases under the targeted pressure. The sensors 302 may include one or more of a flow sensor, a pressure sensor, a sound sensor, a motion sensor, and / or a plethysmograph. The interface 226 may be any suitable system that allows a user to provide data to the control system, such as via a touch screen interface, a keyboard, a display, buttons, switches, or any combination thereof. or similar elements. The control system 224 may be implemented using a device, program, firmware, or any combination thereof. The control system 224 includes a controller 305 comprising one or more computer processors. The control system 224 includes a data storage 310 comprising a nonvolatile computer memory. Control system 224 includes modules 320, 325, 330, 335 adapted to analyze sensor data and user input to determine a targeted pressure to deliver to a patient. In some embodiments, one or more of the modules 320, 325, 330, or 335 uses the regulator 305 and / or the data storage 310 to accomplish this functionality. The controller 305, the data storage 310 and the modules 320, 325, 330 and 335 can be adapted to communicate with each other via the communication bus 315. The communication bus 315 can be any standard communication bus. The communication bus 315 may at least in part include a network connection, using either wire or wireless connections. The communication bus 315 may include communication between the processes or functions that are performed by one or more of the modules 320, 325, 330 or 335 and / or the controller 305. The control system 224 includes the control module. determining the state of sleep 320, adapted to analyze the data acquired by one or more of the sensors 302, to determine a sleep state of a patient. In some embodiments, the sleep determination module 320 attributes the sleep state of the patient as either the asleep state or the awake state. In general, the sleep determination module 320 can analyze the sensor data to identify sleep indicating respiratory profiles. Any suitable methods of establishing that the user is asleep or awake can be used. Some suitable methods are described in other patent publications, for example, U.S. Patent No. 6,988,994 and Pub. U.S. Patent No. 2008/0092894, each of which is incorporated in its entirety by reference herein. The control system 224 includes the TRS 325 detection module adapted to analyze the data acquired by one or more of the sensors 302 to detect TRS events such as apneas, hypopneas, flow limitations, or the like. In general, the TRS 325 detection module can analyze sensor data to identify TRS event-indicating respiratory profiles. Examples of techniques used to detect TRS events are described in US Pat. No. 7,882,834 (Gardon et al.) Entitled "Autotitration Method and Apparatus", issued February 8, 2011, the entire content of which is incorporated herein by reference. incorporated herein by reference. The control system 224 includes the pressure regulator module 330 adapted to analyze the state of the patient's sleep and all events of TRS in order to determine a pressure of breathing gas to be delivered to the patient. For example, if the patient is awake, the pressure regulator module 330 may indicate to the control system 224 that the sleep pressure should be delivered to the patient. If, on the other hand, the patient is asleep, the pressure regulator module 330 may use a control algorithm to determine the pressure to be delivered to the patient, the pressure falling within the pressure range (for example not to exceed the pressure). upper limit of the pressure range or the maximum pressure and not be below the lower limit of the pressure range or the minimum pressure). The pressure regulator module 330 may take into account the presence of one or more events of TRS and adjust the response of the targeted pressure in response. Various control methods or control algorithms are possible, including the methods described in PCT Publication No. WO 2012/020314, filed August 12, 2011 and entitled "APPARATUS AND METHOD FOR DELIVERING GAS TO A USER", which is incorporated in full here by reference. Other examples of control methods include, for example, multinuit, auto-VPPC, two-level, two-level auto, and the like. The control system 224 includes the transition module 335 adapted to control the transitions between the asleep state and the awake state. The module 335 transition module can operate in conjunction with the pressure regulator module 330 for the transition between the awake and sleep mode control modes. For example, when the transition is from an awake state to a sleep state, the transition module 335 can raise the pressure from the idle pressure to the lower limit of the pressure range. As soon as the pressure reaches the pressure range, the pressure regulator module 330 can take control to determine the pressure to be delivered to the patient. As another example, the transition from the asleep state to the awake state can likewise be managed by the transition module 335 which can lower the pressure from the pressure range to the idle pressure. Ramp speeds for pressure elevation and pressure lowering may be the same or differ from each other. Ramp speeds can also be selected or adjusted by a user of the system, such as a clinician, a patient or a physician. In some embodiments, the transition module 335 is adapted to ignore events of TRS during the transition from waked state to sleep state. In some embodiments, if the patient wakes up during the transition to the pressure range from the pressure range, the transition module 335 can lower the standby pressure to the pressure from the pressure to the pressure range. the moment the transition took place. [0048] FIG. 3 represents a graph 350 of a respiratory gas pressure delivered to a patient as a function of time, the graph showing different events and the responses to the events. Line 355 represents the pressure delivered to a patient over time. Initially, the pressure delivered to the patient is the standby pressure, or the standby pressure may have a relatively low value, such as greater than or equal to about 4 cmH2O or less than about 4 cmH2O. When the patient is awake, the pressure delivered remains the standby pressure. When an output trigger occurs, the pressure increases to reach the range of pressures or a pressure between Pmm and Pmax, inclusive. The output trigger can be, for example and without limitation, two apnea events (for example, central or obstructive) in the space of a moving window of 30 consecutive breaths, two hypopnea events (for example central or obstructive) within a moving window of 30 consecutive breaths, or an event with a sequence of three consecutive limited flow breaths. It should be understood that the exit trigger may comprise more than one transition from a waking sleep state to a sleepy sleep state, but may also include other indications that the patient is asleep, such as sleep events. apnea, hypopnea events, etc. At the occurrence of an output trigger, the pressure delivered increases from the standby pressure to reach at least the lower limit of the pressure range. The rate of pressure variation may be adapted to decrease or minimize patient discomfort. The speed of variation can be adapted or adjusted by a user, such as a clinician, patient or physician. An illustrative rate of variation of the idle pressure at the pressure range is about +0.1 cm H20 / s. Other values may also be used, such as at least about +0.02 cm H20 / s and / or less than or equal to about +2 cm H20 / s, at least about +0.05 cm H20 / s and / or less than or equal to about +1 cm H20 / s, or at least about +0.1 cm H20 / s and / or less than or equal to about +0.5 cm 1-120 / s. During the transition from standby pressure to the pressure range, certain events can be ignored. For example, TRS events may be ignored during the transition, as events will be processed using pressures within the pressure range. Raising the pressure to a higher speed than the indicated ramp rate can cause discomfort to the patient. In some embodiments, the ramp rate may vary in response to one or more TRS events. If, during the transition from the standby pressure to the pressure range, the sleep state of the patient is determined as the awake state. The delivered pressure can then be lowered from its current value to the idle pressure. The rate of change leading to the standby pressure may be of the same magnitude as the rate of variation of elevation from the standby pressure or it may be different. An illustrative rate of variation to standby pressure is about -0.1 cm H20 / s. Other values may also be used, such as when the magnitude of the variation is at least about 0.02 cm H20 / s and / or less than or equal to about 2 cm H20 / s, at least about 0, 0.5 cm H 2 O / s and / or less than or equal to about 1 cm H 2 O / s, or at least about 0.1 cm H 2 O / s and / or less than or equal to about 0.5 cm H 2 O / s. As soon as the pressure reaches the lower limit of the pressure range (for example, the pressure algorithm can be used to adjust the pressure, as described in more detail here, for example, the pressure delivered can be raised in response to a TRS event Similarly, the pressure may drop when the patient is breathing normally In both cases, the pressure range delivered via the pressure algorithm is limited, having a lower limit than P ,,, ,,, and a limit greater than Pmax For example, the pressure range may range from about 4 cm H2O to about 20 cm H2O, Pmin being greater than or equal to 4 cm H2O, Pmax being lower or If the patient wakes up while the pressure is in the pressure range, the pressure delivered can be less than 1 cm -1, and Pmin is greater than P [0054]. lower to the indicated speed of variation leading to the standby.
[0008] Positive Pressure Venting Delivery Method [0055] FIG. 4 illustrates a process diagram of an illustrative method 400 of providing a patient with standby pressure and a range of pressures when the patient is asleep, the minimum pressure in the range being different from the idle pressure. . For ease of description, the steps of method 400 will be described as being performed by control system 224. However, one or more process steps may be performed by one or more components of apparatus 200 and / or modules 320, 325, 330, 335. In addition, a single step or a combination of steps can be performed by the combined actions and functionality of the systems and modules described herein. In block 405, the control system 224 detects a sleep state of the patient. By monitoring one or more sensors, the control system 224 can detect the state of sleep and determine whether the patient is asleep or awake. In some embodiments, the state of sleep is detected by tracking the breathing patterns. Any suitable method of determining the sleep state of the patient may be used. Some suitable methods are described in other patent publications, for example, U.S. Patent No. 6,988,994 and Pub. U.S. Patent No. 2008/0092894, each of which is integrally incorporated herein by reference. In the block 410, the control system 224 follows two different control channels depending on whether the patient is awake or not. If the patient is asleep, process 400 continues at block 415 where the control system detects sleep disordered breathing. The control system 224 can analyze the sensor data to detect TRS events. Examples of techniques used to detect TRS events described in US Pat. No. 7,882,834 (Gradon et al.) Titled "Autotitration Method and Apparatus", issued February 8, 2011, all of whose content is in English. integrally incorporated here by reference. If the control system 224 is in transition from an awake state to a sleeping state, or if the pressure is in transition to the pressure range (for example whether or not it starts from the standby pressure), the pressure can vary at a rate of variation adapted to reduce or avoid the discomfort associated with high pressure variations. The speed of the pressure variation, or the elevation speed, can be selected, adjusted or configured by a user. In some embodiments, the rate of elevation may be a constant or it may vary based at least in part on the data acquired with the sensors or other relevant data. During the transition, the control system 224 may be configured to ignore the TRSs detected in the block 415. When the pressure reaches the pressure range, the control system 224 may use control methods that regulate the pressure in the pressure range based at least in part on any detected TRS events or their absence (eg, normal breathing) in block 420. Various regulatory methods or control algorithms are possible, including the methods described in PCT Publication No. WO 2012/020314, filed August 12, 2011 and entitled "APPARATUS AND METHOD FOR GAS SUPPLY TO A USER", which is incorporated herein by reference in its entirety. If the patient is awake, the process 400 goes from block 410 to block 425 where the control system 224 controls the VPP system to deliver respiratory gases under a standby pressure, the standby pressure being less than or equal to the lower limit of the pressure range. If the control system 224 is in transition from a dormant state to an awake state, or if the pressure is in transition to the idle pressure (for example, whether or not it starts from the pressure range), the pressure -17 can vary at a variation speed adapted to reduce or avoid the discomfort associated with large pressure variations. The speed of the pressure variation, or the speed of lowering, can be selected, adjusted or configured by a user. In some embodiments, the rate of fall may be a constant or it may vary based at least in part on the data acquired with the sensors or other relevant data. Once operations in block 420 or block 425 have been performed, process 400 then returns to block 405 where control system 224 detects the sleep state of the patient. The control loop can therefore be continued in a continuous loop to control the VPP system and respond to variations in the patient's sleep state and events of sleep disordered breathing. Conclusion [0062] Examples of VPP systems and methods that deliver a range of pressures for sleeping patients and lower pressure for awake patients have been described with reference to the figures. The representations in the figures have been given to clearly illustrate the principles associated with VPP therapy with standby pressure adjustment, and details of module or system divisions have been provided to facilitate the description rather than to describe distinct concrete embodiments. The examples and figures are intended to illustrate and not limit the scope of the embodiments described herein. As used herein, the term "regulator" or "processor" generally refers to any device, logic block, module, circuit, or any combination of elements suitable for performing controls. For example, the controller 305 may include any conventional multi-chip or multi-chip microprocessor for general purpose, such as a Pentium® processor, MIPS® processor, Power PC® processor, AMD® processor, ARM® processor or ALPHA® processor. In addition, the regulator 305 may include any traditional special purpose microprocessor, such as a digital signal processor. The various logic blocks, modules, and illustrative circuits described in connection with the embodiments described herein may be implemented or executed with a general-purpose processor, a digital signal processor (DSP), an application-specific integrated circuit ( ASIC), an in-situ programmable gate array (FPGA) or other programmable logic device, another discrete or logic gate with programmable transistors, discrete hardware components, or any combination thereof adapted to perform the functions described herein. The controller 305 may be embodied as a combination of computing devices, for example a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other configuration of this type. The data storage 310 may consist of an electronic circuit for storing and extracting information, typically computer or digital data. The data storage 310 may consist of external devices or systems, for example, disk drives or solid state drives. The data storage 310 may also consist of a fast semiconductor storage (chips), for example, a Random Access Memory (RAM) or various forms of Read Only Memory (ROM), which are directly connected to the data bus. Other types of memory include a bubble memory and a torus memory. Data storage can be a physical material suitable for storing information in a non-transitory medium. The conditional terms used herein, such as, inter alia, "may", "could", "should", "would", "for example" and the like, unless otherwise specifically indicated, or otherwise understood in the context as used, are generally intended to express that certain embodiments include certain features, certain elements and / or states, while other embodiments do not include them. Such conditional terms are therefore generally not intended to imply that such features, elements and / or states are in any way required for one or more embodiments. As used herein, the terms "includes", "comprising", "includes", "including", "a", "having" or any other variant thereof, are intended to cover a non-exclusive inclusion. For example, a process, process, article, or apparatus that includes a list of items is not necessarily limited to those items alone but may include other items not expressly listed or inherent in such process, article, or apparatus . Similarly, the term "or" is used in its inclusive sense (and not in its exclusive meaning), so that when used, for example, to link a list of elements, the word "or" means one, some or all of the items in the list. Conjunctive expressions, such as the phrase "at least one of X, Y, and Z", unless specifically indicated otherwise, or understood differently in the context as used, are generally intended to express that an item, term, etc. can be either X, Y or Z. Such conjunctive expressions are therefore generally not intended to imply that certain embodiments require the presence of each of at least one of X, at least Y and minus one of Z. Terms used herein that refer to an approximation, estimate or inaccurate values, such as, among others, "approximately", "approximately", "approximately", and similar, unless otherwise specifically indicated , or understood differently in the context as used, are generally intended to express that the values described by the terms deviate by less than 10% from the stated value, by less than 5% of the stated value or by less than of 1% of the stated value. It should be emphasized that many variations and modifications can be made to the embodiments described herein, the elements of which should be understood as being among other acceptable examples. All such modifications and variations are to be understood to be included herein within the scope of this specification and protected by the following claims. Moreover, nothing in the foregoing description is intended to imply that any particular component, any particular feature or particular process step is necessary or essential.

权利要求:
Claims (19)
[0001]
Claims 1. A positive pressure ventilation system comprising: a flow generator adapted to deliver gas under pressure to a patient; a user interface adapted to deliver the gas to the patient under pressure; a conduit for the gas to pass from the flow generator to the user interface; a sensor adapted to measure the patient's breathing; and a control system adapted to: detect sleep breathing disorders, based at least in part on an analysis of the data acquired by the sensor; determine a patient's sleep state, based at least in part on an analysis of the data acquired by the sensor; controlling the flow generator to deliver a pressure between a low pressure and a high pressure when the sleep state is determined to be the asleep state, the delivered pressure being based at least in part on the fact that sleep are detected or not; and controlling the flow generator to provide a sleep pressure different from the low pressure if the sleep state is determined to be the awake state, the sleep pressure being selected by a user.
[0002]
The positive pressure ventilation system of claim 1, wherein the standby pressure is a therapeutic pressure. 25
[0003]
A positive pressure venting system according to claim 1 or claim 2, wherein the regulator is further adapted to control the flow generator to provide a pressure which increases with time at a first pressure ramp rate when the The pressure that is provided by the flow generator is the sleep pressure and the sleep state is determined to be the sleeping state where sleep breathing disorders are detected.
[0004]
The positive pressure venting system of claim 3, wherein the first pressure ramp rate is adjustable by a user. 35-21 -
[0005]
Positive pressure venting system according to any one of claims 1 to 4, wherein the regulator is further adapted to control the flow generator to provide a pressure which decreases with time at a second ramp rate. pressure when the pressure that is provided by the flow generator is between the low pressure and the high pressure and the state of sleep is determined as the awake state.
[0006]
The positive pressure venting system of claim 5, wherein the second pressure ramp rate is adjustable by a user.
[0007]
Positive pressure ventilation system according to any one of claims 1 to 6, wherein the low pressure and the high pressure are adjustable by a user.
[0008]
Positive pressure ventilation system according to any one of claims 3 to 7, wherein the sensor is one of a flow sensor, a pressure sensor, a sound sensor, a motion sensor or a plethysmograph.
[0009]
A method for providing positive pressure ventilation therapy to a patient, the method comprising: receiving an input from a user to set a sleep pressure; detection of a presence of sleep breathing disorders; determining a patient's sleep state; if the state of sleep is determined to be the sleeping state, the supply of gases having a sleep pressure that is set between a low sleep pressure and a high sleep pressure, the sleep pressure depending at least in part the presence of sleep disordered breathing; and if the state of sleep is determined to be the awake state, the supply of gas having the standby pressure, the standby pressure being lower than the low sleep pressure.
[0010]
The method of claim 9, wherein the standby pressure is a therapeutic pressure.
[0011]
The method of claim 9 or claim 10, further comprising increasing a pressure of the delivered gas at a first ramp rate when the pressure that is delivered is at the standby pressure and the sleep state is determined to be the sleeping state where sleep disordered breathing is detected.
[0012]
The method of claim 11, further comprising receiving an input from a user to set the first ramp rate.
[0013]
The method of any one of claims 9 to 12, further comprising lowering a pressure of the delivered gas to a second ramp rate when the pressure that is delivered is between the low sleep pressure and the pressure. of high sleep and the state of sleep is determined as the waking state.
[0014]
The method of claim 13, further comprising receiving an input from a user to set the second ramp rate.
[0015]
The method of any one of claims 9 to 14, further comprising receiving a user input to set the low sleep pressure and the high sleep pressure.
[0016]
The method of any one of claims 9 to 15, wherein detecting a presence of sleep disordered breathing comprises analyzing values from a sensor, the sensor comprising at least one of a sensor flow, a pressure sensor, a sound sensor, a motion sensor or a plethysmogra phe.
[0017]
A user interface communicatively coupled to a control system of a positive pressure ventilation apparatus, the user interface comprising: a standby pressure node adapted to receive standby pressure data indicative of a standby pressure ; a low pressure node adapted to receive lower limit data indicative of a lower limit of a range of pressures; and a high pressure node adapted to receive upper limit data indicative of an upper limit of the pressure range, the user interface communicating the idle pressure, the lower limit of the pressure range and the limit. greater than the range of pressures to the control system, and the control system instructing the positive pressure ventilation apparatus to deliver breathing gas having the standby pressure if a sleep state is determined to be the awake state, the standby pressure being lower than the lower limit of the pressure range.
[0018]
The user interface of claim 17, further comprising a ramp rate node adapted to receive ramp rate data indicative of a pressure ramp rate.
[0019]
The user interface of claim 18, wherein the control system switches from the standby pressure input to a pressure within the pressure range at the pressure ramp rate.

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

WO2008039979A2|2006-09-29|2008-04-03|Nellcor Puritan Bennett Llc|System and method for controlling respiratory therapy based on detected respiratory events|

---

WO2011006199A1|2009-07-16|2011-01-20|Resmed Ltd|Detection of sleep condition|

---

WO2012075433A2|2010-12-03|2012-06-07|Fisher & Paykel Healthcare Limited|System, apparatus and methods for supplying gases|

---

WO2014007659A1|2012-02-15|2014-01-09|Fisher & Paykel Healthcare Limited|System, apparatus and methods for supplying gases|

---

US5551419A|1994-12-15|1996-09-03|Devilbiss Health Care, Inc.|Control for CPAP apparatus|

---

US6349724B1|2000-07-05|2002-02-26|Compumedics Sleep Pty. Ltd.|Dual-pressure blower for positive air pressure device|

---

UA90651C2|2002-10-09|2010-05-25|Компьюмедикс Лимитед|Method and apparatus for maintaining and monitoring sleep quality during therapeutic treatments|

---

AU2006297468B2|2005-09-30|2012-01-19|New York University|System and method for diagnosis and treatment of a breathing pattern of a patient|

---

US6988994B2|2003-08-14|2006-01-24|New York University|Positive airway pressure system and method for treatment of sleeping disorder in patient|

---

US7896812B2|2003-08-14|2011-03-01|New York University|System and method for diagnosis and treatment of a breathing pattern of a patient|

---

US7882834B2|2004-08-06|2011-02-08|Fisher & Paykel Healthcare Limited|Autotitrating method and apparatus|

---

JP4182956B2|2005-05-31|2008-11-19|ブラザー工業株式会社|COMMUNICATION SYSTEM, COMPUTER, DEVICE, AND PROGRAM|

---

US8528551B2|2005-06-14|2013-09-10|Resmed Limited|Acclimatization therapy for first time users|

---

CN102940925A|2006-06-05|2013-02-27|雷斯梅德有限公司|Positive airway pressure system, transmission treatment therapy system and system for treating sleep-disordered breathing|

---

EP2569035B1|2010-05-14|2018-01-17|Koninklijke Philips N.V.|System for detecting sleep onset in a subject based on responsiveness to breathing cues|

---

EP2603267B1|2010-08-13|2021-11-17|Fisher & Paykel Healthcare Limited|Apparatus for providing gases to a user|

---

US20130190642A1|2010-10-01|2013-07-25|Koninklijke Philips Electronics N.V.|Apparatus and method for diagnosing obstructive sleep apnea|

---

EP2840959B1|2012-05-18|2018-08-22|Fisher&Paykel Healthcare Limited|Control of flow and/or pressure provided by breathing apparatus|US9937309B2|2014-07-22|2018-04-10|Devilbiss Healthcare Llc|Method of optimizing therapy pressure in a breathing therapy machine having an auto-adjust feature|

---

CN107106800B|2014-10-27|2020-12-25|瑞思迈私人有限公司|Method and apparatus for treating hyperarousal disorders|

---

WO2018009078A1|2016-07-06|2018-01-11|Fisher & Paykel Healthcare Limited|A bilevel respiratory therapy system, controller and method|

---

US20190150829A1|2017-11-16|2019-05-23|Verily Life Sciences Llc|Systems and methods for on-demand cpap therapy|

---

WO2021021835A1|2019-07-31|2021-02-04|Resmed Inc.|Systems and methods for tailoring therapy provided by respiratory systems based on sleep stage|

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2017-11-10| PLSC| Publication of the preliminary search report|Effective date: 20171110 |

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2021-03-26| PLFP| Fee payment|Year of fee payment: 7 |

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2022-02-21| PLFP| Fee payment|Year of fee payment: 8 |

优先权:

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申请号 | 申请日 | 专利标题

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US201461974310P| true| 2014-04-02|2014-04-02|

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