U.S. patent application number 09/436858 was filed with the patent office on 2002-02-07 for pressure support system with a low leak alarm and method of using same.
Invention is credited to TRUSCHEL, WILLIAM A..
Application Number | 20020014240 09/436858 |
Document ID | / |
Family ID | 26807339 |
Filed Date | 2002-02-07 |
United States Patent
Application |
20020014240 |
Kind Code |
A1 |
TRUSCHEL, WILLIAM A. |
February 7, 2002 |
PRESSURE SUPPORT SYSTEM WITH A LOW LEAK ALARM AND METHOD OF USING
SAME
Abstract
A pressure support system and method of using same that includes
a pressure generator adapted to provide a gas flow, a conduit
coupled to the pressure generator to deliver a gas flow to a
patient, an interface device coupled to the conduit to communicate
the gas flow to an airway of the patient. An exhaust vent that
provides a flow of exhaust gas to atmosphere is provided in the
conduit or the interface device. A flow sensor detects a rate at
which gas flows in the conduit and provides a first output
indicative thereof, and a pressure sensor detects a pressure of gas
at the patient and provides a second output indicative thereof. A
control system receives the first and second outputs and determines
whether a current flow of exhaust gas passing through the exhaust
vent is below an alarm threshold based on the first and second
outputs and provides a third output indicative of this
determination.
Inventors: |
TRUSCHEL, WILLIAM A.;
(MONROEVILLE, PA) |
Correspondence
Address: |
MICHAEL W. HAAS
RESPIRONICS, INC.
1501 ARDMORE BLVD.
PITTSBURGH
PA
15221
US
|
Family ID: |
26807339 |
Appl. No.: |
09/436858 |
Filed: |
November 9, 1999 |
Current U.S.
Class: |
128/204.22 |
Current CPC
Class: |
A61M 2016/0039 20130101;
A61M 2205/15 20130101; A61M 2205/3561 20130101; A61M 16/0051
20130101; A61M 16/06 20130101; A61M 16/024 20170801; A61M 16/0072
20130101; A61M 16/0069 20140204; A61M 2016/0027 20130101 |
Class at
Publication: |
128/204.22 |
International
Class: |
A62B 007/00; A61M
016/00; F16K 031/02; A62B 009/00 |
Claims
What is claimed is:
1. A pressure support system comprising: a pressure generator
adapted to provide a gas flow; a conduit operatively coupled to
said pressure generator to deliver a gas flow to a patient; an
interface device operatively coupled to said conduit to communicate
a gas flow to an airway of a patient, wherein at least one of said
conduit and said interface device includes an exhaust vent that
provides a flow of exhaust gas to atmosphere from a respective one
of said conduit and said interface device; a sensor operatively
coupled to said conduit to detect a rate at which gas flows in said
conduit and to provide a first output indicative thereof; a sensor
operatively coupled to at least one of said interface device and a
portion of said conduit proximate to said interface device to
detect a pressure of gas at a patient and to provide a second
output indicative thereof; and a control system receiving said
first output and said second output, wherein said control system
determines whether a current flow of exhaust gas passing through
said exhaust vent is below an alarm threshold based on said first
and said second output and provides a third output indicative of
said determination.
2. A pressure support system according to claim 1, further
comprising an alarm device operatively coupled to said control
system to receive said third output, wherein said control system
generates said third output responsive to said current flow of
exhaust gas being below said alarm threshold for a predetermined
period of time, and wherein said alarm device outputs a human
perceivable alarm responsive to receiving said third output.
3. A pressure support system according to claim 1, wherein said
control system sets said alarm threshold according to at least one
detected condition of said pressure support system determined
during a learn period in which at least one parameter associated
with said pressure support system is monitored by said control
system using at least one of said first sensor and said second
sensor.
4. A pressure support system according to claim 3, further
comprising a manual input device operatively coupled to said
control system, wherein said pressure support system is capable of
being operated in a plurality of modes, and wherein at least one of
(1) actuation of said manual input device, (2) start up of said
pressure support system, and (3) a change in a mode of operation of
said pressure support system causes said control system to execute
said learn period.
5. A pressure support system according to claim 3, wherein said
detected conditions include said rate at which gas flows in said
conduit and said pressure of gas at a patient, and wherein said
control system (1) determines a first relationship defined as: 5 T
breath ( Q c - Q known ) t during said learn period, where Q.sub.c
is a current flow of gas within said conduit, Q.sub.known is a
predetermined flow of exhaust gas passing through said exhaust
vent, and T.sub.breath is an integral number of breaching cycles,
and (2) sets said alarm threshold based on a first set of criteria
responsive to said first relationship being negative and based on a
second set of criteria responsive to said first relationship not
being negative.
6. A pressure support system according to claim 5, wherein said
control system calculates a second relationship, R.sub.leak,
defined as: 6 R leak = T breath ( Q c - Q known ) t T breath ,and
wherein said control system sets said alarm threshold as one of (1)
a predetermined percentage less than a sum of Q.sub.known, and
R.sub.leak and (2) a predetermined amount less than a sum of
Q.sub.known, and R.sub.leak, responsive to said first relationship
determined during said learn period being negative.
7. A pressure support system according to claim 5, wherein said
control system monitors said first relationship during normal
operation of said pressure support system and changes from said
first set of criteria to said second set of criteria by which said
alarm threshold is set responsive to said first relationship not
being negative for a predetermined period of time and thereafter
adjusts said alarm threshold according to said second set of
criteria.
8. A pressure support system according to claim 5, wherein
Q.sub.known is determined by one of: (1) performing an exhaust vent
test that includes: (a) providing a plurality of pressures to a
patient via said pressure generator, (b) measuring a current flow
of gas within said conduit associated with each of said plurality
of pressures, (c) establishing a pressure versus flow relationship
for said exhaust vent based on said plurality of pressures and flow
associated therewith, and (d) setting Q.sub.known based on said
pressure versus flow relationship; (2) recalling Q.sub.known from a
database based on said exhaust vent being used with said pressure
support system, wherein said data base contains a plurality of
pressure verses flow relationships associated with various types of
exhaust vents; and (3) setting Q.sub.known to zero if both steps
(1) and (2) are not performed.
9. A pressure support system according to claim 8, wherein said
control system sets said alarm threshold as one of (1) a
predetermined percentage of Q.sub.known and (2) a predetermined
amount less than Q.sub.known, responsive to said first relationship
determined during said learn period not being negative and one of
(1) said exhaust vent test having been performed and (2)
Q.sub.known having been recalled from said database, and wherein
said control system sets said alarm threshold as one of (1) a
predetermined percentage of a predetermined minimum exhaust vent
leakage rate and (2) a predetermined amount less than said
predetermined minimum exhaust vent leakage rate responsive to said
first relationship determined during said learn period not being
negative and said exhaust vent test and recalling of Q.sub.known
from said database having not been performed.
10. A pressure support system according to claim 9, wherein said
control unit determines, during normal operation of said pressure
support system, whether a current flow of exhaust gas passing
through said exhaust vent is below said alarm threshold by
repeatedly determining whether said first relationship is negative,
and wherein said control unit calculates, during normal operation,
a constant R.sub.leak according to a second relationship defined
as: 7 R leak = T breath ( Q c - Q known ) t T breath P p t if said
first relationship is not negative, wherein P.sub.p is a pressure
at an airway of a patient, and according to a third relationship
defined as: 8 R leak = T breath ( Q c - Q known ) t T breath if
said first relationship is negative, and wherein said control
system, during normal operation, provides said third output based
on whether a fourth relationship defined as
Q.sub.known+R.sub.leak{square root}{square root over (P.sub.p)} is
less than said alarm threshold for a first predetermined period of
time, responsive to R.sub.leak not being negative, and wherein said
control system provides said third output based on whether a fifth
relationship defined as Q.sub.known+R.sub.leak is less than said
alarm threshold for a second predetermined period of time,
responsive to R.sub.leak being negative.
11. A pressure support system according to claim 1, wherein said
control unit determines, during normal operation of said pressure
support system, whether a current flow of exhaust gas passing
through said exhaust vent is below said alarm threshold by
repeatedly determining whether a first relationship defined as: 9 T
breath ( Q c - Q known ) t is negative, where Q.sub.c is a flow of
gas within said conduit, Q.sub.known is a predetermined rate of
flow of exhaust gas passing through said exhaust vent, and
T.sub.breath is an integral number of breaching cycles.
12. A pressure support system according to claim 11, wherein said
control unit determines whether said current rate of flow of
exhaust gas passing through said exhaust vent is below said alarm
threshold by calculating a constant R.sub.leak according to a
second relationship defined as: 10 R leak = T breath ( Q c - Q
known ) t T breath P p t if said first relationship is not
negative, wherein P.sub.p is a pressure at an airway of a patient,
and according to a third relationship defined as: 11 R leak = T
breath ( Q c - Q known ) t T breath if said first relationship is
negative.
13. A pressure support system according to claim 12, wherein said
control system, during normal operation, provides said third output
based on whether a fourth relationship defined as
Q.sub.known+R.sub.leak{square root}{square root over (P.sub.p)} is
less than said alarm threshold for a first predetermined period of
time, responsive to R.sub.leak not being negative, and wherein said
control system provides said third output based on whether a fifth
relationship defined as Q.sub.known+R.sub.leak is less than said
alarm threshold for a second predetermined period of time,
responsive to R.sub.leak being negative.
14. A method of providing pressure support including a low leak
alarm comprising the steps of: providing a gas flow from a pressure
generator to a patient via a conduit operatively coupled to said
pressure generator, wherein an interface device is also coupled to
said conduit to communicate a gas flow from said conduit to an
airway of a patient, and wherein an exhaust vent in disposed in one
of said interface device and a portion of said conduit proximate to
said interface device to communicate a flow of exhaust gas to
atmosphere from a respective one of said conduit and said interface
device; detecting a rate at which gas flows in said conduit and
providing a first output indicative thereof; detecting a pressure
of gas at a patient and providing a second output indicative
thereof; determining whether a current flow of exhaust gas passing
through said exhaust vent is below an alarm threshold based on said
first output and said second output; and providing a third output
indicative of a result of said determining step.
15. A method according to claim 14, further comprising a step of
outputting a human perceivable alarm responsive to said current
flow of said exhaust gas being below said alarm threshold for a
predetermined period of time.
16. A method according to claim 14, further comprising the steps
of: monitoring said rate at which gas flows in said conduit and
said pressure of gas at a patient during a learn period; and
setting said alarm threshold based on said monitored gas flow in
said conduit and said pressure of gas at a patient during said
learn period.
17. A method according to claim 16, wherein said monitoring step
includes determining a first relationship defined as: 12 T breath (
Q c - Q known ) t during said learn period, where Q.sub.c is a
current flow of gas within said conduit, Q.sub.known is a
predetermined flow of exhaust gas passing through said exhaust
vent, and T.sub.breath is an integral number of breaching cycles;
and wherein said alarm threshold setting step includes setting said
alarm threshold based on a first set of criteria responsive to said
first relationship being negative and setting said alarm threshold
based on a second set of criteria responsive to said first
relationship not being negative.
18. A method according to claim 17, further comprising a step of
calculating a second relationship, R.sub.leak, defined as: 13 R
leak = T breath ( Q c - Q known ) t T breath ,and wherein said
setting step includes setting said alarm threshold as one of (1) a
predetermined percentage less than a sum of Q.sub.known, and
R.sub.leak and (2) a predetermined amount less than a sum of
Q.sub.known, and R.sub.leak, responsive to said first relationship
determined during said learn period being negative.
19. A method according to claim 17, further comprising the steps
of: monitoring said first relationship during normal operation of
said pressure support system; changing from said first set of
criteria to said second set of criteria by which said alarm
threshold is set responsive to said first relationship not being
negative for a predetermined period of time; and adjusting said
alarm threshold based on said second set of criteria.
20. A method according to claim 17, further comprising the step of
determining Q.sub.known by performing the following steps: (1)
performing an exhaust vent test by performing the following steps:
(a) providing a plurality of pressures to a patient via said
pressure generator, (b) measuring a current flow of gas within said
conduit associated with each of said plurality of pressures, (c)
establishing a pressure versus flow relationship for said exhaust
vent based on said plurality of pressures and rates of flow
associated therewith, and (d) setting Q.sub.known based on said
pressure versus flow relationship; (2) recalling Q.sub.known from a
database based on said exhaust vent being used with said pressure
support system, wherein said database contains a plurality of
pressure verses flow relationships associated with various types of
exhaust vents; and (3) setting Q.sub.known to zero if both steps
(1) and (2) are not performed.
21. A method according to claim 20, wherein said alarm threshold
setting step includes setting said alarm threshold as one of (1) a
predetermined percentage of Q.sub.known and (2) a predetermined
amount less than Q.sub.known, responsive to said first relationship
determined during said learn period not being negative and one of
(1) said exhaust vent test having been performed and (2)
Q.sub.known having been recalled from said database, and wherein
control system sets said alarm threshold as one of (1) a
predetermined percentage of a predetermined minimum exhaust vent
leakage rate and (2) a predetermined amount less than said
predetermined minimum exhaust vent leakage rate responsive to said
first relationship determined during said learn period not being
negative and said exhaust vent test and recalling Q.sub.known from
said database having not been performed.
22. A method according to claim 21, wherein said determining step
includes determining, during normal operation, whether a current
rate of flow of exhaust gas passing through said exhaust vent is
below said alarm threshold by repeatedly determining whether a
first relationship defined as: 14 T breath ( Q c - Q known ) t is
negative, where Q.sub.c is a flow of gas within said conduit,
Q.sub.known is a predetermined flow of exhaust gas passing through
said exhaust vent, and T.sub.breath is an integral number of
breaching cycles, further comprising: calculating a constant
R.sub.leak according to a second relationship defined as: 15 R leak
= T breath ( Q c - Q known ) t T breath P p t if said first
relationship is not negative, wherein P.sub.p is a pressure at an
airway of a patient; and calculating a constant R.sub.leak
according to a third relationship defined as: 16 R leak = T breath
( Q c - Q known ) t T breath if said first relationship is
negative; outputting a low leak alarm responsive to a fourth
relationship defined as Q.sub.known+R.sub.leak{square root}{square
root over (P.sub.p)} being less than said alarm threshold for a
first predetermined period of time, responsive to R.sub.leak not
being negative; and outputting a low leak alarm responsive to a
fifth relationship defined as Q.sub.known+R.sub.leak being less
than said alarm threshold for a second predetermined period of
time, responsive to R.sub.leak being negative.
23. A method according to claim 14, wherein said determining step
includes determining, during normal operation, whether a current
flow of exhaust gas passing through said exhaust vent is below said
alarm threshold by repeatedly determining whether a first
relationship defined as: 17 T breath ( Q c - Q known ) t is
negative, where Q.sub.c is a flow of gas within said conduit,
Q.sub.known is a predetermined rate of flow of exhaust gas passing
through said exhaust vent, and T.sub.breath is an integral number
of breaching cycles.
24. A method according to claim 23, further comprising the steps of
calculating a system constant R.sub.leak according to a second
relationship defined as: 18 R leak = T breath ( Q c - Q known ) t T
breath P p t if said first relationship is not negative, wherein
P.sub.p is a pressure at an airway of a patient; and calculating a
system constant R.sub.leak according to a third relationship
defined as: 19 R leak = T breath ( Q c - Q known ) t T breath if
said first relationship is negative.
25. A method according to claim 24, further comprising the steps
of: determining whether R.sub.leak not being positive; outputting a
low leak alarm responsive to a fourth relationship defined as
Q.sub.known+R.sub.leak{square root}{square root over (P.sub.p)}
being less than said alarm threshold for a first predetermined
period of time, responsive to R.sub.leak not being negative; and
outputting a low leak alarm responsive to a fifth relationship
defined as Q.sub.known+R.sub.leak being less than said alarm
threshold for a second predetermined period of time, responsive to
R.sub.leak being negative.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention pertains to a pressure support system
that includes a low leak alarm and to a method of providing such an
alarm, and, in particular, to a pressure support system, which
provides positive pressure therapy to a patient via a single limb
patient circuit, that includes an alarm indicating that the current
system leak from the patient circuit via an exhaust port is below
an acceptable level, which involves comparing a current system leak
with an adaptive alarm threshold.
[0003] 2. Description of the Related Art
[0004] Pressure support systems that provide a gas flow to an
airway of a patient at an elevated pressure via a single limb
patient circuit to treat a medical disorder are well known. For
example, it is known to use a continuous positive airway pressure
(CPAP) device to supply a constant positive pressure to the airway
of a patient to treat obstructive sleep apnea (OSA). It is also
known to provide a positive pressure therapy in which the pressure
of gas delivered to the patient varies with the patient's breathing
cycle or varies with the patient's effort to increase the comfort
to the patient. It is further known to provide a positive pressure
therapy in which the pressure provided to the patient changes based
on the detected conditions of the patient, such as whether the
patient is snoring or experiencing an apnea, hypopnea or upper
airway resistance.
[0005] Conventional pressure support devices typically include a
pressure generator, for example, a blower, piston or bellows, that
creates a flow of breathing gas having a pressure greater than the
ambient atmospheric pressure. A patient circuit delivers the
elevated pressure breathing gas to the airway of the patient.
Typically, the patient circuit includes a conduit, i.e., a single
lumen, having one end coupled to the pressure generator and a
patient interface device coupled to the other end of the conduit.
The patient interface connects the conduit with the airway of the
patient so that the elevated pressure gas flow is delivered to the
airway of the patient. Examples of patient interface devices
include a nasal mask, nasal and oral mask, full face mask, nasal
cannula, oral mouthpiece, tracheal tube, endotracheal tube, or
hood. A single limb patient circuit further includes an exhalation
port, also referred to as an exhalation vent, exhaust port or
exhaust vent, to allow expired gas from the patient to exhaust to
atmosphere. Generally, the exhaust vent is located in the conduit
near the patient interface and/or in the patient interface device
itself.
[0006] A concern in a single limb pressure support device is that
the exhalation port remains open during use so that a sufficient
amount of expired gas exhausts from the system. Complete or partial
blockage of the exhaust port can occur, for example, by a buildup
of secretions from the patient in the exhaust port. Blockage can
also occur as a result of an external item, such as the patient or
the patient's bedding, covering the port. For example, a patient
using the pressure support system at night to treat OSA might roll
over during sleep so that the exhaust port is covered by the
patient's sheets, pillow and/or mattress and cause a complete or
partial blockage of one or more of the exhaust ports in the patient
circuit.
[0007] Conventional pressure support device attempt to mitigate
this concern by designing exhaust ports that are difficult to
block. For example, multiple flow paths may be provided so that if
one path becomes blocked, another path provides the necessary
exhaust function. Also, routine maintenance, such as daily
inspection and/or weekly cleaning, are recommended to ensure the
integrity of the exhaust paths. These techniques, however, have
several disadvantages. For example, they may not be sufficient to
ensure the continuity of the exhaust paths at all times during the
patient's therapy, are relatively time consuming, and place a
significant burden on the user in requiring the user to perform the
routine maintenance and to remember to perform the maintenance. In
addition, these conventional techniques do nothing to warn the user
that an exhaust port blockage has taken place at the time the
blockage occurs.
SUMMARY OF THE INVENTION
[0008] Accordingly, it is an object of the present invention to
provide a single limb pressure support device having an exhaust
vent in the patient circuit and/or patient interface device and
that does not suffer from the above disadvantages associated with
conventional single limb pressure support devices. This object is
achieved, according to one embodiment of the present invention, by
providing a pressure support device that includes a pressure
generator adapted to provide a gas flow, a conduit coupled to the
pressure generator to deliver the gas flow to a patient, an
interface device coupled to the conduit to communicate the gas flow
to an airway of the patient, and an exhaust vent that provides a
flow of exhaust gas to atmosphere from the conduit and/or the
interface device. A first sensor detects the rate at which gas
flows in the conduit, and a second sensor detects the pressure of
gas at the patient. A control system receives the outputs from the
first and second sensors and determines whether a current flow of
exhaust gas passing through the exhaust vent is below an alarm
threshold based on the first and second outputs and provides a
third output indicative of this determination.
[0009] It is a further object of the present invention to allow the
pressure support system to set the alarm threshold based on the
specific conditions of that pressure support system, so that the
alarm threshold is optimized for the current conditions of the
pressure support system. This object is achieved, according to one
embodiment of the present invention, by having the pressure support
system enter a learn period in which at least one parameter
associated with the pressure support system is monitored. This
parameter, or a plurality of parameters, are used to set the alarm
threshold. Thus, the present invention can set the alarm threshold
taking into consideration the specific conditions of pressure
support system, such as the introduction of a supplemental
breathing gas, e.g. oxygen, into the system, and not produce a
false alarm.
[0010] It is still another object of the present invention to
provide a method of providing pressure support to a patient via a
single limb circuit having an exhaust vent in that circuit and that
does not suffer from the disadvantages associated with the
above-described conventional single limb pressure support
techniques. This object is achieved, according to one embodiment of
the present invention, by providing a method of providing pressure
support via a pressure support system, wherein the method includes
the following steps: (1) providing a gas flow from a pressure
generator to a patient via a conduit coupled to the pressure
generator, wherein an interface device is also coupled to the
conduit to communicate the gas flow from the conduit to an airway
of the patient, and wherein an exhaust vent in disposed in the
interface device or the conduit to communicate a flow of exhaust
gas to atmosphere, (2) detecting a rate at which gas flows in the
conduit, (3) detecting a pressure of gas at the patient, (4)
determining whether a current rate at which exhaust gas passes
through the exhaust vent is below an alarm threshold based on the
detected gas flow and pressure, and (5) providing a third output
indicative of a result of the determining step.
[0011] It is a still further object of the present to provide a
method of setting the alarm threshold based on the conditions of
the pressure support system so that the alarm threshold is
optimized for the current conditions of the pressure support
system. This object is achieved, according to one embodiment of the
present invention, by monitoring the rate at which gas flows in the
conduit and the pressure of gas at the patient during a learn
period and setting the alarm threshold based on the monitored rate
of gas flow in the conduit and the pressure at a patient during the
learn period. Thus, the present method can set the alarm threshold
to account for the specific condition of the pressure support
system, such as the introduction of a supplemental breathing gas,
e.g., oxygen, into the system and not produce a false alarm.
[0012] These and other objects, features and characteristics of the
present invention, as well as the methods of operation and
functions of the related elements of structure and the combination
of parts and economies of manufacture, will become more apparent
upon consideration of the following description and the appended
claims with reference to the accompanying drawings, all of which
form a part of this specification, wherein like reference numerals
designate corresponding parts in the various figures. It is to be
expressly understood, however, that the drawings are for the
purpose of illustration and description only and are not intended
as a definition of the limits of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIG. 1 is schematic diagram of a pressure support system
according to the principles of the present invention;
[0014] FIG. 2 is a schematic diagram illustrating further details
of the pressure support system shown in FIG. 1;
[0015] FIG. 3 is a chart illustrating an exemplary relationship
between pressure and leak rate for a conventional exhaust port;
[0016] FIG. 4 is a flow chart illustrating the steps performed in
determining the alarm threshold according to the principles of the
present invention; and
[0017] FIG. 5 is a flow chart illustrating the steps performed in
monitoring the current system leak and comparing this leak rate to
an alarm threshold to determine whether the current system leak
through the exhaust port is below an acceptable value.
DETAILED DESCRIPTION OF THE INVENTION
[0018] The basic components of a pressure support system 30
according to the principles of the present invention are discussed
below with reference to FIGS. 1 and 2. Pressure support system 30
includes a pressure generating system 32 and a patient circuit 31,
which includes a conduit 34 and a patient interface 36. Pressure
generating system 32 is a ventilation or pressure support device
that delivers breathing gas to the patient at a variable or
constant pressure that is greater than atmospheric pressure.
Pressure generating system 32 includes a pressure generating device
33, such as a blower, bellows or piston, that receives a breathing
gas and outputs the breathing gas at a pressure that is greater
than atmosphere.
[0019] Typically, the breathing gas received by pressure generating
device 33 is air taken from the ambient atmosphere. It is to be
understood, however, that the present invention contemplates that a
source of pressurized breathing gas can be used in combination with
the mechanical pressure generating device to provide the breathing
gas to the patient at an elevated pressure. For example, in the
embodiment illustrated in FIGS. 1 and 2, pressure generator 32 is a
mechanical pressure generator, such as a blower, bellows or piston,
that receives ambient air at an inlet as the gas source. FIG. 2
further illustrates an optional arrangement in which a supplemental
gas, such as oxygen from an oxygen source 35, is delivered to the
inlet of the pressure generator via a delivery tube 37.
[0020] It is to be further understood that pressure generator 33
can also be a source of pressurized air, oxygen or an oxygen
mixture in lieu of a mechanical pressure elevating device. For
example, pressurized air can be provided to the airway of the
patient directly from a tank of pressurized air via the patient
circuit without using a mechanical device, such as a blower,
bellows or piston, to increase the pressure of the air. The
important feature with respect to the present invention is that
pressurized breathing gas is provided in the patient circuit for
delivery to the patient, not necessarily the source of the
pressurized breathing gas.
[0021] If the pressure of the breathing gas delivered to the
patient is variable, pressure generating system 32 includes a
mechanism that creates the pressure variations. Examples of
suitable pressure control mechanisms include (1) a pressure control
valve (not shown) downstream of the blower, bellows or piston or
(2) a variable speed motor (not shown) associated with the blower,
bellows or piston to vary the pressure output by pressure generator
33 by controlling blower, bellows or piston speed. The pressure
control valve or viable speed motor typically operate under the
control of a control unit 38 in a feedback fashion based on signals
from sensors associated with the patient circuit. A pressure
support system that provides a variable pressure to the patient
based on patient's respiratory cycle, for example, is taught in
U.S. Pat. Nos. 5,148,802 and 5,433,193, both to Sanders et al., the
contents of which are incorporated by reference into the present
application.
[0022] Although pressure generating system 32 has been described
above in the context of providing CPAP or bilevel pressure therapy
to a patient, it is to be understood that other types of pressure
support functions can be provided by this system. For example, the
present invention contemplates that pressure generating system 32
can correspond to a pressure support device that provides
proportional airway pressure ventilation or PAV.RTM. to the
patient, as taught, for example, in U.S. Pat. No. 5,044,362 to
Younes, the contents of which are incorporated by reference into
the present application. Pressure generating system 32 can also
provide proportional positive airway pressure or PPAP to the
patient, as taught, for example, in U.S. Pat. Nos. 5,535,738 and
5,794,615 both to Estes et al., the contents of which are also
incorporated by reference into the present application, which teach
providing PPAP to treat OSA and to treat congestive heart failure
(CHF), respectively. Furthermore, pressure generating system 32 can
correspond to a system that monitors the conditions of the patient,
such as the occurrence of snoring or an apnea or a lack thereof,
and automatically alters the pressure provided to the patient based
on this monitoring.
[0023] In the illustrated embodiment, conduit 34 has one end
coupled to the output of the pressure generator 33 and another end
coupled to patient interface 36. Conduit 34 is any tubing capable
of carrying the gas flow from the pressure generator to the airway
of the patient. Typically, a distal portion of the conduit 34
relative to pressure generator 33 is flexible to allow for freedom
of movement of the patient. It is to be understood that various
components may be provided in or coupled to patient circuit 31. For
example, a bacteria filter, pressure control valve, flow control
valve, sensor, meter, pressure filter, humidifier and/or heater can
be provided in or attached to the patient circuit.
[0024] Patient interface 36 in patient circuit 31 is any device
suitable for communicating an end of conduit 34 with the airway of
the patient. Examples of suitable patient interface devices include
a nasal mask, oral mask or mouthpiece, nasal/oral mask, nasal
cannula, trachea tube, intubation tube, hood or full face mask. It
is to be understood that this list of suitable interface devices is
not intended to be exclusive or exhaustive.
[0025] In the single limb patient circuit of the present invention,
a majority of the exhaled gas from the patient exits the pressure
generating system via an exhaust vent 40. In the illustrated
embodiment, exhaust vent 40 is provided on a distal portion of
conduit 34. Depending on the tidal volume of the patient, a small
percentage of the exhaled gas may travel back up the conduit into
pressure generator 33 and may even be exhausted to atmosphere
through the gas inlet of the pressure generator and/or through a
pressure control valve associated therewith, if such a valve is
being used with the pressure generator. Typically, exhaust vent 40
is an orifice provided in the conduit that communicates the
interior of the conduit with atmosphere, with no active control
over the flow of gas from the system. It is to be understood,
however, that a wide variety of exhaust devices and configurations
are contemplated for use with the pressure generating system of the
present invention. For example, U.S. Pat. No. 5,685,296 to
Zdrojkowski et al. discloses an exhalation device and method where
the exhalation flow rate through the device remains substantially
constant over a range of pressures in the patient circuit. This
exhalation device, which is commonly referred to as a plateau
exhalation valve or PEV, is suitable for use with the pressure
support system of the present invention.
[0026] As shown in FIG. 2, pressure generating system 32 in
pressure support system 30 also includes a flow sensor 42 that
measures a rate at which the breathing gas flows within conduit 34.
The present invention contemplates that any suitable sensor, such
as a pneumatach, can be used for flow sensor 42. It is to be
further understood that flow sensor 42 need not be coupled directly
to conduit 34. On the contrary, the present invention contemplates
the use of any sensor or a plurality of sensors that can
quantitatively measure airflow in the patient circuit. For example,
flow in the system can be measured at the patient interface device
or can be measured or estimated from the motor or piston speed or
from torque used to provide the elevated pressure by pressure
generator 33.
[0027] Pressure support system 30 also includes a pressure sensor
44 that detects the pressure of the gas at the patient. In the
illustrated embodiment, pressure sensor 44 is in fluid
communication with patient interface device 36 via a conduit 46.
Furthermore, pressure support system 30 includes an alarm 48 that
communicates with control unit 38 to output a human perceptible
warning, such as an audible sound or a visual light, to wake and/or
warn the user or caregiver of an occlusion of exhaust vent 40.
[0028] Although not illustrated, the present invention contemplates
that pressure generating system 32 includes an input/output
interface device, such as a keypad and/or display, for
communicating, information, data and/or instructions between the
user and control unit 38. Also, computer communications, either
hard-wired or wireless, can be provided to allow an external device
to communicate with the control unit using conventional
communication methods, such as by modem. In addition, the
components illustrated in FIG. 2 need not be in hardwired
communication with one another as shown and need not be provided in
the same housing. On the contrary, the present invention
contemplates, for example, that alarm 48, flow sensor 42 and
pressure sensor 44 can be provided at locations remote and external
to pressure generating system 32 and can communicate with control
unit 38 wirelessly or via hardwires. For example, in a clinical or
hospital setting, a single control unit can be used to communicate
with a plurality of alarms, sensors, and flow/pressure generators.
Alternatively, a central base station can be provided that
communicates with a plurality of pressure support systems 30 so
that a central operator can monitor the operation and alarms for
each system.
[0029] As discussed in greater detail below, control unit 38
determines, based on the output of flow and pressure sensors 42 and
44, when the rate of exhaust gas passing through exhaust vent 40,
i.e., the system leak rate, falls below an acceptable leak rate
level and provides the user or caregiver with a warning, via alarm
48, of this condition. A drop in the system leak rate below the
alarm threshold level is an indication that the exhaust ports are
at least partially occluded and, therefore, are not venting a
sufficient amount of expired gas to atmosphere. This low leak alarm
alerts the user and caregiver of the potential that the user may be
rebreathing expired CO.sub.2 and ensures that the patient or
caregiver is warned whenever the exhaust ports become blocked so
that appropriated remedial action can be taken.
[0030] In general, the present invention determines whether the
current rate of exhaust is sufficient, i.e., the exhaust ports are
not occluded or significantly occluded so as to create a hazard, by
comparing the current system leak with an alarm threshold leak
rate. If the current system leak rate is less than the alarm
threshold for a predetermined time period, the alarms sounds. The
alarm is not actuated unless the current system leak rate is less
than the alarm threshold for a predetermined time period to account
for transient aberrations in the current leak rate.
[0031] For example, the predetermined time period during which the
current system leak rate must be less than the alarm threshold
before the alarm is triggered is selected to be sufficiently long
so that the alarm is not actuated if the patient momentarily blocks
the exhaust port while adjusting the mask. On the other hand, the
time period should not be so long that the user's exposure to
rebreathing of expired gasses posses a safety concern. In a
preferred embodiment of the present invention, this period is
selected to be approximately one minute.
[0032] In a preferred embodiment of the present invention,
operation of the pressure support system begins by having the user
perform an exhaust vent test. The exhaust vent test establishes the
known rate at which gas flows through the exhaust port, referred to
as the known leak rate, Q.sub.known, over a range of pressures.
FIG. 3 illustrates an example of a pressure versus flow
relationship 50 between the known leak rate, Q.sub.known, through a
constant orifice exhaust vent over a range of system pressures. It
should be noted that different exhaust ports will have different
pressure versus flow relationships, because the pressure-flow
relationship depends on a number of factors, such as port size and
geometry, as well as the density and viscosity of gas passing
through the port.
[0033] The pressure versus flow relationship determined from the
exhaust vent test is used, at least one embodiment, to set the
alarm threshold. For example, one embodiment of the present
invention contemplates setting the alarm threshold at a certain
percentage, such as approximately 50%, less than the known leak.
Alternatively, the alarm threshold can be set at a fixed flow rate,
such as 5 liters per minute (lpm), less than the known leak. The
pressure versus flow relationship 52 corresponding to an alarm
threshold leak rate over a range of pressures that is approximately
50% less than the known leak rate is illustrated in FIG. 3.
[0034] By determining the pressure versus flow relationship for the
particular system configuration being used by the patient and by
basing the alarm threshold on this relationship, the present
invention allows the alarm threshold to be optimized for each
pressure support system. Thus, the present invention provides
flexibility in the alarm generating function to take into
consideration that fact that not all pressure supports systems are
the same. For example, two pressure support systems may use
differently sized exhalation ports so that the rate at which
exhaust gas passes through these ports will be different for each
system. In which case, different alarm thresholds will be used.
[0035] While the present invention is described above as setting
the alarm threshold at 50% of Q.sub.known or at 5 lpm less than
Q.sub.known, it is to be understood that other alarm thresholds can
be selected. The particular percentage of Q.sub.known, or rate less
than Q.sub.known will depend, for example, on the patient's
tolerance for CO.sub.2 rebreathing. For example, in some patients,
it may be desirable that as little CO.sub.2 rebreathing as possible
occurs. In which case, the alarm threshold is set higher than those
patients in which a greater amount of CO.sub.2 rebreathing is
tolerable. It should also be noted that different alarm thresholds
can used depending on the whichever one is higher or lower or
depending on the monitored conditions. For example, one alarm
threshold may be used for patient pressures up to 10 cmH.sub.2O,
and another threshold used for patient pressures at or above 10
cmH.sub.2O.
[0036] It should also be noted that the pressure support system
being used by one patient may not always have the same
configuration or may not be used in the same manner by that
patient. In which case, it is again preferable that the same alarm
not be used in both configurations or uses. For example, the user
may introduce oxygen as a supplemental gas downstream of the flow
sensor during a portion of the pressure support therapy or may
change the type or number of exhaust ports. A common alarm
threshold would not be suitable if either of these alterations in
the pressure support system have taken place. Instead, different
alarm thresholds should be used for the original system and the
modified system. Thus, it is particularly advantageous that the
present invention allows the alarm threshold to be optimized for
the specific pressure support system being used by the patient.
[0037] In a preferred embodiment of the present invention, the
exhaust vent test is performed by the user, e.g., the patient or
caregiver, once the system configuration is established. For
example, once the system has been assembled and is ready for use,
an input device, such as a button provided on the housing of
pressure generating system 32 or a remote control that communicates
with control unit 38, is actuated by the user to initiate the
exhaust vent test. To perform the exhaust vent test, the user
blocks the end of the patient circuit, for example, by blocking the
opening in the mask, so that all gas delivered to the patient
circuit is vented to atmosphere through the exhaust vent. The
pressure generating system 32 then varies the pressure delivered to
the patient circuit and measures the flow in the conduit associated
with each pressure level. In a preferred embodiment of the present
invention, the system also detects the pressure at patient
interface 36 using pressure sensor 44 and measures the flow through
conduit 34 at that pressure and plots this pressure-flow
relationship, as shown, for example, in FIG. 3. The diamond-shaped
boxes in pressure versus flow relationship 50 represent specific
pressure-flow points measured in this manner.
[0038] Once a number of such points have been determined over a
range of pressures, any one of a number of techniques are used to
define the pressure versus flow relationship. For example, in a
preferred embodiment of the present invention, control unit uses 38
linear interpolation between the fixed, measured points, which are
calculated at 10 msec intervals, to derive the pressure versus flow
relationship 50, Q.sub.known, over a range of pressures. As a
result of performing the exhaust vent test, the flow out of the
exhaust vent, Q.sub.known, which is also referred to as the leak
rate, that is expected for any pressure detected at the patient
interface device is known.
[0039] As noted above, in normal circumstances, Q.sub.known,
represented by pressure versus flow relationship 50, is used to set
the alarm threshold 52. For example, the alarm threshold in one
embodiment of the present invention is set at 50% less than
Q.sub.known or at 5 lpm less than Q.sub.known. If the total system
leak during normal operation falls below this alarm threshold for
more than a predetermined period of time, such as one minute, the
alarm triggers.
[0040] As noted above, this one minute delay is provided to give a
modicum of noise immunity in the alarm detection. In the normal
case, when the accumulation of the patient's secretions are
blocking the exhaust port, there will be a steady decline in the
total system leak and reasonable delays, such as one minute, can be
used without sacrificing patient safety.
[0041] In a preferred embodiment of the present invention, the
results of the exhaust vent test are also used to verify the
integrity of the exhaust vent and to verify that the exhaust vent
test was valid. For example, maximum and/or minimum leak rates can
be set so that if these rates are exceeded during the exhaust vent
test, this is an indication that the test was performed incorrectly
and/or that the exhaust vents are leaking excessively or are
occluded. For example, in a preferred embodiment of the present
invention, the known leak should less than 80 lpm at 40 cmH.sub.2O,
otherwise there is deemed to be an excessive leak in the exhaust
port and/or the exhaust vent test is considered invalid. Similarly,
Q.sub.known, should be greater than 5 lpm at 20 cmH.sub.2O,
otherwise there is deemed to be an insufficient leak in the exhaust
port and/or the exhaust vent test considered invalid.
[0042] It can be appreciated that a wide variety of parameters
associated with the pressure versus flow relationship can be
monitored to determine the validity of the exhaust vent test. For
example, the present invention also contemplates that as the
pressure increases, the flow cannot decrease by more than 5 lpm.
Monitoring these parameters ensures the accuracy of the exhaust
vent test and that the exhaust vents are operating within
acceptable parameters.
[0043] The present invention also uses the exhaust vent test to
test the operation of pressure generating system 32. For example,
if pressure generating system 32 is instructed to output a certain
pressure, the pressured measured by pressure sensor 44 provides a
check on the ability of the pressure generating system to hit the
target pressure. In a preferred embodiment of the present
invention, the pressure generating system is instructed to output a
pressure of 30 cmH.sub.2O. If the pressured measured by pressure
sensor 44 is .+-.2 cmH.sub.2O from 30 cmH.sub.2O, the flow/pressure
generating system is considered to be operating normally.
[0044] The present invention contemplates that the pressure versus
flow relationship, Q.sub.known, for a particular pressure support
system configuration can be established without performing the
above-described exhaust vent test. More specifically, the pressure
versus flow relationship, i.e., Q.sub.known, for a plurality of
different patient circuits or a plurality of different types of
exhaust ports that can be inserted into or used with the patient
circuit are stored in advance in control unit 38. The user can
designate the patient circuit and/or the exhaust vent that is being
used in their particular pressure support system configuration, and
the appropriate relationship for that patient circuit and/or
exhaust vent is retrieved from memory and used to set the alarm
threshold. This embodiment provides the flexibility advantages
associated with performing the exhaust vent test but does not
require the user to perform this test. It does, however, require
that the pressure versus flow relationship for a variety of
different exhaust vents or patient circuit be determined in advance
and stored in the pressure support system. It also requires that
there by a technique for identify the particular type of exhaust
vent and/or patient circuit to the control unit so that the
appropriate pressure versus flow relationship for that exhaust vent
and/or patient circuit can be retrieved. Of course, the pressure
versus flow relationship can be manually entered or downloaded to
the control unit for each patient circuit and/or exhaust port.
[0045] The present invention also contemplates that the control
unit automatically retrieve the proper pressure versus flow
relationship by identifying which patient circuit and/or exhaust
port is currently being used in the pressure support system.
Automatically identifying the patient circuit and/or exhaust port
being used in the pressure support system can be accomplished, for
example, using a resistance identification technique. According to
this technique, for example, the control unit can recognize, via an
electrical contact on the patient circuit and/or the exhaust vent
and an identification resistance located thereon, which patient
circuit and/or exhaust vent is coupled to the pressure generating
system.
[0046] If exhaust vent test is not performed or if the pressure
versus flow relationship, i.e., Q.sub.known, for the exhaust vent
patient circuit is not known, the system sets Q.sub.known to zero
and the alarm threshold is set based on the known flow rate out of
the smallest exhaust port that can be used with the patient
circuit, referred to as the "minimum exhalation port." For example,
in a preferred embodiment of the present invention the alarm
threshold is set to 50% or 5 lpm less than the flow rate out of the
minimum exhalation port when Q.sub.known cannot not be established
using either of the other two techniques discussed above.
[0047] Of importance in carrying out the present invention is the
ability to accurately measure the system leak, i.e., the rate at
which gas exits the pressure support system. This is done in the
present invention by first assuming that, based on human
physiology, over a single breath, a person exhales generally the
same amount of gas that he or she inhales so that the patient's end
tidal volume is zero. This circumstance most definitely is true
over an integral number of breaths, and assuming it to be true over
a single breath is a close approximation. Stated another way, the
integral of patient flow, Q.sub.p, over any one complete breathing
cycle is zero, as follows: 1 T breath Q p t = 0. ( 1 )
[0048] Because pressure support system 30 has no provision for
measuring the patient flow Q.sub.p, the pressure support system of
the present invention instead measures the flow, Q.sub.c, in the
patient circuit, i.e., the flow within conduit 34. Flow in the
patient circuit Q.sub.c is measured, for example, by flow sensor
42. The flow in patient circuit Q.sub.c is the sum of the patient
flow and any leak flows and is defined as follows:
Q.sub.c=Q.sub.p+Q.sub.leak (2)
[0049] where,
Q.sub.leak=Q.sub.known+Q.sub.unknown (3)
[0050] Q.sub.known is any leak other than the known leak
Q.sub.known out of the exhaust port, which, as discussed above, is
determined via the exhaust port test or from predetermined pressure
versus flow data. Q.sub.unknown is modeled according to the
following equations:
Q.sub.unknownR.sub.leak{square root}{square root over (P.sub.p)}
(4)
[0051] if R.sub.leak is positive or zero, and
Q.sub.unknown=R.sub.leak (5)
[0052] if R.sub.leak is negative. P.sub.p is the pressure at the
mask measured by pressure sensor 44 in FIG. 2, for example.
R.sub.leak is a constant that is calculated by the processor in
control unit 38 and is described in greater detail below.
[0053] Determining whether the constant R.sub.leak is positive,
zero or negative is accomplished by determining whether the
following relation is positive, zero or negative: 2 T breath ( Q c
- Q known ) t ( 6 )
[0054] As noted above, Q.sub.c is the measured flow in the patient
circuit, preferably measured by flow sensor 42, and Q.sub.known is
a predetermined known flow out of the exhaust port associated with
the measured pressure at the patient interface device. Preferably,
the pressure at the patient interface device is measured by
pressure sensor 44.
[0055] If the result of equation (6) is positive or zero,
R.sub.leak it is calculated as follows: 3 R leak = T breath ( Q c -
Q known ) t T breath P p t . ( 7 )
[0056] If the result of equation (6) is negative, R.sub.leak is
calculated as flows: 4 R leak = T breath ( Q c - Q known ) t T
breath ( 8 )
[0057] Once the sign of equation (6) is known, the appropriate
equation, i.e., equation (7) or (8), is used to calculate
R.sub.leak, which is then used in either equation (4) or equation
(5) for determining Q.sub.unknown. For example, if equation (6) is
positive or zero, equation (7) is used to calculate R.sub.leak,
which is then used in equation (4) for determining Q.sub.unknown.
If, on the other hand, equation (6) is negative, R.sub.leak is
calculated using equation (8), and used in equation (5) to
calculate Q.sub.unknown. In this manner, the present invention
calculates system leak as a function of pressure. It should be
noted that equation (6) is the equation used in the numerator of
equations (7) and (8) to determine R.sub.leak. Therefore, the steps
to determine the sign of equation (6) are directly applicable to
the calculation to determine R.sub.leak using equation (7) or (8).
Similarly, the sign of R.sub.leak is determined based on equation
(6) because the denominators of equations (7) and (8) are never
negative in a positive pressure support system.
[0058] The operation of the system is described below with
reference to FIGS. 4 and 5. FIG. 4 illustrates the process carried
out by the pressure support system 30, and, in particular, control
unit 38, in establishing the alarm thresholds. FIG. 5 illustrates
the process by which the control unit compares the current system
leak, which is determined from data gathered from the flow and
pressure sensors, with the alarm threshold to determine whether the
leak rate from the system is below an acceptable level.
[0059] The operation of the pressure support system of the present
invention begins by causing the system to enter a learn period,
shown in step 54, which is initiated in any one of a variety of
ways. In an exemplary embodiment of the present invention, as
illustrated in FIG. 4, the learn period in step 54 is initiated
either (1) automatically when the system is activated, preferably
after a system diagnostic is completed, step 56, (2) when a manual
input device, such as a learn key, is actuated, step 58, or (3)
automatically after a change in the operating mode of the pressure
support system, step 60.
[0060] The learn period is a period of time during which a learned
constant R.sub.leak is calculated and stored in control unit 38.
The learned constant R.sub.leak is the same constant R.sub.leak
discussed except that the learned constant R.sub.leak is determined
over this learn period. In a preferred embodiment of the present
invention, the learn period is a one minute time interval. It is to
be understood, however, that the length of the learn period is not
limited to this particular value. On the contrary the learn period
is any timer interval that is long enough to allow the patient to
enter their normal breathing pattern. Typically, this takes
approximately 1-5 minutes.
[0061] During this period, the pressure at the patient interface
and the flow in the patient circuit is measured and used by the
control unit to calculate equation (6), which, as discussed above,
is then used to establish whether equation (7) or (8) is used to
calculate the learned constant R.sub.leak. The appropriate equation
(7) or (8) is selected and the learned constant R.sub.leak is
calculated. If the learned constant R.sub.leak at the end of the
learn period is positive or zero, no special processing is
necessary. If, however, R.sub.leak at the end of the learn period
is negative, then the system is placed into a special mode of low
leak detection discussed in greater detail below.
[0062] A negative learned constant R.sub.leak at the end of the
learn period implies, in most cases, one of two scenarios. The
first scenario occurs if the caregiver adds a supplemental gas,
such as oxygen, downstream of flow sensor 42 into the patient
circuit during the learn period. FIG. 2 illustrates this scenario,
with dashed line 51 representing an oxygen delivery tube that
delivers oxygen from source 35 to patient interface device 36,
which is downstream of flow sensor 42 relative to flow provided by
pressure generator 33. Delivering a supplemental gas flow to the
patient circuit downstream of flow sensor 42 increases the learned
constant R.sub.leak negatively because leak flow is modeled above
in a direction leaving the circuit, while the supplemental gas, on
the other hand, is entering the circuit. If, during the known
period, the known leak, Q.sub.known, out of the exhaust vent is
less than the rate at which the supplemental gas is added, the
learned constant R.sub.leak, will be negative. It should be
understood that this is possible because leaks at the mask-patient
interface, for example, can vent off the excess supplemental gas
and/or the excess supplemental gas may back-up into the pressure
generator and possibly exit the system from the pressure generator
inlet or pressure control valve associated therewith.
[0063] The second scenario that can cause the learned constant
R.sub.leak to be negative at the end of the learn period pertains
to the exhaust vent test. If the user performs the exhaust vent
test with a given leak device and then switches the exhaust vent
with a more restrictive exhaust port that is used to calculate the
learned constant R.sub.leak during the learn period, the learned
constant R.sub.leak detected during the learn period will become
negative. Similarly, if the learn period is executed with the same
exhaust vent used during the exhaust vent test but the exhaust vent
is more obstructed during the learn period than it was during the
exhaust vent test, it appears to the control unit that a new, more
restrictive exhaust vent has replaced the previous exhaust vent and
the alarm threshold will be reduced, as discussed below, because
the learned constant R.sub.leak will be negative. It should be
understood that the learned constant R.sub.leak is calculated
during the learn period based on Q.sub.known, which is determined,
at least in one embodiment, based on the exhaust vent test and in
another embodiment based on predetermined pressure versus flow
relationships. Therefore, using a different exhaust vent in the
exhaust vent test than that used during the learn period,
retrieving pressure versus flow information for the wrong patient
circuit or exhaust vent, or changing the rate of exhaust between
the exhaust vent test and the learn period for the same exhaust
vent, such as would occur if the vent becomes obstructed, affects
the results of the learn period and can cause the resulting learned
constant R.sub.leak to be negative.
[0064] If the learned constant R.sub.leak determined at the end of
the learn period is positive or zero, the alarm threshold is
determined based on whether or not the exhaust vent test was
performed, step 62. If the exhaust vent test was determined to have
been performed in step 62, the alarm threshold is set in step 64,
according to a preferred embodiment of the present invention, as
either (1) a predetermined percentage of the known leak rate,
Q.sub.known, determined during the exhaust vent test or (2) a
predetermined amount less than this known exhaust vent leak rate.
In a preferred embodiment of the present invention, whichever alarm
threshold is the smallest is used. An example of this alarm
threshold is illustrated in FIG. 3 by curve 52, which is generally
50% of the known leak 50. In a preferred embodiment of the present
invention, and as illustrated in FIG. 4, the alarm threshold is set
to either 50% or 5 lpm less than the known leak Q.sub.known,
whichever is smaller.
[0065] It is to be understood that different percentages of the
known leak, amounts of the known leak or combinations of the two
can be used as the alarm threshold depending, for example, on the
detected pressure. For example, an alarm threshold of 75% of the
known leak can be used for pressures between 0-5 cmH.sub.2O and an
alarm threshold of 50% of the known leak or 5 lpm less than the
known leak, whichever is smaller, can be used for all other
pressures.
[0066] It is to be understood that the alarm threshold will also be
set as described above with respect to step 64 if the known leak,
Q.sub.known, is established based on data stored in memory. The
effect of (1) performing the exhaust vent test or (2) recalling
predetermined pressure versus flow data from memory based on the
system configuration, and, more particularly, the type of exhaust
vent or vents used, is the same. In both situations, a known
pressure versus flow relationship, Q.sub.known, is established so
that the flow out of the exhaust vent associated with a given
pressure at the patient interface device is known.
[0067] If the exhalation vent test was not performed or if the
pressure versus flow relationship is not known, the alarm threshold
is set in step 66 as either (1) a predetermined percentage or (2) a
predetermined amount less than the leak from the smallest known
port that can be used in the patient circuit. Preferably, whichever
of the predetermined percentage or the predetermined amount less
than the leak from the smallest known port that results in the
lowest alarm threshold is used. Also, in this situation, the known
leak, Q.sub.known, is set to zero in step 68.
[0068] If the learned constant R.sub.leak at the end of the learn
period is negative, the alarm threshold must be carefully monitored
to ensure that false alarms are not generated, which might
otherwise occur, for example, once the caregiver ceases supplying
supplemental oxygen. If the learned constant R.sub.leak at the end
of the learn period is negative, the alarm threshold is set in step
70 as the sum of the known leak, Q.sub.known, and the constant
R.sub.leak, which was determined in the learn period, minus either
(1) a predetermined percentage of the sum of the known leak,
Q.sub.known, and the constant R.sub.leak or (2) a predetermined
amount of flow less that this sum. In the exemplary embodiment
illustrated in FIG. 4, the alarm threshold is set in step 70 as
either 50% or 5 lpm less than the known leak, Q.sub.known, plus the
constant R.sub.leak established as a result of the learn period.
The known leak value Q.sub.known varies with pressure, but the
learned constant R.sub.leak established as a result of the learn
period is now representative of an average leak valve and does not
change with pressure.
[0069] Setting the alarm threshold in the manner discussed above
with respect to step 70 is necessary to prevent situations, for
example, where supplemental oxygen is added to the patient circuit
downstream of the pressure/flow generator from generating a false
alarm. When the supplemental gas is first introduced, the user
initiates the learn period, for example, by actuating the learn
key. (It is also preferable for the user to make sure that the
patient interface device is properly positioned.) The system sets
the alarm threshold as discussed above taking into consideration
the fact that supplemental gas is being introduced into the patient
circuit.
[0070] When the supplemental gas is not longer being administered,
the system leak will return to its original value. Therefore, it is
preferable to again initiate the learn period in step 54 to
reestablish the normal baseline alarm threshold of the exhaust port
without the supplemental gas being introduced into the system.
Preferably, the user actuates the learn key, step 58, to initiate
the learn period. However, the present invention contemplates that
the learn period can be automatically. For example, if the system
detects that a new exhaust port has replaced the previous port, the
learn period can be automatically entered.
[0071] If, however, the learn period is not initiated at the
cessation of the supplemental gas therapy, either manually or
automatically, the system of the present invention automatically
returns the alarm threshold to the exhaust port's baseline values.
This is accomplished in step 72 in FIG. 4. According to step 72, if
the learned constant R.sub.leak was determined to be negative
during the learn period, the system continuously calculates
R.sub.leak. If R.sub.leak becomes zero or positive for a
predetermined period of time, such as one (1) minute, the alarm
threshold is then set as discussed above according to step 64 or
step 66 depending on whether the exhaust vent test was performed
(step 62). Otherwise, if R.sub.leak remains negative, the alarm
threshold continues to be set according to step 70. It is to be
understood that the predetermined period of time set forth in step
72 can be values other than one minute, so long as this period of
time is sufficient to detect an actual change in the system
configuration and not a temporary phenomena, such as a readjustment
of the patient interface device by the user.
[0072] The present invention further contemplates that the alarm
threshold can be altered automatically (without waiting for
R.sub.leak to be positive for a predetermined period of time as
required by step 72) based on detected changes in the pressure
support system. For example, sensors or other means can be provided
for determining when the supplemental gas is no longer being
introduced into the system. For example, a valve controlling the
supplemental gas supply, or a control unit that controls the valve,
can signal when the valve is shut, thereby causing the system to
move from step 70 to step 62. Alternatively, an oxygen sensor, for
example, can be provided to detect when oxygen is no longer being
administered to the patient and cause the system to enter the reset
the alarm threshold via steps 62-66.
[0073] This automatic resetting of the alarm threshold also guards
against users that mistakenly initiate the learn period when no
exhaust port is present in the patient circuit or when the exhaust
port is blocked. In these situations, the learned constant
R.sub.leak will likely be calculated during the learn period as
being negative. If the exhaust port is later added to the circuit,
becomes unblocked, or if another leak occurs, such as leak at the
mask seal, R.sub.leak becomes positive. This is detected in step
72, and the alarm threshold is set according to steps 64 or 66.
Thus, the pressure support system of the present invention
automatically corrects the alarm threshold for such user errors and
other events to prevent false alarms.
[0074] FIG. 5 illustrates the steps the control unit performs in
determining whether the system leak through the exhaust port is
below an acceptable value during normal operation of the pressure
support system after the alarm threshold has been set as discussed
above with respect to FIG. 4. During operation, the pressure
support system continuously determines in step 74 whether the
constant R.sub.leak is positive or not. This is accomplished by
continuously calculating equation (6) based on the pressure and
flow measurements discussed above. (See above). Only equation (6)
need be considered because equation (6) is the numerator for both
equations (7) and (8). The denominator for these equations is never
negative. Thus, the result of calculating equation (6) establishes
whether R.sub.leak is positive, zero or negative.
[0075] If the result of equation (6) is positive or zero, the
system compares in step 76 the sum of the known leak, Q.sub.known,
and R.sub.leak*{square root}{square root over (P.sub.p)} to the
alarm threshold established as discussed above with respect to FIG.
4. It should be noted that the product R.sub.leak*{square
root}{square root over (P.sub.p)}, when R.sub.leak is positive or
zero, corresponds to equation (4) which defines Q.sub.unknown.
Thus, the sum of the known leak, Q.sub.known, and
R.sub.leak*{square root}{square root over (P.sub.p)}, when
R.sub.leak is positive or zero, corresponds to equation (3) which
defines the system leak as Q.sub.known+Q.sub.unknown. If this sum,
i.e. Q.sub.leak or system leak, is less than the alarm threshold
for more than a predetermined period of time, the low leak alarm is
actuated in step 78.
[0076] In the illustrated exemplary embodiment, the predetermined
period of time is selected to be one (1) minute. It is to be
understood that this time period can be other values so long as the
period of time is long enough to prevent transient aberrations from
causing a false alarm yet not so long that the user suffers from
having the system running with the exhaust port completely or
partially blocked.
[0077] If the result of equation (6) is not positive or zero, i.e.
negative, the system compares, in step 80, the sum of the known
leak, Q.sub.known, and R.sub.leak to the alarm threshold
established, as discussed above, with respect to FIG. 4. It should
be noted that when result of equation (6) is negative, R.sub.leak
corresponds to Q.sub.unknown as set forth above in equation (5).
Thus, the sum of the known leak, Q.sub.known, and R.sub.leak, when
R.sub.leak is negative, also corresponds to equation (3), which
defines the system leak as Q.sub.known+Q.sub.unknown. If this sum,
i.e. Q.sub.leak or system leak, is less than the alarm threshold
for more than a predetermined period of time, the low leak alarm is
actuated in step 78.
[0078] A more thorough understanding of the present invention may
be appreciated by considering the following examples. It is to be
understood that these are hypothetical examples that illustrate,
with reference to FIGS. 4 and 5, how the system determines the
alarm threshold and uses this threshold to judge whether the system
leak rate is below acceptable levels. The values for the leak rate
used in these examples are selected to illustrate the system
operation and do not necessarily reflect actual values.
EXAMPLE 1
[0079] In this example, the pressure support system is as shown in
FIG. 1, and no supplemental gas is being delivered to the patient.
Suppose that an exhaust vent test has been performed and the known
leak rate has been determined to be a constant 30 lpm,
Q.sub.known=30 lpm, for the entire range of operating pressures.
Suppose, also, that the learn period has been performed and the
learned constant R.sub.leak is determined to be positive or zero.
The system determines the alarm threshold according to step 64 as,
for example, 50% less than Q.sub.known, i.e., 50% less than 30 lpm
or 15 lpm.
[0080] After the learn period, the system then continuously
determines whether the sign on the constant R.sub.leak is positive
or zero in step 74 of FIG. 5. As long as R.sub.leak remains
positive or zero, step 76, which is the test used if R.sub.leak is
positive, will not produce an alarm because the known leak,
Q.sub.known, plus a positive R.sub.leak value multiplied by the
square root of pressure at the patient interface, i.e., step 76,
will not yield a result that is less than the alarm threshold.
[0081] However, as the exhaust vent becomes occluded, R.sub.leak
will decrease and become negative. If, for example, R.sub.leak is
-10 lpm, the system leak Q.sub.leak will be Q.sub.known+R.sub.leak,
see equations (2) and (4) and step 80 in FIG. 5. In this example,
Q.sub.leak=30 lpm+(-10 lpm)=20 lpm. Because 20 lpm is not less than
the alarm threshold of 15 lpm, the low leak alarm will not yet be
activated. As the exhaust vent becomes more occluded, R.sub.leak
continues to decrease, i.e., become more negative, and eventually
the system leak Q.sub.leak will fall below the alarm threshold, and
the low leak alarm will sound.
EXAMPLE 2
[0082] This example is the same as the pervious example except that
the exhaust vent test has not been performed. In this situation,
because the learned constant R.sub.leak determined during the learn
period is positive and because the exhaust vent test was not
performed, the alarm threshold is set according to step 66 in FIG.
4, for example, as 50% less than the leak from the minimum exhaust
vent that can be used with the patient circuit. Suppose, in this
example, that the leak rate from the smallest useable exhaust port
is a constant 10 lpm over the range of operating pressures. Half of
this rate is 5 lpm, so that the alarm threshold is set at 5 lpm. In
addition, Q.sub.known is set at zero in step 68.
[0083] R.sub.leak is continuously calculated in step 74 following
the learn period. If, for example, R.sub.leak is determined to be
10, the system leak (known leak, Q.sub.known+R.sub.leak*{square
root}{square root over (P.sub.p)}) in step 76 is determined as
follows: 0+10{square root}{square root over (P.sub.p)} or simply,
10{square root}{square root over (P.sub.p)}; recall that the known
leak, Q.sub.known, was set to zero. It can be appreciated that it
may be possible for the value of R.sub.leak to decrease, as the
exhaust vent becomes occluded, such that R.sub.leak drops to a
level in which the system leak, Q.sub.leak (known leak,
Q.sub.known+R.sub.leak*{square root}{square root over (P.sub.p)})
falls below the alarm threshold level so that the lower leak alarm
sounds. If R.sub.leak becomes negative, which might occur if
supplemental gas is added to the system, the alarm threshold test
set forth in step 80 of FIG. 5 is used. It can be appreciated that
as R.sub.leak falls as a result of the exhaust vent becoming more
occluded, eventually R.sub.leak will fall to a level below the
alarm threshold and the low level alarm will be actuated.
EXAMPLE 3
[0084] This example is the same as Example 1 in that the exhaust
vent test has been performed so that Q.sub.known, i.e., the
pressure versus flow relationship for the pressure support system
being used by the patient, is established as, for example, 30 lpm
over the range of operating pressures. In this example, however,
suppose that as a result of the learn period, the learned constant
R.sub.leak is determined to be negative, such as -10 lpm. The alarm
threshold is then set according to step 70 in FIG. 4 as, for
example, 50% less than Q.sub.known+R.sub.leak. In this example,
Q.sub.known=30 lpm and R.sub.leak=-10 lpm so that the alarm
threshold is 50% less than 20 lpm or 10 lpm.
[0085] Referring now to FIG. 5, the system continuously determines
R.sub.leak in step 74. If R.sub.leak continues to be -10 the system
leak, alarm threshold test set forth in step 80 is used because
R.sub.leak is negative. In step 80, the current system leak,
Q.sub.leak, is Q.sub.known (30 lpm)+R.sub.leak (-10 lpm)=20 lpm,
which is not less than the alarm threshold of 10 lpm so that the
alarm is not actuated. As the exhaust port becomes occluded,
R.sub.leak drops. Eventually, R.sub.leak will drop to a level where
the system leak, Q.sub.known+R.sub.leak of step 80, is less than
the alarm threshold.
EXAMPLE 4
[0086] This example is the same as Example 2 in that the exhaust
vent test has not been performed. In addition, at a result of the
learn period the learned constant R.sub.leak is determined to be
negative, for example -10. In this example, as with Example 3, the
alarm threshold is set according step 70 in FIG. 4. For example,
the alarm threshold is set as 50% less than Q.sub.known+R.sub.leak.
In this example, Q.sub.known=0 lpm and R.sub.leak=-10 lpm so that
the alarm threshold is 50% less than -10 lpm or -15 lpm.
[0087] Thereafter, the pressure support system continuously
determines R.sub.leak in step 74 of FIG. 5. If R.sub.leak continues
to be negative, the alarm threshold test set forth in step 80 is
used. According to step 80, the current system leak, Q.sub.leak, is
determined as Q.sub.known (0 lpm)+R.sub.leak (-10 lpm)=-10 lpm,
which is not less than the alarm threshold of -15 lpm so that the
alarm is not actuated. As the exhaust port becomes occluded,
R.sub.leak drops. Eventually, R.sub.leak will drop to a level where
the system leak, Q.sub.known+R.sub.leak because R.sub.leak is
negative, is less than the alarm threshold.
[0088] It should be noted that in Examples 3 and 4, if R.sub.leak
becomes positive for more than one minute, for example, the alarm
threshold will be recalculated as discussed above with respect to
step 72 of FIG. 4.
[0089] It can thus be appreciated that the pressure support system
of the present invention provides an alarm that indicates
situations where the system leak rate is below an acceptable level
that is reliable for detecting blockage of an exhalation port under
a variety of different scenarios. The low leak alarm system of the
present invention is particularly advantageous in that the alarm
threshold is adaptable to the specific exhaust port requirements
through the use of the exhaust vent test or the ability to recall
predetermined flow versus pressure relationships for a particular
type of exhaust port. Furthermore, the low leak alarm system can
detect blockage of the exhaust vent even if a supplemental gas is
added to the system while minimizing false alarms once the
supplemental gas flow ceases.
[0090] Although the invention has been described in detail for the
purpose of illustration, it is to be understood that such detail is
solely for that purpose and that variations can be made therein by
those skilled in the art without departing from the spirit and
scope of the invention except as it may be limited by the
claims.
* * * * *