Aspects of the present invention relate to humidification systems which provide humidified gas to a patient.
Humidification systems have long been used to treat patients in need of respiratory assistance. A typical humidification system generally includes a source of gas, a source of water vapor, and a delivery system. In the typical humidification systems, the water vapor is first produced by heating a stationary body of water contained in a humidifying chamber. Then, the water vapor mixes with gases passing through the humidifying chamber, thereby humidifying the gas. However, heating the body of water to a point sufficient to produce water vapor can take a significant amount of time, depending on the amount of water contained in the chamber. In the stationary water humidifier, the humidifying chamber containing the water is arranged so that the water vapor mixes with the gas flowing through the humidifying chamber, thereby humidifying the gas. Furthermore, because the stationary water is heated, when the gas passes over the heated water, the gas is also heated. Thus, a heating step occurs simultaneously with the humidifying step. The humidified gas then proceeds through a respiratory circuit, which directs the humidified gas to a patient. U.S. Pat. No. 5,445,143 discloses such a system.
It is known to implement a stationary water humidifier in a humidifying system having parallel gas flow paths. U.S. Pat. No. 7,146,979 discloses such a system. In particular, U.S. Pat. No. 7,146,979 discloses a humidification system having a valve for splitting a gas into two different paths, wherein one path is humidified while the other is heated by a heater. The system is capable of adjusting the valve to control the relative humidity of the gas being delivered to the patient. However, operating the system in this manner requires implementing sensors for determining relative and absolute humidity of the gas.
Other humidification systems may meter a flow of water to an evaporator. U.S. Pat. No. 6,102,037 describes such a system. The system disclosed in U.S. Pat. No. 6,102,037 provides water vapor with a temperature above 134° C., which heats the respiratory gas. Another humidification system has been disclosed that avoids pumping water and reduces the time required to heat the water by using a capillary system. For example, U.S. Pat. No. 7,694,675 uses a low porosity sintered glass or ceramic to draw water to and through an evaporator tube, where the water is evaporated into a gas.
Regardless of the type of humidifier used, conventional humidifying systems implement a respiratory circuit to provide a flow path from the humidified gas to the patient. Many of the known humidification systems are capable of delivering over 100 Watts to evaporate the water. Therefore, it is preferable to locate the evaporating components away from the patient to simplify system design and minimize patient risk. Furthermore, it would not be comfortable for the patient to have bulky equipment located directly by the patient's face. It is also important to ensure the gas flow being received by the patient arrives at a safe temperature, which is capable of being measured and controlled. By providing a respiratory circuit extending from the humidifier to the patient, the above problems are avoided. However, using a respiratory circuit to deliver the humidified gas creates additional problems.
A significant problem that occurs when using a respiratory circuit to deliver humidified gas is the formation of condensation in the respiratory circuit. Condensation, or “rainout,” occurs due to the temperature gradient existing between the respiratory circuit and the external temperature of the patient's room. The ambient room temperature is generally lower than the temperature of the gases inside the respiratory circuit because the patient's room is usually maintained at a comfortable level for the patient. As humidified gas flow passes within the relatively colder walls of a respiratory circuit, a certain amount of water vapor will condense along the walls of the respiratory circuit. After too much condensation builds up, a practitioner must manually remove the condensation from the respiratory circuit because it is dangerous for a patient to accidentally inhale liquid. The manual removal of condensation requires taking apart the respiratory circuit or replacing the respiratory circuit, which can take a substantial amount of time. Taking down the circuit to remove condensation breaks the continuity of delivering humidified gas to the patient. Furthermore opening the circuit to remove condensation causes a loss of respiratory pressure support and may result in alelactasis or respiratory distress.
Several of the known humidification systems attempt to solve the problem by providing heated elements within the respiratory circuit itself. By selectively heating the heated elements, the operator maintains a temperature of the heated walls to maintain the temperature of the gas above the dewpoint, thereby potentially reducing condensation. Such a system is disclosed in U.S. Pat. No. 7,146,979. However, as discussed in U.S. Pat. No. 6,078,730, in such a system, the temperature is highest close to the wire, but low on the wall across from the heater, thereby allowing condensation to occur. To improve on this system, U.S. Pat. No. 6,078,730 discloses an alternative humidification system that includes a heater wire sitting against or adjacent to an internal wall of a respiratory conduit. Furthermore, DE 4312793 discloses a humidification system having a heater provided in a respiratory circuit. However, these systems require additional heated elements and controls to heat the respiratory circuit walls and the gas to reduce the condensation.
Thus, there is a need in the art for a simple method for reducing condensation in a respiratory circuit.
The present invention provides a method of reducing condensed humidifying agent in a humidification system, the method includes providing a humidification system having a respiratory circuit for delivering a volume of gas to a patient and a humidifier portion for delivering a humidifying agent to the volume of gas, pulsing a delivery of the humidifying agent to the volume of gas at a pulsed interval via the humidifier portion, heating the volume of gas, and vaporizing, during a non-pulsed interval, condensed humidifying agent present in the respiratory circuit to reduce the condensed humidifying agent present in the humidification system.
The present invention also provides a method of delivering a humidified volume of gas to a patient, the method including providing a humidification system having a respiratory circuit for delivering the volume of gas to a patient and a humidifier portion for delivering a humidifying agent to the volume of gas, providing the humidifying agent at a controlled flow rate to the humidifier portion via a humidifying agent input line, vaporizing the humidifying agent via a heated element, delivering the humidifying agent to the volume of gas, thereby humidifying the volume of gas, heating the gas flow, and delivering the humidified volume of gas to the patient via the respiratory circuit.
The present invention also provides a humidification system for carrying out the method of reducing condensed humidifying agent and the method of delivering humidified gas.
The above and still other advantages of the invention will be apparent from the detailed description and drawings. What follows are one or more preferred embodiments of the present invention.
The present invention provides a method of removing condensed humidifying agent from a humidification system, a method of delivering humidifying gas to a patient, and a humidification system for performing the methods. It is to be understood that the term gas is intended to include any gas suitable for use with the following disclosure. For example, the gas may comprise oxygen, ambient air, or any other breathable gas. The method of removing condensed humidifying agent includes pulsing the delivery of a humidifying agent to a heated volume of gas as the volume of gas travels towards the patient and evaporating the condensed humidifying agent during a non-pulsed interval. The method of delivering humidified gas to the patient includes delivering a controlled amount of humidifying agent to a humidifier portion. Thus, the present invention effectively and easily allows a practitioner to reduce condensation present in a humidification system by removing condensation. Furthermore, the present invention also provides an alternative to a humidifier having a stationary water chamber.
In the exemplary aspects described herein, the humidifying portion 130 vaporizes the humidifying agent and delivers the vaporized humidifying agent to the volume of gas. The volume of gas provided to the respiratory circuit 120 is generally dryer and colder relative to the later humidified state when the gas is first provided from the gas source 110. The gas flow is heated at one or more of the following points in flow path: before passing through the humidifying portion 130, while passing through the humidifying portion, and after exiting the humidifying portion 130. Thus, when the humidifying agent is delivered to the volume of gas via the humidifying portion 130, the volume of gas becomes more humid, while the heating step ensures the humidifying agent is in a vapor state, thereby making the gas safe for breathing. The respiratory circuit 120 is also in communication with the patient 140 at a point downstream of the humidifying portion 130. Thus, after the humidifying agent is delivered to the volume of gas, the humidified volume of gas reaches the patient 140 and is inhaled by the patient 140. The patient then exhales through an exhaust portion of the respiratory circuit 120. The exhaust portion may lead back to the gas source 110.
In an exemplary aspect of the present invention, the humidifying portion 130 is operated to pulse the delivery of humidifying agent to a volume of gas flowing through the respiratory circuit 120. The gas source 110 is configured to provide a volume of gas corresponding to a patient's normal breathing volume. More specifically, the humidifying portion 130 is operated to quickly increase the delivery of humidifying agent to the volume of gas that is being delivered to the patient 140. During patient exhalation, the gas source 110 provides a second volume of gas, alternatively referred hereinafter to as a bias volume. At a time when it is desirable to remove condensation from the respiratory circuit 120, i.e., when the bias volume of gas is being delivered, the humidifying portion 130 is operated so that less humidifying agent is delivered to the bias volume of gas as compared to the pulsed delivery of humidifying agent to the inhaled volume of gas. Because the bias volume of gas has less humidifying agent as it passes through the respiratory circuit 120, the bias volume of gas will vaporize condensed humidifying agent present in the respiratory circuit 120. Thus, in the non-pulsed interval, the flow of the bias volume of gas effectively removes condensed humidifying agent from the respiratory circuit 120. As will be described in more detail herein, in one aspect the pulse may be provided by directing a volume of gas toward the humidifying portion 130, while in another aspect the pulse may be provided by controlling the rate of flow of humidifying agent into the humidifying portion 130.
In an aspect of the present invention, the timing of the pulse may be set according to the breathing pattern of the patient 140. For example, because it is desirable for the patient to receive the humidified gas during inhalation, the humidifying portion 130 may be operated to pulse the delivery of humidifying agent to a volume of gas at the start of inhalation or immediately following patient exhalation. Likewise, it is not desirable for the patient 140 to inhale a non-humidified gas stream. Therefore, in an aspect of the present invention the humidifying portion 130 may be operated to provide humidifying agent to a bias volume of gas in the non-pulsed state during patient exhalation or immediately after patient inhalation. By delivering the pulse in the above-described manner, the patient 140 will preferentially receive humidified gas when inhaling and the respiratory circuit 120 may be cleared of condensation at other times.
Additionally, the timing of the pulse may be set so that the volume of gas containing a pulsed amount of humidifying agent is present in some part of the respiratory circuit 120 at the same time a bias volume of gas containing a non-pulsed amount of humidifying agent is present in another part of the respiratory circuit 120. For example, a bias gas may be delivered to the respiratory circuit 120 from the gas source 110, to which a non-pulsed amount of humidifying agent is delivered. Immediately following, while the non-pulsed bias volume is traveling through respiratory circuit and evaporating condensation, a volume of gas to which the pulsed amount of humidifying agent is delivered, is provided to the respiratory circuit. Accordingly, the condensation is being evaporated while the volume of gas receiving a pulsed amount of humidifying agent is traveling through the respiratory circuit. It is also within the scope of the invention that under certain circumstances the bias volume receiving the non-pulsed delivery of humidifying agent may be delivered the patient. The non-pulsed bias volume may be delivered to the patient when the amount of condensation present in the respiratory circuit 120 is great enough that the bias volume ultimately ends up being adequately humidified as the gas travels through the respiratory circuit 120.
The method of delivering humidified gas to a patient 140 also uses the above-described components of the humidifying system 100. The method provides a manner of delivering a controlled amount of humidifying agent to the gas stream, thereby avoiding the problems associated with a stationary water humidifier, while allowing precise control of the amount of humidifying agent delivered to the dry gas. As with the method of reducing condensed humidifying agent, in the method of delivering humidified gas, the volume of gas flowing from the gas source 110 is heated to the proper temperature to ensure the humidifying agent is vaporized before reaching the patient. The heating step may be performed as described above, i.e. before, after, or simultaneous with the humidifying step. Also as described above, the volume of gas flows to the humidifying portion 130 of the humidification system 100 where the humidification of the volume of gas occurs. In an exemplary aspect of the present invention, instead of including a stationary water humidifier, the humidifying portion 130 includes a flow controller that controls delivery of the humidifying agent to a heated element. The flow controller may be operated and controlled to provide a particular flow of humidifying agent to the humidifying portion 130. More specifically, by optimizing the flow of humidifying agent delivered to the humidifying portion 130, the amount of humidifying agent delivered to the volume of gas may be precisely controlled. As discussed in more detail herein, the other variables may be controlled, such as, but not limited to, fresh gas flow rate and heated element temperature. Furthermore, by delivering humidifying agent to a heated element, the above-described disadvantages of the stationary water humidifier are avoided. In particular, as discussed in more detail herein, by delivering humidifying agent, the heating step and the humidifying step will not occur simultaneously, thereby allowing more flexibility in controlling the system.
Several exemplary aspects of the humidifying portion will now be described.
As described above, when allowing the volume of gas to travel through the humidifying flow path 230, the volume of gas will pass through a chamber of heated stationary humidifying agent 210. As the volume of gas passes through the chamber, the volume of gas will absorb humidifying agent vapor and will be heated. For the reasons described above, after the humidified gas exits the humidifying portion 200, condensation may likely form in a discharge line 260 that is positioned downstream of the humidifying portion 200. In the case where at least some volume of gas passes through the humidifying flow path 230, in addition to the heating of the gas as it passes through the chamber of heated stationary water, the volume of gas may be heated upstream in the gas inlet line 270 and/or downstream in the discharge line 260. In the case where at least some volume of gas is passing through the diverted flow path 240, the gas may additionally be heated in the diverted flow path 240. The gas inlet line 270, the diverted flow path 240, and the discharge line 260 may each include a heating element (not shown), such as a heating wire, to facilitate the additional heating. The heating elements may be used to ensure that the humidifying agent present in the volume of gas remains in a vapor state upon delivery to the patient. The heating element in the diverted flow path 240 may be used to increase the temperature of the volume of gas passing through the diverted flow path 240, thereby facilitating removal of condensation from the discharge line 260. Furthermore, when heating is carried out in the discharge line 260, the heating step may be used in conjunction with the pulsing method to further reduce condensation.
To remove the condensation from the discharge line 260, the diverter 220 may be actuated to divert the gas flow between the diverted flow path 240 and the humidifying flow path 230 in pulsed intervals. In the simplest aspect, when humidified gas is desirable, the controller 250 can actuate the diverter 220 to immediately direct all of a volume of gas through the humidifying flow path 230. Because the valve was previously directing all of a volume of gas through the diverted flow path 240, the amount of humidifying agent delivered to the volume of gas is increased, as compared to the previous volume of gas passing through the system. After the humidified gas has been delivered to the patient 140, and it becomes desirable to remove any condensation that has formed in the discharge line 260, the controller 250 can immediately actuate the diverter 220 to direct all of the volume of gas through the diverted flow path 240. Because all the gas is being directed through the diverted flow path 240, the amount of humidifying agent delivered to the volume of gas is decreased, as compared to the previous volume of gas passing through the system. Thus, by switching the diverter 220 between the two paths, the delivery of humidifying agent to the gas flow is pulsed. Furthermore, in another aspect, the above-described concept can be applied to any degree of flow splitting. For example, during the pulsing step a volume gas may be divided between the humidifying flow path 230 and the diverted flow path 240 such that 25% of the volume of gas passes through the diverted flow path 240 and 75% of the volume of gas passes through the humidifying flow path 230. In such a case the delivery of humidifying agent to the total volume of gas is being pulsed as compared to the opposite split (i.e. 25% of the volume passing through the humidifying flow path 230 and 75% passing through the diverted flow path 240). The above-described ratios are merely exemplary, and it is within the scope of the invention that any ratio of split may used, as long as the amount of humidifying agent delivered to the volume of gas is increased (i.e. pulsed) as compared to a volume of gas (i.e. a bias volume) that is intended to remove condensation.
As shown in
The controller 250 may communicate with a variety of feedback sensors 280, 282, 284, 286 to provide optimal timing of the delivery of pulsed humidifying agent to a volume of gas. In particular, sensor 280 may detect a flow rate of gas, sensor 282 may detect a temperature and flow rate of gas passing through the humidifying flow path 230, sensor 284 may detect the humidifying agent water level, temperature, and number of times the chamber has been refilled with humidifying agent, and sensor 286 may detect the temperature of the gas passing through the discharge line 260. In some aspects, the gas source 110 and the controller 250 may be preconfigured to communicate with each other such that the controller 250 receives timing/breathing pattern information from the gas source 110, such as when the gas source is a lung ventilator. When the controller 250 and gas source 110 communicate in this manner, it is not necessary to use the flow sensor 280. However, when controller 250 and the gas source 110 are not preconfigured to communicate with each other, the flow sensor 280 is necessary to control the system. Notably, in the aspect of
In the aspect of
The heated element 320 is maintained at a temperature sufficient to vaporize the humidifying agent as soon as the humidifying agent comes into contact with the heated element 320. The heat from the heated element may be sufficient to heat the gas to the necessary temperature, in which case upstream and downstream heaters would not be necessary. The heated element 320 may be made of any material that is suitable of achieving this function. In an exemplary aspect, the heated element 320 may comprise a porous mass of thermally conductive material. More specifically, the heated element 320 may comprise a thermally conductive fiber wool or sintered particulate mass manufactured from, for example, copper or stainless steel. The heated element 320 may be enclosed within a heater coupling 370 to maintain the temperature of the heated element 320.
In operation, unlike the aspect of
As with the aspect of
Furthermore, a controller 360 and sensors 380, 382, 384, 386 may be implemented in a similar manner as in the aspect of
The aspect of
In the aspect of
Unlike the above-described aspects, the humidifying portion 400 does not convert the humidifying agent to vapor before it reaches the volume of gas passing through the humidifying portion 400. Rather, the fine droplets, which are still in a liquid state, are delivered to the gas inlet line 430 and are vaporized within the volume of gas. The fine droplets are vaporized when the droplets enter the gas inlet line 430 when the entry point into the gas inlet line 430 includes a heated element 420, as shown in the exemplary aspect of
The pulsing step of the aspect of
The humidifying system of
The above-described aspects are directed to pulsing the delivery of humidifying agent in order to reduce condensation present in a discharge line 365, 490. As described above, the pulsing method can be used in each of the exemplary aspects illustrated in
The method of delivering humidified gas is the same as the method described above with respect to the pulsing method, except that the pulsing step is omitted. That is, the apparatus of
It is within the scope of the invention that any of the above aspects can be duplicated within the same humidifying system 100 to provide multiple points of entry to introduce humidifying agent to the respiratory circuit 120. This is especially true with the aspect of
While aspects of the present invention have been described in a discrete manner to facilitate understanding, it is within the scope of the invention that the aspects may be used in conjunction with each other. For example, the humidifying portions 200, 300, 400 illustrated in
Furthermore, it is within the scope of the invention that a humidification system 100 may include multiple humidifying portions 200, 300, 400 of the various types disclosed above. Additionally, the methods disclosed above may all be used within the same humidification system 100. For example, in the aspects of
The invention has been described herein with reference to various specific and preferred materials, embodiments and techniques. It should be understood that many modifications and variations to such materials, embodiments and techniques will be apparent to those skilled in the art within the spirit and scope of the invention. Therefore, the invention should not be limited by the above description, and to ascertain the full scope of the invention, the following embodiments should be referenced.
All references cited herein are hereby incorporated by reference in their entirety.
This application is a Continuation of U.S. patent application Ser. No. 12/952,658, filed Nov. 23, 2010. The disclosure of the prior application is hereby incorporated in its entirety by reference.
Number | Name | Date | Kind |
---|---|---|---|
4159803 | Cameto et al. | Jul 1979 | A |
4722334 | Blackmer et al. | Feb 1988 | A |
4747403 | Gluck | May 1988 | A |
4829998 | Jackson | May 1989 | A |
5148801 | Douwens et al. | Sep 1992 | A |
5445143 | Sims | Aug 1995 | A |
5518179 | Humberstone et al. | May 1996 | A |
5890490 | Aylsworth et al. | Apr 1999 | A |
6078730 | Huddart et al. | Jun 2000 | A |
6095505 | Miller | Aug 2000 | A |
6102037 | Koch | Aug 2000 | A |
6859617 | Goodsel et al. | Feb 2005 | B2 |
6918389 | Seakins et al. | Jul 2005 | B2 |
7073500 | Kates | Jul 2006 | B2 |
7146979 | Seakins et al. | Dec 2006 | B2 |
7267121 | Ivri | Sep 2007 | B2 |
7694675 | Koch et al. | Apr 2010 | B2 |
20010050080 | Seakins | Dec 2001 | A1 |
20050139221 | Duncan | Jun 2005 | A1 |
20070051368 | Seakins et al. | Mar 2007 | A1 |
20070277825 | Bordewick et al. | Dec 2007 | A1 |
20080302362 | Kwok | Dec 2008 | A1 |
20080308100 | Pujol | Dec 2008 | A1 |
20090224064 | Brodbeck et al. | Sep 2009 | A1 |
20090241948 | Clancy et al. | Oct 2009 | A1 |
20090267242 | Nichols | Oct 2009 | A1 |
20100242956 | Yamada et al. | Sep 2010 | A1 |
20120017904 | Ratto et al. | Jan 2012 | A1 |
Number | Date | Country |
---|---|---|
43 12 793 | Oct 1994 | DE |
WO 2009022004 | Feb 2009 | WO |
WO 2009146484 | Dec 2009 | WO |
WO 2012031315 | Mar 2012 | WO |
Entry |
---|
European Office Action for Application No. 11842735.0, dated Jun. 8, 2018, 6 pages. |
Supplementary European Search Report and Written Opinion issued in European Patent Application No. 11842735.0 dated Apr. 26, 2016. |
Number | Date | Country | |
---|---|---|---|
20160151599 A1 | Jun 2016 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 12952658 | Nov 2010 | US |
Child | 15018163 | US |