Nebulizers are well known. One configuration of a percussive ventilation breathing head is described in U.S. Pat. No. 6,595,203 to Bird, the contents of which is incorporated herein by reference thereto.
It is an object of the present invention to provide an improved percussive ventilation breathing head.
It is another object of the present invention to provide the breathing head with a unitary entrainment valve either as a flapper valve, a one-way over-pressure valve, a hydrophobic filter, or overpressure valve.
It is a further object of the present invention to provide an improved percussive ventilation breathing head with a transparent viewport channel alongside said elongated breathing head body such that the patient or caregiver can view the absence or presence of excess fluid in the flow passages in the breathing head body (especially mucus which may accumulate in the breathing head body).
It is an additional object of the present invention to provide an improved percussive ventilation breathing head which has an operational configuration mode and a disassembled cleaning mode, such that when disassembled, the percussive ventilation breathing head can be easily cleaned and reassembled for future use.
It is another object of the present invention to provide an improved percussive ventilation breathing head with a unique sealable attachment between the nebulizer body and an overmold lid on a depending body defining a plenum, such that (a) during assembly, the seal is confirmed by audible and/or tactile responses and (b) the turn-and-click, one-way attachment is nearly foolproof, and (c) during non-use, the unique sealable attachment permits the nebulizer body to be rotated and positioned 90 degrees from the depending body centerline such that the nebulizer body is positioned below the elongated percussive ventilation breathing head and the centerline through the nebulizer body is parallel to the centerline through the elongated percussive ventilation breathing head.
It is a further object of the present invention to provide an improved percussive ventilation breathing head with first and second complementary connective surfaces, one connective surface on the conjoined terminal ends of the pulsatile gas/pressurized gas/pressure sensing lines and a second connective surface formed in the control housing such that said first and second connective surfaces only interface in a single positional manner. As a result, the interconnection is a one-way connection between (a) a control housing for the control system, which control system supplies a flow of pulsatile gas and a flow of pressurized gas to the breathing head and which control system monitors pressure in the breathing head via a pressure sensor line, and (b) the percussive ventilation breathing head system.
The percussive ventilation breathing head is adapted to be supplied with a flow of pulsatile gas fed to an elongated breathing head body at a proximal end thereof. The breathing head body defines an interior passageway therein. A reciprocating injector shuttle is movably mounted in the breathing head passageway. The shuttle moves distally due to the pulsatile gas, assisted by a diaphragm and a venturi-like jet nozzle which nozzle pulls nebulized aerosol from a depending plenum and a nebulizer attached below the depending plenum. A depending body defines the plenum between the breathing head flow passages and the nebulizer. The generally cylindrical nebulizer is attached below the depending body. The shuttle is biased in a proximal direction within the interior passageway and moves proximally due to the bias. The shuttle defines an internal flow passage from a proximal shuttle input port to a distal shuttle output port at the distalmost mouth of the percussive ventilation breathing head body.
A unitary entrainment valve on the breathing head body has an entrainment valve body defining an entrainment valve chamber in fluid communication with the proximal shuttle input port. In one embodiment, the entrainment valve includes a valve flapper biased closed and separating an ambient environment from the entrainment valve chamber. When the pressure in the internal shuttle flow passage falls below a predetermined value (set by the flapper bias), the entrainment valve opens to the ambient and ambient air is introduced and mixed with the aerosol in the proximal shuttle input port area. An over-pressure valve on the entrainment valve body adapted to release aerosol to the ambient at a predetermined pressure set by the valve. In another embodiment, a hydrophobic filter mounted in the entrainment valve body separating the ambient from the entrainment valve chamber and permitting substantially one-way ambient air flow to the entrainment valve chamber.
An interface coupler is also disclosed which is adapted to be coupled to a ventilator line between a conventional ventilator and a patient for continuing patient treatment. The interface coupler includes an interface coupler body and a coupler through channel defined between a coupler input port and a coupler output port. These interface input and output ports are to be coupled in the ventilator line. The interface coupler body has a pulsatile flow port coupler in fluid communication with the coupler channel via a one-way flow valve mounted in the pulsatile flow port coupler. Also, a supplemental air valve may be included. The supplemental air valve body is open to the coupler channel. The supplemental air valve has a variable valve control stem between a supplemental air vent open to the ambient and the coupler channel.
The percussive ventilation breathing head may also include an elongated transparent viewport channel alongside the outside of the elongated breathing head body. The view channel extends from a pressure sensor portal in the breathing head body to the proximal end of the breathing head body. The pressure sensor portal is defined in the breathing head body near the distal mouth of the breathing head. In this manner, the sensor portal can be used to sense pressure near the patient's airway. The elongated transparent viewport channel terminates in a pressure sensor fitting at the proximal end of the breathing head body. A pressure sending tube is attached to this fitting such that pressure can be sensed by a control monitor in a control housing which controller also supplies pulsatile gas to the breathing head and supplies pressurized gas to the head. The pressurized gas is fed to the nebulizer.
The elongated breathing head body also includes an end cap having, on a proximal cap region, an aerosol tube fitting adapted to receive the pulsatile gas flow thereat. The end cap has, on a distal cap region, the diaphragm mounted thereon. The diaphragm forms an expandable chamber between the diaphragm and the distal cap region. Pulsatile gas flow from the aerosol tube fitting expands the diaphragm's expandable chamber. The venturi-like jet nozzle is mounted on the diaphragm at a distal diaphragm region. The venturi-like jet nozzle is in fluid communication with the expandable chamber and the proximal shuttle input port, thereby permitting pulsatile gas flow to the proximal shuttle input port. The shuttle moves distally due to the diaphragm movement and the pulsatile gas ejected from the venturi-like jet nozzle into the proximal shuttle input port. The shuttle is biased in a proximal direction within the breathing head passageway by a biasing means and moves proximally due to the biasing means.
The percussive ventilation breathing head has (a) an operational configuration wherein upon application of the pulsatile gas and the nebulized gas flow from the depending plenum, the shuttle is adapted to move distally into the proximal shuttle passageway and then move proximally due to a biasing spring or other biasing mechanism, and (b) a disassembled cleaning mode wherein the end cap is removed from the proximal end of the elongated breathing head body and the shuttle is withdrawn from the breathing head body interior passageway, such that the end cap, elongated breathing head body, and shuttle is adapted to be cleaned. In most cases, the spring is removed. To facilitate cleaning, the unitary entrainment valve may also removably attached the breathing head body.
A generally cylindrical nebulizer body is threadably removably attached to an overmold lid at the bottom of the depending body. The overmold lid forms a lower interior lid chamber in fluid communication with the nebulizer body and forms a vertical lid chamber and a horizontal lid chamber both in fluid communication with the lower interior lid chamber and the nebulizer body. The overmold lid has a horizontal threaded lid element about a portion of the horizontal lid chamber. The depending body has a horizontal depending body threaded stem formed at a lower end region thereof with a threaded stem complementary to the horizontal threaded lid element. The horizontal depending body threaded stem sealingly engaging the horizontal threaded lid element.
Tabs act as male nebulizer threads and the overmold lid in the lower interior lid chamber forms horizontal overmold lid threads complementary to the male nebulizer threads. The horizontal overmold lid threads sealingly engage the male nebulizer threads. The overmold lid threads and the male nebulizer threads include one or more locking mode elements. For example, these locking mode elements include (I) an audible click lock indicator formed by a pair of complementary detents formed on the horizontal overmold lid threads and the male nebulizer threads; and (ii) a tactile click lock indicator formed by a pair of complementary detents formed on the horizontal overmold lid threads and the male nebulizer threads.
To connect the percussive ventilation breathing head to a control system (the control system also supplying pulsatile gas and pressurized gas to the breathing head), the pressure supply end of the gas pressure tube and the pulsatile supply end of the pulsatile gas tube terminates in a housing connector having a first connective surface. The terminating tube housing fits in a complementary second connective surface formed in the control housing such that the first and second connective surfaces only interface in a single positional manner. In one embodiment, the first connective surface is D-shaped and the complementary second connective surface in the control housing is an inverse D-shape.
Further objects and advantages of the present invention can be found in the detailed description of the embodiments when taken in conjunction with the accompanying drawings.
The percussive ventilation breathing head administers intermittent percussive ventilation to a patient's airway. During an inhalation phase, the patient pulls nebulized aerosol gas into his or her lungs through the percussive ventilation breathing head. During pulsatile gas flow, additional aerosol is provided to the patient during inhalation. During exhalation, pressure sensitive systems in the percussive ventilation breathing head permit exhalation through an exhalation tube in the breathing head.
In
Gas pulses are fed into proximal chamber 38 from pulsatile gas tube 24. The pulsatile gas tube 24 is connected to aerosol fitting 23 at the proximal side of the breathing head 10. Plenum chamber 36 pneumatically and hydraulically connects (that is, fluidly connects) the interior chamber of nebulizer 20 with the depending body member's plenum 36 and ultimately proximal chamber 38 in breathing head 10. As shown in
Injector or shuttle body 44 defines an interior elongated aerosol flow chamber 40 having variable radial dimensions from a generally narrow proximal region 29 near proximal chamber 38 leading distally towards the distal injector/shuttle region 28 generally near O-ring 46. The proximal flow end region 29 near the venturi-like jet is smaller than the flow region near distal region 28. Hence, distal movement of shuttle 44 injects aerosol into the patient's airway.
Exhalation port 50 is defined on the side of the breathing head body 10. Mouthpiece 18 defines a distalmost aerosol flow chamber 42. A gas sensor pressure port 54 is also defined at a distal location beyond exhalation port 50 in the breathing head body 10.
A unitary entrainment valve 52 is disposed at a generally proximal location on the breathing head body 10 or carried by or upon body 10. Entrainment valve 52 has a valve chamber 63 and is in fluid or pneumatic connection with proximal chamber 38 at the output of the venturi-like jet. Since the aerosol gas flows through the percussive ventilation breathing head are relatively heavily dosed with nebulized particles, reference herein to “fluid connection/communication” or similar words refers to gas with entrained nebulized particles.
Diaphragm 34 has, at its proximalmost portion, a circumferential O-ring type seal ring 118. O-ring seal 118 is seated between a ledge in the proximal region of the breathing head body and ring seal surface 78A in
In the disassembled state shown in
In a second construction, with attention given to
In a third construct, the venturi-like nozzle is fixedly mounted to the proximal end of shuttle 44 and there is a seal between the proximal end of stem 83 and the distal end of diaphragm 34. In this third construct during disassembly, end cap 32 is unscrewed, O-ring seal 118 is opened, the seal between the proximal end of stem 83 and the distal end of diaphragm 34 is opened, and then the proximal end of the shuttle 44 includes the entirety of the venturi-like nozzle, including stem 83. The venturi-like nozzle and stem 83 is fixedly mounted to the proximal end of the shuttle 44. In the third alternative embodiment, the proximal end of stem 83 is removably seated against a distal seal at an output port of diaphragm 34.
Operationally, the percussive ventilation breathing head administers intermittent percussive ventilation to a patient's airway. In general, the breathing head includes a nebulizer depending from the generally cylindrical headpiece. The breathing head is supplied with a constant pressurized gas (line 22,
The aerosol generally passes around and through the reciprocating injector body or shuttle 44 movably mounted in the breathing head passageway. The injector body or shuttle 44 includes outboard radial ribs 33 (see
To continue with the inspiratory phase with cyclic percussion, pulses of gas are supplied to the percussive ventilation breathing head through a separate pulsatile supply line 24 at a proximal end 16 of the breathing head and these pulses of gas overwhelm the venturi orifice at the proximal end of the breathing head. These pulsatile gases, during a peak gaseous flow cycle, inflate a diaphragm space 27 in the proximal portion of the breathing head to overcome the reactive force in the diaphragm and thereby cause movement of the injector body or shuttle 44 to move in a distal direction 14 toward the mouthpiece 18 causing the distalmost portion of the injector body or shuttle 44 to form a seal with an O-ring 46 against a valve seat 48 in the distal cavity region of the breathing head. At this maximal distal end, the O-ring seals 46 off injector body/shuttle 44 against a valve seat 48 and this seal closes off an exhalation port 50 in the breathing head body thereby delivering a pulse of aerosol laden gas into the patient's lungs. As a result, the pulsatile gases are supplied through the diaphragm-defined space 27 to a venturi input orifice and through the venturi-like passageway 38 and into the patient's airway via the mouth 18 of the breathing head 10.
During the supply of these pulsatile gases, the shuttle or injector body repeatedly reciprocates back and forth between closed and open positions with the valve seat at the proximal end of the breathing head based essentially on the pulsed gas cycles. A spring 45 (
Although the gases are released through the exhalation port with each opening of the exhalation port, there is only a partial release of the gas from each cyclic pulse until a maximum inflated pressure achieved given the patient's capacity. The maximum inflated pressure is determined by the patient's breathing cycle and lung capacity. This can be measured by pressure sensor port 54, sensor line 26 (
A diaphragm 34 is mounted at a proximal position in the breathing head 10 and is also connected to an end cap 32 at the proximal end 16 of the injector/shuttle 44. The injector/shuttle 44 is moved to its distalmost position in the breathing head body 10, by the expanse 27 of diaphragm 34 at the proximal end 16 of the breathing head and by the pulsatile gas pressure at port end 29 of shuttle 44. The shuttle movement reduces spaces 40, 42 filled with aerosol. Thereafter during lower pressure gas cycles, and the diaphragm 34 biases, collapses or pulls back the injector/shuttle away from its distalmost position/valve sealed position and towards the valve open position of
As soon as the high-pressure pulse cycle of gas is terminated from the pulsating gas supply line (at the low pressure cycle), the diaphragm 34 with its retracting memory returns the injector or shuttle 44 to its proximalmost position to again open the expiratory port 50 to provide partial release of expiratory gases. Therefore, there is a rapid opening and closing of the expiratory port 50 in accordance with the frequency of the pulsatile gases at certain cyclical rates.
When the patient desires to exhale, the patient exhales against the incoming pulsatile gases and creates a pressure against the proximal diaphragm 34 to overwhelm the forces applied to the diaphragm 34 and move the injector body or shuttle away from the distal valve seat 48 thereby opening the valve at the proximal location (
During the inhalation phase, at any time that the demand of the patient exceeds the outflow from the nebulizer, ambient air is introduced into flow chambers 40, 42 for mixing with the nebulized aerosol from plenum 36 through a specially designed valve 52 serving as an ambient entrainment gate. This entrainment of ambient air with the aerosol greatly enhances uninterrupted therapeutic aerosol delivery during the inspiratory phase at or near the metered start of the percussive injection of pulsatile gases into the airway the patient. When the physiological airway pressure increases to or beyond the selected fluid clutching pressure (which may be characterized as a venturi stalling pressure) within the injector body or shuttle, the ambient entrainment gate closes 52 and prevents ambient aerosol flushing from the plenum chamber 36 between the nebulizer 20 and the entrainment port 38 of the venturi-like passageway at proximal end 29 of the injector/shuttle 44. This maintains a potential directional flow of aerosol upward in and around the injector body or shuttle 44 to an ambient through the exhalation port 50 at all times.
The components of the present invention include breathing head assembly 10, having a distal end 14 and a proximal end 16 (which is farther away from patient mouthpiece assembly 18), a venturi-like chamber 38, and a reciprocating injector body or shuttle 44. The reciprocating injector body or shuttle 44 provides step-wise pulsatile aerosol to the patient. The breathing head assembly 10 includes a hollow body cavity 11 within which the shuttle 44 opens and closes the aerosol flow by coacting against a step valve seat 48 in flow passage 42. The breathing head further includes a pressure sensor port 54 which is an input to a longitudinal view channel 12 leading to a tube 26 which monitors pressure in the flow passage 40, 42. Port 54 is disposed in an upper region of view channel 12. At the proximal end 16, the flow passage 40 has a diaphragm 34 with a retracting memory which, in cooperation with the pulsatile gas flow fed into the flow passage 40 generates or assists the pulsatile and shuttle action of the shuttle 44 in the hollow body breathing head. An entrainment port cap 52 is used to admit ambient air into flow passage 40. The ambient entrainment gate flapper valve 64 is shown in
The resulting breathing head can be made sterile with its biocompatible gas pathway and airway. Further, it is easier to clean open the hollow body with the removable rear cap 32 and withdraw the spring 45 and the shuttle 44. Spring 45 is disposed in percussive ventilation breathing head space 75. In
Spring 45 biases the injector body or shuttle 44 in a proximal position away from valve seat 48 (see
Supplemental mouthpiece 54 has a proximal end 57 which fits within the mouthpiece 18 defined at distal end 14 of breathing head 10. The supplemental mouthpiece 54 is inserted as shown by arrow 59 into the mouthpiece 18 of breathing head 10 in
A single unitary entrainment valve is defined one or more apertures 58A, 58B, open to the ambient environment. These apertures are normally closed by a flapper valve member 64 (member 64 shown in
The flapper valve member 64 opens when the interior or internal pressure is lower than the ambient pressure during the patient's inspiration cycle. The unitary entrainment valve 62 also includes another aperture (not numbered) into which is mounted one-way over-pressure pop open valve 60. This third aperture is completely filled and blocked by the one-way over-pressure pop open valve 60.
In one embodiment, the over-pressure pop open valve 60 all is configured as an umbrella valve. The umbrella valve 60 opens when the interior or internal pressure exceeds the biased closing force of the umbrella flap 60A surrounding the umbrella valve stem. The umbrella valve 60 has formed therein one or more small apertures. One aperture 60B in shown in
The over-pressure pop open valve 60 is typically opened when the interior pressure exceeds about 30-40 cm water pressure. The pop open valve 60 is pressure loaded or biased closed such that the umbrella ring flap 60A is biased to a closed position until the interior pressure exceeds the pressure release point for the umbrella valve 60.
Unitary entrainment valve 37 has side clip-over legs 41 which coact and clip-over interior lip 42. Lip 42 protrudes slightly outboard and the inboard leg element 41A of leg 41 protrudes over and then under lip 42. Clip 43 is pulled upward as shown by arrow 47 thereby permitting the release of the opposing, left and right-side leg elements 41A over opposing left and right-side lips 42. At distal end 49 of unitary entrainment valve 37, another latch and latch-lock channel is formed, thereby permitting the complete removal of unitary entrainment valve 37 from the percussive ventilation breathing head 10. The same latch and latch-lock channel closure system is used for unitary valve 52. Therefore, replacement of the valve is easily permitted as well as removal of the valve for cleaning the breathing head.
It is known the hydrophobic filters can permit one-way gas flow. See Millapore http://www.emdmillipore.com/US/en/life-science-research/chromatography-sample-preparation/membrane-learning-center/Flow-Rate/ZMSb.qB.th0AAAFMBEh88eJv,nav.
End cap passageway 72A permits the introduction of pulsatile pressurized air into venturi-like chamber 38 shown in
The rear cap 32 has a screw surface 79 with stop limiters 76A, 76B, marked to match with stop element 77 (see
The percussive ventilation breathing head and end cap include one or more locking mode elements. One locking mode element includes a mechanical stop sub-system formed by cooperating stop elements on said end cap and said percussive ventilation breathing head. See
A third locking mode element is an audible click lock indicator formed by a pair of complementary detents formed on said end cap and said percussive ventilation breathing head. The audible click lock indicator is similar to the audible and tactile response discussed below in connection with
In the same manner, rear cap 70 may define a small tab in the thread system which passes over a small protruding detent on the percussive ventilation breathing head body 10, generating both an audible click-to-lock indicator and a tactile click-to-lock indicator. The protruding detent and the recessive or channel detent can be formed on either the body 10 of the end cap 70. The tactile click lock indicator is described above as being formed by a pair of complementary detents formed on the end cap and the percussive ventilation breathing head.
The breathing head also includes a patient measuring port with visibility window passage 12.
During the breathing cycle of the patient, sometimes aerosol droplets accumulate in the interior head passageway 42 and injector/shuttle passageway 40 because of (a) condensation of the nebulized droplets out of the nebulized aerosol and (b) the two-way patient breathing cycle through the passageways 40, 42. Visibility window 12 permits the patient or user to determine if there is an unacceptable accumulation of mucus or excessive liquid accumulation within the interior passages 40, 42 of the breathing head 10. Further, if there is a drop or a loss of pressure on pressure sensing line 26, the patient or healthcare worker can view the window passage 12 to determine the status of the pressure sensing line and reason for the drop in pressure. Therefore, view passage 12 provides a visual feedback to the patient and care giver.
View passage 12 can be cleaned by inserting a medical grade 3 mm pipe cleaner into the channel once the pressure line 26 (
The invention also includes a new overmolded seal for the nebulizer bowl 20 which permits the generally cylindrical nebulizer body 20 to rotate 90 degrees during non-use as shown in
The fluid or aerosol flow through the overmold lid 80 includes a vertical flow through lower lid chamber 122 (when nebulizer 20 is vertically oriented as shown at centerline 19A-19B in
The new overmold nebulizer bowl seal eliminates the common O-ring that was typically utilized in connection with obtaining a hydraulic and pneumatic seal between the nebulizer unit and the depending body defining plenum 36. The current nebulizer lid overmold 80 has interlocking male and female screw thread threads that involve a click turn. The click turn seal/lock provides both tactile confirmation to the patient or care giver that the nebulizer body 20 is securely mounted on the overmold lid 80 and an audible indicator of the same.
Periodically along the peripheral wall surface 91 of the overmold lid wall 82, are a number of vertical detent channels 97A (hollowed-out spaces). Detent channels 97A are formed on the inboard wall surface 91. The upper region of detent 97A near upper detent wall-limit 97C leads to a partial arcuate channel 97B, formed as a partial circumferential arc in the wall surface 91. There is a angular offset of the partial circumferential arc 97B compared to the generally vertical detent 97A which enhances the fluid seal between the nebulizer peripheral edge ring 19 and the inboard circumferential ring 93B in the overmold lid 80. The angular offset tightens the seal between edge lip 19 and lid ring 93B.
The partial channel-like arc 97B is structurally defined by and also physically defined by a small inboard extending demarcation ridge 99 between partial arcuate peripheral channel 97B and the generally vertical detent 97A (vertical compared to the lid wall 82 in
Gas supply, pressure controller and control monitor 30 is shown in
Interface coupler 100 has an input port 101 and an output port 103 that is connected to conventional ventilator lines or tubes. The input to these ventilator lines or tubes (not shown) is attached to an output of a ventilator machine (not shown). Output port 103 is connected to a typical output tube (not shown) leading to the patient being treated. The interface coupler body 100A has a coupler through channel 100B defined between coupler input port 101 and coupler output port 103. The coupler input and output ports are adapted to be coupled into the ventilator line. Interface coupler 100 has a pulsatile flow port coupler 105 shaped such that the distal mouthpiece assembly 18 of the breathing head 10 (
In
The claims appended hereto are mean to cover modifications and changes within the scope and spirit of the present invention.
This is a regular patent application based upon and claiming the priority of provisional patent application Ser. No. 62/754,340, filed Nov. 1, 2018, the contents of which is incorporated herein by reference thereto. The percussive ventilation breathing head administers intermittent percussive ventilation to a patient's airway. In general, the breathing head includes a nebulizer depending from the generally cylindrical headpiece via a depending body. The breathing head is supplied with a constant pressurized gas which nebulizes liquid contained in the nebulizer unit. Aerosol from the nebulizer passes through a plenum in the depending body to a proximally disposed venturi-like passageway in the breathing head and into a mouthpiece at a distal end of the breathing head and further into the airway of the patient to begin inflation of the patient's lungs during commencement of the inspiratory phase. The inventive breathing head includes several improvements, each unique in their use, construction and implementation, including a unitary entrainment valve (such as a flapper valve, a one-way over-pressure valve, a hydrophobic filter, or overpressure valve); a transparent viewport channel alongside said elongated breathing head body; a breathing head having an operational configuration mode and a disassembled cleaning mode; a unique sealable attachment between the nebulizer body and an overmold lid on a depending body defining a plenum; and first and second complementary connective surfaces on the conjoined terminal ends of the pulsatile gas/pressurized gas/pressure sensing lines and formed in the control housing such that said first and second connective surfaces only interface in a single positional manner.
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Number | Date | Country | |
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20200139076 A1 | May 2020 | US |
Number | Date | Country | |
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62754340 | Nov 2018 | US |