The invention relates to the field of generally, to devices for administering therapeutic substances in predefined dosages and concentrations, and, more specifically, to devices for applying a high velocity therapeutic liquid-gas stream for administering such substances to body tissue in predefined dosages and concentrations.
Devices for dermal abrasion of exposed in vivo tissue are known in the art. One such device is described in International Publication Number WO 2005/065032, “A High Velocity Liquid-Gas Mist Tissue Abrasion Device”, included herein by reference. This document also provides a general overview of the prior art of dermal abrasion and dermal abrasion devices.
Disclosed in the above referenced document is a device for dermal abrasion employing a high-velocity liquid-gas streaming mist. The disclosed device is particularly successful in overcoming the difficulty of stagnant boundary layers. When a fluid stream is employed to irrigate a tissue surface, a boundary layer is formed which is characterized by having a fluid velocity which decreases sharply adjacent to the flow surface, being virtually zero at the tissue surface. As a result, particles which are smaller than the thickness of the boundary layer of the fluid stream are often difficult or impossible to remove. The smallest particles in the boundary layer exhibit a drag resistance of a magnitude sufficient for these particles to remain attached to the surface and to resist being swept away by the fluid stream. The device disclosed in the above referenced document overcomes this difficulty, its liquid-gas streaming mist producing a boundary layer of minimal to negligible thickness.
However, neither the device disclosed in the above-mentioned document nor other prior art devices discussed therein provides for easy treatment of abraded tissue with therapeutic substances in predefined dosages and/or concentrations. Additionally, the above-mentioned device and other prior art devices require relatively large liquid and gas sources, suitable for use with a plurality of patients. These sources are positioned distant from the device necessitating the use of connecting tubes which inter alia impede use, especially one-hand use, of the devices.
The liquid-gas stream consists of one or more therapeutic liquids provided at a high velocity, generally within the range of sub-sonic to super-sonic. To achieve these high velocities, gas is discharged from a device containing a stream jet nozzle arrangement, the arrangement containing one or more converging-diverging gas nozzles configured to accelerate the flow of gas so as to discharge it at an elevated velocity. A low rate of flow of therapeutic liquid is discharged into the elevated velocity flow of gas, thereby accelerating the discharged therapeutic liquid as a therapeutic stream of accelerated droplets. The volumetric rate of flow of therapeutic liquid from the device is relatively low, thereby essentially preventing the formation of a virtually stagnant liquid boundary layer on the surface of the tissue to which the therapeutic substances is being administered.
The housing of the device is in fluid flow communication with one or more containers containing one or more therapeutic substances. The therapeutic substances may be provided in bottles, vials, ampoules, or any other suitable containers. The containers are removably affixed to and positioned on the housing via a therapeutic substance supply assembly as described below and shown in
When the therapeutic liquid administered by the present invention is saline solution, the invention can be employed to clean a tissue surface. Subsequently, additional therapeutic substances, such as medications, nutrients, moisturizers or colorants may be administered. These therapeutic substances may be in liquid, emulsion or soluble powder form. This allows for more efficient dosing of the therapeutic substances, since, as will be appreciated by persons skilled in the art, the substances removed by cleaning would, if left in place, likely impede application and/or absorption of the desired therapeutic substances to the tissue undergoing therapeutic treatment.
The therapeutic substance supply assembly attached to the substantially tubular shaped housing of the present invention may include control valves operative for introducing into the device of the present invention a mixed flow of saline solution and other therapeutic substances. The valves can be used to obtain a desired concentration therein which can further be controlled, typically but without limiting the invention, by the operator during operation, to produce the mixed flow at specified times and for specified intervals. The device of the present invention would then accordingly produce a mixed therapeutic stream as desired and needed. Thus, as described above, a tissue surface could first be cleaned by saline solution and then dosed therapeutically with a medication solution when it is ready to optimally receive the dosage.
In an alternative embodiment of the present invention, instead of one mixed flow as mentioned hereinabove, the device of the present invention may be controlled and used to produce a number of therapeutic liquid flows for discharge into the elevated velocity gas flow. The therapeutic substances may also be turned on and off at specified times and for specified intervals. This arrangement also produces a mixed therapeutic stream as desired and needed. For example, the present invention can be used to treat a human scalp even where hair is present. First, the device provides an accelerated saline stream to clean the scalp of extraneous material, excess oils, and dead sloughed off epidermal tissue such as is known to produce dandruff. Then a moisturizing, nutrient, anti-dandruff, or anti-hair loss therapeutic substance is included in the accelerated stream to apply the desired therapeutic treatment to the scalp.
It should further be noted that the present invention is capable of applying the therapeutic substance to the desired tissue both topically and subcutaneously. Investigations employing prototype versions of the present invention have shown that the accelerated therapeutic stream produced thereby will, for suitable droplet flow velocities and time of exposure of the tissue to the droplet flow, penetrate the tissue surface. This capacity of non-invasive subcutaneous treatment and dosage is a further advantage of the present invention.
It is contemplated that the present invention can also be used in lavage of hollow organs of the body.
The discussion in conjunction with
With reference to
In
Referring now to
Pressurized gas supplied from a pressurized gas source (not shown) enters device 100 through gas inlet port 108 of
Liquid, including therapeutic substances, from one or more pressurized therapeutic liquid sources (not shown) enters device 100 through liquid inlet port 110 and passes, as indicated by arrow 132, through liquid communication tube 118. In turn, at distal end 106, therapeutic liquid is discharged through an opening 128 in the distal end of liquid discharge nozzle 116 into discharging flow 126 of gas, the therapeutic liquid flow being indicated by arrow 130.
It will be appreciated by persons skilled in the art that, as the pressurized discharging gas emerges 126 from gas discharge nozzle 114 into the atmosphere, it undergoes a rapid drop in pressure to atmospheric pressure. The sudden pressure drop results in a substantial acceleration of the velocity of the discharging gas flow that approximates or even exceeds the velocity of sound and results in the production of a shock wave. The effect of the shock wave is to atomize the therapeutic liquid discharging from liquid discharge nozzle 116 into the flow of gas as a stream of therapeutic liquid droplets 130, such that there is obtained a relatively narrow jet of therapeutic liquid droplets in a high velocity gas flow 126.
Further, by way of example, the proportion of liquid flow to gas flow is extremely low due to the relatively high gas pressure of about 100 pounds per square inch (“psi”) and low liquid pressure of about 2 psi, as well as the relatively large internal diameter of gas discharge nozzle 114, for example 0.5 mm, compared to a small internal diameter, for example 0.09 mm, of liquid discharge nozzle 116. Consequently, little liquid tends to accumulate at the site to be cleaned or treated with one or more therapeutic substances. Furthermore, the relatively high gas flow has the effect of dispersing any accumulated liquid. When using a jet utilizing only liquid for cleansing, the liquid tends to accumulate on the tissue surface resulting in formation of a virtually stagnant liquid boundary layer close to and in contact with the surface, thereby reducing the effectiveness of cleansing. The very thin to negligible layer of liquid produced on the tissue surface by the above described nozzle arrangement allows more efficient dosage of additional therapeutic substances to the tissue surface, including the possibility of subcutaneous application of the therapeutic substances.
Referring now to
Referring now to
Referring now to
The foregoing examples of the related art and limitations related therewith are intended to be illustrative and not exclusive. Other limitations of the related art will become apparent to those of skill in the art upon a reading of the specification and a study of the figures.
In the discussion herein below, the term “distal” refers to the position on the devices discussed herein furthest from the user that is the portion closest to the nozzle arrangement of the devices. The term “proximal” refers to the position on the devices closest to the user that is the portion furthest from the nozzle arrangement of the devices.
The terms “cleanse”, “cleaning” and variants thereof in the discussion herein below, refers to the removal of solid contaminants, such as fibers, dust, sand particles, and the like, as well as the removal of organic matter, such as pus, fats, and the like from the surface of tissue being cleaned and/or being treated with therapeutic substances. The term “cleanse” includes lavage of hollow organs of the body.
The term “tissue” as used herein can refer to either human or animal tissue.
The following embodiments and aspects thereof are described and illustrated in conjunction with systems, tools and methods which are meant to be exemplary and illustrative, not limiting in scope.
There is provided, in accordance with an embodiment, a device for administering a liquid therapeutic substance to tissue, including a housing having a liquid inlet port; a gas inlet port connected to a pressurized gas source; at least one therapeutic substance supply assembly mounted onto said housing, each therapeutic substance supply assembly including: at least one syringe dispenser connector configured for receiving a syringe dispenser containing a predefined quantity or concentration of the liquid therapeutic substance, each syringe dispenser in fluid flow communication with one of at least one valve projecting from and external to said assembly, each of the at least one valve is associated with a different syringe dispenser and user operable between an open and a closed position, the at least one valve is adapted for control of a continuous flow of the at least one liquid therapeutic substance during operation of the device, the syringe dispenser includes a container configured to store the liquid therapeutic substance and a piston configured to be pulled into the container as the liquid therapeutic substance is removed from the container under suction so as to flow through said at least one valve; and, at least one liquid conduit in liquid communication the liquid inlet port and said at least one syringe dispenser connector; a stream jet delivery nozzle arrangement in fluid flow communication with the gas inlet port and in fluid flow communication with the conduit, operative to deliver the liquid therapeutic substance in an elevated velocity flow of gas discharged from the delivery nozzle arrangement at a predetermined concentration.
In certain embodiments, the container includes a collapsible bag configured to store the liquid therapeutic substance, the collapsible bag configured to collapse when liquid is removed from the collapsible bag.
In certain embodiments, the further includes at least one therapeutic substance supply assembly mounted onto the housing, each therapeutic substance supply assembly configured for receiving at least one syringe dispense containing a predefined quantity or concentration of liquid therapeutic substance.
In certain embodiments, the liquid therapeutic substance inlet port is in fluid flow communication with the therapeutic substance supply assembly and also in fluid flow communication with the stream jet delivery nozzle arrangement.
In certain embodiments, the stream jet delivery nozzle arrangement includes: at least one gas discharge nozzle arranged to receive a flow of pressurized gas from the gas inlet port and configured to accelerate the flow of gas so as to discharge it at an elevated velocity and, at least one liquid discharge nozzle arranged to receive a flow of liquid therapeutic substance from a therapeutic substance supply assembly and operative to discharge the flow of therapeutic substance into the elevated velocity flow of gas, thereby accelerating the velocity of the discharged liquid therapeutic substance as a stream of accelerated therapeutic droplets and to discharge the stream of accelerated therapeutic droplets towards a tissue mass for treatment by the therapeutic substance.
In addition to the exemplary aspects and embodiments described above, further aspects and embodiments will become apparent by reference to the figures and by study of the following detailed description.
Exemplary embodiments are illustrated in referenced figures. Dimensions of components and features shown in the figures are generally chosen for convenience and clarity of presentation and are not necessarily shown to scale. The figures are listed below.
Disclosed herein is a device for administering therapeutic substances to tissue by directing a liquid-gas stream of droplets containing one or more therapeutic substances, according to certain embodiments.
Referring now to
Nozzle arrangement 220, discharge nozzles 222 and hand piece housing portion 212 are constructed and configured substantially as described herein above and shown in
Two containers 218, such as, but without intending to limit the invention, bottles, vials or ampoules containing predefined dosages and/or concentrations of therapeutic liquid substances that are required in treating a patient, are positioned in container connectors 216. In certain embodiments, these containers 218 may be single-use containers. Container connectors 216 can be removably attachable and can be single-use connectors. Container connectors 216 can be connected by luer locks 214 to liquid conduits 215 that lead to assembly base 210.
In some embodiments, device 200 can include valves, such as stopcock valves 224, positioned between container connectors 216 and luer locks 214. In other embodiments (not shown), stopcock valves 224 can be positioned between luer locks 214 and liquid conduits 215. It should be appreciated by persons skilled in the art that valves other than stopcock valves may also be used.
While luer locks 214 generally are disclosed herein, it should readily be understood that other suitable connection fittings known to persons skilled in the art may also be used. In the claims, this element will generally be noted as “connection fittings” or “connection fitting”. Such designation is intended to include inter alia luer locks 214.
Assembly base 210, luer locks 214, stopcock valves 224, containers 218, container connectors 216, and liquid conduits 215 are typically, but without intending to limit the invention, made of rigid plastic. In certain embodiments, housing portion 212 can be formed of a rigid plastic. The exact plastics to be used for these elements are readily selectable by persons skilled in the art.
In certain embodiments, a side of assembly base 210 is disposed adjacent to device housing portion 212 and is shaped to conform to the adjacent side of housing portion 212. Assembly base 210 can be ultravioletly or ultrasonically bonded to housing portion 212. Alternatively, other methods of attachment known to persons skilled in the art suitable for use with plastics, such as adhesive gluing, can be used.
In certain embodiments, assembly base 210, luer lock 214, liquid conduit 215, stopcock valve 224 and container connector 216 can be constructed as an integral unit with handpiece housing portion 212 by using, for example, injection molding.
Container connectors 216, luer locks 214, liquid conduits 215, stopcock valves 224 and assembly base 210 collectively define, and will be herein referred to as a therapeutic substance supply assembly 290.
In some embodiments, such as the one discussed in conjunction with
In certain embodiments, a therapeutic substance supply assembly 290 is a structure attachable to a housing portion, such as element 212, including container connector 216, configured to receive a container, such as container 218. In certain embodiments, container 218 is in fluid flow communication with liquid discharge nozzles, such as discharge nozzles 222, of nozzle arrangement 220.
It should be understood that the specific embodiment of the therapeutic substance supply assemblies 290 shown in
In certain embodiments, assembly base 210 is constructed and configured to fulfill two functions. First, it is configured to allow mounting of the therapeutic substance supply assembly 290 on housing portion 212. Second, assembly base 210 is formed with a conduit (242 in
In certain embodiments, container connector 216 can be a separate adaptor-like element screwable into, or otherwise removably positionable, in a conduit so that container 218, when positioned in connector 216, is in fluid flow communication with liquid conduits 215 and assembly base 210.
The therapeutic substances in containers 218 are conveyed through container connectors 216 either under gravity or as a result of the therapeutic substances in container 218 being provided under pressure. In certain embodiments, a puncturing element 217, as shown in
Stopcock valves 224 can be operated by the user to control flow of the therapeutic substance from containers 218 into housing portion 212. The operator may, by opening or closing stopcock valves 224, allow the therapeutic materials in one or both of therapeutic substance containers 218 to enter housing portion 212 and exit from nozzle arrangement 220 through liquid discharge nozzle(s) 222 (similar to elements 116 and 154 in, for example,
The liquid therapeutic materials from containers 218 enter housing portion 212 through liquid inlet port 209. Liquid conduits 215 and the conduit formed in assembly base 210 (i.e. assembly base conduit—not shown) are in fluid flow communication with liquid inlet port 209. The liquid therapeutic materials flow from the conduit formed in assembly base 210 (i.e. the assembly base conduit 242 in
A gas inlet port 208 and a liquid inlet port 209 are shown at proximal end 204 of device 200. Gas and liquid are introduced into device 200 through these ports from appropriate gas sources (not shown) and liquid sources (such as containers 218) as described above. The gas may be selected from air, oxygen, nitrogen and carbon dioxide but other non-reactive gases may also be used.
It should readily be understood by persons skilled in the art that the flow of a therapeutic substance from a container 218 positioned in a container connector 216 of a therapeutic substance supply assembly 290 to nozzle arrangement 220 can occur using any suitable fluid flow communication configuration.
According to certain embodiments, a side view schematically illustrated in
A tube 233 equivalent to liquid communication tube 118 (the latter best seen in
In certain embodiments, no transmission tube 230 and no liquid inlet port 209 are required. In to certain embodiments, an adhesive, such as a silicon adhesive, which is used to connect therapeutic substance supply assembly 290 to housing portion 212 may also function as a sealant preventing loss of liquid during its transfer from containers 28 through assembly base 210 into housing portion 212, via aperture 231 and liquid communication tube 233.
Referring now to,
It should readily be evident to one skilled in the art that devices, such as device 200, may also be configured to operate with more than two therapeutic substance container connectors 216 and/or more than two therapeutic substance supply assemblies.
In certain embodiments, device 200 discussed in conjunction with
In certain embodiments, device 200 can be used to apply the therapeutic droplet stream either topically or subcutaneously.
In certain embodiments, device 200 can be constructed to have a multiple nozzle configuration, similar to, for example, the one shown in and discussed hereinabove in conjunction with
Because many therapeutic substances have a reduced shelf life after their original container has been opened, use of throw-away single-use therapeutic solution containers 218 obviates many difficulties readily apparent to persons skilled in the art. Moreover, since containers 218 to be used may be selected from among containers that may contain a wide variety of therapeutic substances each being manufactured at different quantities and/or concentrations, the use of such containers is an advantage. The positioning of therapeutic containers 218 directly on operating devices 200 allows for ease of use of devices 200 by reducing the need for restricting tubing and conduits. Devices 200 therefore are more easily adapted for single hand use by the user.
In certain embodiments, container 218 can be a collapsible bag, which collapses as the liquid therapeutic substance is sucked into device 200 due to a vacuum created in container 218 resulting from removal of the liquid therapeutic substance from container 218. In certain embodiments, container 218 can include a rigid housing for storing the collapsible bag containing the liquid therapeutic substances to prevent the collapsible bag from tearing.
Referring now to
Nozzle arrangement 320, discharge nozzles 322 and hand piece housing portion 312 are constructed and configured substantially as described herein above and shown in
A syringe dispenser 318 includes a container 303 configure to store predefined dosages and/or concentrations of therapeutic liquid substances that are required in treating a patient, are positioned in dispenser connectors 316. Syringe dispensers 318 can be single-use dispensers or multi-use dispensers. Dispenser connectors 3316 can be removably attachable and can be single-use connectors. Dispenser connectors 316 can be connected by luer locks 314 to liquid conduits 315 that lead to assembly base 310.
The therapeutic materials in syringe dispenser 318 enters housing portion 312 and exits from nozzle arrangement 320 through liquid discharge nozzle(s) 322 (similar to elements 116 and 154 in, for example,
The liquid therapeutic materials from syringe dispense 318 enter housing portion 312 of device 300 through liquid inlet port 309. Liquid conduits 315 and the conduit formed in assembly base 310 (i.e. assembly base conduit—not shown) are in fluid flow communication with liquid inlet port 309. The liquid materials flow from the conduit formed in assembly base 310 through a flexible plastic tube 330 to inlet port 309. From there, the liquid therapeutic material is transported either via flexible plastic tube 330 or liquid communication tube 118 (
A gas inlet port 308 and liquid inlet port 309 are shown at the proximal end 304 of device 300. Gas and liquid are introduced into device 300 through these ports from appropriate gas sources (not shown) and liquid sources (such as syringe dispenser 318) as described above. The gas may be selected from air, oxygen, nitrogen and carbon dioxide but other non-reactive gases may also be used.
It should readily be understood by persons skilled in the art that the flow of a therapeutic substance from a syringe dispenser 318 positioned in a dispenser connector 316 of a therapeutic substance supply assembly 390 to nozzle arrangement 320 can occur using any suitable fluid flow communication.
Syringe dispenser 318 includes a piston 317 connected to container 303 enabling piston 317 to ingress and egress into container 303 to reduce the space within container 303. Piston 317 is configured to be pulled into container 303 as the therapeutic liquid substance is removed under suction from container 303. More specifically, as the therapeutic liquid substance flows out of container 303, a vacuum is generated within container 303, which pulls piston 317 into container to reduce the space within container 303 and prevents gas from entering container 303, which may contaminate the remaining therapeutic liquid substances.
In certain embodiments, an empty container 303 of syringe dispenser 318 can be replaced with a full container. For example, piston 317 can be disconnected from syringe dispenser 318 to enable quick replacement of an empty container and a new full container without disconnecting syringe dispenser 318 from dispenser connector 316.
The descriptions of the various embodiments of the present invention have been presented for purposes of illustration, but are not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein was chosen to best explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.
Filing Document | Filing Date | Country | Kind |
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PCT/IL2019/050952 | 8/25/2019 | WO | 00 |
Number | Date | Country | |
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62730011 | Sep 2018 | US |