BENEFICIAL AGENT DISPENSER
A dispensing device for use with a beneficial agent has a dispensing package, a dispenser disposed on an end portion of the dispensing package, and an actuator movably disposed along at least a portion of the package between a pre-dispensing state and a dispensing state. One arrangement also provides a beneficial agent dispenser having a dispensing port, an elongate portion and a plunger that is movably disposed relative to a tubular wall of the elongate portion during a dispensing stroke to partially penetrate a separable barrier and expel the beneficial agent through the dispensing port.
Latest AKTIVPAK, INC. Patents:
- FILING SYSTEM AND METHODS FOR ASEPTIC CARTRIDGE AND DISPENSER ARRANGEMENT
- Hypodermic drug delivery reservoir and apparatus
- Dispenser and therapeutic package suitable for administering a therapeutic substance to a subject, along with method relating to same
- Dispensing device incorporating frangible section, along with dispensing method
- ASEPTIC CARTRIDGE AND DISPENSER ARRANGEMENT
The present disclosure preferably, but without limitation, generally pertains to prefilled single use, single dose dispensing devices. More specifically, the present disclosure pertains to dispensing packages for administration of beneficial agents, namely, medication.
DESCRIPTION OF THE BACKGROUNDSeveral commercial single dose dispensing packages are in a fashion of a syringe where a piston comprising a plunger, comprising a sealing surface, is introduced at a proximal end of a barrel comprising a dispensing port at its distal end; said piston is disposed in a movable fashion along the axis of said plunger and barrel. The plunger seals against the internal wall of the barrel to form a chamber for a dispensable product, and the arrangement is such that the piston and plunger are movable toward said dispensing port of the barrel to deplete the volume of said product chamber thereby forcing the product to dispense through the dispensing port. Such syringe barrels are typically made from clear plastic or glass and the plunger is typically made from chemically stable rubbers.
In drug delivery applications, the most common practice with syringe products is that the syringe is filled at the time of use (typically by a caregiver). In some drug delivery applications, it is desired that the syringe will be prefilled and serve as a primary container for the dispensable product for a defined duration and at specific conditions; in which case, it is required to limit the interactions between the primary package materials and the product that may affect the product composition or properties. It is also desired to limit the dispensable product, or elements of it, from migrating out of the package, or materials migrating to the dispensable product from the package's walls or through the package's wall (i.e. the plunger, barrel, etc.) These product stability requirements present a challenge in some industries including the pharmaceutical industry. Molded plastic syringe barrels suffer from relatively high moisture and oxygen transferability, specifically Polypropylene (PP) and Polyethylene (PE). In recent years, new commercial moldable plastic materials provide higher moisture and gas barriers such as Cyclic Olefin Copolymer (COC) and Cyclo Olefin Polymer (COP), yet their barrier properties are limited compared to glass or high barrier films which are typically used in the pharmaceutical industry as a primary package for elongated shelf life. Glass syringe barrels, on the other hand, present other challenges as a primary container. For one, it is becoming more obvious in recent years that residues of tungsten in the barrel resulting from wear of the tools used for forming the glass present a problem for stability of certain products. In addition, the friction between the rubber plunger and the glass barrel during dispensing is high and is commonly addressed in the industry by coating the inner side of the barrel with lubricants (typically silicone lubricants) which also affect certain products' stability and, in particular, has been shown to cause protein aggregation which affect the potency of some protein based drugs. The lubricants do not completely solve the slip force problem with glass syringes which remains an undesirable property of glass syringes. In some pharmaceutical applications, and particularly for stability and shelf life purposes, it is desired to store a dispensable product as separate substances that are mixed at a time of use to form the dispensable product just prior to dispensing. As one example, certain drug or vaccines are preserved in dry format to extend their shelf life and reduce their thermal sensitivity, and are mixed with a diluent just prior to injection to a patient. Some prefilled syringes have been developed to address these applications and provide a primary container having two storage compartments for two substances (commonly, one is for the dry drug or vaccine, and the other is for the diluent). These syringes are constructed such that the two substances are mixed by a certain manipulation of the syringe prior to the injection step, the last being very similar to the injection procedure with a regular syringe. These syringes are typically made from glass or COC/COP and commercial products are commercially available from Vetter (Ravensburg, Germany).
U.S. Pat. No. 6,817,987 teaches a mixing hypodermic syringe holding a solvent and a soluble component that has a tubular body formed at its front and rear ends with a bypass, a plunger axially slidable in the body, and a stem projecting axially rearward out of the body from the plunger. A cover fits over the front end of the body and is so tight that the front compartment can be pressurized to a super atmospheric pressure without leakage out the front end. A free piston slidable in the body forward of the plunger subdivides the body forward of the plunger into a front compartment at the front body end holding the soluble component and a rear compartment between the plunger and the piston holding the solvent. Stops are provided for arresting the free piston when it is level with the bypass in a position permitting flow through the bypass between the compartments. However, there are several drawbacks with this approach: (a) the barrel is made from glass or molded plastic which presents the problems discussed above, (b) the additional piston complicates the product and adds to its bill of material cost and manufacturing costs, (c) the extra piston limits the ability to mix between the two compartments to form a uniform dispensable product, and (d) it does not provide needle-stick safety and post-use disabling features which are becoming a more regular requirement in the medical field.
SUMMARYThe present disclosure overcomes the disadvantages and limitations of the prior art by providing a low cost, simple and easy to use dispensing device, preferably formed as a package, that allows the user to dispense the contents of the package in a controlled manner through a fluid transport device, also referred to as a dispenser. As used herein, the term “fluid transport device” generally refers to any means for transporting a flowable product having at least one inlet port for introducing the product and at least one outlet port to dispense the product. Examples of fluid transport devices include a spout, a connector, a fitting, a Luer Slip connector/fitting, a Luer Lock connector, a needle, a hypodermic needle, a mini-needle, a set of mini needles, a micro needle, an array of micro needles, a tube or a pipe, a spray head, an oral dropper, a nasal dropper or sprayer, an eye dropper or sprayer, a topical applicator, a jet injector an adaptor to any of the above, an adapter to an absorbent material (such as a sponge, woven or none-woven pads, or a cloth that may be used to apply a substance to a surface such as the skin). The fluid transport device may further comprise a cap, a valve, a septum, a stopper or a tap for sealing the outlet port, which may be used to allow multi-dose dispensing from the package. A one way valve (check valve) may be formed in the fluid transport device, to avoid refill and reuse of the device.
According to the present disclosure there is now a dispensing device substantially resembling the form of a hypodermic syringe, comprising an elongate member (referred to at times as a “barrel”) comprising a tubular wall partially defining at least one compartment of a dispensable product (or “product”). The barrel comprises a proximal end and a distal end; said distal end is associated with a fluid transport device. The product compartment can be manipulated to reduce its volume forcing the product to advance in the barrel. At least one portion of the tubular wall of the barrel comprises a thin collapsible wall, substantially thinner than the wall of a typical hypodermic syringe. The thin wall is pinched in certain areas to form a separable barrier defining a wall of said compartment. The tubular wall may be made from high barrier material. In one arrangement the tubular wall is made from multi-layer plastic material. The high barrier layer can be made from polychlorotrifluoroethylene (PCTFE) commercially branded by Honeywell as Aclar or COC. In one arrangement the inner layer of the tubular wall material is made from an adhesive material such that it can be deformed (pinched) and sealed to itself or to a second component to form a barrier. In one arrangement said adhesive material is a thermal adhesive which bonds the pinched section of the tubular wall under the presence of a threshold temperature. A number of olefin polymers can provide for the thermally adhesive inner layer of the tubular wall including olefin ionomer blend such as the commercial brand EasyPeel™ from Bemis (Oshkosh, Wis.). The tubular wall can be made by various methods known in the art including extrusion, co-extrusion, molding, or rolling of a film material. The inner adhesive layer of the tubular wall can be made by any of the methods known in the art including co-extrusion with other layers of the tubular wall, coating, blown from a thin sleeve inside the tubular wall, etc. The adhesive layer can be applied throughout the inner side of the tubular wall or applied to selective sections on the inner side of the tubular wall. A lubricant component can be blended in the inner layer to improve the slip of a plunger in the barrel. In one arrangement, the tubular wall is produced by a process which includes the following steps: (a) a high barrier film is unwound from a roll, (b) the leading end of said high barrier film is rolled around an extrusion head such that its longitudinal fringes align or slightly overlap, (c) the longitudinal rolled film is fed to a calendar and the extrusion head extrudes an internal cylindrical layer bonded to the high barrier rolled film, forming a tube, (d) the tube is cooled and then cut into sections. In some arrangements, the high barrier film is printed or otherwise marked with visual information. In some arrangements, an external tubular layer is extruded onto the rolled sheet such that the high barrier film is confined between an inner tubular extruded layer and an outer extruded layer. In another arrangement, the tubular wall comprises a high barrier layer made from a rolled film or foil, and an inner layer extruded onto and bonded to the rolled layer, and the bonding is such that at least a section of the rolled layer is peelable from the extruded layer. In another arrangement, the tubular wall is produced by inserting a portion of a high barrier film or foil into the female side of a plastic injection mold such that its longitudinal fringes are aligned or slightly overlapping; molding an inner tubular layer bonded to the tubular high barrier section, in a similar fashion to an in-mold-labeling process, which is well know in the art of injection molding. The molded portion of the tubular section may further include details, such as finger flange and a tip. The rolled high barrier section may be printed or otherwise marked with visual information. Similar process may be implemented with blow molding or blow-fill-seal process where the molded material is blown onto the inner side of a high barrier film or foil rolled portion that is inserted into the mold.
The barrier, or barriers, at the pinched sections along the tubular wall are made such that they burst upon the presence of a threshold pressure in the compartment. In one arrangement, a pinched section of the tubular wall forms a barrier between the product compartment and the fluid transport device at the distal end of the barrel. In one arrangement, a pinched section of the tubular wall forms a barrier between the product compartment and the proximal end of the barrel. In one arrangement, a pinched section of the tubular wall forms a barrier between a first substance compartment and a second substance compartment along the barrel. When the barrier is ruptured, the first substance and the second substance are allowed to mix to form the dispensable product. In some arrangements, more than two compartments are formed along the barrel holding different substances which form the dispensable product when mixed. The threshold pressure needed to rupture the barriers along the barrel can be similar or different. There are various actuators which can be used to accomplish this. In one arrangement, the volume of the compartment, or compartments, is reduced by advancing a plunger in an axial direction along the compartment. In one arrangement, the volume of the compartment, or compartments, is reduced by compressing the tubular wall. In one arrangement, the tubular wall is compressed by a compression panel. In another arrangement, the tubular wall is compressed by a roller. The volume reduction of the compartment causes at least one of: (a) rupturing a barrier between the proximal end of the barrel and the first compartment, (b) rupturing a barrier between a first compartment and a second compartment, (c) rupturing a barrier between a compartment and the fluid transport device, and (d) dispensing the fluid out of the barrel through the fluid transport device. The dispensable product is dispensed by manipulating the device to reduce the compartment volume after the barrier between the compartment and the fluid transport device is ruptured. In some arrangements, a stem is provided to facilitate the axial manipulation which causes the volume reduction of the compartment. Finger flanges may be associated with the proximal end of the barrel. Said finger flanges may be made from molded plastic and attached to the barrel through one of the means known in the art including adhesives, one of the methods of heat welding, or through a mechanical lock. In one arrangement, the proximal end of the tubular wall is flared to provide a substantially radial surface for engagement with the finger flanges. The fluid transport device may have a molded plastic interface to engage with distal end of the barrel. This engagement may be accomplished by one of the methods known in the art including adhesion, heat welding, or mechanical engagement, such as a tight co-annular fit between the tubular wall and a cylindrical interface of the fluid transport device.
In some arrangements, the barrel is further supported by a rigid sheath, substantially extending along the barrel's axis between the proximal and the distal end of the barrel. In one arrangement, the sheath supports the fluid transport device. In one arrangement, the sheath provides the finger flanges. The sheath is engaged with the barrel by one of the methods known in the art including mechanical fit, adhesion, or heat welding. In one arrangement, the device is a hypodermic syringe comprising a needle-stick safety feature. In one arrangement, the needle is biased by a spring toward the proximal end of the barrel and is arrested in its position by a detent feature until the plunger reaches the distal end of the barrel, at which point, the needle is released to retract into the barrel such that its sharp point is protected and cannot be reached by a person at the normal course of use of the device. In another arrangement, the needle assembly clings to the plunger when the last reaches the proximal end of the barrel, such that when the plunger is retracted, the needle is withdrawn into the barrel to a protected position. This action also disables the syringe from subsequent use. Other needle safety features and subsequent use disabling features are applicable to the device of the present disclosure. In some arrangements, one compartment contains a soluble substance and a second compartment contains a diluent. An aseptic cap may be disposed to seal over the fluid transport device to maintain its sterility and/or a moisture and oxygen barrier until use. In some arrangements, the product is packaged in an aseptic package to maintain its sterility. In one arrangement, the device package further contains a drying agent, such as a desiccant material, to further limit the moisture that could penetrate the soluble substance's compartment.
One preferred method for filling a dual compartment reconstitution syringe of the present disclosure, with 0.5 ml of diluent and 0.2 ml of active powder, is described below:
Step 1: The tubular wall is extruded as a multilayer tube comprising an inner layer made from EasyPeel™, a middle layer made from Aclar™, and an outer layer made from PET, together forming a wall 150 microns thick; typically for this dose volume, an inner diameter of 3.5 mm to 4.5 mm is preferable;
Step 2: The extruded tube is cut to the desired tubular wall length; typically for this dose volume, a length of 50 mm to 65 mm is preferable;
Step 3: The tubular wall is pinched and heat welded along approximately 3 mm at the crimp location, dividing the tubular wall into two sections each opened to an opposite end of the tubular wall. Typically, a 140° C. temperature is desired with EasyPeel adhesive to form a good seal yet with weak peeling force;
Step 4: Vertically filling an aliquot powder dose through the distal end of the tubular wall by one of the powder filling methods known in this industry, such as the Hofliger Harro Verpackungsmaschinen GmbH (Allmersbach i.T.) Drum Filler;
Step 5: Crimping and sealing between the distal end of the tubular wall and the powder dose to form a sealed compartment of the powder;
Step 6: Vertically filling an aliquot of diluent dose through the proximal open end of the tubular wall with a metering dose pump;
Step 7: Crimping and heat sealing between the proximal end of the tubular wall and the diluent dose to form a sealed diluent compartment;
Step 8: Introducing a needle assembly, including a stainless steel needle, a cylindrical molded plastic needle hub, and a needle-protecting cap, by inserting the proximal end of the needle hub in a tight fit fashion into the distal end of the tubular wall;
Step 9: Introducing a plunger into the proximal end of the tubular wall;
Step 10: Heat welding the tubular wall to the needle-hub;
Step 11: Flaring the proximal end of the tubular wall;
Step 12: Axially introducing the sheath over the tubular wall;
Step 13: Heat welding the flare of the tubular wall to a reciprocal surface at the proximal end of the sheath;
Step 14: Engaging a stem with the plunger; and
Step 15: Seaing in a sterile pouch.
Some of the steps of this process may be performed in an aseptic environment with the components pre-sterilized to avoid terminal sterilization. In other cases, the aseptic environment may be avoided if the device can withstand terminal sterilization. In some arrangements, Step 5 may be avoided and the powder compartment merely sealed by the needle assembly (as in Step 8). In some arrangements, Step 7 may be avoided and the diluent compartment merely sealed by the plunger (as in Step 9). In some arrangements, Steps 1-7 are implemented, then Step 15, to create a sterile cartridge to be introduced to a delivery device at a later stage. In one arrangement, this later stage is accomplished on a different manufacturing line. In another arrangement, this later stage is accomplished by the user. In some arrangements, Steps 1-8 are implemented, then Step 15, to create a sterile cartridge to be introduced to a delivery device at a later stage. In one arrangement, this later stage is accomplished on a different manufacturing line. In another arrangement, this later stage is accomplished by the user. In some arrangements, Steps 1-9 are implemented, then Step 15, to create a sterile cartridge to be introduced to a delivery device at a later stage. In one arrangement, this later stage is accomplished on a different manufacturing line. In another arrangement, this later stage is accomplished by the user. In some arrangements, Steps 1-13 are implemented, then Step 15, where the stem is packed in the sterile pouch alongside the barrel assembly to reduce the overall shipping volume. The stem may be introduced to the plunger by the user.
In another preferred manufacturing method, at least one of the first substance, the second substance, the fluid transport device, or the plunger is introduced to the tubular wall on the tubular wall's extrusion line. Several patents and commercial products, such as the ones taught by U.S. Pat. Nos. 5,111,996 and 4,824,025, employ a method for introducing a desired component into an extruded tube during the tube extrusion. General examples of this method are taught by U.S. Pat. Nos. 6,896,758 and 5,271,786, incorporated here by reference. According to this manufacturing approach, a desired component is introduced to the central core of the extrusion die at the extruder head. In one arrangement, a first crimp is formed in the tubular wall as it exits the extrusion head, then a powder dose is advanced through an opening in the die core toward the first crimp, and then a second crimp is performed to seal a powder chamber. A similar method can be applied to the liquid filling. At least part of this process can be performed in a vertical direction to keep the dose adjacent to the first crimp.
In another preferred manufacturing method, at least one substance is lyophilized in the barrel, either prior or after creating the barrier between the first and the second substance compartments. In one arrangement, the device is intended for intramuscular vaccination. In one arrangement, the device is intended for intradermal vaccination in which case the fluid transport device may be a micro-needle or a needle with a limited skin penetration depth. Intradermal injection is typically set for smaller injectable volumes in the range of 0.1-0.15 ml and, therefore, the tubular wall diameter and the barrel's compartment lengths will be smaller than the dimensions proposed above for 0.5 ml dose.
In one arrangement, the device is intended for needle-free jet injection to the skin either for intradermal, subcutaneous or intramuscular administration, in which case the fluid transport device would be a jet-injector nozzle disposed at the contact surface of the device with the subject's skin. In one arrangement, the tubular section is substantially accommodated in a pressure chamber which serves as the actuator to which pressure is applied at the point of injection, and causes the tubular walls to collapse as the dispensable product is driven through the jet-nozzle. Alternatively, the dispensable product delivery can be driven by a piston or rollers.
The dispensing device of the present invention may be manually operated by a user in the same fashion that a regular syringe is. In one arrangement, the dispensing device is operated by an apparatus which manipulates the stem inwardly. In another arrangement, the device is operated by an apparatus where the apparatus provides the stem or other object for depleting the volume of at least one product or substance compartment. In one arrangement, the dispensing device is at least partially disposed in a pressure chamber of a dispensing apparatus such that when pressure is raised in the pressure chamber, the tubular wall collapses and dispenses the product. In one arrangement, the dispensing device serves as a cartridge for a dispensing apparatus. In one arrangement, the device is associated with at least one similar device to auto-load into a dispensing apparatus. In one arrangement, one device is linked with at least one similar device. In another arrangement, numerous devices are organized in a magazine.
In one arrangement, the tubular wall comprises at least one layer made from metal oxide, such as aluminum oxide or silicone oxide. The metal oxide layer may be applied by lamination, vapor deposition, or by one of the means known in the art.
The applications of the present invention are not limited to drug delivery which is provided here by way of example, and the teachings described herein can be applied to other applications of prefilled syringes such as glue dispensing, chemicals dispensing etc.
The present disclosure provides various configurations for accomplishing this.
In one arrangement, compartment 16 or a further compartment of the tubular section, is overwrapped with a high barrier foil wrap comprising a first side and a second side adhered to each other to define a sealed enclosure around said compartment. In at least one pinched section (14, 15 or other), each of the first side of the overwrap and the second side of the overwrap are adhered to a pinched section to complete an integral seal around said compartment. The overwrap can be removed to allow visual inspection of the tubular section or its content.
In one arrangement, compartment 16 or a further compartment of the tubular section, is overwrapped with an adhesive foil that is wound around the compartment to form a sealed enclosure around said compartment. The overwrap can be removed to allow visual inspection of the tubular section or its content.
Referring now to
Referring now to
Referring now to
Referring to
Referring to
Referring now to
Referring now to
Referring to
Proximal end 12 of the extended portion 131 is pinched and sealed to form an aseptic enclosure to the needle assembly and ensure its sterility. The extended section 131 may also provide mechanical protection to a needle and may eliminate the need for a needle shield as shown in earlier Figures. The distal extending portion 131 may be removed to expose the fluid transport device. In one arrangement, the distal extended portion 131 is removed by twisting it off. A weakened section about where number 133 points defines the breaking off zone of the distal extended portion 131. The tubular wall also extends at its proximal end forming a proximal extended portion 132 pinched and sealed at its proximal end 13, providing an aseptic enclosure to the piston shown in earlier figures. The proximal extended section is corrugated in a form of a bellows axially movable between a pre-injection position to an injection position, allowing manipulation of the piston to operate the delivery device 130.
Referring now to
Referring to
Accordingly, the present invention has been described with some degree of particularity directed to the exemplary arrangements thereof. It should be appreciated, though, that the present invention is defined by the following claims construed in light of the prior art so that modifications or changes may be made to the exemplary arrangements of the present invention without departing from the inventive concepts contained herein.
Claims
1. A dispensing device for use with a beneficial agent, comprising:
- a dispensing package, comprising: an elongate, at least partially flexible member comprising a sealed tubular compartment and at least one separable barrier enclosing one end of said tubular compartment; and one of a beneficial agent or a constituent of a beneficial agent contained in said tubular compartment;
- a dispenser disposed on a dispensing end portion of said package; and
- an actuator movably disposed along at least a portion of said package between a pre-dispensing state and a dispensing state.
2. A dispensing device according to claim 1 wherein said separable barrier is formed along said tubular wall by pinching said one end of said tubular compartment and thereafter sealing across said one end.
3. A dispensing device according to claim 1 wherein said separable barrier defines a distal end of said tubular compartment.
4. A dispensing device according to claim 1 wherein said separable barrier defines a proximal end of said first compartment.
5. A dispensing device according to claim 1 wherein said first compartment stores a first constituent of the beneficial agent, and further comprising at least a second compartment storing a second constituent of the beneficial agent, and wherein said separable barrier is located between said first and second compartments.
6. A dispensing device according to claim 1 wherein said separable barrier is located between said first compartment and said dispensing end portion.
7. A dispensing device according to claim 1 wherein said tubular wall comprises a multi-layer material.
8. A dispensing device according to claim 1 where said tubular wall is an extrusion.
9. A dispensing device according to claim 8 wherein said tubular wall is made from an extruded sheet rolled and seamed to form a tube.
10. A dispensing device according to claim 1 wherein said dispensing end portion includes a dispensing port and said actuator comprises a plunger and a piston joined to said plunger, said tubular wall extending to aseptically enclose at least one of said dispensing port, said plunger, and said piston.
11. A dispensing device according to claim 5 further comprising a peelable foil, substantially protecting at least one of said first and second compartments from an ambient environment.
12. A dispensing device according to claim 11 wherein said peelable foil is attached to at least one of said first and second separable barriers.
13. A dispensing device according to claim 12 wherein said peelable foil extends to provide an aseptic enclosure to one of the group of a dispensing port, a plunger, and a piston.
14. A dispensing device according to claim 1 wherein said dispenser is selected from a group consisting of a needle, a micro-needle, an intra-dermal needle, a subcutaneous needle, an intramuscular needle, an IV catheter, a jet injection nozzle, a catheter, a tube, a hose, a topical applicator, a nasal applicator, an auricular dispenser, an ocular dispenser, a dropper, an adapter, or a connector to one of the above.
15. A dispensing device according to claim 1 further comprising a housing surrounding at least a portion of said tubular wall.
16. A dispensing device according to claim 15 wherein said housing restricts movement of said tubular wall toward a distal end of said housing.
17. A dispensing device according to claim 16 wherein said tubular wall is moveable toward a proximal end of said housing to draw said dispenser at least partially into said housing.
18. A dispensing device according to claim 1 wherein said actuator comprises a roller operative to collapse said tubular wall resulting in expulsion of said beneficial agent.
19. A dispensing device according to claim 1 wherein said actuator comprises at least one compression panel operative to collapse said tubular wall resulting in expulsion of said beneficial agent.
20. A dispensing device according to claim 1 wherein said actuator comprises a pressure chamber adapted to receive at least a portion of said tubular wall such that elevated pressure in said pressure chamber results in expulsion of said beneficial agent.
21. A dispensing device according to claim 1 wherein said actuator comprises a plunger.
22. A dispensing device according to claim 1 wherein said dispenser includes a dispensing port, and wherein at least a portion of said dispenser is moveable toward the proximal end of said tubular wall to conceal at least a portion of said dispensing port.
23. A dispensing device according to claim 5 wherein movement of said actuator causes said first and second constituents to mix and thereafter be expelled through said dispenser.
24. A beneficial agent dispensing device, comprising:
- an elongate portion, comprising: a first compartment for storing a first constituent of the beneficial agent, said first compartment comprising a tubular wall; at least a second compartment for storing at least a second constituent of the beneficial agent; and at least a first separable barrier located between said first and second compartments;
- a dispenser; and
- a plunger comprising a plunger portion moveably disposed in said tubular wall between a pre-dispensing position wherein said plunger portion is outside said first compartment, and a dispensing position wherein said plunger portion is at least partially disposed within said second compartment.
25. A dispensing device according to claim 24 further comprising a piston attached to said plunger.
26. A dispensing device according to claim 24 further comprising a second separable barrier located between said second compartment and said dispenser.
27. A dispensing device according to claim 24 further comprising a second separable barrier located between said first compartment and said plunger.
28. A dispensing device according to claim 24 wherein said dispenser is selected from a group consisting of a needle, a micro-needle, an intradermal needle, a subcutaneous needle, an intramuscular needle, an IV catheter, a jet injection nozzle, a catheter, a tube, a hose, a topical applicator, a nasal applicator, an auricular dispenser, an ocular dispenser, a dropper, an adapter, or a connector to any of the above.
29. A dispensing device according to claim 24 wherein said tubular wall comprises molded plastic.
30. A dispensing device according to claim 24 wherein at least one of said first and second compartments comprises a flexible tube.
31. A dispensing device according to claim 24 wherein said separable barrier comprises a rupturable foil.
32. A dispensing device according to claim 27 wherein at least one said first and second separable barriers comprises a tubular portion that has been crimped and sealed there across.
33. A dispensing device according to claim 24 further comprising a second plunger portion operative to couple with said first plunger portion as said second plunger portion moves toward said dispenser.
34. A beneficial agent dispenser, comprising:
- a dispensing port;
- an elongate portion, comprising: a first compartment for storing a first constituent of the beneficial agent, said first compartment comprising a tubular wall; and at least a first separable barrier located between said first compartment and said dispensing port; and
- a plunger comprising a first plunger portion moveably disposed relative to said tubular wall during a dispensing stroke to partially penetrate said first separable barrier and expel the beneficial agent through said dispensing port.
35. A dispenser according to claim 34 further comprising a piston attached to said plunger.
36. A dispenser according to claim 34 further comprising a second compartment disposed between said first compartment and said dispensing port, said at least a first separable barrier located between said first and second compartments.
37. A dispenser according to claim 34 further comprising a second separable barrier located between said first compartment and said plunger portion.
38. A dispenser according to claim 34 wherein said dispensing port is part of a dispensing device that is selected from a group consisting of a needle, a micro-needle, an intradermal needle, a subcutaneous needle, an intramuscular needle, an IV catheter, a jet injection nozzle, a catheter, a tube, a hose, an adapter, or a connector to any of the above.
39. A dispenser according to claim 34 wherein said tubular first compartment wall comprises molded plastic.
40. A dispenser according to claim 36 wherein said second compartment comprises a flexible tube.
41. A dispenser according to claim 36 where said first and second compartments comprises first and second flexible tubes, respectively.
42. A dispenser according to claim 34 wherein said at least one separable barrier comprises a rupturable foil.
43. A dispenser according to claim 37 wherein at least one of the said first and second separable barriers comprises a flexible tube section pinched and welded there across to form seal.
44. A dispenser according to claim 34 wherein first plunger portion is moveably disposed in said first tubular compartment, and further comprising at least a second plunger portion adapted to couple with said first plunger portion as it penetrates said first separable barrier.
45. A beneficial agent dispensing device, comprising:
- a dispensing package comprising at least a first compartment constructed at least partially from a flexible tubular wall, and one of a beneficial agent or a constituent of a beneficial agent contained in said first compartment;
- a dispenser disposed on a dispensing end portion of said package; and
- an actuator movably disposed along at least a portion of said package between a pre-dispensing state and a dispensing state to expel contents of said at least a first compartment through said dispensing end portion.
Type: Application
Filed: Nov 8, 2011
Publication Date: Mar 6, 2014
Applicant: AKTIVPAK, INC. (Aurora, CO)
Inventor: Amir Genosar (Aurora, CO)
Application Number: 13/884,246
International Classification: A61M 5/24 (20060101); A61M 5/315 (20060101);