Patent Grant
9616171
In general, various embodiments of this invention relate to flexible patch pumps for use in delivering medicament to a patient and, specifically, to a patch pump including a plurality of rigid reservoirs disposed in a flexible material capable of accurately delivering precise amounts of medicament.
The treatment of many medical conditions requires the subcutaneous delivery of a medicament. As one example, the treatment of diabetes requires the subcutaneous delivery of insulin. In some instances, subcutaneously delivered medicament must be continuously delivered in small and at time varying doses over along period of time. It is important that such delivery be accurate, as over or under delivery can cause serious health risks. For example, the subcutaneous delivery of insulin can require accuracies as low as 0.5 microliters per hour. One widely used technique for subcutaneously delivering medicament is by pumping the medicament from a large external storage container through a long tube to a cannula of an infusion set attached to a patient's skin. An improvement over this technique is the use of a patch pump. A patch pump incorporates the medicament, pumping mechanism, and infusion set into a patch that attaches to a patient's skin, thus eliminating the need for long tubes. However, existing patch pumps still present a number of drawbacks and their overall adoption is low compared to the use of syringes and syringe pens. Such pumps are rigid and bulky and consequently are prone to detachment and/or require the use of aggressive adhesives to adhere to the skin, which can lead to irritation. Further, because existing pumps usually contain a single reservoir or at most two (e.g. reservoirs for insulin and potentially glucagon), they are also limited in their ability to deliver combination therapies, requiring patients to use separate patch pumps to deliver multiple medicaments. In addition, the use of a single or dual reservoir(s) can make it difficult to control the delivery of accurate amounts of medicament. Some prior art pumps require a flow meter to determine the amount of medicament delivered, which can lead to imprecise measurements.
Accordingly, there exists a need for an improved patch pump.
A bandage-like patch pump for actively controllable subcutaneous delivery of one or more medications, operating by means of a flexible pump mechanism, includes valves and micro Channels embedded in a flexible substrate, and multiple rigid drug reservoirs that deliver precise volumes of liquid set in motion by the pressure change created by a membrane undergoing unfolding, stretching or another transformation. The mechanism driving the membrane's transformation can be electrolysis, thermal bubble, thermal expansion of wax (or other temperature sensitive material), or a phase change/same phase expanding and/or shrinking, which causes a volume change. The thin, flexible bandage-like form factor enabled by the invention allows for a more comfortable device that can fit the curvature of the human body and be hidden beneath a patient's clothes to protect privacy. The device requires less aggressive adhesive, is less prone to detachment, and is more comfortable and less irritating to the skin than existing devices, while not compromising its delivery or absorption accuracy. The pump includes the potential to deliver multiple medications simultaneously and/or sequentially in one device. Embodiments of the invention use an array of multiple tiny rigid reservoirs, rather than a single large reservoir, which allows for the accurate and safe delivery of precise amounts of one or more medicaments. With the reservoirs embedded in a flexible substrate, even though each reservoir is rigid, the flexible space between reservoirs enables the device to maintain an overall form factor which is highly flexible.
In general, in one aspect, embodiments of the invention feature a patch pump for delivering a medicament to a patient. The patch pump includes a flexible layered structure that includes: a reservoir layer including rigid reservoirs adapted to contain medicament disposed in a flexible material; a flexible microfluidic layer including an element for sealing the rigid reservoirs, a network of microfluidic channels connecting the rigid reservoirs, and at least one outlet valve connected to the network; and a flexible-rigid electronic circuit layer below the microfluidic layer including individually-addressable actuators.
In various embodiments, the rigid reservoirs can be arranged in an array. In some embodiments, at least a portion of an interior surface of each rigid reservoir forms at least one channel. The pump can include at least three rigid reservoirs. The rigid reservoirs can include at least one of glass, polymer, and polypropylene and the flexible material can include at least one of elastomer, protein hydrogel, polyurahane, and polyethylene. Each rigid reservoir may be adapted to contain a volume of medicament in a range from about 10 nanoliters to about 10,000 microliters, and in some instances in a range from about 6 microliters to about 135 microliters. The sealing material can be a compliant membrane that can include at least one of a resilient material and a folded material, and in some cases can include polyethylene. In some embodiments, the flexible microfluidic layer has a laminated structure that includes an upper layer adhered to a middle layer adhered to a lower layer, which can form inlet and outlet valve pairs corresponding to the rigid reservoirs, Each valve may be a one-way valve. The inlet and outlet valve pairs may be formed from corresponding apertures and resilient blocking portions. In some embodiments, the middle layer may not be adhered at each valve, allowing pressurized fluid to flow through each valve. In certain embodiments, the network of microfluidic channels includes an inner tubing encapsulated by a flexible packaging. The inner tubing and flexible packaging may include different materials, for example, the inner tubing may include polyethylene and the flexible packaging may include polyurethane. In some embodiments, each actuator is adapted to contain at least one of an electrolytic material, a volume change material, and a shape change material. The actuators may operate based on one or more of the following techniques: electrolysis of liquid, electrolysis of hydrogel, a piezoelectric technique, a thermopneurnatic technique, an electrostatic technique, a pneumatic technique, a linear piston drive mechanism, a rotary drive mechanism, a shape change mechanism, a phase change technique, an electrowetting/thermocapillary technique, an electrohydrodynamic technique, an electroosmotic technique, a magnetohydrodynamic technique, an electrochemical technique, and a selectively permeable membrane technique. The flexible-rigid electronic circuit layer may be made of stretchable electronics and/or rigid-flexible circuitry, and may be adapted to permit filling of each actuator. In some embodiments, the individually-addressable actuators may include individually-addressable electrode pairs, which may be made of stainless steel, iron, nickel, cobalt, Fe—Ni alloy, indium tin oxide, gold, platinum, a coating film comprising a low surface energy material, fluorine, and alloys and combinations thereof. In some instances the individually-addressable electrode pairs may include a working perimeter electrode surrounding a counter electrode. In some instances, the individually-addressable electrode pairs may be adapted to contact an electrolyte (e.g., an aqueous ion solution). In some embodiments the pump can have a thickness of up to about 5 millimeters. The pump may further include at least one inlet and/or an outlet in fluidic communication with the reservoir layer. The pump may further include a controller connected to the flexible electronic circuit layer, where the controller is adapted to selectively energize the actuators. The pump may further include a power source for powering the controller and/or the actuators.
In general, in another aspect, embodiments of the invention feature a method of using a flexible patch pump. The method may include the steps of providing a flexible patch pump including rigid reservoirs disposed in a flexible material and corresponding actuators, adhering the flexible patch pump to a skin surface of a patient, and controlling the flexible patch pump to selectively energize at least one of the actuators to deliver medicament disposed in the corresponding rigid reservoir to the patient.
In various embodiments, the method can further include the step of filling the rigid reservoirs with medicament. The method can further include the step of subcutaneously inserting a cannula fluidicly connecting the flexible patch pump with the patient. The method can further include the step of removing the flexible patch pump from the skin surface.
In general, in another aspect, embodiments of the invention feature a method of manufacturing a flexible patch pump. The method may include the steps of providing a reservoir layer including a plurality of rigid reservoirs adapted to contain medicament disposed in a flexible material; adhering to the reservoir layer a flexible microfluidic layer including an element for sealing the rigid reservoirs, a network of microfluidic channels connecting the rigid reservoirs, and at least one outlet valve in the network; and adhering below the flexible microfluidic layer a flexible-rigid electronic circuit layer including individually-addressable actuators.
In various embodiments, the method can further include the steps of adhering below the flexible-rigid electronic circuit layer at least one of a pressure sensitive adhesive layer and a hydrogel layer, filling the rigid reservoirs with medicament, and/or disposing in the actuators at least one of an electrolytic material, a volume change material, and a shape change material. The method can further include the steps of sterilizing a least a portion of the flexible patch pump, connecting a controller to the flexible-rigid electronic circuit layer, connecting a power source to the flexible patch pump, connecting an infusion set to an outlet of the flexible patch pump, and/or verifying operation of the flexible patch pump. In some embodiments, the network of microfluidic channels includes a plurality of materials, which in some cases can include polyethylene channels formed by supersonic or ultrasonic welding encapsulated in another material.
In the drawings, like reference characters generally refer to the same parts throughout the different views. Also, the drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles of the invention. In the following description, various embodiments of the present invention are described with reference to the following drawings.
Embodiments of the present invention are directed to a patch pump having a flexible layered laminated structure. This structure results in a pump that is less prone to detachment, more comfortable, and less irritating to the skin than existing pumps with hard, inflexible housings, while meeting or improving delivery accuracy of alternative pumps. In some embodiments, the patch pump of the present invention can be significantly thinner than existing pumps, in some cases having a thickness less than or equal to about 5 millimeters, which allows the pump to be concealed comfortably beneath a patient's clothing. Further the pumps according to the invention can allow for the delivery of multiple medicaments using a single device. In a particular embodiment, layered laminated structure may include a reservoir layer including a plurality of rigid reservoirs disposed in a flexible material, a flexible microfluidic layer including a compliant membrane that seals the rigid reservoirs, and a flexible-rigid electronic circuit layer below the microfluidic layer having a plurality of individually-addressable actuators. The configuration and operation of each of these layers are discussed in greater detail below.
In various embodiments, the pump 100 includes a flexible microfluidic layer 108. The flexible microfluidic layer 108 may include an element, such as compliant membrane 120 for sealing the rigid reservoirs, an example of which is shown in
In various embodiments the flexible microfluidic layer 108 may include valves through which medicament can be transported into and out of the rigid reservoirs 104. In some instances, an upper layer 110 of the microfluidic layer 108 can be selectively adhered to a middle layer 112 to form a plurality of inlet valves 116 and/or a plurality of outlet valves 118, both of which can be one-way valves. Although
In various embodiments, the flexible microfluidic layer 108 can include at least one microfluidic channel 122 for fluidicly communicating an outlet valve of each reservoir with an outlet 502 of the pump. Although
The microfluidic channels 122 can all be similarly sized or they can be of different sizes, for example with a plurality of small channels connecting each reservoir 104 to a larger trunk or main channel directly connected to the outlet 502. The microfluidic network of channels 122 can connect to the outlet 502 of the pump, as shown in
In various embodiments, the pump 100 includes a flexible-rigid electronic circuit layer 126 below the microfluidic layer 108. The electronic circuit layer 126 can include stretchable electronics or in some cases, rigid-flexible circuitry, Stretchable electronics are electronics that are stretchable, bendable, and compressible. The electronic circuit layer 126 may include a plurality of individually-addressable actuators 128 and/or subsets of simultaneously addressable actuators (e.g., to deliver a bolus dose). Although
In embodiments in which the compliant membrane 120 is actuated using an electrolysis technique, each actuator 128 can include an individually-addressable electrode pair, which can be adapted to apply a voltage differential to an electrolytic fluid. The electrodes may be any suitable material, such as stainless steel, iron, nickel, cobalt, Fe—Ni alloy, indium tin oxide, gold, platinum, and alloys and combinations thereof. In some embodiments, the flexible-rigid electronic circuit layer 126 may be adapted to permit filling of the electrolytic fluid into the chamber 124, for example via at least one hole that can be sealed after filling.
The electrode pairs may be a working perimeter electrode 602 surrounding a counter electrode 604, as shown for example in
In various embodiments the pump 100 includes a controller 202 (
As mentioned above, it is important that a medicament pump be able to deliver precise amounts of medicament accurately. One challenge to delivering medicament accurately over extended periods is that various parameters affecting medicament flow rate can change over time. In certain embodiments, the pump may include operational and/or environmental sensors 212 (
In various embodiments the pump 100 may also include external pressure sensor(s) 130 that can determine whether delivered medicament has been absorbed by the subcutaneous tissue of a patient. Because of the variable resistance to injection inherent in various human tissues, delivered medicament will often diffuse into the subcutaneous fat layer at a slow rate. External pressure sensors 130 can be located against a patient's skin such that they experience a sudden pressure increase following delivery of a medicament (due to an increased area of skin pressing against the sensor), and then a slow pressure drop as the medicament is absorbed into the subcutaneous tissue. When the pressure reading returns to zero, a signal can be generated indicating that all medicament has been absorbed, which in some cases can allow for an additional delivery of medicament to occur.
In another aspect, the present invention relates to a method of using the flexible patch pump. The method can include adhering the patch pump to a skin surface of a patient. A patient controls the pump to deliver medicament disposed therein, for example by selectively addressing at least one of the actuators. Addressing a particular actuator associated with a particular rigid reservoir causes the compliant membrane or other element corresponding to that rigid reservoir to expand into and increase the pressure within the rigid reservoir or otherwise displace the contents of the rigid reservoir. Under the increased pressure, medicament may be evacuated from the rigid reservoir through an outlet valve, into a microfluidic channel from which it can be delivered to the pump outlet and ultimately an infusion set for subcutaneous delivery into the patient. The outlet valves in the microfluidic network prevent back-flow of the medicament into the reservoir it came from or a neighboring reservoir once it has been evacuated. In general, addressing a particular actuator can include any of the actuating techniques described above. In the embodiment in which the actuators include individually-addressable electrode pairs, addressing a particular actuator can include delivering current to the electrode pairs, which results in a voltage differential being applied to an electrolysis fluid, generating a gas (e.g., hydrogen). The gas volume causes the compliant membrane to expand or unfold into the rigid reservoir, resulting in the evacuation of medicament. In such an embodiment, the amount of medicament evacuated is determined by the magnitude and duration of the compliant membrane's deflection, which corresponds to the applied voltage and the duration of the delivered current.
The pump 100 can be adapted to deliver medicament from a single rigid reservoir (or a portion thereof) or many rigid reservoirs at a given time, depending on how many actuators are addressed. Thus, the pump 100 can be adapted to deliver both basal and bolus doses of medicament. With an electrolytic-based actuator, the flow rate is controlled by the current supply. As one example, potassium chloride solution can be used as the electrolyte and the progress of water electrolysis (with associated gas bubble generation) can be governed by the current supply. In such embodiments, the volume of gas generated can be linear with respect to the amount of time current is applied. In some embodiments, the pump 100 may be adapted to deliver doses as small as 1 nanoliter.
By way of example, the patch pump 100 may deliver basal doses at a flow rate in a range from between about 10 nanoliters per minute to about 1,000 nanoliters per minute, depending on the amount of current delivered to the actuator or actuators. Because basal dose rates are relatively small, a single reservoir may provide the medicament for multiple doses using intermittent actuation techniques. For example, a current may be applied to a particular actuator for a predetermined amount of time e.g., 2 seconds) until a programmed amount of medicament is released (which can be less than the volume contained within the reservoir), after which the current flow stops and the voltage returns to zero. After a predetermined interval (e.g., 3 minutes) current may again be applied to the same actuator, releasing more medicament from the reservoir. This process repeats until all the medicament in a particular reservoir has been released, after which current can be applied to a different actuator. In some instances, depending on the amount of insulin required by the patient and the size of the reservoir, a particular electrode may be actuated multiple times (e.g., between 3 and 7 times) before releasing all of the medicament contained in the reservoir.
In some embodiments, each individual reservoir may be either completely full or completely evacuated, in which case the delivered dose will be pre-determined by the size of the individual reservoirs, which may vary from one medicament reservoir to another.
In various embodiments, the patch pump 100 may deliver bolus doses at a flow rate of up to about 1 milliliter per minute, depending on the amount of current applied to an actuator or actuators. In some instances, in delivering a bolus injection, current may be applied to a particular actuator for a longer period of time than for a basal dose (e.g., 20 seconds), releasing more medicament In other instances, in delivering a bolus injection, several reservoirs may be actuated, either concurrently or sequentially.
For example, for a type 1 diabetic patient weighing 70 kilograms, the estimated daily basal insulin injection is 40 units (i.e., 0.4 mL, 1 unit equals 0.01 mL), which is equivalent to 277 nL/min (lower flow rates can be used with ultra-concentrated insulin). Although in some embodiments such a flow rate can be generated through the intermittent actuation techniques described above, in other embodiments this flow rate can be accurately delivered through the constant application of current to the actuators. In an experiment, the data from which is shown in
In embodiments in which different rigid reservoirs contain different medicaments, the pump can be adapted to actuate multiple reservoirs to deliver more than one medicament or a combination of medicaments. In embodiments in which the controller 202 is operated from a remote control unit 204 by a patient, the patient may instruct the controller 202 how much medicament to deliver at a particular trifle e.g., a diabetic may instruct the controller 202 to deliver a bolus dose of insulin prior to a meal) and/or which medicament/combination of medicaments to deliver at a particular time. The controller 202 may then determine which actuators to selectively address in order to deliver the instructed amount of the selected medicament. A combination of medicaments can be blended in the microfluidic network of the pump 100, immediately prior to delivery via a common outlet, if desired.
In some embodiments, the rigid reservoirs 104 of the pump 100 may be filled during manufacture of the pump 100. In other embodiments, the pump 100 is fillable after the pump has been manufactured, for example, by the patient. In such embodiments, one method of using the flexible patch pump can further include the step of filling the rigid reservoirs with medicament, by connecting the outlet 502 of the pump to a vacuum, to evacuate any gas contained within the microfluidic channels and reservoirs, while providing a supply of medicament (optionally pressurized) at the inlet 504. The differential pressure opens the inlet and outlet valves associated with each rigid reservoir. An example configuration of the valves during this filling process can be seen in
Additional aspects of the present invention relate to methods of manufacturing the flexible patch pump. The reservoir layer can be manufactured by molding the rigid reservoirs in a reservoir mold 802, as shown for example in
The flexible microfluidic layer can include: (i) a plurality of outlet and/or inlet valves, (ii) a compliant membrane for sealing the rigid reservoirs, and (iii) a network of microfluidic channels connecting the rigid reservoirs. In certain embodiments, fabricating the plurality of outlet and/or inlet valves includes separately molding an upper layer and a middle layer, as shown for example in
Fabricating the compliant membrane and network of microfluidic channels of the flexible microfluidic layer can include molding a resilient material using the mold 1902 shown in
The flexible-rigid electronic circuit layer includes a plurality of individually-addressable actuators. This circuit layer can include stretchable electronics and/or rigid-flexible electronics (as described above). The flexible-rigid electronic circuit layer may then be adhered below the layer including the compliant membrane and microfluidic channel(s), which in some cases can forma chamber for containing an actuating fluid. In embodiments in which actuation of the compliant membrane requires a fluid contained in the chamber, the rigid-flexible electronic circuit layer may include at least one hole for filling the chamber. After the chamber is filled, the hole(s) may be sealed. In certain embodiments in which the pump 100 is manufactured with the rigid reservoirs containing medicament, the rigid reservoirs can be filled with medicament prior to being sealed by the compliant membrane. Removal of the flexible layer mold 1002 results in the structure shown, for example, in
In an alternative embodiment, it can be desirable to isolate medicament from the materials in the other layers of the pump, for example by channeling the medicament through a microfluidic network manufactured by a different material. In such embodiments, the microfluidic layer 122 can be made with multiple layers of materials, as shown in
The tubing 2202 can be fabricated using a supersonic or ultrasonic welding process. As shown for example in
Alternatively or additionally, rather than being separated from medicament contained within the rigid reservoirs 104 by inlet valves 116 and/or outlet valves 118, the network of microfluidic channels can be in direct fluidic contact with the interior of each rigid reservoir 104, as shown for example in
Each numerical value presented herein, for example, in a table, a chart, or a graph, is contemplated to represent a minimum value or a maximum value in a range for a corresponding parameter. Accordingly, when added to the claims, the numerical value provides express support for claiming the range, which may lie above or below the numerical value, in accordance with the teachings herein. Absent inclusion in the claims, each numerical value presented herein is not to be considered limiting in any regard.
The terms and expressions employed herein are used as terms and expressions of description and not of limitation, and there is no intention, in the use of such terms and expressions, of excluding any equivalents of the features shown and described or portions thereof. In addition, having described certain embodiments of the invention, it will be apparent to those of ordinary skill in the art that other embodiments incorporating the concepts disclosed herein may be used without departing from the spirit and scope of the invention. The structural features and operational functions of the various embodiments may be arranged in various combinations and permutations, and all are considered to be within the scope of the disclosed invention. Accordingly, the described embodiments are to be considered in all respects as only illustrative and not restrictive. Furthermore, the configurations, materials, and dimensions described herein are intended as illustrative and in no way limiting. Similarly, although physical explanations have been provided for explanatory purposes, there is no intent to be bound by any particular theory or mechanism or to limit the claims in accordance therewith.
This application is a continuation of and claims priority to International Patent Application No. PCT/US2014/049755, titled “Conformable Patch Pump,” filed on Aug. 5, 2014, which claims priority to U.S. provisional patent application Ser. No. 62/007,770, titled “Conformable Patch Pump,” filed on Jun. 4, 2014, and U.S. provisional patent application Ser. No. 61/862,124, titled “Flexible Thin Infusion Pump With Self-Regulation Reservoir Arrays,” filed on Aug. 5, 2013, the disclosures of all three of which are herein incorporated by reference in their entireties.
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| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/US2014/049755 | Aug 2014 | US |
| Child | 15015627 | US |
