PORTABLE MEDICINE INJECTION DEVICE AND ANALYTE METERING SYSTEM
Methods, systems, and devices are described for setting a dose of medicine and injecting the medicine. In one aspect, a method to dispense a medicine includes inserting a cartridge containing a medicine into a cartridge holder coupled to a housing of a medicine injection device, positioning a spine component of the device to make contact with the cartridge in the cartridge holder, selecting a dose of the medicine for injection, in which the selecting includes rotating an injection component of the device to a setting corresponding to the selected dose, and linearly advancing the injection component to rotate a drive gear coupled to the injection component to drive the spine component so as to push the end of the cartridge to dispense the medicine in the amount of the selected dose.
This patent document is a continuation of U.S. patent application Ser. No. 14/371,401, entitled “PORTABLE MEDICINE INJECTION DEVICE AND ANALYTE METERING SYSTEM” filed Jul. 9, 2014, which is a 35 U.S.C. §371 National Stage Application of International Application No. PCT/US2013/062048 filed Sep. 26, 2013, which claims the benefit of priority from Canadian Patent Application No. 2,808,738, entitled “PORTABLE MEDICINE INJECTION DEVICE AND ANALYTE METERING SYSTEM” filed Mar. 6, 2013, now granted as Canadian Patent No. 2,808,738, on Mar. 18, 2014, and U.S. Provisional Application No. 61/706,071, entitled “PORTABLE MEDICINE INJECTION DEVICE” filed on Sep. 26, 2012. The entire disclosure of the above-referenced applications is incorporated by reference as part of the specification of this application.
FIELDThis patent document relates to medicine injection devices technologies, including portable medicine injection devices such as portable insulin injection devices for self-administration by diabetic patients.
BACKGROUNDDiabetes mellitus is a group of metabolic diseases associated with high blood sugar, e.g., which may be due to insufficient production of insulin by the body or inadequate response by cells to the insulin that is produced. There are three main types of diabetes mellitus (diabetes). Type 1 diabetes results from the body's failure to produce insulin, and presently requires the person to inject insulin (e.g., manually or using a wearable insulin pump). Type 2 diabetes results from insulin resistance, in which cells fail to use insulin properly, sometimes combined with an absolute insulin deficiency. Types 1 and 2 diabetes are considered chronic conditions that cannot be cured. The third main form, referred to as gestational diabetes, can occur when pregnant women without a previous history of diabetes develop a high blood glucose level, e.g., which can develop into type 2 diabetes, but often resolves after the pregnancy. Other forms of diabetes include congenital diabetes (e.g., due to genetic defects of insulin secretion), cystic fibrosis-related diabetes, steroid diabetes (e.g., due to high doses of glucocorticoids), and other forms of monogenic diabetes.
For example, diabetes, without proper treatment, may cause acute complications, e.g., including hypoglycemia, diabetic ketoacidosis, or nonketotic hyperosmolar coma, or in some instances, may cause serious long-term complications, e.g., cardiovascular disease, chronic renal failure, and/or diabetic retinopathy (retinal damage). Adequate treatment of diabetes is thus important, as well as controlling blood pressure and managing lifestyle factors such as nonsmoking and healthy body weight. Insulin is used to treat the many of the forms of diabetes, including type 1 diabetes. Other medications are used to treat type 2 diabetes.
SUMMARYSystems, devices, and techniques are described for injecting a medicine using a mechanical dose setting and dispensing mechanism with built in intelligence to track the use of the medicine and communicate the data in a closed loop system.
In one aspect of the disclosed technology, a method to dispense a medicine includes inserting a cartridge containing a medicine into a cartridge holder coupled to a housing of a medicine injection device, positioning a spine component of the device to make contact with the cartridge in the cartridge holder, selecting a dose of the medicine for injection, in which the selecting includes rotating an injection component of the device to a setting corresponding to the selected dose, and linearly advancing the injection component to rotate a drive gear coupled to the injection component to drive the spine component so as to push the end of the cartridge to dispense the medicine in the amount of the selected dose.
In another aspect, a device to dispense a medicine includes a housing configured to include a curved channel, a cartridge holder coupled to the housing via a pivot joint, the cartridge holder including a chamber structured to encase a cartridge containing a medicine and having a first opening that aligns with one end of the curved channel and a second opening at the opposite end of the chamber, and a dose setting and injecting mechanism. The dose setting and injection mechanism includes (i) a spine component housed in the curved channel of the housing, the spine component including a plurality of link structures linked together to allow curved movement of the spine component within the curved channel, in which the one end of the curved channel includes a channel opening interlaced with the first opening to enable the spine component to push against the cartridge for dispensing a selected amount of the medicine through the second opening, (ii) a shaft component structured to include a threaded cylindrical section encased at least in part within the housing and a knob disposed at least in part outside of the housing, (iii) a gear mechanism including a rod having a first gear and a second gear which is coupled to the spine component, and a drive gear having a first gear engagement for engaging to the first gear and a second gear engagement for engaging to threads of the threaded cylindrical section of the shaft component, in which, upon engaging the first gear and the drive gear to each other, a linear movement of the shaft component moves the spine component, and (iv) a disengagement button coupled to the rod to disengage the first gear and the drive gear from each other, e.g., to allow the spine component to move independent of the shaft component. The device can be operated such that a rotation of the shaft component moves the shaft component to a distance from the housing that corresponds selected amount of the medicine.
In another aspect, a health management system includes an analyte monitoring device to determine a concentration level of an analyte; a computing system in communication with the analyte monitoring device, in which the computing system includes a memory unit and a processor configured to process data; and a medicine injection device in communication with at least one of the analyte monitoring device or the computing system. The medicine injection device includes a housing configured to include a curved channel, a cartridge holder coupled to the housing via a pivot joint, the cartridge holder including a chamber structured to encase a cartridge containing a medicine and having a first opening that aligns with a first end of the curved channel and a second opening, and a dose setting and injecting mechanism. The dose setting and injection mechanism includes (i) a spine component housed in the curved channel of the housing, the spine component including a plurality of link structures linked together to allow curved movement of the spine component within the curved channel, in which the first end of the curved channel includes a channel opening interlaced with the first opening to enable the spine component to push against the cartridge for dispensing a selected amount of the medicine through the second opening, (ii) a shaft component structured to include a threaded cylindrical section encased at least in part within the housing and a knob disposed at least in part outside of the housing, (iii) a gear mechanism including a rod having a first gear and a second gear, the second gear coupled to the spine component, and a drive gear having a first gear engagement mechanism for engaging to the first gear and a second gear engagement mechanism for engaging to threads of the threaded cylindrical section of the shaft component, in which, upon engagement of the first gear and the drive gear to each other, a linear movement of the shaft component moves the spine component, and (iv) a disengagement button coupled to the rod to disengage the first gear and the drive gear from each other, thereby allowing the spine component to move independent of the shaft component, in which a rotation of the shaft component moves the shaft component to a distance from the housing that corresponds to the selected amount of the medicine.
The subject matter described in this patent document can be implemented in specific ways that provide one or more of the following features. For example, the disclosed medicine dispensing device can be configured to have a small, compact size enabling convenient portability of the device, e.g., in which a user can store within one's pocket, purse, handbag, etc. For example, the disclosed medicine dispensing device can include an electronic display that provides the user with information including, but not limited to, a current dose setting that the device is dialed to inject, the amount of medicine previously injected from the existing loaded medicine cartridge in the device, the type of medicine in the loaded cartridge (e.g., such as the name of the drug, manufactured lot number, etc.), when to perform medicine injections, and instructions for the user about the use of the device or status of the device. For example, the disclosed medicine dispensing device can include a cartridge holder that opens and closes in a manner that provides ease of loading and removal of a medicine cartridge. For example, the disclosed medicine dispensing device can include an optical scanner that can scan an identification code located on the medicine cartridge and detect the type of medicine contained in the cartridge, e.g., which can be processed as data in the device. For example, the disclosed medicine dispensing device can be implemented as a reusable medicine dispensing pen that communicates wirelessly with other devices, e.g., such as a blood glucose monitor, mobile phone or computing device including a user interface for health management (e.g., including glucose monitoring and insulin treatments), creating a closed loop system that provides convenience and ease of use for a user to monitor analyte levels and perform drug-related treatments. For example, the closed loop system can enable the information stored on the disclosed medicine injection device to be relayed (e.g., such as the type, amount, and injection time of a medicine) to other device(s), which can store the reported information as data and utilize the stored data with other user data that can be used in health management, e.g. in real time).
Like reference symbols and designations in the various drawings indicate like elements.
DETAILED DESCRIPTIONThe technologies and technical features described in this document can be implemented to provide portable insulin injection devices for self-administration by diabetic patients. The described technologies and technical features can be implemented in various medicine injection devices including portable medicine injection devices other than the portable insulin injection devices.
A portable insulin injection device can be configured as a compact insulin pen for injecting insulin as part of treatment and/or management of diabetic conditions in a patient. For example, an insulin pen device can include an insulin cartridge holder and mechanisms to dial to measure a dose of the insulin and to dispense the measured dose. The insulin pen 5 device can include a housing structure which can be shaped like a pen or other suitable geometries for encasing or holding the insulin contained in a cartridge, which can also be referred to as a container or vial. The insulin pen device also includes a mechanism that uses disposable needles to inject the dose into the patient's body. Insulin pens can be configured as disposable pens that do not replace vials of insulin after use or as reusable pens that allow for replaceable insulin cartridges to be loaded into the cartridge holder of the pen device. For example, insulin pens can be configured to provide advantages over vial and syringe modalities that include greater convenience in portability for daily use and transport, increased accuracy in doses, improved ease to implement (e.g., particularly among those with visual or fine motor skills impairments), and reduced pain caused by injection.
Yet, some existing modalities of insulin treatments for diabetic patients suffer certain problems and inefficiencies. For example, in some existing insulin injection devices, unless a pump is used, an insulin dose for injection needs to be tracked and recorded manually. For example, some existing insulin injection devices do not provide an insulin pen that is integrated with a blood glucose monitor device to track test results and insulin dosage. For example, various existing insulin injection devices have designs that render it difficult to accurately administer using insulin pens, e.g., various features associated with the mechanics of the pen devices to set a dose, prime the injection, and replace the insulin cartridge may cause the above mentioned difficulty. Additionally, for example, some existing insulin pen devices include large physical dimensions that are inconvenient for a user to portably carry and store. In some existing insulin injection devices, spent cartridges of reusable insulin pens are difficult to remove, making it inconvenient for the patient to reset the pen for next use. Disposable insulin injection pens may provide convenient features in some regards but they tend to be expensive on a per use basis and also do not include tracking and reporting functionalities.
Disclosed are systems, devices, and techniques for injecting a medicine including insulin using a precise mechanical dose setting and a convenient and accurate dispensing mechanism with built in intelligence to track the use of the medicine and communicate the data in a closed loop system. While the disclosed embodiments described in this patent document are primarily based on systems, devices and techniques to inject insulin, e.g., in order to facilitate understanding of the underlying concepts, it is understood that the disclosed embodiments can also be used for injection of other medicines.
In one embodiment of the disclosed technology, a device can include a mechanical dose setting and dispensing mechanism with integrated electronics to monitor and display the use of the medicine and communicate the data in a closed loop system. For example, the exemplary medicine injection device can include a housing configured to include a curved channel, a medicine cartridge holder coupled to the housing (e.g., via a pivot joint), in which the cartridge holder includes a chamber structured to encase a cartridge containing a medicine and having a first opening that aligns with one end of the curved channel and a second opening at the opposite end of the chamber, and a dose setting and injecting mechanism. The dose setting and injection mechanism can include (i) a spine component housed in the curved channel of the housing, the spine component including a plurality of link structures linked together to allow curved movement of the spine component within the curved channel, in which the one end of the curved channel includes a channel opening interlaced with the first opening to enable the spine component to push against the medicine cartridge for dispensing a selected amount of the medicine through the second opening, (ii) a shaft component structured to include a threaded cylindrical section encased at least in part within the housing and a knob disposed at least in part outside of the housing, (iii) a gear mechanism including a rod having a first gear and a second gear which is coupled to the spine component, and a drive gear having a first gear engagement for engaging to the first gear and a second gear engagement for engaging to threads of the threaded cylindrical section of the shaft component, in which, upon engaging the first gear and the drive gear to each other, a linear movement of the shaft component moves the spine component, and (iv) a disengagement button coupled to the rod to disengage the first gear and the drive gear from each other, e.g., to allow the spine component to move independent of the shaft component. The exemplary medicine injection device can be operated such that a rotation of the shaft component moves the shaft component to a distance from the housing that corresponds selected amount of the medicine.
In some examples, the drive gear of the gear mechanism can be structured to include external threads that couple to the shaft component between threads of the threaded cylindrical section and internal threads located within a hole through the center of the drive gear, in which the drive gear moves in response to a movement of the shaft component. For example, the rod can intersect through the drive gear via the hole and be structured to include a threaded gear (e.g., the first gear) and an indentation, in which the threaded gear is capable of coupling to the drive gear between internal threads when the gear mechanism is in an engaged position. The rod can also include a second gear located between the threaded gear and the indentation. For example, the second gear of the rod can be structured to include outer threads that couple between threads of the link structures of the spine component. For example, an advancement of the disengagement button advances the rod from the engaged position to a disengaged position that disengages the drive gear from the threaded gear of the rod, e.g., allowing the spine component to move independent of the shaft component.
For example, the exemplary medicine injection device can also include a data processing unit that includes a processor and a memory unit, in which the selected dose for an injection and dispensed dose are processed as data by the processor and stored in the memory unit. For example, the exemplary medicine injection device can also include a wireless transmitter unit to transmit the data to another mobile and/or computing device or system. For example, the exemplary medicine injection device can also include an electronic display that provides the user with information including, but not limited to, a current dose setting that the device is dialed to inject, the amount of medicine previously injected from the existing loaded medicine cartridge in the device, the type of medicine in the loaded cartridge (e.g., such as the name of the drug, manufactured lot number, etc.), when to perform medicine injections, and instructions for the user about the use of the device or status of the device. For example, exemplary medicine injection device can also include an optical scanner located within the housing and coupled to the data processing unit, in which the optical scanner includes an optical sensor (e.g., a laser scanner) that can scan an identification code located on a cartridge of medicine and detect the type of medicine contained in the cartridge, e.g., which can be processed as data in the device. For example, the identification code can be configured to include bars (e.g., of varying thicknesses, spacing, opacity, color, or other parameters) that radially wrap around the cylindrical casing of the medicine cartridge. In this exemplary configuration, the optical scanner can detect the identification code in any orientation that the cartridge is placed within the cartridge holder, e.g., such that the cartridge position (rotationally) is not critical to the ability to detect the identification code.
The disclosed medicine injection device can be configured to have a small, compact size enabling convenient portability of the device, e.g., in which a user can store within one's pocket, purse, handbag, etc. For example, the cartridge holder of the disclosed device can be configured to open and close in a manner that provides ease of loading and removal of a medicine cartridge. For example, the disclosed device can be implemented as a reusable medicine dispensing pen that communicates wirelessly with other devices, e.g., such as a blood glucose monitor or mobile phone or computing device including a user interface for health management (e.g., including glucose monitoring and insulin treatments), creating a closed loop system that provides convenience and ease of use for a user to monitor analyte levels and perform drug-related treatments. For example, the closed loop system can enable the information stored on the disclosed medicine injection device to be relayed (e.g., such as the type, amount, and injection time of a medicine) to other device(s), which can store the reported information as data and utilize the stored data with other user data that can be used in health management, e.g. in real time).
As shown in
The device 100 can include a data processing unit 186 including a processor and a memory coupled to the processor. The data processing unit 186 in this example is shown to be a separate unit from the electronics unit 185 and is positioned underneath of the electronics unit 185. In other implementations, the electronics unit 185 and data processing unit 186 may be integrated into one module as a single unit. The data processing unit 186 can be configured to continuously monitor data provided by sensors configured along a travel path of a push spine component 110 of the dose setting and injecting mechanism to determine the movement of the push spine component 110 and process the data as an administered or dispensed dose of the medicine. For example, the processing unit 186 can report the dispensed dose data and/or provide alarms regarding the dose to a user on a display (e.g., via the display electronics of the electronics unit 185) on the exterior of the device 100, e.g., which can confirm to the user that a complete injection dose was administered. The data processing unit 186 can be configured to continuously monitor data provided by sensors configured along a travel path of an injection shaft component 102 of the dose setting and injecting mechanism to determine the movement of the injection shaft component 102 and process the data as a selected or set dose of the medicine to be dispensed. The sensors configured within the travel path of the injection shaft component 102 can measure the rotation and/or related (linear) translation of the injection shaft component 102 to indicate the selected dose. Exemplary sensors can include a linear encoder that can be optical, magnetic, or capacitive to perform the dose volume metering. For example, the processing unit 186 can report the selected dose data and/or provide alarms regarding the dose to a user on the display of the device 100, which can confirm to the user that the desired dose was dialed. For example, the data processing unit 186 can be in wired or wireless communication with a mobile device (e.g., such as a cell phone) or a computing device that includes a application portal featuring a user interface that the user of the device 100 can use for various functions, including, but not limited to, monitoring the status of the device 100 (e.g., such as if the device is ready to dispense the medicine, a setting value of the medicine to be dispensed, etc.), the presence of a cartridge in the cartridge holder 121, or the amount of medicine contained in the cartridge 120. Some examples for wireless communications of the device 100 include 3G wireless communication standards, 4G wireless communication standards including, LTE, WiFi, Blue tooth, Bluetooth LE, and other suitable wireless communications via radio frequency waves and other electromagnetic waves.
The dose setting and injecting mechanism can include a push spine component 110 encased in a curved channel 101a of the housing structure 101, an injection shaft component 102 having a threaded cylindrical section 102b at least partially encased within the housing structure 101 and a knob section 102a disposed at least partially outside of the housing structure 101, and a button 111 partially encased within a button casing structure 112 structured to expose a top surface of the button 111 outside of the housing structure 101. The dose setting and injecting mechanism can also include a gear mechanism to interact with the push spine component 110, the injection shaft component 102, and the button 111 and can be encased within a mechanism encasement structure 116 located within the housing structure 101. The mechanism encasement structure 116 can include multiple sections having to two joined chambers, in which one chamber includes a hollowed cylindrical chamber structured to encase at least a portion of the threaded cylindrical section 102b of the shaft component 102 and in which the other chamber is structured to fit the components of the gear mechanism.
Referring to
The schematic in
In another aspect of the disclosed technology, an integrated analyte monitoring and medicine treatment system is described for health management. In some exemplary embodiments, the system includes the disclosed medicine injection device and an analyte monitoring device (e.g., such as a glucose meter) that wirelessly communicate with a remote computerized system (e.g., server in the cloud), as well as with each other.
The cloud-based computing device 910 can include a database to store and organize data received from devices of the system 900, e.g., such as the analyte monitoring device 950, the medicine injection device 100, or a user input terminal such as the computer 930 or mobile communication device 920, among others. For example, the information stored in the database of the cloud-based computing device 910 can be shared between any or all of the devices of the system 900. In some implementations, the database can exist on other the devices of the system 900 in addition or as an alternative to residing on the cloud-based computing device 910.
In some implementations, the system 900 includes the analyte monitoring device 950 and the medicine injection device 100 in communication with each other, in which the analyte monitoring device 950 communicates with the one or more cloud-based computing devices 910. In this example, the medicine injection device 100 communicates solely with the analyte monitoring device 950, which can relay the raw data or process the data and relay the processed data from the device 100 to the cloud-based computing device 910. For example, this exemplary configuration can permit the device 100 to operate with a scaled down communication system, e.g., which may reduce the number of components included in the device 100 and improve the overall power consumption rate of the device 100.
In some implementations, the system 900 includes multiple analyte monitoring devices 950 and/or multiple medicine injection device 100 in communication with the one or more cloud-based computing devices 910. For example, it may be desirable for a user to possess multiple medicine injection devices 100 that can be kept in various locations that a user may be frequently located, e.g., such as a user's home, car, workplace, gym, etc., while keeping a single analyte monitoring device 950 on the user's person. Additionally, the user may possess multiple analyte monitoring devices 950 in various desired locations. For example, since both the analyte monitoring devices 950 and medicine injection device 100 can include a user identification mechanism that permits only authorized users to operate the device, the user's data, settings, and other features personalized to the user remain secure on the devices.
The analyte monitoring device 950 can be configured as a blood analyte meter having a compact, all-in-one lancet/strip/meter structure that enables a user to perform a test using one hand. The analyte monitoring device 950 can be configured to be cassette based, e.g., enabling a user to easily change test strip and lancet cartridges. The analyte monitoring device 950 can be configured to include web-based tracking services and wireless communication devices and components. In some implementations, the analyte monitoring device 950 includes a plurality of analyte sensors (e.g., housed in an analyte sensor cartridge) and a plurality of lancets (e.g., housed in a lancet cartridge), in which a one-handed operation of an actuator mechanism can be implemented to ready the device for a test, prick the user to extract blood to be analyzed in the test, and reset the device for another use. For example, the actuator mechanism of the analyte monitoring device can be implemented to ready the device for a test by moving an analyte sensor (e.g., a test strip) forward to expose the sensor and advancing a firing component to a position for projection of a lancet. The actuator mechanism can subsequently be implemented to project (or fire) the lancet to prick a user to draw blood for analysis in the test. The actuator mechanism can be implemented to reset the device by ejecting the test strip and returning the components of the actuator mechanism to an initial position.
For example, in one exemplary embodiment, the analyte monitoring device 950 includes an analyte sensor module configured to hold a sensor cartridge structured to store analyte sensors, the analyte sensor module including an opening from which an analyte sensor advances to a testing position to expose at least a portion of the analyte sensor to outside of the analyte testing device. The analyte monitoring device 950 includes a lancet module configured to hold a lancet cartridge structured to store lancets. And, the analyte monitoring device 950 includes an actuator, in which the actuator includes: (i) a button; (ii) a first linking component coupled to the button and the analyte sensor module, in which the first linking component moves in response to a movement of the button including a movement between a first position and a second position or a movement between the second position and a third position; (iii) a second linking component coupled to the button and the lancet module, in which the second linking component moves in response to a movement of the button between the first position and the second position; (iv) a third linking component coupled to the second linking component and moveable in response to a movement of the second linking component; and (v) a lancet projecting component coupled to the third linking component. The analyte monitoring device 950 can be implemented such that a single operation of the button moves the analyte sensor to the testing position and moves the lancet projecting component from an initial position to a cocked position for projecting a lancet.
This exemplary embodiment of the analyte monitoring device 950 can be implemented in ways that provide one or more of the following features. For example, the analyte monitoring device 950 can include a processing unit coupled to a memory unit configured to store data, in which the processing unit is configured to evaluate data obtained from the analyte sensor module, lancet module, or information derived from data out of the analyte monitoring device 950. The processing unit can be configured to send a notification to a recipient based on the evaluated data. In some implementations, the processing unit can correlate individual instances of the data with time stamps, threshold values, alerts and user-entered information, e.g., including user-entered speech and text. The analyte monitoring device 950 can include a facility configured to transmit data obtained using a wireless protocol, or in other examples, a wired path, to other devices of the system 900. For example, the processing unit can be configured to keep track of inventory of lancets and analyte sensors, both within the device 950 and outside the device 950, e.g., such as test strip and lancet cartridges previously ordered and received by the user not in use within the device. For example, the processing unit can be configured to reorder inventory of lancets and analyte sensors. In some implementations, the processing unit can be configured to store voice recordings of diary information, e.g., for supplies used or ordered, food eaten, exercise, medication taken, and estimated calories burned. For example, the processing unit can be configured to produce a prompt to direct a user to use the device 950 according to at least one of a selected time or a selected time interval. The analyte sensor module of the analyte monitoring device 950 can include a temperature sensor to monitor temperature in the analyte sensor module. The analyte monitoring device 950 can also include an LCD touch screen display, e.g., to display a user interface for the user to interact with the device. Additionally, for example, the analyte monitoring device 950 can include a work light positioned to illuminate a lancet exit hole, as well as a work light positioned to illuminate an analyte sensor exit slot. In some implementations, the analyte monitoring device 950 can include a pedometer communicatively coupled with the processing unit configured to calculate, for example, the distance a user travels, speed of travel, and/or an amount of calories burned associated with the distance traveled. In some implementations, the analyte monitoring device 950 can be docked in a docking station that provides power and data connectivity to the device. In some implementations, the analyte monitoring device 950 can include a personal emergency response system (PERS) that includes a button for alerting a third party. For example, the PERS can be configured to perform the following functions, including, but not limited to, contact a third party, identify the device, provide health data associated with a user of the device, automatically contact a third party in response to health data associated with a user of the device, notify a third party as an urgency level of an emergency, and determine identity of a third party to be contacted.
The system 900 includes a data management and interface application that can be operated to manage the data stored in the database and associated with the medicine dispensing device 100 and the analyte monitoring device 950, as well as other forms of data inputted into the system 900 (e.g., by the user). The application can be operated on any of the devices of the system 900 with the same or varying amount of controls or functionalities, for example, based on a user interface presented to the devices, e.g., such as the analyte monitoring device 950, the cloud-based computing devices 910, the mobile device 920, the computer 930, and the medicine injection device 100. In some examples, the exemplary mobile device 920 operates a mobile application including a mobile user interface that is adapted for the particular mobile device.
The user interface of the data management and interface application in the system 900 is configured to provide a functional interface for a user to manage health information. For example, the application provides a health information and management interface that includes several interactive features that display information, e.g., including analyzed health information, and allow a user to input data. For example, the exemplary user health information and management interface can include a presentation of the data from the analyte monitor device 950 (e.g., raw data, analyzed data, and/or summary data), data from the medicine injection device 100 (e.g., raw data, analyzed data, and/or summary data), and data received as input from a user of the application interface.
In some exemplary embodiments, the application includes a user interface that can be accessed by each of a variety of users, e.g., including a patient (e.g., a diabetic person), a caregiver (e.g., a nurse or doctor or family member), and a payer (e.g., an insurance company) to facilitate the sharing of information and to enhance the quality of care. For example, the UI of the application can be configured differently for each type of user. The application of the system 900 can be configured in a variety of modules, e.g., in which each module can include a distinct user interface or include an inclusive user interface for some or all of the modules. For example, in some implementations, the application includes a UI for analyte monitoring (e.g., glucose level monitoring), a UI for medicine dispensing (e.g., insulin dose injections), a UI for lifestyle tracking (e.g., diet, exercise, etc.), and a UI for user information. In one example, an analyte monitoring user interface can be presented on any of the devices of the system 900 to enable the user to identify individual patterns and changes in the level of analytical substances found in a bodily fluid (e.g., blood, saliva, or urine) of a patient, as well as guide (e.g., provide pertinent info/test data to support guidance) the user (e.g., patient, care taker, doctor, etc.) as to what actions to take based on the analyte level, e.g., such as the timing and dosage of a medication, meal planning, physical activities, or other interventions. For example, the application can include an inclusive UI with viewable information to the user providing the analyzed analyte level and/or dispensed medicine data, tags and details, user goal information, selectable sub categories (e.g., including, but not limited to, nutrition information such as carbohydrates, steps, exercise, and goal information), selectable data history information, personalized settings, and flagging/data storing/questions settings.
The exemplary health management application of the system 900 can be used to identify a pattern (or patterns) or a threshold (e.g., maximum or minimum) that are analyzed from the analyte monitoring data or obtained as input from the user. For example, such data patterns and thresholds can include an analyte testing regime pattern, a medicine injection regime pattern, a hypo- or hyper-blood analyte level pattern or threshold, a pattern of variability in analyzed or input data, and a comparative pattern to a particular standard. For example, the inclusion of such a variety of information can be displayed on a single display of any of the devices of the system 900, which greatly enhances the user's experience and provides functionalities that would not have been possible, or readily discernible, from data that is dispersed throughout multiple plots, or lists, etc. Based on an identified pattern or threshold, alerts or messages can be generated by the exemplary health management system 900 and displayed on a screen of any of the devices of the system 900, e.g., such as the analyte monitoring device 950, the cloud-based computing devices 910, the mobile device 920, the computer 930, and the medicine injection device 100. Other types of messages can also be generated for the user, e.g., including, but not limited to, reminders, encouraging messages, factoids, etc.
For example, actual analyte levels and fluctuations therein can be easily correlated to one or more of the factors presented to the user using the UL For example, fluctuations in analyte levels can be correlated to a variety of factors, e.g., including, but not limited to, consumption of nutrients, injection of a particular medicine and other medications taken by the patient for other conditions outside the condition being monitored, a patient's exercise schedule, a patient's stress, sickness, and other factors that may be inputted health information and management interface. By providing such a detailed and comprehensive picture on a single display screen, e.g., with a properly selected granularity, the system 900 enables a user to determine the effects of a particular factor on the patient's analyte levels. Further, such correlations can be further analyzed to set alerts (or alarms or reminders) to predict, prevent and/or mitigate adverse effects of such factors before the analyte levels reach a critical limit. In some embodiments, a caregiver is alerted to a particular analyte level fluctuations through a text message, a phone call, an email or other communication methods.
The application of the system 900 provide the following exemplary features that are operated on and/or displayed on, for example, the analyte monitoring device 950 and/or the medicine injection device 100. The exemplary features include, but are not limited to: (1) event time stamping and updating to database (e.g., including time stamping data associated with an analyte level test, injection, status of devices, or user inputted data such as exercise, meals, moments of stress, illness, or other types of data); (2) event displaying to the user through the UI, in which the events are stored in a running log in the database; (3) displaying motivational messages and images before and/or after test results; (4) temperature checking of the analyte test module (e.g., to confirm safe exposure of the analyte test strips, as extreme high or low temperatures can damage stored strips); (5) comparative data checking with control results data; (6) consumables/disposables monitoring, e.g., of the test strips and lancets of the analyte monitoring device 950 and/or the medicine level in the medicine cartridge loaded in the cartridge holder of the medicine injection device 100; (7) providing tutorials (e.g., such as animations educating the user on testing/injecting procedure); (8) authenticating a user prior to any or certain operations of the device; and (9) providing emergency contact information (e.g., such as 911, emergency respondents, and user-identified contacts, such as family), as well as, in some implementations, alerting identified persons or entities in case of emergency. For example, the application can keep track of unused and used consumables/disposables by the device 950 and/or the device 100, keep track of ordered (and unused) consumables/disposables in the user's possession, as well as keep track of remaining stock (e.g., packages) by manufacturers that the application is in communication with (e.g., using the internet). For example, the application can contact the manufacturers of such consumables/disposables when the user's remaining stock is low and re-order the consumables/disposables, e.g., by communicating using links to e-commerce.
Implementations of the subject matter and the functional operations described in this patent document can be implemented in various systems, digital electronic circuitry, or in computer software, firmware, or hardware, including the structures disclosed in this specification and their structural equivalents, or in combinations of one or more of them. Implementations of the subject matter described in this specification can be implemented as one or more computer program products, i.e., one or more modules of computer program instructions encoded on a tangible and non-transitory computer readable medium for execution by, or to control the operation of, data processing apparatus. The computer readable medium can be a machine-readable storage device, a machine-readable storage substrate, a memory device, a composition of matter effecting a machine-readable propagated signal, or a combination of one or more of them. The term “data processing apparatus” encompasses all apparatus, devices, and machines for processing data, including by way of example a programmable processor, a computer, or multiple processors or computers. The apparatus can include, in addition to hardware, code that creates an execution environment for the computer program in question, e.g., code that constitutes processor firmware, a protocol stack, a database management system, an operating system, or a combination of one or more of them.
A computer program (also known as a program, software, software application, script, or code) can be written in any form of programming language, including compiled or interpreted languages, and it can be deployed in any form, including as a standalone program or as a module, component, subroutine, or other unit suitable for use in a computing environment. A computer program does not necessarily correspond to a file in a file system. A program can be stored in a portion of a file that holds other programs or data (e.g., one or more scripts stored in a markup language document), in a single file dedicated to the program in question, or in multiple coordinated files (e.g., files that store one or more modules, sub programs, or portions of code). A computer program can be deployed to be executed on one computer or on multiple computers that are located at one site or distributed across multiple sites and interconnected by a communication network.
The processes and logic flows described in this specification can be performed by one or more programmable processors executing one or more computer programs to perform functions by operating on input data and generating output. The processes and logic flows can also be performed by, and apparatus can also be implemented as, special purpose logic circuitry, e.g., an FPGA (field programmable gate array) or an ASIC (application specific integrated circuit).
Processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer. Generally, a processor will receive instructions and data from a read only memory or a random access memory or both. The essential elements of a computer are a processor for performing instructions and one or more memory devices for storing instructions and data. Generally, a computer will also include, or be operatively coupled to receive data from or transfer data to, or both, one or more mass storage devices for storing data, e.g., magnetic, magneto optical disks, or optical disks. However, a computer need not have such devices. Computer readable media suitable for storing computer program instructions and data include all forms of nonvolatile memory, media and memory devices, including by way of example semiconductor memory devices, e.g., EPROM, EEPROM, and flash memory devices. The processor and the memory can be supplemented by, or incorporated in, special purpose logic circuitry.
While this patent document contains many specifics, these should not be construed as limitations on the scope of any invention or of what may be claimed, but rather as descriptions of features that may be specific to particular embodiments of particular inventions. Certain features that are described in this patent document in the context of separate embodiments can also be implemented in combination in a single embodiment. Conversely, various features that are described in the context of a single embodiment can also be implemented in multiple embodiments separately or in any suitable subcombination. Moreover, although features may be described above as acting in certain combinations and even initially claimed as such, one or more features from a claimed combination can in some cases be excised from the combination, and the claimed combination may be directed to a subcombination or variation of a subcombination.
Similarly, while operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results. Moreover, the separation of various system components in the embodiments described in this patent document should not be understood as requiring such separation in all embodiments.
Only a few implementations and examples are described and other implementations, enhancements and variations can be made based on what is described and illustrated in this patent document.
Claims
1. A health management system, comprising:
- an analyte monitoring device configured to determine a concentration level of an analyte;
- a computing system in communication with the analyte monitoring device, the computing system comprising: (a) a memory unit; and (b) a processor configured to process data; and
- a medicine injection device in communication with at least one of the analyte monitoring device or the computing system.
2. The system of claim 1, wherein the computing system is further configured to transmit and/or receive at least one of: (a) data obtained from the analyte monitoring device, (b) data obtained from the medicine injection device, or (c) information derived from data from a user-operated computing device, based on a wireless or wired communication protocol.
3. The system of claim 1, wherein the processor is configured to keep track of inventory of lancets and analyte sensors in the analyte monitoring device.
4. The system of claim 3, wherein the processor is configured to reorder the inventory of one or both of the lancets and the analyte sensors from a lancet or analyte sensor manufacturer.
5. The system of claim 1, wherein the processor is configured to produce a prompt to direct a user to use one or both of the analyte monitoring device and the medicine injection device at a predetermined time or time interval.
6. The system of claim 1, wherein the computing system is configured to process and store user input data selected from the group consisting of: supplies used, supplies ordered, food eaten, duration, type and/or intensity of an exercise, type, dosage, and/or time of medication taken, and estimated calories burned.
7. The system of claim 1, wherein the medicine injection device comprises:
- (a) a housing;
- (b) a cartridge holder coupled to the housing, the cartridge holder including a chamber structured to encase a cartridge containing a medicine and having an opening configured to receive a cartridge containing a medicine; and
- (c) an injecting mechanism including: (i) a component configured to push against the cartridge for dispensing a selected amount of the medicine; (ii) a gear mechanism including a drive gear and one or more other gears, wherein the drive gear has at least one engagement mechanism for engaging to at least one of the one or more other gears, wherein the drive gear is configured to advance the component configured to push against the cartridge; and (iii) a button coupled to the gear mechanism and disposed at least in part outside of the housing, wherein linear advancement of the button moves the drive gear.
8. The system of claim 1, wherein the medicine injection device comprises:
- (a) a housing;
- (b) a cartridge holder coupled to the housing, the cartridge holder including a chamber structured to encase a cartridge containing a medicine and having an opening configured to receive a cartridge containing a medicine;
- (c) a component configured to push against the cartridge for dispensing a selected amount of the medicine;
- (d) a sliding button coupled to the component configured to push against the cartridge and disposed at least partially outside of the housing such that movement of the sliding button is configured to move the component configured to push against the cartridge.
9. The system of claim 1, wherein the medicine injection device further comprises a data processing unit, comprising:
- a processor; and
- a memory coupled to the processor,
- wherein at least one of a selected amount of medicine or a dispensed amount of medicine is processed as data by the processor and stored in the memory.
10. The system of claim 9, wherein the medicine injection device further comprises an optical scanner coupled to the data processing unit and configured to scan an identification code located on an external surface of a cartridge containing medicine when the cartridge is engaged to the medicine injection device, wherein the identification code corresponds to information about the medicine contained in the cartridge.
11. The system of claim 9, wherein one or more of the medicine injection device and the analyte monitoring device further comprise a display unit to display data.
12. The system of claim 9, wherein the medicine injection device further comprises injection sensors configured to measure at least one of rotation or linear movement to indicate the selected dose, wherein the injection sensors are in communication with the data processing unit.
13. The system of claim 11, wherein the injection device comprises a display unit to display data, wherein the display unit is configured to display one or more of: a current dose setting that the device is dialed to inject, an amount of medicine previously injected from a medicine cartridge engaged to the injection device, a type of medicine in the cartridge, instructions for when to perform a medical injection, instructions about the use of the injection device, or instructions about the status of the injection device.
14. The system of claim 12, wherein the injection sensors include at least one of an optical linear encoder, a magnetic linear encoder, or a capacitive linear encoder.
15. The system of claim 1, wherein one or more of the analyte monitoring device, the computing system, and the medicine injection device include a user identification mechanism that permits only authorized users to operate the device and access data.
16. The system of claim 1, wherein the processor is configured to correlate data with one or more of time stamps, threshold values, alerts, and user entered information.
17. The system of claim 1, wherein the processor is configured to store voice recordings.
18. The system of claim 1, wherein the analyte monitoring device further comprises a temperature sensor module.
19. The system of claim 1, further comprising a pedometer, wherein the pedometer is communicatively coupled to the processor, wherein the processor is configured to calculate one or more: distance traveled, speed of travel, or an amount of calories associated with distance traveled.
20. The system of claim 1, wherein the analyte monitoring device further comprises an emergency response system, wherein the emergency response system is configured to perform one or more of: contacting a third party, identifying the analyte monitoring device, providing health data associated with a user of the analyte monitoring device, notifying a third party of an urgency level of an emergency, and determining an identity of a third party to be contacted.
21. The system of claim 1, further comprising a user interface configured to provide health information and allow user input, wherein the user interface can be accessed by one or more of: a patient, a caregiver, and a payer.
22. The system of claim 21, wherein the user interface includes one or more modules, the one or more modules including one or more of: analyte monitoring, medicine dispensing, lifestyle tracking, and user information.
23. A method for operating a medicine injection device to dispense medicine comprising:
- inserting a cartridge containing a medicine into a cartridge holder coupled to a housing of a medicine injection device;
- selecting a dose of the medicine for injection;
- linearly advancing a button coupled to at least one gear and disposed at least in part outside of the housing, wherein linear advancement of the button moves the at least one gear;
- and rotating the at least one gear to drive a movable component so as to push the end of the cartridge to dispense the medicine in the amount of the selected dose.
24. The method of claim 23, further comprising displaying on a display of the device the corresponding dose during the selecting.
25. The method of claim 23, further comprising optically scanning an identification code that includes a plurality of bars wrapped radially around the external surface of the cartridge when the cartridge is inserted in the cartridge holder, wherein the identification code corresponds to information about the medicine contained in the cartridge.
26. The method of claim 23, further comprising wirelessly communicating information related to the dispensed dose to another device or system.
27. A device to dispense a medicine, comprising:
- a housing;
- a cartridge holder coupled to the housing, the cartridge holder including a chamber structured to encase a cartridge containing a medicine and having an opening configured to receive a cartridge containing a medicine;
- an injecting mechanism including: (i) a component configured to push against the cartridge for dispensing a selected amount of the medicine; (ii) a gear mechanism including a drive gear and one or more other gears, wherein the drive gear has at least one engagement mechanism for engaging to at least one of the one or more other gears, wherein the drive gear is configured to advance the component configured to push against the cartridge; and (iii) a button coupled to the gear mechanism and disposed at least in part outside of the housing, wherein linear advancement of the button moves the drive gear; and
- a data processing unit, comprising: a processor; and a memory coupled to the processor, wherein at least one of a selected amount of medicine or a dispensed amount of medicine is processed as data by the processor and stored in the memory.
28. The device of claim 27, further comprising an optical scanner coupled to the data processing unit and configured to scan an identification code located on an external surface of a cartridge containing medicine when the cartridge is engaged to the medicine injection device, wherein the identification code corresponds to information about the medicine contained in the cartridge.
29. The device of claim 27, further comprising a wireless transmitter unit to transmit the data to a computing device.
30. The device of claim 27, further comprising sensors configured to measure at least one of rotation or linear movement to indicate the selected dose, wherein the injection sensors are in communication with the data processing unit.
Type: Application
Filed: Apr 8, 2016
Publication Date: Aug 4, 2016
Inventors: Gad Shaanan (La Jolla, CA), Marc Goldman (La Jolla, CA)
Application Number: 15/094,886