A Dose Counting System

TECHNICAL FIELD

The present disclosure relates to a dose counting system of an injection device or of a module configured to be used with or applied to an injection device and a method of operating the dose counting system.

BACKGROUND

A variety of diseases exists that require regular treatment by injection of a medicament. Such injection can be performed by using injection devices, which are applied either by medical personnel or by patients themselves. As an example, type1 and type2 diabetes can be treated by patients themselves by injection of insulin doses, for example once or several times per day. For instance, a prefilled disposable insulin pen can be used as an injection device. Alternatively, a reusable pen may be used. A reusable pen allows replacement of an empty medicament cartridge by a new one. Either pen may come with a set of one-way needles that are replaced before each use. The insulin dose to be injected can then for instance be manually selected at the insulin pen by turning a dosage knob and observing the actual dose from a dose window or display of the insulin pen. The dose is then injected by inserting the needle into a suited skin portion and pressing an injection button of the insulin pen. To be able to monitor insulin injection, for instance to prevent false handling of the insulin pen or to keep track of the doses already applied, it is desirable to measure information related to a condition and/or use of the injection device, such as for instance information on the injected insulin dose.

WO2019/101962A1 describes an injection device comprising a movable dosage programming component comprising a rotary encoder system having a predefined angular periodicity, a sensor arrangement comprising a first optical sensor configured to detect movement of the movable dosage programming component relative to the sensor arrangement during dosing of a medicament and a second optical sensor configured to detect movement of the rotary encoder system relative to the second optical sensor. The first optical sensor is configured to operate in a strobe-sampling mode at a first frequency and the second optical sensor is configured to operate in a strobe-sampling mode at a second frequency lower than the first frequency. The injection device also comprises a processor arrangement configured to, based on said detected movement, determine a medicament dosage administered by the injection device. WO2019/101962A1 further describes a method for processing signals generated by the sensor arrangement with two optical sensors arranged with a 180° shift such that the signal of the first sensor of the two sensors and the signal of the second sensor of the two sensors are in anti-phase. The method comprises the steps of setting a high threshold and a low threshold for the signal of the first sensor and for the signal of the second sensor, respectively, and counting a unit of a dose selected with the movable dosage programming component if the signal of the second sensor passes the high threshold and thereafter passes the low threshold, and thereafter the signal of the first sensor passes the low threshold and thereafter passes the high threshold.

SUMMARY

A first aspect disclosed herein requires a dose counting system of an injection device or of a module configured to be used with or applied to an injection device. The dose counting system includes:

- a sensor arrangement comprising a first sensor configured to output a first signal and a second sensor configured to output a second signal, wherein the first sensor and the second sensor have an angular offset relative to each other and wherein the sensor arrangement is configured to detect movement of a rotary encoder system relative to the respective sensor arrangement during dosing of a medicament; and
- a processor configured to:
  - compute numerical derivatives of the first signal and the second signal;
  - detect a peak in the derivative values of the first signal and a peak in the derivative values of the second signal when the first and second derivative signal values exceed a predefined threshold;
  - determine that a unit of medicament has been administered when the peaks in the derivative values of the first signal and the derivative values of the second signal are simultaneous, the peak in the derivative values of the first signal has a different sign from the peak in the derivative values of the second signal and the peak in the derivative values of the first signal has a different sign for the previous peak in the derivative values of the first signal; and
  - determine a medicament dosage administered by the injection device by counting the administered units of medicament.

The processor may be further configured to calculate a moving average of a series of values of the first signal and the second signal.

The moving average may comprise a mean of a first set of values minus a mean of a second set of values of the same sensor wherein the first and second sets contain the same number of values. The first and second set may be overlapping.

Alternatively, the processor may be further configured to calculate a moving median of a series of values of the first signal and the second signal. The moving median may comprise a median value of a first set of values minus a median value of a second set of values, wherein the first and second sets contain the same number of values. The first and second set may be overlapping.

The injection device may comprise an injection button configured to be pressed in order to administer a dose of medicament from the injection device. The processor may be further configured to determine that the injection button has been pressed or released when the peaks in the first signal and the second signal have the same sign.

The processor may be further configured to, in response to determining that the injection button has been pressed, initiate a communication pairing with an external device or execute a data synchronisation with the external device. The communication pairing may be a Bluetooth pairing.

The processor may be further configured to, in response to determining that the injection button has been released, initiate a manual data synchronisation.

The processor may be further configured to, in response to determining that the injection button has been released, cause an end of dose indication to be outputted.

The rotary encoder system may comprise an encoder ring comprising a plurality of substantially light reflective flags arranged circumferentially around the encoder ring in accordance with the predefined angular periodicity.

A second aspect disclosed herein requires a method of operating a dose counting system of an injection device or of a module configured to be used with or applied to an injection device. The dose counting system includes:

- a sensor arrangement comprising a first sensor configured to output a first signal and a second sensor configured to output a second signal, wherein the first sensor and the second sensor have an angular offset relative to each other and wherein the sensor arrangement is configured to detect movement of a rotary encoder system relative to the respective sensor arrangement during dosing of a medicament; and
- a processor;
- wherein the method comprises:
  - computing numerical derivatives of the first signal and the second signal;
  - detecting a peak in the derivative values of the first signal and a peak in the derivative values of the second signal when the first and second derivative signal values exceed a predefined threshold;
  - determining that a unit of medicament has been administered when the peaks in the derivative values of the first signal and the derivative values of the second signal are simultaneous, the peak in the derivative values of the first signal has a different sign from the peak in the derivative values of the second signal and the peak in the derivative values of the first signal has a different sign for the previous peak in the derivative values of the first signal;
  - determining a medicament dosage administered by the injection device by counting the administered units of medicament.

The method of the second aspect may further include calculating a moving average of a series of values of the first signal and the second signal.

BRIEF DESCRIPTION OF THE FIGURES

So that the general concepts set out in the foregoing sections can be more fully understood, embodiments thereof will be described with reference to the accompanying figures, in which:

FIG. 1 shows an injection device according to a first embodiment;

FIG. 2 is a schematic block diagram of a dose counting system;

FIG. 3A is an elevated side view of a first type of encoder system;

FIG. 3B is a plan view of the encoder system shown in FIG. 3A;

FIG. 4A is an elevated side view of a second type of encoder system;

FIG. 4B is a plan view of the encoder system shown in FIG. 4A;

FIG. 5A is an elevated side view of an eight type of encoder system;

FIG. 5B is a plan view of the encoder system shown in FIG. 5A;

FIG. 6 is a detailed view on an encoder system;

FIG. 7 shows the course of signal voltages generated by two optical sensors of a sensor arrangement during movement of a movable dosage programming component relative to the sensor arrangement when a dosage is dispensed with an injection device and derivate signals; and

FIG. 8 shows the course of signal voltages generated by two optical sensors of a sensor arrangement during depression and release of the dose button with no dose dialled in and derivate signals; and

FIG. 9 illustrates a Gray code output with an optical dose counting system having an alternative arrangement.

DETAILED DESCRIPTION

In the following, embodiments will be described with reference to an insulin injection device. The present disclosure is however not limited to such application and may equally well be deployed with injection devices that eject other medicaments.

Embodiments are provided in relation to injection devices, in particular to variable dose injection devices, which record and/or track data on doses delivered thereby. These data may include the size of the selected dose, the time and date of administration, the duration of the administration and the like. Features described herein include the arrangement of sensing elements, power management techniques (to facilitate small batteries) and a trigger switch arrangement to enable efficient power usage.

Certain embodiments in this document are illustrated with respect to Sanofi's an injection device where an injection button and grip are combined. The mechanical construction of such an injection device is described in detail in the international patent application WO2014/033195A1, which is incorporated herein by reference. Other injection devices with the same kinematical behaviour of the dial extension and trigger button during dose setting and dose expelling operational mode are known as, for example, the Kwikpen® device marketed by Eli Lilly and the Novopen® device marketed by Novo Nordisk. An application of the general principles to these devices therefore appears straightforward and further explanations will be omitted. However, the general principles of the present disclosure are not limited to that kinematical behaviour. Certain other embodiments may be conceived for application to an injection device where there are separate injection button and grip components like the device described in WO2004078239. The embodiments described in this document may be particularly based on the embodiments described in WO2019/101962A1, which is incorporated herein by reference.

In the following discussion, the terms “distal”, “distally” and “distal end” refer to the end of an injection device towards which a needle is provided. The terms “proximal”, “proximally” and “proximal end” refer to the opposite end of the injection device towards which an injection button or dosage knob is provided.

FIG. 1 from WO2019/101962A1 is an exploded view of a medicament delivery device. In this example, the medicament delivery device is an injection device 1, such as the injection pen described in WO2014/033195A1.

The injection device 1 of FIG. 1 is a prefilled, disposable injection pen that comprises a housing 10 and contains an insulin container 14, to which a needle 15 can be affixed. The needle is protected by an inner needle cap 16 and either an outer needle cap 17 other cap 18. An insulin dose to be ejected from injection device 1 can be programmed, or ‘dialled in’ by turning a dosage knob 12, and a currently programmed dose is then displayed via dosage window 13, for instance in multiples of units. For example, where the injection device 1 is configured to administer human insulin, the dosage may be displayed in so-called International Units (IU), wherein one IU is the biological equivalent of about 45.5 micrograms of pure crystalline insulin ( 1/22 mg). Other units may be employed in injection devices for delivering analogue insulin or other medicaments. It should be noted that the selected dose may equally well be displayed differently than as shown in the dosage window 13 in FIG. 1.

The dosage window 13 may be in the form of an aperture in the housing 10, which permits a user to view a limited portion of a dial sleeve 70 that is configured to move when the dosage knob 12 is turned, to provide a visual indication of a currently programmed dose. The dosage knob 12 is rotated on a helical path with respect to the housing 10 when turned during programming.

In this example, the dosage knob 12 includes one or more formations 71a, 71b, 71c to facilitate attachment of a data collection device.

The injection device 1 may be configured so that turning the dosage knob 12 causes a mechanical click sound to provide acoustical feedback to a user. The dial sleeve 70 mechanically interacts with a piston in insulin container 14. In this embodiment, the dosage knob 12 also acts as an injection button. The dosage knob may house a separate depressible button, or may be an unitary component which the user presses on to effect a dosing process. When needle 15 is stuck into a skin portion of a patient, and then dosage knob 12 is pushed in an axial direction, the insulin dose displayed in display window 13 will be ejected from injection device 1. When the needle 15 of injection device 1 remains for a certain time in the skin portion after the dosage knob 12 is pushed, a high percentage of the dose is actually injected into the patient's body. Ejection of the insulin dose may also cause a mechanical click sound, which is however different from the sounds produced when rotating the dosage knob 12 during dialling of the dose.

In this embodiment, during delivery of the insulin dose, the dosage knob 12 is returned to its initial position in an axial movement, without rotation, while the dial sleeve 70 is rotated to return to its initial position, e.g. to display a dose of zero units.

Injection device 1 may be used for several injection processes until either the insulin container 14 is empty or the expiration date of the medicament in the injection device 1 (e.g. 28 days after the first use) is reached.

Furthermore, before using injection device 1 for the first time, it may be necessary to perform a so-called “prime shot” to remove air from insulin container 14 and needle 15, for instance by selecting two units of insulin and pressing dosage knob 12 while holding injection device 1 with the needle 15 upwards. For simplicity of presentation, in the following, it will be assumed that the ejected amounts substantially correspond to the injected doses, so that, for instance the amount of medicament ejected from the injection device 1 is equal to the dose received by the user. Nevertheless, differences (e.g. losses) between the ejected amounts and the injected doses may need to be taken into account.

As explained above, the dosage knob 12 also functions as an injection button so that the same component is used for dialling and dispensing.

FIGS. 3A and 3B show an encoder system 500 according to certain embodiments. The encoder system may be configured for use with the injection device 1 described above. As shown in FIG. 3A and FIG. 3B, the primary sensor 215a and secondary sensor 215b are configured to target specially adapted regions at the proximal end of the dial sleeve 70. In this embodiment, the primary sensor 215a and secondary sensor 215b are infrared (IR) reflective sensors. Therefore, the specially adapted proximal regions of the dial sleeve 70 are divided into a reflective area 70a and a non-reflective (or absorbent) area 70b. The part of the dial sleeve 70 comprising the reflective area 70a and a non-reflective (or absorbent) area 70b may be termed an encoder ring.

Having two sensors facilitates a power management technique described below. The primary sensor 215a is arranged to target a series of alternating reflective regions 70a and non-reflective regions 70b at a frequency commensurate with the resolution required for the dose history requirements applicable to a particular drug or dosing regime, for example, 1 IU. The secondary sensor 215b is arranged to target a series of alternating reflective regions 70a and non-reflective regions 70b at a reduced frequency compared to the primary sensor 215a. It should be understood that the encoder system 500 could function with only a primary sensor 215a to measure the dispensed dose. The secondary sensor 215b facilitates the power management technique described below.

The two sets of encoded regions 70a, 70b are shown in FIGS. 3A and 3B concentrically with one external and the other internal. However, any suitable arrangement of the two encoded regions 70a, 70b is possible. Whilst the regions 70a, 70b are shown as castellated regions, it should be borne in mind that other shapes and configurations are possible.

A dose counting system 700 is shown schematically in FIG. 2. The dose counting system 700 may be an integral part of the injection device 1 or part of a module configured to be attached to the injection device 1. The dose counting system 700 comprises a processor arrangement 23 including one or more processors, such as a microprocessor, a Digital Signal Processor (DSP), Application Specific Integrated Circuit (ASIC), Field Programmable Gate Array (FPGA) or the like, together with memory units 24, 25, including program memory 24 and main memory 25, which can store software for execution by the processor arrangement 23.

The dose counting system 700 controls a sensor arrangement 215, comprising one or more sensors 215a, 215b.

An output 27 is provided, which may be a wireless communications interface for communicating with another device via a wireless network such as Wi-Fi or Bluetooth®, or an interface for a wired communications link, such as a socket for receiving a Universal Series Bus (USB), mini-USB or micro-USB connector. For example, data may be output to a data collection device attached to the device 1.

A power switch 28 is also provided, together with a battery 29.

Power Management

It is advantageous to be able to minimise the power usage of the dose counting system 700 so that the size of a battery 29 needed to be packaged into the device 1 can be minimised. The sensors 215a, 215b used in this embodiment require a certain amount of power to operate. This embodiment is arranged such that the sensors 215a, 215b can be switched on and off intermittently at a controlled frequency (i.e. in a strobe-sampling mode). There is inherently a limit to the maximum rotational speed that can be counted by a sampled encoder system before aliasing occurs. Aliasing is the phenomenon where the sampling rate is less than the rate at which sensed regions pass the sensor which means that a miscount could occur when a region change is missed. The secondary sensor 215b with a reduced frequency compared to the primary frequency 215a can tolerate a higher rotational speed before it too becomes aliased. Whilst the secondary sensor 215b is not able to resolve the dose dispensed to the same resolution as the primary sensor 215a, the output of the secondary sensor 215b remains reliable at higher speeds. Therefore both sensors 215a, 215b are used in combination to be able to accurately determine dose delivered up to a first threshold rotational (dispensing) speed. The sensors 215a, 215b can then be used to determine an approximate dose delivered up to a second (higher) threshold dosing speed. At speeds above the second threshold speed the sensors 215a, 215b will not be able to accurately or approximately determine the dose delivered, therefore the second threshold is set above a speed which is not physically possible in the injection device 12.

The first speed threshold is determined by the sampling rate of primary sensor 215a and the frequency of encoder region transitions, which is fixed at the resolution required by the intended drug or dosing regime (for example one transition per 1 IU). The second speed threshold is determined by the sampling rate of the secondary sensor 215b and the frequency of encoder region transitions. The first threshold is set such that the largest range of dispensing speeds can be covered by the system for accurate reporting of dose dispensed.

The example embodiment shown in FIG. 3B has primary sensor 215a targeting region transitions at 1 transition per 1 IU of dose delivered and the secondary sensor 215b targeting region transitions at 1 transition per 6 IU of dose delivered. Other options are possible which include 1 transition per 2 IU, 1 transition per 4 IU, 1 transition per 8 IU and 1 transition per IU units. These options are each possible because there are 24 separate regions 70a, 70b per revolution in the encoder system 500 shown in FIG. 3B. In general, if the number of separate regions 70a, 70b per revolution were n units then there would be options at one region transition per m units where m was any integer factor of n greater than 1 and less than n.

The slower the sampling frequency of both sensors 215a, 215b, the lower the power consumption required and therefore the smaller the required size of the battery 29. It is therefore optimal to minimise, by design, the sampling frequency as far as is practical.

The following embodiments relate to an alternative sensing technique to determine the number of medicament units that have been dispensed from the device 1.

As with the embodiments described above, two sensors 215 are mounted in the injection button 12 and are configured to sense the relative rotational position of the dial sleeve 70 relative to the injection button during the dispensing of a dose. This relative rotation can be equated to the size of the dose dispensed and used for the purpose of generating and storing or displaying dose history information.

As shown in FIG. 4A, the two sensors 215 from this embodiment are configured to target specially adapted regions 70a, 70b of the dial sleeve 70. In this embodiment IR reflective sensors are used, therefore the regions of the dial sleeve 70 are divided into reflective and absorbent segments 70a, 70b. The segments 70a, 70b may also be referred to herein as flags.

Unlike the encoder system 500 described above in relation to FIGS. 3A and 3B, the encoder system 900 shown in FIGS. 4A and 4B has both IR sensors 215 target the same type of region 70a, 70b. In other words, the sensors 215 are arranged so that they both face reflective regions 70a or both face absorbent regions 70b at the same time. During the dispensing of a dose, the dial sleeve 70 rotates anti-clockwise 15° relative to the injection button 12 for every medicament unit that has been dispensed. The alternate flag elements are in 30° (or two unit) sections. The sensors 215 are arranged to be out of phase with each other, such that the angle between them equates to an odd number of units (e.g. 15°, 45°, 75°, etc.), as shown in FIG. 4B.

The encoder system 900 shown in FIG. 4B has 12 units per revolution, i.e. 12 alternating regions 70a, 70b. In general, embodiments work with any multiple of 4 units per revolution. The angle, a, between sensors 215 can be expressed by Equation 1, where both m and n are any integers and there are 4 m units dispensed per revolution.

$\begin{matrix} α = (2 n - 1) \begin{matrix} 360 \\ 4 m \end{matrix} & Equation 1 \end{matrix}$

$Angle between sensors$

FIG. 10 shows how the outputs for a Sensor A and Sensor B change as the dial sleeve 70 rotates anti-clockwise during dispensing of a medicament.

In combination, the two sensors A, B produce a 2-bit Gray code output (11, 01, 00, 10). The 2-bit code sequence repeats every four units dispensed. This coded output facilitates the detection of positive (anticlockwise) and negative (clockwise) rotations. For example, when the sensors read ‘11’ a change to ‘01’ would be a positive rotation and the change to ‘10’ would be a negative rotation. This directionally sensitive system has advantages over a purely incremental system, in the ability to accurately determine true dispensed dose volume in the cases where negative rotations can occur. For example, in mechanisms that over rotate at the end of dose stop before ‘backing-off’ when the user releases the injection button 12.

An encoder system according to further embodiments will now be described with reference to FIGS. 5A and 5B. This encoder system may be used to record doses that are delivered from the injection device. The concept of this encoder system is based on a light guide used to convey the status of an indicator flag to a reflective sensor, which is located physically remote to the flag. The embodiments shown in FIGS. 5A and 5B use an optical add-on module configured to be attached to an injection device. For simplicity, the housing of the add-on module is omitted and only the sensor and optical components are shown in FIGS. 5A and 5B. The add-on module also contains a dose counting system 700, such as that shown in FIG. 2. Such an add-on module may be configured to be added to a suitably configured pen injection device for the purpose of recording doses that are dialled and delivered from the device. The add-on module may be configured to replace the dialling knob/injection button of an injection pen, or alternatively may fit over the existing dialling knob/injection button. In these embodiments, the indicator flag is formed by a relative rotation of a number sleeve or the dial sleeve and the add-on module, the latter of which houses at least one optical sensor. This functionality may be of value to a wide variety of device users as a memory aid or to support detailed logging of dose history. The add-on module may be configured to be connectable to an external device such as a smartphone or a tablet PC, or similar, to enable the dose history to be downloaded from the module on a periodic basis. However, the concept of the encoder system is also applicable to any device with the indicator flag and sensor separation, for example the injection device 1 of FIG. 1, wherein the module may be implemented in the dosage knob 12, which could be removable.

According to the encoder system concept, a collimating optics is arranged between the active face of at least one optical sensor, which may be a IR reflective sensor, and a movable dosage programming component. The collimating optics may comprise one or more discrete collimating lenses and one or more light pipes. The lens geometry may be selected to parallelize (“collimate”) divergent radiation emitted by the at least one optical sensor prior to transmission through the light pipe between the at least one sensor and the target, namely the indicator flag.

FIG. 5A shows essential parts of an embodiment of a module 1000 implementing this encoder concept: an indicator flag 1008 may be formed by relative rotation of a number sleeve 1006 around a rotation axis 1010, wherein the indicator flag 1008 is implemented in the shown embodiment by radially projecting teeth, formed in the top of for example the number sleeve or the dial sleeve 70 of the injection device 1; an optical sensor 215c and collimating optics comprising two collimating lenses 1004a, 1004b and a light guidance in the form of a light pipe 1002 for conveying the status of the indicator flag 1008 to the sensor 215c which is located remote from the flag. The collimating optics 1002, 1004a, 1004b and the optical sensor 215c may be positioned relative to surrounding components within the injection device and particularly associated to an add-on module. As can be seen, the collimating optics comprising the lenses 1004a, 1004 and the light pipe 1002 are arranged between the active side, i.e. the IR emitting and receiving side of the optical sensor 215c and the indicator flag 1008 formed by the number sleeve 1006.

FIG. 5B shows a chassis 1012 housing two optical sensors 215c (represented by their locations in the chassis 1012 shown by the rectangles with bold lines) and their respective collimating lenses 1004a, 1004b according to an embodiment of a module 1000. The collimating lenses 1004a, 1004b, here implemented by discrete lenses, are envisaged to be held relative to the optical sensors 215c and proximal face of the light pipes by means of a cradle or other locating geometry existing as a feature within the chassis 1012.

All of the above points relate, fundamentally, to more robust encoding mechanical system where an optical (reflective) sensor form the active element in an optical encoder. If the motion of the number sleeve relative to the dose button is more efficiently captured, reduced emitter power of an optical sensor and the use of algorithms requiring fewer microcontroller operations can be utilized, reducing energy consumption and extending battery life. The encoder system described herein is equally applicable to inclusion in a disposable or a re-usable injection device, or any device containing an optical encoder arrangement with a similar light pipe architecture.

FIG. 6 shows a partial view of a number sleeve 400 and the arrangement of teeth or flags 402 on the number sleeve. The flags 402 are substantially light reflecting. For example, the flags 402 may be made of or coated with a reflective material, or the reflective material may be printed on the surface of the flags 402. The flags 402 are spaced by an angle of 30 degrees form each other, such that there are twelve flags 402 evenly spaced around the circumference of the number sleeve 400. FIG. 6 also shows exemplary positions of two light pipes associated with respective optical sensors, indicated by the ovals numbered 1 and 2. The light pipes are separated by an angle of 45 degrees, such that the difference between the angular separation go the light pipes and the angular separation of the flags 402 is 15 degrees and the signals from the two sensors are out of phase with each other. In some embodiments of an injection device, the number sleeve 400 is configured to rotate by 15 degrees for each unit of medicament dialled or delivered. The arrangement shown in FIG. 6 therefore allows the signals from the two sensors to be used to measure the numbered of dialled or delivered units of medicament. Although this embodiment has been described in terms of optical sensing and reflective flags, in some other embodiments inductive, capacitive or magnetic sensing may be used. For example, the flags 402 may comprise conductive or magnetic regions which pass under inductive, capacitive or magnetic sensors in order to determine the amount of rotation of the number sleeve 400.

Next, embodiments of an algorithm for processing the signals, particularly signal voltages, generated by the optical sensors of sensor arrangements as described above with regard to the injection device and the module are described. The algorithm is implemented as a computer program for execution by one or more processors, for example of the processor arrangement 23 comprised by the dose counting system 700 as shown in FIG. 2.

The algorithm is implemented for processing the signals delivered by the one or more optical sensors 215a, 215b, 215c, namely for decoding the selected medicament dosage for delivery by or delivered by an injection device. The algorithm is preferably applicable to devices with an indicator flag and sensor separation with light pipes such as the module as described above.

The relative rotation between the dose button and the number sleeve may be encoded optically using an incremental encoder, for example a quadrature encoder, with two or more optical sensors, particularly reflective IR sensors, looking axially at castellations or radially projecting teeth or flags, formed on the top surface of the number sleeve. The encoder system may be implemented as an addon module, which means that the position of the castellations or teeth being detected may vary relative to the positions of the optical sensors from device to device, even after calibration of the module due to the variation of the manufacturing process of the injection device to which the module is fitted. It is therefore likely that there will be variation in signal between devices and during typical usage. Additionally, while the dose button is being depressed and released, the axial position of the optical sensors may also vary relative to the castellations.

The algorithm described in the following may be implemented in an injection device or an addon module particularly for the purpose of recording doses that are delivered from the injection device. This functionality may be of value to a wide variety of injection device users as a memory aid or to support detailed logging of dose history. It is envisaged that the electronics implementing the algorithms may be configured to be connectable to a mobile device such as a smartphone, or similar, to enable the dose history to be downloaded from the electronics on a periodic basis.

The algorithm is configured for detecting the relative rotation of castellations or teeth on a number sleeve relative to a nonrotating component such as the dose button. The presence or otherwise of a castellation or tooth feature provides a binary code, which may be used to count the number of units dispensed from the injection device. The voltage output of the optical sensors may be typically approximated to a sinusoid. The algorithm is able to detect the presence or otherwise of a castellation or tooth feature across all devices, which may have any combination of geometrical tolerances on the physical features.

Additionally, as the dose button moves axially towards or away from the castellation or tooth features at the beginning and end of dose ejection, the change in the signal generated by the optical sensor should not be incorrectly interpreted as a rotation of the castellation or tooth features. Therefore, the algorithm may accommodate significant amplitude modulation of the signal generated by the optical sensor.

The algorithm pertains to a system with two optical sensors being arranged with a 180° phase shift so that the signal voltages generated by both sensors are antiphase.

An embodiment of the algorithm provides improved noise resilience and false positive reduction and is not affected by offset drift (amplitude modulation) and sensor amplitude variations.

The first image in FIG. 7 shows the typical course of the signal voltages generated by two optical sensors when a dose is being administered. The first sensor signal voltage is shown by the heavier line, while the second sensor signal voltage is shown by the lighter line. The two optical sensors may have a different gain profile to each other. The signal voltages are amplitude modulated. The different gain profiles may lead to significantly different signal voltages being generated by the two optical sensors and sent to a processor for processing the signal voltages. The different gain profiles may be for example due to tolerances associated with electronic components. In this system the two optical sensors are arranged with a 180° phase shift so that the signal voltages generated by both sensors are antiphase.

The second image in FIG. 7 shows the numerical derivative values of the signal course of the first image. Where there are simultaneous peaks (positive and negative) in the derivative values of the first and second signal voltages, a detection of an administered unit of medicament is made by the algorithm. The small series of peaks (in the first sensor signal only) at the beginning of the derivative value graph are caused by the pressing of the injection button and accompanying axial movement. This is not counted as a medicament unit administered as there is no corresponding peak of opposite sign in the second sensor signal. The peaks in the derivative values of both the first and second sensors at the end of the derivative value graph are caused by the release of the injection button. Again, these peaks are not counted as a medicament unit administered, as the peaks in the two sensors do not have opposite signs.

The first image in FIG. 8 shows the typical course of the signal voltages generated by two optical sensors when the injection button is pressed when no dose has been dialled into the injection device. The first sensor signal voltage is shown by the heavier line, while the second sensor signal voltage is shown by the lighter line.

The second image in FIG. 8 shows the derivate values of the signal courses of the first image. The series of positive peaks in both the first and second sensor signals at the beginning of the derivative value graph are caused by pressing of the injection button. The depression of the injection button is therefore detected by the algorithm, but is not counted as an administration of a unit of medicament. The series of negative peaks in both the first and second sensor signals at the end of the derivative value graph are caused by release of the injection button. The release of the injection button is therefore detected by the algorithm, but is not counted as an administration of a unit of medicament. Therefore, the signals caused by pressing and releasing the injection button are not falsely identified as dosing events.

In order to determine a medicament dosage administered by the injection device, the algorithm computes numerical derivatives of the first signal and the second signal. The algorithm then identifies maximums and minimums in the derivative values of the two sensor signals. The algorithm defines a derivative peak threshold, which determines the size a derivate peak value needs to be confirmed as a peak. The derivative peak threshold may be set during a calibration of the sensors during manufacture. The algorithm may define different derivate peak thresholds for the first and second sensors due to differences in gain profile. The algorithm detects a peak in the derivative values of the first signal and a peak in the derivative values of the second signal when the first and second derivative signal values exceed the derivative peak threshold, or their respective derivative peak thresholds.

The algorithm determines that a unit of medicament has been administered when the following three criteria are met:

- (a) The detected peaks in the derivative values of the first signal and the derivative values of the second signal are simultaneous. The degree to which the detected peaks in the two derivate signals must be simultaneous may be predefined in the algorithm. For example it may be expected that the peaks will not occur exactly simultaneously due to manufacturing tolerances of the dose counting system. The algorithm may therefore define a synchronicity threshold and if the peaks in in the derivative values of the first signal and the derivative values of the second signal occur within this threshold, then they are considered to be simultaneous;
- (b) the peak in the derivative values of the first signal has a different sign from the peak in the derivative values of the second signal. The two sensors are arranged such that their signals are in antiphase. Therefore the signal from the first sensor should be reducing when the signal form the second sensor is increasing and vice versa, resulting in opposite signs for their respective derivative values; and
- (c) the peak in the derivative values of the first signal has a different sign from the previous peak in the derivative values of the first signal. This criteria contributes to ensuring that the peak in the derivative value represents the passing of a flag in front of the sensor, rather than a button press or release.

The algorithm then determines a medicament dosage administered by the injection device by counting the number of administered units of medicament.

In order to further improve the robustness of the peak detection steps, the algorithm may calculate a moving average or a moving median of a series of values of the first and second signals.

Where a moving average is used, it may comprise an average of a first set of sensor values minus an average of a second set of sensor values, wherein the first and second sets contain the same number of values and may be overlapping. In a simple example, a moving average of 8 values may be calculated, e.g. Average= . . . , mean (1 to 8), mean (2 to 9), mean (3 to 10), etc. . . . The first and last 7 samples of each sensor may be used without any averaging or may be averaged with the available information, e.g. Average=1, mean(1 to 2), mean(1 to 3), mean(1 to 4), . . . , mean(1 to 7), mean(1 to 8), mean(2 to 9), mean(3 to 10), etc. . . . Alternatively, the first seven values could be ignored completely. As the sample rate of the sensors is in the kHz range, this would result in a delay of less than 1/100 of a second, so no doses would be missed. In another example, a greater overlap is used in the average calculation. The average value may be calculated as the average of sensor values 6 to 13 minus the average of sensor values 2 to 9. This average value can be said to have an average of eight and a distance of four. Once the averaged values have been calculated as described above, the derivative of the averaged signal is calculated.

Where a moving median is used, it may comprise a median value of a first set of sensor values minus a median value of a second set of sensor values, wherein the first and second sets contain the same number of values and are overlapping. For example, an averaged value may be calculated as the median of peaks 6 to 12 minus the median of peaks 3 to 9. This averaged value can be said to have an average of seven and a distance (or overlap) of three. Once the averaged values have been calculated as described above, the derivative of the averaged signal is calculated.

The algorithm as discussed above is not affected by offset drift (amplitude modulation) and sensor amplitude variations, since the raw sensor data is first averaged before the derivation is applied.

As previously discussed, the injection device comprises an injection button configured to be pressed by a user in order to administer a dose of medicament from the injection device. The algorithm is configured such that the pressing and releasing of the injection button is not falsely identified as administration of a dose of medicament. The algorithm achieves this by determining that the injection button has been pressed or released when the peaks in the first signal and the second signal have the same sign, as can be seen in the second images in FIGS. 7 and 8.

The processor of the dose counting system may be configured to cause further actions to occur in response to detecting that the injection button has been pressed or released. For example, in response to determining that the injection button has been pressed, the processor may initiate a communication pairing with an external device using a (not shown) wireless transceiver unit of the injection device or module. The communication pairing may be a Bluetooth pairing.

In response to determining that the injection button has been released, the processor may initiate a manual data synchronisation. Typically at the end of each dosing event, the dose data is synchronised automatically. If the algorithm detects a button press and release with no dose delivered, this will also cause the data to be synchronised.

As a further example, in response to determining that the injection button has been released the processor may cause an end of dose indication to be outputted. This may take the form of an audible alert or a visual display of information on a display of the injection device or module. The end of dose indication may be preceded by a dwell time countdown, triggered by detection of the button release, indicating a time for which the user should keep the needle of the injection evince in their skin after the injection device reaches zero units.

As previously discussed, the rotary encoder system may comprise an encoder ring with a plurality of substantially light reflective flags arranged circumferentially. Each of these flags may have a concave or convex shape. Such a shape increases the signal gradient of the signal received by the first and second sensors and hence the amplitude of the derivate of these signals.

While the embodiments above have been described in relation to collecting data from an insulin injector pen, it is noted that embodiments of the invention may be used for other purposes, such as monitoring of injections of other medicaments.

The terms “drug” or “medicament” are used synonymously herein and describe a pharmaceutical formulation containing one or more active pharmaceutical ingredients or pharmaceutically acceptable salts or solvates thereof, and optionally a pharmaceutically acceptable carrier. An active pharmaceutical ingredient (“API”), in the broadest terms, is a chemical structure that has a biological effect on humans or animals. In pharmacology, a drug or medicament is used in the treatment, cure, prevention, or diagnosis of disease or used to otherwise enhance physical or mental well-being. A drug or medicament may be used for a limited duration, or on a regular basis for chronic disorders.

As described below, a drug or medicament can include at least one API, or combinations thereof, in various types of formulations, for the treatment of one or more diseases. Examples of API may include small molecules having a molecular weight of 500 Da or less; polypeptides, peptides and proteins (e.g., hormones, growth factors, antibodies, antibody fragments, and enzymes); carbohydrates and polysaccharides; and nucleic acids, double or single stranded DNA (including naked and cDNA), RNA, antisense nucleic acids such as antisense DNA and RNA, small interfering RNA (siRNA), ribozymes, genes, and oligonucleotides. Nucleic acids may be incorporated into molecular delivery systems such as vectors, plasmids, or liposomes. Mixtures of one or more drugs are also contemplated.

The drug or medicament may be contained in a primary package or “drug container” adapted for use with a drug delivery device. The drug container may be, e.g., a cartridge, syringe, reservoir, or other solid or flexible vessel configured to provide a suitable chamber for storage (e.g., short- or long-term storage) of one or more drugs. For example, in some instances, the chamber may be designed to store a drug for at least one day (e.g., 1 to at least 30 days). In some instances, the chamber may be designed to store a drug for about 1 month to about 2 years. Storage may occur at room temperature (e.g., about 20° C.), or refrigerated temperatures (e.g., from about −4° C. to about 4° C.). In some instances, the drug container may be or may include a dual-chamber cartridge configured to store two or more components of the pharmaceutical formulation to-be-administered (e.g., an API and a diluent, or two different drugs) separately, one in each chamber. In such instances, the two chambers of the dual-chamber cartridge may be configured to allow mixing between the two or more components prior to and/or during dispensing into the human or animal body. For example, the two chambers may be configured such that they are in fluid communication with each other (e.g., by way of a conduit between the two chambers) and allow mixing of the two components when desired by a user prior to dispensing. Alternatively, or in addition, the two chambers may be configured to allow mixing as the components are being dispensed into the human or animal body.

The drugs or medicaments contained in the drug delivery devices as described herein can be used for the treatment and/or prophylaxis of many different types of medical disorders. Examples of disorders include, e.g., diabetes mellitus or complications associated with diabetes mellitus such as diabetic retinopathy, thromboembolism disorders such as deep vein or pulmonary thromboembolism. Further examples of disorders are acute coronary syndrome (ACS), angina, myocardial infarction, cancer, macular degeneration, inflammation, hay fever, atherosclerosis and/or rheumatoid arthritis. Examples of APIs and drugs are those as described in handbooks such as Rote Liste 2014, for example, without limitation, main groups 12 (anti-diabetic drugs) or 86 (oncology drugs), and Merck Index, 15th edition.

Examples of APIs for the treatment and/or prophylaxis of type 1 or type 2 diabetes mellitus or complications associated with type 1 or type 2 diabetes mellitus include an insulin, e.g., human insulin, or a human insulin analogue or derivative, a glucagon-like peptide (GLP-1), GLP-1 analogues or GLP-1 receptor agonists, or an analogue or derivative thereof, a dipeptidyl peptidase-4 (DPP4) inhibitor, or a pharmaceutically acceptable salt or solvate thereof, or any mixture thereof. As used herein, the terms “analogue” and “derivative” refers to a polypeptide which has a molecular structure which formally can be derived from the structure of a naturally occurring peptide, for example that of human insulin, by deleting and/or exchanging at least one amino acid residue occurring in the naturally occurring peptide and/or by adding at least one amino acid residue. The added and/or exchanged amino acid residue can either be codable amino acid residues or other naturally occurring residues or purely synthetic amino acid residues. Insulin analogues are also referred to as “insulin receptor ligands”. In particular, the term “derivative” refers to a polypeptide which has a molecular structure which formally can be derived from the structure of a naturally occurring peptide, for example that of human insulin, in which one or more organic substituent (e.g. a fatty acid) is bound to one or more of the amino acids. Optionally, one or more amino acids occurring in the naturally occurring peptide may have been deleted and/or replaced by other amino acids, including non-codeable amino acids, or amino acids, including non-codeable, have been added to the naturally occurring peptide.

Examples of insulin analogues are Gly(A21), Arg(B31), Arg(B32) human insulin (insulin glargine); Lys(B3), Glu(B29) human insulin (insulin glulisine); Lys(B28), Pro(B29) human insulin (insulin lispro); Asp(B28) human insulin (insulin aspart); human insulin, wherein proline in position B28 is replaced by Asp, Lys, Leu, Val or Ala and wherein in position B29 Lys may be replaced by Pro; Ala(B26) human insulin; Des(B28-B30) human insulin; Des(B27) human insulin and Des(B30) human insulin.

Examples of insulin derivatives are, for example, B29-N-myristoyl-des(B30) human insulin, Lys(B29) (N-tetradecanoyl)-des(B30) human insulin (insulin detemir, Levemir®); B29-N-palmitoyl-des(B30) human insulin; B29-N-myristoyl human insulin; B29-N-palmitoyl human insulin; B28-N-myristoyl LysB28ProB29 human insulin; B28-N-palmitoyl-LysB28ProB29 human insulin; B30-N-myristoyl-ThrB29LysB30 human insulin; B30-N-palmitoyl-ThrB29LysB30 human insulin; B29-N—(N-palmitoyl-gamma-glutamyl)-des(B30) human insulin, B29-N-omega-carboxypentadecanoyl-gamma-L-glutamyl-des(B30) human insulin (insulin degludec, Tresiba®); B29-N—(N-lithocholyl-gamma-glutamyl)-des(B30) human insulin; B29-N-(ω-carboxyheptadecanoyl)-des(B30) human insulin and B29-N-(ω-carboxyheptadecanoyl) human insulin.

Examples of GLP-1, GLP-1 analogues and GLP-1 receptor agonists are, for example, Lixisenatide (Lyxumia®), Exenatide (Exendin-4, Byetta®, Bydureon®, a 39 amino acid peptide which is produced by the salivary glands of the Gila monster), Liraglutide (Victoza®), Semaglutide, Taspoglutide, Albiglutide (Syncria®), Dulaglutide (Trulicity®), rExendin-4, CJC-1134-PC, PB-1023, TTP-054, Langlenatide/HM-11260C, CM-3, GLP-1 Eligen, ORMD-0901, NN-9924, NN-9926, NN-9927, Nodexen, Viador-GLP-1, CVX-096, ZYOG-1, ZYD-1, GSK-2374697, DA-3091, MAR-701, MAR709, ZP-2929, ZP-3022, TT-401, BHM-034. MOD-6030, CAM-2036, DA-15864, ARI-2651, ARI-2255, Exenatide-XTEN and Glucagon-Xten.

An examples of an oligonucleotide is, for example: mipomersen sodium (Kynamro®), a cholesterol-reducing antisense therapeutic for the treatment of familial hypercholesterolemia.

Examples of DPP4 inhibitors are Vildagliptin, Sitagliptin, Denagliptin, Saxagliptin, Berberine.

Examples of hormones include hypophysis hormones or hypothalamus hormones or regulatory active peptides and their antagonists, such as Gonadotropine (Follitropin, Lutropin, Choriongonadotropin, Menotropin), Somatropine (Somatropin), Desmopressin, Terlipressin, Gonadorelin, Triptorelin, Leuprorelin, Buserelin, Nafarelin, and Goserelin.

Examples of polysaccharides include a glucosaminoglycane, a hyaluronic acid, a heparin, a low molecular weight heparin or an ultra-low molecular weight heparin or a derivative thereof, or a sulphated polysaccharide, e.g. a poly-sulphated form of the above-mentioned polysaccharides, and/or a pharmaceutically acceptable salt thereof. An example of a pharmaceutically acceptable salt of a poly-sulphated low molecular weight heparin is enoxaparin sodium. An example of a hyaluronic acid derivative is Hylan G-F 20 (Synvisc®), a sodium hyaluronate.

The term “antibody”, as used herein, refers to an immunoglobulin molecule or an antigen-binding portion thereof. Examples of antigen-binding portions of immunoglobulin molecules include F(ab) and F(ab′)2 fragments, which retain the ability to bind antigen. The antibody can be polyclonal, monoclonal, recombinant, chimeric, de-immunized or humanized, fully human, non-human, (e.g., murine), or single chain antibody. In some embodiments, the antibody has effector function and can fix complement. In some embodiments, the antibody has reduced or no ability to bind an Fc receptor. For example, the antibody can be an isotype or subtype, an antibody fragment or mutant, which does not support binding to an Fc receptor, e.g., it has a mutagenized or deleted Fc receptor binding region. The term antibody also includes an antigen-binding molecule based on tetravalent bispecific tandem immunoglobulins (TBTI) and/or a dual variable region antibody-like binding protein having cross-over binding region orientation (CODV).

The terms “fragment” or “antibody fragment” refer to a polypeptide derived from an antibody polypeptide molecule (e.g., an antibody heavy and/or light chain polypeptide) that does not comprise a full-length antibody polypeptide, but that still comprises at least a portion of a full-length antibody polypeptide that is capable of binding to an antigen. Antibody fragments can comprise a cleaved portion of a full length antibody polypeptide, although the term is not limited to such cleaved fragments. Antibody fragments that are useful in the present invention include, for example, Fab fragments, F(ab′)2 fragments, scFv (single-chain Fv) fragments, linear antibodies, monospecific or multispecific antibody fragments such as bispecific, trispecific, tetraspecific and multispecific antibodies (e.g., diabodies, triabodies, tetrabodies), monovalent or multivalent antibody fragments such as bivalent, trivalent, tetravalent and multivalent antibodies, minibodies, chelating recombinant antibodies, tribodies or bibodies, intrabodies, nanobodies, small modular immunopharmaceuticals (SMIP), binding-domain immunoglobulin fusion proteins, camelized antibodies, and VHH containing antibodies. Additional examples of antigen-binding antibody fragments are known in the art.

The terms “Complementarity-determining region” or “CDR” refer to short polypeptide sequences within the variable region of both heavy and light chain polypeptides that are primarily responsible for mediating specific antigen recognition. The term “framework region” refers to amino acid sequences within the variable region of both heavy and light chain polypeptides that are not CDR sequences, and are primarily responsible for maintaining correct positioning of the CDR sequences to permit antigen binding. Although the framework regions themselves typically do not directly participate in antigen binding, as is known in the art, certain residues within the framework regions of certain antibodies can directly participate in antigen binding or can affect the ability of one or more amino acids in CDRs to interact with antigen.

Examples of antibodies are anti PCSK-9 mAb (e.g., Alirocumab), anti IL-6 mAb (e.g., Sarilumab), and anti IL-4 mAb (e.g., Dupilumab).

Pharmaceutically acceptable salts of any API described herein are also contemplated for use in a drug or medicament in a drug delivery device. Pharmaceutically acceptable salts are for example acid addition salts and basic salts.

Those of skill in the art will understand that modifications (additions and/or removals) of various components of the APIs, formulations, apparatuses, methods, systems and embodiments described herein may be made without departing from the full scope and spirit of the present invention, which encompass such modifications and any and all equivalents thereof.

A Dose Counting System

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