Source: https://patents.google.com/patent/RU2555133C2/en
Timestamp: 2020-02-21 10:49:28
Document Index: 603981823

Matched Legal Cases: ['art 2', 'art 2', 'art 2', 'arts 44', 'arts 44', 'art 46', 'art 46', 'art 44', 'art 46', 'art 44', 'art 44', 'art 46', 'art 44', 'art 46', 'arts 44', 'art 44', 'art 44', 'art 46', 'art 44', 'art 207', 'art 212', 'art 207', 'art 207', 'art 207', 'art 212', 'arts 207', 'art 207', 'art 212', 'art 207', 'art 212', 'art 207', 'art 212', 'art 212', 'art 207', 'art 212', 'arts 207', 'art 207', 'art 212', 'art 212', 'art 212', 'art 207', 'art 211', 'art 210', 'art 211', 'art 211', 'art 212', 'art 307', 'art 312', 'art 307', 'art 307', 'art 307', 'art 307', 'art 312', 'arts 307', 'art 307', 'art 307', 'art 376', 'art 377', 'arts 376', 'art 377', 'art 307', 'arts 376', 'art 307', 'arts 376', 'art 376', 'art 376', 'art 377', 'art 376', 'art 376', 'art 376', 'arts 376', 'art 377', 'art 307', 'art 307', 'art 307', 'art 307', 'art 477', 'art 476', 'art 477', 'art 476', 'art 477', 'art 476', 'art 477', 'art 477', 'art 412', 'art 477', 'art 412']

RU2555133C2 - Internal case of device, possessing spiral slot, for delivery of medication - Google Patents
Internal case of device, possessing spiral slot, for delivery of medication Download PDF
RU2555133C2
RU2555133C2 RU2011154367/14A RU2011154367A RU2555133C2 RU 2555133 C2 RU2555133 C2 RU 2555133C2 RU 2011154367/14 A RU2011154367/14 A RU 2011154367/14A RU 2011154367 A RU2011154367 A RU 2011154367A RU 2555133 C2 RU2555133 C2 RU 2555133C2
RU2011154367/14A
RU2011154367A (en
Дэвид ПЛАМПТР
2009-06-01 Priority to US18286409P priority Critical
2009-06-01 Priority to US61/182,864 priority
2009-07-10 Priority to EP09009044.0 priority
2009-07-10 Priority to EP09009044 priority
2010-05-28 Application filed by Санофи-Авентис Дойчланд Гмбх filed Critical Санофи-Авентис Дойчланд Гмбх
2010-05-28 Priority to PCT/EP2010/057490 priority patent/WO2010139643A1/en
2013-07-20 Publication of RU2011154367A publication Critical patent/RU2011154367A/en
2015-07-10 Publication of RU2555133C2 publication Critical patent/RU2555133C2/en
238000002483 medication Methods 0 abstract title 4
SUBSTANCE: invention relates to medical equipment, namely to dose-setting mechanisms for medication delivery. Dose-setting mechanism contains: external case, internal case and sleeve with scale. Internal case has external groove and is made with possibility to direct drive for distribution of dose, set with dose-setting mechanism. Sleeve with scale is located between external case and internal case and is in rotary engagement with said external groove of internal case. Sleeve with case is made with possibility of rotation relative to both external case and internal case during dose setting and is made with possibility of travel both from external case and internal case. Internal case contains internal spiral slot.
EFFECT: application of invention makes it possible to simplify stage of discharge of dose-setting mechanism; number of composite parts of device for medication delivery is reduced, which makes device less complex and more compact, cost and complexity of assembling and production is reduced.
2420-181312EN / 023
In general, this application relates to dose-setting mechanisms for drug delivery devices. More specifically, the present application generally relates to a dose setting mechanism that comprises an inner case having a helical groove and which is used in drug delivery devices. Aspects of the invention may equally be applicable to other tasks.
Pen-shaped drug delivery devices are used where regular injections are carried out by persons without formal medical training. This is becoming more and more common among patients with diabetes, where self-treatment allows such patients to effectively manage their disease.
There are two main types of pen-shaped delivery devices: resettable devices (i.e., reusable) and non-resettable (i.e., disposable). Pen-shaped delivery devices (so named because they usually look like a fountain pen) of these types typically contain three main elements: (i) a cartridge compartment, which contains a cartridge that is often located in a case or holder; (ii) a needle assembly that is connected to one end of the cartridge compartment; and (iii) a metering compartment that is connected to the other end of the cartridge compartment. The cartridge (often referred to as an ampoule) typically contains a reservoir that is filled with a drug (e.g., insulin), a movable rubber plug or stopper located at one end of the cartridge reservoir, and an upper portion that has a punctured rubber seal located on the other, often narrowed end. Typically, a crimped annular metal strip is used to hold the rubber seal in place. While the cartridge body is typically made of plastic, the cartridge reservoirs have historically been made of glass.
The needle assembly is typically a replaceable double-sided needle assembly. Before injection, a replaceable double-sided needle assembly is attached to one end of the cartridge assembly, a dose is set, and then a dose is administered. Such removable needle assemblies can be screwed onto or inserted (i.e. snap into) the end of the punctured seal of the cartridge assembly.
The dispensing compartment or dose setting mechanism typically is part of a pen-shaped device that is used to set the dose. During injection, the spindle, which is located inside the dose-setting mechanism, presses on the cork or stopper of the cartridge. Due to this force, the drug is injected, which is contained in the cartridge, through the attached needle assembly. After the injection, in general, as recommended by most manufacturers of drug delivery devices and / or needle assemblies, the needle assembly is removed and discarded.
Over the years, various types of pen-shaped delivery devices have evolved, including disposable (i.e., non-resettable) and reusable (i.e., resettable) varieties. For example, disposable pen-shaped delivery devices are delivered as embedded devices. Such embedded devices do not contain removable pre-filled cartridges. In contrast, in these devices, pre-filled cartridges cannot be removed and replaced without destroying the device itself. Thus, such disposable devices should not contain a resettable dose setting mechanism.
Unlike typical disposable pen-shaped devices, typical pen-shaped reusable delivery devices differ in essence by two main reusable components: a cartridge holder and a dose setting mechanism. After the cartridge is inserted into the cartridge holder, this cartridge holder is attached to a dose setting mechanism. The user uses a dose-setting mechanism to select a dose. Before the user injects a predetermined dose, a replaceable double-sided needle assembly is attached to the cartridge body.
This needle assembly can be screwed on or put on (i.e. snap on) at the distal end of the cartridge body. Thus, a double-sided needle mounted on the needle assembly penetrates through the punctured seal at the distal end of the cartridge. After injection, the needle assembly is removed and discarded. After the insulin in the cartridge has run out, the user disconnects the cartridge case from the dose-setting mechanism. The user can then remove the empty cartridge from the cartridge retainer and replace the empty cartridge with a new (full) cartridge.
In addition to replacing an empty cartridge with a new cartridge, the user must prepare the dose-setting mechanism for the new cartridge in a certain way: the dose-setting mechanism must be returned to its original or initial position. For example, in certain typical resettable devices, in order to reset the dose setting mechanism, the spindle which is advanced distally during dose injection needs to be retracted in a certain way in the dose setting mechanism. Certain known methods for retracting this spindle back in a dose-setting mechanism to a restart position or to a starting position are known in the art. As only one example, in certain known reset mechanisms, it is necessary for the user to return or push back (retract) the spindle or some other part of the dose-setting mechanism.
Resetting known dose-setting mechanisms has certain obvious disadvantages. One obvious drawback is that the pen-shaped device user must disassemble the device in order to either remove the empty cartridge or reset the device in a certain way. Essentially, another obvious drawback is that such devices contain a large number of parts and, therefore, such devices are typically complex in terms of production and assembly. For example, certain typical pen-shaped resettable devices are not intuitively understood as to how a user needs to replace an empty cartridge or how a user can reset a device. In addition, since a large number of components are used in such discharged devices, such discharged devices are usually large in size and volume, and therefore not easy to carry or hide.
Therefore, there is a general need to take these disadvantages associated with the dumping problem into account when designing and developing discarded drug delivery devices. Such desired drug delivery devices will tend to reduce the number of components, as well as lower production costs, while the devices will also be less complex to assemble and manufacture. Such desired devices will also tend to simplify the steps that the user must perform to reset the dose setting mechanism, while the device will also be less complex and more compact in size.
According to an exemplary arrangement, a dose-setting mechanism for a drug delivery device comprises an outer case and an inner case that has an outer groove and a helical groove. The inner housing guides the drive in order to dose the dose set by the dose-setting mechanism. A sleeve with a scale can be positioned between the outer and inner case and it is in rotary engagement with the inner case. When a dose is set, the sleeve with the scale is rotated relative to both the outer case and the inner case. The sleeve with the scale is moved far from both the outer case and the inner case.
These, as well as other advantages of various aspects of the present invention, will become apparent to those skilled in the art after reading the following detailed description, with appropriate reference to the accompanying drawings.
in FIG. 1 illustrates a first embodiment of a discarded drug delivery device;
in FIG. 2 is a cross-sectional view of a first embodiment of the drug delivery device illustrated in FIG. one;
in FIG. 3 is a cross-sectional view of a first embodiment of the drug delivery device of FIG. 2 in the first position;
in FIG. 4 is a sectional view of a first embodiment of the drug delivery device of FIG. 2 in the second position;
in FIG. 5 illustrates a sectional view of a first embodiment of the drug delivery device of FIG. 2 in the third position;
in FIG. 6 illustrates a first arrangement of the actuator illustrated in FIG. 2-5, which contains the first part of the drive and the second part of the drive;
in FIG. 7 illustrates the distal end of the spindle of the dose-setting mechanism illustrated in FIG. 2-5;
in FIG. 8 is a cross-sectional view of a second embodiment of a dose-setting mechanism for the drug delivery device illustrated in FIG. one;
in FIG. 9 is a partial cross-sectional view of a second embodiment of a dose setting mechanism illustrated in FIG. 8;
in FIG. 10 illustrates a close view of the gap “a” illustrated in FIG. 8;
in FIG. 11 illustrates a second arrangement of the actuator illustrated in FIG. 6-8, which contains the first part of the drive and the second part of the drive;
in FIG. 12 illustrates a dose defining mechanism, illustrated or in FIG. 2-5 or in FIG. 6-8, and
in FIG. 13 illustrates the dose setting mechanism illustrated in FIG. 12, in which the user set the dose;
in FIG. 14 is a cross-sectional view of another embodiment of a dose-setting mechanism of the drug delivery device illustrated in FIG. one;
in FIG. 15 is a partial cross-sectional view of an embodiment of the dose setting mechanism illustrated in FIG. fourteen;
in FIG. 16 is a cross-sectional view of yet another embodiment of a dose-setting mechanism for the drug delivery device illustrated in FIG. one;
in FIG. 17 is a partial cross-sectional view of an embodiment of a dose setting mechanism illustrated in FIG. 16, in a second position;
in FIG. 18 is a partial sectional view of an embodiment of a dose setting mechanism illustrated in FIG. 16, with the remote buzzer part removed; and
in FIG. 19 illustrates a part of an audible warning device that can be used with the dose setting mechanism illustrated in FIG. 16.
The terms “drug” or “drug product”, as used herein, means a pharmaceutical composition containing at least one pharmaceutically active compound,
where in one embodiment the pharmaceutically active compound has a molecular weight of up to 1,500 Da and / or is a peptide, protein, polysaccharide, vaccine, DNA, RNA, antibody, enzyme, antibody, hormone or oligonucleotide, or a mixture of the above pharmaceutically active compound,
where in an additional embodiment, the pharmaceutically active compound can be used to treat and / or prevent diabetes mellitus or complications associated with diabetes mellitus, such as diabetic retinopathy, thromboembolic disorders such as deep vein thromboembolism or pulmonary thromboembolism, acute coronary syndrome (ACS), angina pectoris, myocardial infarction, malignant tumor, macular degeneration, inflammation, hay fever, atherosclerosis and / or rheumatoid arthritis,
where in an additional embodiment, the pharmaceutically active compound contains at least one peptide for the treatment and / or prevention of diabetes mellitus or complications associated with diabetes mellitus, such as diabetic retinopathy,
wherein, in a further embodiment, the pharmaceutically active compound comprises at least one human insulin or analog or derivative of human insulin, a glucagon-like peptide (GLP-1) or its analog or derivative, or exedin-3, or exedin-4, or an analog, or derivative exedina-3, or exedina-4.
Analogs of insulin are, for example, Gly (A21), Arg (B31), Arg (B32) human insulin; Lys (B3); Glu (B29) human insulin; Lys (B28), Pro (B29) human insulin; Asp (B28) human insulin; human insulin, where the proline at position B28 is replaced with Asp, Lys, Leu, Val or Ala and where at position B29 Lys can be replaced with Pro; Ala (B26) human insulin; des (B28-B30) human insulin; des (B27) human insulin and des (B30) human insulin.
Derivatives of insulin are, for example, B29-N-myristoyl des (B30) human insulin; 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-Υ-glutamyl) des (B30) human insulin; B29-N- (N-lithocholyl-Υ-glutamyl) des (B30) human insulin; B29-N- (ω-carboxyheptadecanoyl) des (B30) human insulin; and B29-N- (ω-carboxyheptadecanoyl) human insulin.
Exendin-4, for example, refers to exendin-4 (1-39), a peptide from the sequence H-His-Gly-Glu-Gly-Thr-Phe-Thr-Ser-Asp-Leu-Ser-Lys-Gln-Met-Glu -Glu-Glu-Ala-Val-Arg-Leu-Phe-Ile-Glu-Trp-Leu-Lys-Asn-Gly-Gly-Pro-Ser-Ser-Gly-Ala-Pro-Pro-Pro-Ser-NH2 .
Derivatives of exendin-4 are, for example, selected from the following list of compounds:
where the -Lys6-NH2 group may be bonded to the C-terminus of the exendin-4 derivative;
or with an exendin-4 derivative with the sequence
H-Asn- (Glu) 5-des Pro36, Pro37, Pro38 [Asp28] Exendin-4 (1-39) -NH2,
H-Asn- (Glu) 5-des Pro36, Pro37, Pro38 [Met (O) 14, Asp28] Exendin-4 (1-39) - (Lys) 6-NH2,
or with a pharmaceutically acceptable salt or solvate of any of the above exedin-4 derivatives.
Hormones are, for example, pituitary hormones or hypothalamic hormones, or active regulatory peptides and their antagonists, as listed in Rote Liste, ed. 2008, Chapter 50, such as gonadotropin (follitropin, lutropin, choriogonadotropin, menotropin), somatropin, desmopressin, terlipressin, gonadorelin, triptorelin, leuprorelin, buserelin, nafarelin, goserelin.
The polysaccharide is, for example, glucosaminoglycan, hyaluronic acid, heparin, low molecular weight heparin or ultra low molecular weight heparin or a derivative thereof, or a sulfated, for example, polysulfated form of the above polysaccharide, and / or a pharmaceutically acceptable salt thereof. An example of a pharmaceutically acceptable low molecular weight polysulfated heparin salt is enoxaparin sodium.
Pharmaceutically acceptable salts are, for example, acid addition salts and basic salts. Acid addition salts are, for example, HCl or HBr salts. The main salts are, for example, salts containing a cation selected from alkali or alkaline earth, for example, Na + or K +, or Ca2 +, or ammonium ion N + (R1) (R2) (R3) (R4), where R1 to R4 are independently from each other are: hydrogen, an optionally substituted C1-C6 alkyl group, an optionally substituted C2-C6 alkenyl group, an optionally substituted C6-C10 aryl group or an optionally substituted C6-C10 heteroaryl group. Further examples of pharmaceutically acceptable salts are described in Remington's Pharmaceutical Sciences 17. ed. Alfonso R. Gennaro (Ed.), Mark Publishing Company, Easton, Pa., U.S.A., 1985 and Encyclopedia of Pharmaceutical Technology.
In FIG. 1 shows a drug delivery device 1 in accordance with a first arrangement of the present invention. The drug delivery device 1 comprises a housing that has a first cartridge holding part 2 and a dose setting mechanism 4. The first end of the cartridge holding part 2 and the second end of the dose setting mechanism 4 are fastened together by holding structural features. In this illustrated arrangement, the cartridge holding part 2 is fixed inside the second end of the dose setting mechanism 4. The second end or the distal end of the cartridge holding part is detachably holding the removable cap 3. As described in more detail, the dose setting mechanism 4 comprises a dose scale grip 12 and a window or lens 14. To set the dose of the drug contained within the drug delivery device 1, the user rotates the capture of the dose scale 12 and the window allows the user to see the dialed dose by arranging a dose scale of 16.
In FIG. 2 illustrates the medical delivery device 1 of FIG. 1 with a cover 3, removed from the distal end of the medical device for delivery. As illustrated, a cartridge 20, from which several doses of a drug product can be dispensed, is provided in the housing of the cartridge 6. Preferably, the cartridge 20 contains a drug of the type that is often administered, for example, one or more times per day. One such drug is insulin. The first end or proximal end of the cartridge 20 holds the plug or stopper (not shown in FIG. 2).
The dose setting mechanism 4 of the drug delivery device illustrated in FIG. 2 can be used as a reusable (and thus disposable) or reusable (and thus non-disposable) drug delivery device. When the drug delivery device 1 contains a reusable drug delivery device, the cartridge is removable from the cartridge body 6. The user can remove the cartridge 20 from the device without destroying the device by only disconnecting the dose setting mechanism 4 from the cartridge holder 20.
In use, after removing the removable cap 3, the user can attach a suitable needle assembly to the distal end of the cartridge holder. Such a needle block can be screwed onto the distal end of the body, or alternatively can be snapped onto its distal end. The removable cap 3 is used to close the cartridge holder 6 protruding from the dose setting mechanism 4. Preferably, the external dimensions of the removable cap 3 are similar or identical to the external dimensions of the dose setting mechanism 4 so as to give an impression of integrity when the removable cap 3 is in position that covers the cartridge holder 2.
In FIG. 3 illustrates a cross-sectional view of a dose-setting mechanism 4 detachably connected to the cartridge holder 29. The dose-setting mechanism 4 includes an outer casing 40 comprising a spindle 42, a numerical sleeve 24, a clutch 26, a buzzer 75, and a drive 30. The first spiral groove 19 extends from the first end of the spindle 42. In one arrangement, the spindle 42 has a generally circular cross section, but other arrangements can also be used. The first end of the spindle 42 (distal end 43 of the spindle 42) goes through the pressure disk 64. The spindle carrier 50 is located on the distal end 43 of the spindle 42. The spindle carrier 50 is located to abut the second end of the cartridge plunger 18. The drive 30 extends near the spindle 42 .
Clutch 26 is located near the drive 30, between the drive 30 and the numerical sleeve 24. The clutch 26 is adjacent to the second end of the drive 30. The numerical sleeve 24 is provided on the outside of the clutch 26 and radially inside the housing 40. The main body 4 is provided with a window 14 through which you can see part of the outer surface 11 of the numerical sleeve 10.
Returning to FIG. 1-2, the capture of the dose scale 12 is located near the outer surface of the second end of the numerical sleeve 10. The outer diameter of the capture of the dose scale 12 preferably corresponds to the external diameter of the housing 40. The capture of the dose scale 12 is attached to the digital sleeve 10 in order to prevent relative movement between the two components. In one preferred arrangement, the dose dial grip 12 and the numerical sleeve 10 comprise an integral component that is rotationally coupled to the clutch and drive clutch and axially connected to the numerical sleeve 10. However, alternative coupling arrangements can also be used.
Returning to FIG. 3-5, in this arrangement, the actuator 30 comprises a first part of the actuator 44 and a second part of the actuator 46, and these parts extend near the spindle 42. Both the first and second parts of the actuator 44, 46 are generally cylindrical in shape. As can be seen in FIG. 6, a first radially extending flange 56 is provided at the first end of the first part of the actuator 44. A second radially extending flange 58 is provided remote at a distance along the first part of the actuator 44 from the first flange 56. An intermediate helical groove 62 is provided on the outer part of the first part of the actuator 44, which goes between the first flange 56 and the second flange 58. A portion or part of the spiral groove 68 extends along the inner surface of the first part of the actuator 44. The spindle 42 is adapted to operate within this incomplete spiral groove 68.
The dose limiter 38 (illustrated in FIG. 3) is located between the actuator 30 and the housing 4, between the first flange 56 and the second flange 58. In the illustrated arrangement, the dose limiter 38 comprises a nut. The dose limiter 38 has an internal spiral groove coinciding with the spiral groove 66 of the actuator 30. In one preferred arrangement, the outer surface of the dose limiter 38 and the inner surface of the housing 40 are jammed by slots 65a, 65b. In this preferred arrangement, the grooves 65a, 65b comprise linear grooves. This prevents relative movement between the dose limiter 38 and the housing 40, while making possible a relative longitudinal movement between the two components.
Returning to FIG. 2-5, essentially under normal use, the operation of the dose-setting mechanism 4 occurs as follows. In order to set the dose in the arrangement illustrated in FIG. 1-5, the user rotates the grip of the dose scale 12. The drive 30, the clutch 26 and the number sleeve 10 rotate together with the grip of the dose scale 12. In this preferred arrangement, an audible warning device 75 is located between the distal end 23 of the clutch 26 and the flange 80 of the drive clutch 46. The buzzer 75 and the inner surface of the housing 40 are jammed by the grooves 65a, 65b. This prevents the buzzer 75 from rotating with respect to the housing 40 either during dose selection or during dose administration.
The numerical sleeve 10 extends proximally from the housing 40. Thus, the actuator 30 rises along the spindle 42. When the actuator 30 and the clutch are rotated, the distal clutch portion 23 carries a horn 75 to generate a click. Preferably, the distal portion comprises a plurality of grooves or structural features that are arranged such that each click corresponds to an accepted unit dose or the like.
At the displacement boundary, the radial stop is engaged on the numerical sleeve 10 with either the first stop or the second stop provided on the housing 40 to prevent further movement. Prevention of rotation of the spindle 42 occurs due to the opposite direction of the resettable thread and the drive thread on the spindle 42. The dose limiter 38, stuck on the housing 40, is advanced along the thread 66 by rotation of the drive 30.
In FIG. 2 illustrates a medical device for delivery after dialing the desired dose of 79 International Units (IU). When this desired dose is dialed, the user can then dose the desired dose of 79 IU by clicking on the grab bar. When the user clicks on the grasp of the scale 12, this biases the clutch 26 in the axial direction with respect to the numerical sleeve 10, causing the clutch 26 to disengage. However, the clutch 26 remains stuck upon rotation to the actuator 30.
The drive 30 cannot rotate with respect to the main body 4, but it moves freely in the axial direction relative to it. The longitudinal axial movement of the actuator 30 causes the rotation of the spindle 42 and thereby advances the plunger 18 into the cartridge 20.
In normal use, the first and second parts 44, 46 of the actuator 30 are connected together when the sleeve is rotated with a dose scale 10. That is, in normal use, the first and second parts 44, 46 of the actuator 30 are connected together with the sleeve with a dose scale 10 when the user sets the dose by turning the grip of the dose scale 12. After each dosed dose, the spindle 42 is pushed distally, acting on the plug 18 of the cartridge 20 in order to continue to push the collected dose of the drug from the attached needle assembly, the cartridge holder 6 connected to the distal end 8.
After the user uses the drug delivery device 1 to dispense all of the drug contained in the cartridge 20, the user may wish to replace the empty cartridge in the cartridge holder 6 with a new cartridge. Then, the user must also reinstall the dose-setting mechanism 4: for example, the user must then pull or push the spindle 42 back into the dose-setting mechanism 4.
If the user decides to replace the empty cartridge and reinstall the device 1, the first and second parts of the drive 44, 46 should be disconnected from each other. After disconnecting the first part of the actuator 44 from the second part of the actuator 46, the first part of the actuator 44 will rotate freely, while the second part of the actuator 46 will not rotate freely.
During the reinstallation stage of the device, the rotation of the first part of the actuator 44 achieves at least two results. First, the rotation of the first part of the actuator 44 will reset the axial position of the spindle 42 with respect to the dose setting mechanism 4, since the rotation of the first part of the actuator 44 causes the spindle 42 to rotate. The rotation of the spindle 42 (since the spindle is in the grooved connection with the spindle guide 48) moves spindle in the proximal direction back into the dose-setting mechanism. For example, in FIG. 7 illustrates one arrangement for connecting spindle 42 to spindle guide 48. In FIG. 7, the spindle 42 comprises a first groove 51 and a second groove 52. The guide of the spindle 48 comprises a substantially circular element that has an opening. The hole contains two internal protruding elements 55, 57, which engage with the first and second grooves 51, 52, respectively, so as to fix the spindle guide 48 on the spindle and rotate with the spindle during rotation of the spindle.
Secondly, the rotation of the first part of the actuator 44 will also move along the axis or reset the dose limiter 38 to its initial or starting position. That is, since the first part of the actuator 44 is rotated back to its original starting position, therefore, the dose limiter 38 is threadedly engaged with the external groove and in grooved connection with the inner surface of the housing part, such as the external housing 40. In this configuration, the dose limiter 38 cannot rotate, but will move along the outer groove 62 of the first part of the actuator 44 when this part is rotated during the reset stage. In addition, since it is in grooved connection with the longitudinal grooves 65a, 65b of the outer casing 4, the buzzer 75 also cannot rotate during this reset stage.
In the first drive arrangement illustrated in FIG. 3, the two parts of the actuator 30 are disconnected when the first part of the actuator 44 is pulled axially from the second part of the actuator 46. This can be achieved by using biasing means (such as at least one spring) that cooperate together when the cartridge holder 6 is removed from the front or distal end of the device in order to first fix the relative rotation between the spindle 42 and the spindle guide 48 through which the spindle passes, and then in order to push this spindle guide 48, and same nut 66 in the axial direction at a fixed distance. Since the spindle 42 is rotationally fixed in this guide of the spindle 48 and is in threaded engagement with the nut of the spindle 66, the spindle 42 will move in the axial direction.
The spindle 42 is connected through a groove engaged in the first part of the actuator 44. The first part of the actuator 44 cannot rotate due to the coupling with the second part of the actuator 46. In one preferred arrangement, the second part of the actuator 46 cannot rotate due to the buzzer 75, which is located between the clutch and the flange 80 of the drive coupling 46. Therefore, the axial movement of the spindle 42 disengages the two parts of the drive 44, 46 so as to disconnect the coupling.
This sequence of actions, when the cartridge holder 6 is removed or disconnected from the dose setting mechanism 4, is illustrated in FIG. 3-5. In FIG. 3 various components of a drug delivery device include: a dose-defining housing 40, a cartridge 20, a spindle 42, a first drive portion 44; the second part 46 of the drive bearing 50 spindle guide 48 of the spindle, the spring plate 54; a main spring 60, a pressure plate 64, a cartridge holder 20; spindle nut 66; and a second spring 70. In this preferred arrangement, the spindle guide 48 is rotationally fixed relative to the spindle 20. In addition, the spring plate 54, the pressure plate 64 and the spindle nut 66 are rotationally fixed relative to the outer casing.
In FIG. 3, the cartridge holder 6 is mounted through openings in the pressure plate 64 and applies a load to the spring plate 54. It contains a first biasing means or main spring 60. These holes in the pressure disk 64 (not shown) allow the pressure disk 64 to be moved away from the spring plate 54 ( in the distal direction relative to the cartridge holder 6) under the action of the second biasing means or the second spring 70. This opens the gap “A” as shown in FIG. 3. The clearance “A” is the gap created between the pressure plate 64 and the spring plate 54. This also opens the gap “b”, the gap between the spindle nut 66 and the spring plate 54. This clearance “B” is illustrated in FIG. 3. The clearance “B” in combination with a slight force from the side of the second spring or biasing means 70 moves the spindle nut 66 towards the distal end of the drug delivery device 1. This creates a slight pressure on the spindle guide 48.
The spindle guide 48 is compressed by a second spring 70 between the spindle nut 66 and the pressure plate 64. This light force combined with the coefficient of friction on either side of the edge of the spindle guide 48, through which this force acts, provides resistance to rotation of the spindle guide 48, and also therefore, the rotation resistance of the spindle 42. One advantage of this configuration is that at the end of the dose it favorably prevents the spindle 42 from being screwed back into the dose setting mechanism 4 with a slight residual Loading the which may remain on the stopper 18 of the cartridge. By preventing the spindle 42 from being screwed back in proximal, the distal end 43 of the spindle 42 (and thus the spindle carrier 50) remains on the plug 18. Holding the distal end 43 of the spindle 42 on the plug 18 helps to prevent the user from introducing a lower dose.
When the user delivers the dose, the backward load on the spindle nut 66 increases with increasing metering force to the point where the spindle nut 66 moves back in the proximal direction and compresses the second spring 70. This releases axial force acting on the spindle guide 48. This eliminates the rotation resistance of the spindle guide 48 and thus the spindle 42. Therefore, this configuration prevents the spindle 42 from being screwed back under low loads caused by the cartridge plug 18, but does not increase the metering force after increasing this metering force above a certain threshold level.
In FIG. 4 illustrates the dose setting mechanism 4 of FIG. 3 with a cartridge holder 6, rotated to release the type of connection between the housing 40 of the dose-setting mechanism 4 and the cartridge holder 6. In one arrangement, this type of connection 22 is a bayonet connection. However, one of ordinary skill in the art will appreciate that other types of joints 22 can be used, as well as threads, snap joints, snap joints, Luer joints, and other similar types of joints. In the arrangement illustrated in FIG. 3-5, rotating the cartridge holder 6 with respect to the housing 40, the design features that initially acted on the spring plate 54 to compress the main biasing means 60 through the holes in the pressure disk 64 are rotated so that they now release this force created by the main biasing means 60. This allows the spring plate 54 to be moved distally until the spring plate 54 makes contact with the spindle nut 66 on the inner surface of the spindle nut 66.
In this second state, the previously considered clearance “A” (with FIG. 3) is now reduced to the clearance “C” (as seen in FIG. 4). Thus, the relatively high axial force from the side of the main biasing means 60 acts through the spring plate 54 on the spindle nut 66 and from the spindle nut 66 through the spindle guide 48 to the pressure plate 64. This relatively high axial force from the side of the main biasing means 60 is enough to prevent rotation of the spindle guide 48 and thus of the spindle 42.
After the cartridge holder 6 is rotated sufficiently, the cartridge holder 6 disengages from the housing 40, which is mediated by the type of connection 22. Then, the cartridge holder 6 is axially moved from the housing 40 by the main biasing means 60 (i.e., in the distal direction). However, during this movement, the main spring 60 continues to load the cartridge holder 6 through the spindle guide 48, and therefore, the spindle 42 cannot rotate. Since the spindle 42 is also threadedly connected to the first drive portion 44, the first drive portion 44 also moves axially distally and thus disengages from the second drive portion 46. The second drive portion 46 is axially fixed and cannot rotate. In one arrangement, the second part 46 of the drive cannot rotate due to the elements of the audible warning device and cannot perform axial movement due to its axial connection with the numerical sleeve.
In FIG. 5 illustrates the dose setting mechanism illustrated in FIG. 3 in the third position, that is, with the cartridge holder 6 removed. When the cartridge holder 6 is removed from the housing 40, the design features of the mount shown in FIG. 5 (illustrated in the form of round pins extending radially inward on the inner side of the inner case) limit the movement of the pressure plate 64 but allow the clearance “C” (as shown in FIG. 4) to be widened to a wider clearance “D” (as shown in Fig. 5). As a result, the gap “E” is revealed. The clearance “E” relieves the high spring force generated by the main biasing means 60 from the spindle guide 48. Now, the dose setting mechanism 4 in FIG. 4 ready to reset.
In order to reset this dose setting mechanism 4, the user retracts the spindle 42 in the proximal direction back into the housing 40, pushing the distal end 43 of the spindle 42. Therefore, during this stage of resetting the dose setting mechanism 4, when the spindle 42 is pushed back inside the dose setting mechanism 4, the movement of the spindle 42 causes the spindle nut 66 to move backward despite the light spring force created by the second biasing means 70. This movement releases axial load and, thus, rotational resistance Orons guide 48 spindle. Therefore, when the dose setting mechanism 4 is reset by rotating the spindle 42 back into the dose setting mechanism 4, the spindle guide 48 also rotates.
When the spindle 42 is pushed further back into the dose setting mechanism 4, the spindle 42 rotates in the spindle nut 66. When the first part 44 of the drive is disconnected from the second part 46 of the drive, the first part 44 of the drive rotates (with flexible elements 102, 103 extending along the groove 90 of the conical surface formed by the first annular protrusion 91 on the second half of the drive coupling 46, Fig. 5 and 6) . Here, the axial and rotational movement of the spindle 42 occurs.
When the first drive portion 44 is rotated during a reset, the first drive portion 44 also resets the dose nut. More specifically, when the first actuator portion 44 is rotated, a dose nut that cannot be rotated since it is grooved to the inner surface of the housing 40 extends along the spiral groove 62 provided along the outer surface of the first actuator portion 44 and extends to the starting or starting position . In one preferred arrangement, this initial position of the dose nut is located along the first circular flange 56 of the first drive portion 44.
After resetting the dose setting mechanism 4, the dose setting mechanism 4 needs to be reconnected to the cartridge holder 6. When these two components are reconnected, the process generally proceeds in the opposite direction. However, this time the axial compression of the main spring 60 causes the first part 44 of the actuator to re-engage the second part of the actuator 46. Thus, the flexible elements re-engage the second annular groove 94 on the second part 46 of the actuator.
In FIG. 6 illustrates a first arrangement of a second drive portion 46 and a first drive portion 44, illustrated in FIG. 3. As shown in FIG. 6, the second drive portion 46 has a generally tubular shape and comprises a first annular groove 90 at the distal end of the second drive portion 46. The first annular groove 90 has a conical surface 91. The second part of the drive further comprises a second annular groove 94 and at least one groove 96 located along the surface of the second part of the drive.
The first part of the drive 44 also has a generally tubular shape and retains the first and second flexible elements 102, 103 and a plurality of recesses 100 grooves. This plurality of recesses 100 detachably connects a longitudinal groove 96 of the first drive part 44 to the second drive part 46 when both the first and second drive parts 44, 46 are axially pushed together so that they engage detachably with each other. When they are pushed together, the flexible members 102, 103 of the first drive portion 44 are pushed over the first annular groove 90 of the second drive portion 46 and then stopped when the flange 80 of the second drive portion abuts the first axial flange 56 of the first drive portion 44.
The first drive part 44 also comprises a plurality of ratchet components 104. These ratchet components 104 are provided at the distal end 106 of the first drive part 44. These ratchet components 104 are engaged with similar ratchet components on a spring plate 25 which is grooved to the housing 2. (See, for example, FIGS. 3-5) At the end of the reset stage, these ratchet components are engaged. with each other so as to prevent rotation of the first drive portion 44. This ensures that when the spindle 42 is reset, the first part of the drive moves axially to re-engage the second part 46 of the drive and not rotate on the conical surface 90. Also, these structural elements define the orientation of the spring plate 25 relative to the second part 44 of the drive so so that the two parts of the drive 44, 46 are easily engaged during assembly or after reset. Therefore, these ratchet components also prevent the connecting structural elements 100, 96 from impacting each other.
A second arrangement of a resettable dose setting mechanism is illustrated in FIG. 8-10. In FIG. 8 illustrates a cross-sectional view of a second arrangement of a dose setting mechanism 200. Those skilled in the art will appreciate that the dose setting mechanism 200 may include a connection mechanism for releasably connecting to the cartridge holder, such as the cartridge holder 6, illustrated in FIG. 2. However, one skilled in the art will appreciate that the dose setting mechanism may also include an integral coupling mechanism for irreversibly connecting to the cartridge holder.
In FIG. 9 illustrates a portion of a dose-setting mechanism illustrating the operation of a drive. In FIG. 10 illustrates a close-up view of the connection between the first part of the drive and the second part of the drive, illustrated in FIG. 9. The second arrangement of the dose setting mechanism 200 functions in a similar manner to the first arrangement of the dose setting mechanism 4 illustrated in FIG. 1-5.
As shown in FIG. 8-10, the dose setting mechanism 200 comprises a dose scale grip 202, a spring 201, an external housing 204, a clutch 205, an actuator 209, a numerical sleeve 206, an audible warning device 220, and an internal housing 208. Similar to the actuator 30 illustrated in FIG. 2-5, the drive 209 of the dose setting mechanism 200 comprises a first drive part 207 and a second drive part 212. In one arrangement, the first drive part 207 comprises a first component 210 and a second component 211. Alternatively, the first drive part 207 is an integral component.
When the dose setting mechanism 200 illustrated in FIG. 8 and 9 contains a resettable dose setting mechanism, the first drive part 207 is disconnected from the dose setting mechanism 200 when the first part of the drive 207 is axially pushed toward the second part 212 of the drive (i.e., pushed in the proximal direction). In one arrangement, this can be achieved by pushing the distal end of the spindle 214 in the axial direction. To do this, you do not need any mechanism associated with the removal of the cartridge holder. The mechanism is also designed so that the first and second parts 207, 212 of the drive together remain rotationally fixed during dose setting, as well as during dose administration.
The axial force on the spindle 214 causes the spindle 214 to rotate due to its threaded connection to the inner housing 208. This rotation and axial movement of the spindle 214 in turn causes the first drive part 207 to move axially towards the second drive part 212. In the end, this will lead to the disconnection of the connecting elements 250 between the first part 207 of the drive and the second part 212 of the drive. This can be seen in FIG. eleven.
This axial movement of the first part 207 of the drive towards the second part 212 of the drive leads to certain advantages. For example, one advantage is that the metal spring 201 will compress and therefore close the gap “A” illustrated in FIG. 8-10. This in turn prevents the clutch 205 from being released from the buzzer 220 or from the numerical sleeve 206. As illustrated in FIG. 9, the distal end of the clutch 205 comprises several clutch teeth 203. These clutch teeth 203 engage with a plurality of teeth of the horn 222 located at the proximal end of the horn 220. Essentially, when the user gains a dose, these clutch teeth and horn 203, 222 respectively mesh with each other to produce an audible click (and possibly a tactile click designation). Preferably, the tines 222 of the buzzer are geometrically arranged so that each click corresponds to an accepted standard dose or the like. Therefore, when the dose scale grip 202 is rotated and thus the clutch 205 is heard, an audible sound is heard when the clutch teeth 203 pass through the teeth 222 of the buzzer.
The second drive 212 cannot rotate because it is grooved to the clutch 205. The buzzer 220 has a plurality of grooves 221. These grooves 221 are grooved to the inner surface of the inner housing 208. Therefore, when the clearance “A” is reduced or closed , the second part 212 of the drive cannot rotate relative to the housing 204 or the numerical sleeve 206. As a result, the numerical sleeve 206 cannot rotate relative to the housing 204. If the numerical sleeve 206 cannot rotate, then there will be no risk pushing the numerical sleeve 206 from the proximal side of the dose setting mechanism 200 as a result of the force exerted on the spindle 214 when the spindle 214 is pulled back into the dose setting mechanism 200 and thereby reset.
Similarly, when dispensing is performed by the drug delivery device, the user applies an axial load to the dose button 216. The gripper 202 of the dose scale is pivotally connected to the sleeve with the scale and non-rotatably connected to the dose button. The axial dose button 216 is connected to the clutch 205, and this prevents relative axial movement. Consequently, the clutch 205 is displaced axially toward the end of the cartridge or the distal end of the dose setting mechanism 200. This movement disengages the clutch 205 from the numerical sleeve 206, allowing relative rotation while closing the gap “A”.
As described above, this prevents the clutch 205 from rotating relative to the buzzer 220 and thus relative to the housing 204. However, in this scenario, the connection between the first drive part 207 and the second drive part 212 is also prevented from engaging. Therefore, any axial load on the spindle 214 only disengages the first and second drive parts 207, 212 when there is no axial load on the dose button 216. Therefore, this does not occur during dosing.
For the dose-setting mechanism 200, as the user picks up the dose using the dose scale grip 202, a sufficiently strong metal spring 201 is selected to maintain engagement of both couplers: the coupler between the coupler 205 and the number sleeve 206 and the coupler between the first drive part 207 and the second part 212 drives.
In FIG. 11 shows in detail the first arrangement of the first drive portion 207 and the second drive portion 212 illustrated in FIG. 8. As illustrated in FIG. 11, the second drive part 212 has a generally tubular shape and comprises at least one drive dog 250 located at the distal end of the second drive part 212. The first drive portion 207 also has a generally tubular shape and comprises a plurality of recesses 252 that are sized to mesh with the drive dog 250 on the second drive portion 212. The design of the drive dog and the recesses allows it to disengage from the drive dog 250 when the first and second parts of the drive are pushed together in the axial direction. This design also creates a rotational connection when these components are removed by means of a spring. On the first drive portion 207, a dose limiter can be provided that acts in a manner similar to the dose limiter 38 illustrated in FIG. 3.
In this arrangement, the first part 207 of the actuator comprises a first part 211, which is irreversibly clamped in the second part 210. In this arrangement, the first part 211 contains pawls 252 of the actuator and the second component 210 contains an external groove for the nut of the last dose, as well as an internal groove 254. This internal groove 254 is used to connect to spindle 214 and it moves spindle 214 during dose administration.
In the illustrated arrangement, the inner groove 254 comprises a partially helical groove rather than a fully helical groove. One advantage of this arrangement is that it is generally easier to manufacture.
As can be seen from the arrangement illustrated in FIG. 8-10, in addition, there are certain improvements in design features with respect to the dose-setting mechanism 4 illustrated in FIG. 3-5. They can be added regardless of the ability to reset the device to replace an empty cartridge with a new cartridge. Therefore, these improvements are appropriate for both resettable and non-resettable dose-setting mechanisms.
One of the advantages of the two illustrated arrangements is possible, with the exception of only the arrangement, in particular, illustrated in FIG. 8-11, the dose setting mechanism 200 has a reduced number of components relative to other known dose setting mechanisms. In addition, with the exception of the metal coil spring 201 (see FIGS. 9 and 10), all of these components making up the dose-setting mechanism 200 can be injection molded using economical and uncomplicated equipment. As just one example, these components making up the dose-setting mechanism 200 can be injection molded without the expense and complexity of the pivot shaft.
Another advantage of the dose setting mechanism 200 comprising an inner case 208, such as that illustrated in FIG. 8-11, the dose-setting mechanism 200 can be designed with minor modifications as a platform for a drug delivery device that will be capable of supporting both resettable and non-resettable drug delivery devices. By way of just one example, in order to modify a variant of the resettable dose setting mechanism 200 illustrated in FIG. 8-11, to the non-resettable drug delivery device, the first drive part 211 and 210 and the second drive part 212 can be cast as one integral part. This reduces the total number of components of the drug delivery device by two. In another case, the drug delivery device illustrated in FIG. 8-11 may remain unchanged. In such a disposable device, the cartridge holder will be fixed to the housing, or alternatively will be in the form of a single solid body and cartridge holder.
In the illustration of FIG. 8-11, an inner case 208 is shown that has a length “L” 230, generally similar in total length to the dose setting mechanism 200. As described, providing an internal case 208 of length “L” has many advantages over other known dose setting mechanisms, which the inner case is not used or the inner case has a length generally equal to the length of the dose-setting mechanism.
The inner housing 208 comprises a groove 232 provided along the outer surface 234 of the inner housing. A guide groove 236 provided on the inner surface 238 of the numerical sleeve 206 is in rotational engagement with this groove 232.
One advantage of this dose-setting mechanism 200, in which the inner housing 208 is used, is that the inner housing 208 can be made of structural plastic that minimizes friction against the number sleeve 206, the guide grooves 236 and the groove 232. For example, one such structural plastic may contain acetal. However, one skilled in the art will appreciate that other compatible structural plastics having a low coefficient of friction can also be used. The use of such structural plastic allows the material to be selected for the outer casing 204 based on aesthetic or tactile considerations that are not related to friction requirements, since the outer casing 204 is not engaged with any moving components during normal operation.
The inner housing 208 also allows a spiral groove to be provided in the numerical sleeve 206 on the inner surface 238 of the numerical sleeve 206, rather than providing such a spiral groove on the outer surface 240 of the numerical sleeve 206. Providing such an inner groove has several advantages. For example, this leads to one advantage in the form of a larger surface area on the outer surface 240 of the numerical sleeve 206 so as to provide for the placement of a scale 242. The increased surface area of the numerical sleeve can be used for identification of a drug or device. Another advantage associated with the provision of a spiral groove 236 on the inner surface 238 of the drive coupling 206 is that the inner groove 236 is protected against penetration of dirt. In other words, dirt is much more difficult to get into this contact area of the inner groove than if the groove were made along the outer surface 240 of the numerical sleeve 206. This feature is, in particular, important for the dropping drug delivery device, which must last for a much longer time time period than non-resettable device.
The effective driving diameter (represented by “D”) of the contact area with the groove between the numeric sleeve 206 and the inner housing 208 is reduced compared to certain known devices for delivering the drug to the same diameter of the external body. This increases efficiency and allows the drug delivery device to function in smaller steps (represented by “P”) to connect this groove and the guide groove. Thus, in other words, the spiral angle of the thread determines whether the numerical sleeve rotates or locks on the inner body when pressed in the axial direction, where this spiral angle is proportional to the P / D ratio.
You can make a numerical sleeve 206 the length of the mechanism "L" 230, and not divide this length into the space required for the numerical sleeve 206, and the space required for the buzzer and dose limiter. One advantage of this configuration is that it provides good axial engagement between the numeric sleeve 206 and the outer case 204. This improves the functionality (obviously, and quality) of the dose setting mechanism when the user uses the drug delivery device to set the maximum dose set. In FIG. 13 illustrates a dose-setting mechanism 200 on which a maximum dose of 80 international units (“ME”) is set.
Another advantage is that it allows you to hide the layout of the scale 242 inside the outer casing 204, even when the maximum value is reached on the numerical sleeve 206, as can be seen in FIG. 13. However, the structure does not limit the position of the window 14 shown in FIG. 8, a allows you to place this window 14 next to the capture 202 of the dose rate device. In the arrangements illustrated in FIG. 12 and 13, the layout of the scale 242 is visible only through window 14.
Also, the actuator 209 (made in two parts or only in one solid component) can be made with a flat internal through hole plus a thread profile that can be cast using forming pins that are axially moved. This avoids the drawback of the drive, which has an internal thread with more than one revolution and, therefore, requires turning the forming pin a few turns during the extraction process from the mold.
One potential drawback of using a dose-setting mechanism that includes an inner case 208 is that the use of an internal case 208 adds an integral part to the total dose-setting mechanism 200. Thus, this inner case 208 will increase the overall wall thickness to be constructed so as to be installed between the clutch 205 and the numerical sleeve 206. One way to circumvent this design problem, as illustrated in FIG. 8, is to reduce the diameter of the clutch 205 and the numerical sleeve 206. This, in turn, can be achieved since the thread profile between the drive 209 and the spindle 214 contains a protruding internal design feature on the drive 209 and the profile of the concave outer groove on the spindle 214, which overlap (with a similar diameter) with the profile of the spindle groove, which fits into the groove along the inner surface 234 of the inner housing 208 or body part.
Overlapping the groove profiles of the spindle 214 reduces the effective diameter of the thread contact surface with the actuator 209. This also reduces the possible external diameter of the actuator 209, which allows the inner housing 208 to be added without increasing the overall external diameter of the dose setting mechanism 200. Another additional advantage of the reduced effective diameter of the thread contact surface with driven 209 is that this improves the efficiency of the drug delivery device during dosing, as explained above.
The window 244 through which the layout of the scale 242 can be seen may either be simply a hole in the outer housing 204 or it may contain a transparent lens or a window designed to increase the layout of the scale (i.e., dose values printed or laser applied) along part of the outer surface 240 on the numerical sleeve 206.
The connection of the cartridge holder to the external housing 204 can be accomplished using a screw or bayonet type connection. Alternatively, you can also use any similar durable structures used in drug delivery devices where you need to remove and then re-attach a large cylindrical part.
With a limited selection of mechanical advantages available when using the overlapping scroll spindle 214 in the arrangement illustrated in FIG. 8-11, it is often difficult to achieve the necessary optimal choice of mechanical advantage for the length of the dose-setting mechanism (and thus the overall length of the drug delivery device). Thus, an alternative arrangement for this dose setting mechanism that has a multi-component drive clutch may be desirable. Consequently, there may be a need for an improved dose-setting mechanism that allows the mechanical advantage to be varied without changing the groove pitch ratio on the spindle, such as the multi-groove spindle illustrated in FIG. 8-10. Such an improved dose setting mechanism is illustrated in FIG. 14 and 15.
For example, in FIG. 14 is a cross-sectional view of another embodiment of a dose-setting mechanism of the drug delivery device illustrated in FIG. 1. In FIG. 15 is a partial cross-sectional view of an embodiment of the dose setting mechanism illustrated in FIG. 14. This alternative arrangement of the dose setting mechanism 300 as a whole is the same as the dose setting mechanism 200 illustrated in FIG. 8-11. That is, the operations of setting the dose and injection of the dose are generally similar. However, one difference between the two dose-setting mechanisms is what happens when the user resets the dose-setting mechanism 300.
As shown in FIG. 14 and 15, the dose setting mechanism 300 comprises a dose scale grip 302, a spring 301, an external housing 304, a clutch 305, an actuator 309, a numerical sleeve 306, an audible alarm 375, a dose limiter 318, and an internal housing 308. Similar to the actuator 209 illustrated in FIG. . 8-11, the drive 309 of the dose setting mechanism 300 comprises a first drive part 307 and a second drive part 312. In one arrangement, the first drive part 307 comprises a first component 310 and a second component 311 (generally see FIG. 11). Alternatively, the first drive part 307 is an integral component.
When the dose setting mechanism 300 illustrated in FIG. 14 and 15 contains a resettable dose setting mechanism, the first drive part 307 is disconnected from the dose setting mechanism 300 when the first drive part 307 is axially pushed toward the second drive part 312 (i.e., pushed in the proximal direction). This does not require any mechanism associated with the removal of the cartridge holder. The mechanism is also designed so that the first and second drive parts 307, 312 remain rotationally fixed together during dose setting as well as during dose administration.
Returning to the arrangements illustrated in FIG. 8-10, the multi-component actuator 209 is moved axially without rotation relative to the inner housing 208 during dose dosing. In the alternative arrangement illustrated in FIG. 14-15, the actuator 309 is not only axially moved during dispensing, but also must be moved along a spiral path. Such a helical path can be defined by one or more helical grooves 341 cast in the inner surface of the inner housing 308. In such an arrangement, the path of the actuator 309 can be controlled through a rotational connection between the buzzer 375 (preferably through the second part of the buzzer 377) with at least one a spiral groove 341 provided along the inner surface of the inner housing 308.
If these helical grooves provided along the inside of the inner housing 308 rotate in the opposite direction with respect to the thread profile on the first drive portion 307 or the numerical sleeve 306, then the mechanical advantage can be reduced. However, if these spiral grooves rotate in the same direction as the thread profile on the first part 307 of the drive or the numerical sleeve 306, and with a large step, then the mechanical advantage can be increased.
Using such a proposed dose-setting mechanism 300, equations for the resulting mechanical advantage can be calculated using the following equation: (A + B) / [A × (1-B / C)]. In this equation, A represents the groove pitch between the spindle 314 and the inner housing 308, B represents the groove pitch between the spindle 314 and the first drive part 307, and C represents the pitch of the spiral grooves 341 with a positive sign that represents the same direction as B.
In this arrangement, and as illustrated in FIG. 14 and 15, the buzzer 375 comprises a multi-component buzzer. In particular, the buzzer 375 comprises a first buzzer part 376 and a second buzzer part 377. The first and second parts 376, 377 of the buzzer contain the teeth 378 and 377 of the buzzer, respectively. Both the first and second parts of the buzzer 376, 377 are located on the distal side of the metal coil spring 301. This is different from the buzzer located in the dose-setting mechanism 200 illustrated in FIG. 8. In the arrangement illustrated in FIG. 8, the arrangement of the audible warning device 220 is located on the proximal side of the spring 201.
Placing the buzzer 375 on the distal side of the metal coil spring 301 provides several advantages. For example, this helps to ensure that the second part 377 of the buzzer, which is rotationally connected to the helical grooves provided along the inner housing 308, cannot be axially moved and thus cannot be rotated relative to the housing when the button 316 is pressed so that thereby disengaging the clutch 305 from the numerical sleeve 312. If the buzzer 375 can be rotated, the buzzer 375 will cause the clutch 305 to rotate. If this occurs, this can prevent re-engagement of the clutch 305 with the sleeve 306 with a dose scale at the end of the dose. Also, if the clutch 305 can rotate when the button 316 is pressed, the actuator 309 will also rotate and this will affect dose accuracy when the user releases the button 316 and rotates the actuator 309.
Again, in this alternative arrangement of the dose-setting mechanism 300, instead of having teeth of an audible warning device between the audible warning device 375 and the first drive part 307, the audible warning device 375 is divided into two parts 376, 377. In this arrangement, the first drive part 307 can be rotated by round bearing surface during the reset of the spindle 314, and the teeth of the buzzer instead are placed between the first and second parts 376, 377, buzzer, respectively. The first buzzer part 376 can be rotationally connected to either the actuator 309 or the clutch 305. Therefore, during dose setting, the first buzzer part 376 is rotated relative to the second buzzer part 377, which is rotationally connected to the spiral grooves 341 in the inner housing 308, as indicated above.
Also in this arrangement, where it is the first part 376 of the buzzer, which oscillates in the axial direction (in the proximal direction and then in the distal direction) during dialing, the teeth 378, 379 of the buzzer can be symmetrical. One advantage of the symmetrical prongs of the buzzer is that the user is provided with a similar tactile response when he or she increases the dose compared to decreasing the dose. If the first part 376 of the buzzer is rotationally connected to the inner housing 308, since this first part 376 of the buzzer vibrates proximally and distally during dialing, it will also rotate rotationally. One obvious drawback of such an arrangement is that the resulting set-up torque will substantially differ when the user increases or decreases the dose.
It should be noted that in the dose setting arrangement 300 illustrated in FIG. 14 and 15, the number of teeth of the buzzer on the first and second parts 376, 377 of the buzzer should be changed in order to take into account the thread pitch B and C in order to get the correct number of clicks per rotation to match numbers or other similar dose setting pointers provided on sleeve 312 with a dose scale. In addition, the dose limiter 318 also includes a slot 333, which is included in the same spiral grooves 341 in the inner housing 308, as the second part 377 of the audible warning device. Therefore, during dose dosing, the dose limiter 318 will not rotate relative to the actuator 309, thereby ensuring that no additional doses can be gained after the dose limiter 318 is in contact with the stopper on the first drive part 307. Similarly to the drive illustrated in FIG. 8-11, the first part 307 of the drive of the dose setting mechanism 300 comprises two parts compressed together.
Although the dose setting mechanism 300 illustrated in FIG. 14 and 15, provides several advantages, there are also certain limitations associated with this arrangement. For example, one problem with the dose-setting mechanism 300 is that when the mechanism is discarded so as to replace a used cartridge, the spindle 314 is retracted in the proximal direction. Pulling the spindle back in the proximal direction moves the first part 307 of the drive and thus the buzzer 375 in the proximal direction relative to the outer casing 304. If the buzzer 375 is moved relative to the casing 304, then the buzzer 375 is also rotated. Therefore, during the reset stage, the first the drive part 307 not only compresses the spring 301, but must rotate the buzzer 375 and, thus, the drive 309, the clutch 305 and the sleeve 306 with the dose scale relative to the housing 304. This increases the effort the amount needed to reset the dose-setting mechanism 300.
In FIG. 16 is a cross-sectional view of yet another embodiment of a dose-setting mechanism for the drug delivery device illustrated in FIG. 1. In this illustration, the dose setting mechanism 400 is illustrated with the dose setting button depressed. In FIG. 17 is a partial cross-sectional view of an embodiment of a dose setting mechanism 400 illustrated in FIG. 16, in a second position with the dose setting button depressed. In FIG. 18 is a partial cross-sectional view of an embodiment of the dose setting mechanism 400 illustrated in FIG. 17, with the second beacon part 477 removed.
An alternative embodiment of the dose setting mechanism 400 comprises a clutch 405, an audible warning device 475, and a spring 401. As shown in FIG. 16, the buzzer 475 comprises a first buzzer part 476 and a second buzzer part 477. In this arrangement, the first buzzer portion 476 is similar to the buzzer illustrated in FIG. 8-11, in that the first part 476 of the acoustic signal device contains a plurality of teeth 422 of the acoustic signal device. These tines 422 of the buzzer are engaged with a plurality of tines 403 of the clutch.
However, unlike the buzzer 220 of FIG. 8, comprising slots that engage with the spiral groove 241 provided on the inner housing 208, the first portion 476 of the sound detector of the dose setting mechanism 400 is not in grooved connection with the inner housing. Conversely, the second buzzer part 477 is rotationally connected to the first buzzer part 476, axially connected to the actuator 409, and rotationally connected to the spiral grooves provided on the inner case. In this arrangement of the dose-setting mechanism 400, neither the drive 409, nor the clutch 405, nor the buzzer will rotate when the dose button is pressed. Similarly, neither the actuator 409, nor the clutch 405, nor the buzzer will rotate when the dose setting mechanism 400 is reset. One advantage of this arrangement is that this mechanism provides low force to reset the handle and good dose accuracy.
In FIG. 19 illustrates a second buzzer portion 477, which can be used with the dose setting mechanism illustrated in FIG. 16. As can be seen in FIG. 19, the second part 477 of the buzzer contains a plurality of grooves 480 that engage with a spiral groove made along the inner surface of the inner case. In addition, the second part 477 of the audible warning device further comprises a recess 482. This recess 482 is engaged with a ridge formed on the second part 412 of the drive. When this recess 482 engages with this ridge, the second part 477 of the acoustic warning device in the axial direction is fixed on the second part 412 of the drive.
In particular, the various arrangements of the horn presented in embodiments 200, 300, and 400 can be installed either inside the inner body, as shown, or externally, where ridges or grooves in the horn engage with ridges or grooves on the outer surface of the inner body or, as shown in the first embodiment (see FIGS. 3-5), on the inner surface of the external body. When the inner body exists, in these alternative arrangements, the clutch, spring, and horn components must lie outside the inner body, and the drive can still be rotationally connected to the clutch and lie inside the inner body to move the spindle forward.
Exemplary embodiments of the present invention are described. However, specialists in this field will understand that you can make changes and modifications of these embodiments without departing from the essence and scope of the present invention, which is defined by the claims.
1. A dose-setting mechanism for a drug delivery device, comprising:
outer casing;
an inner case that has an outer groove, wherein said inner case is configured to direct a drive to distribute a dose given by a specified dose-setting mechanism; and
a sleeve with a scale located between the outer case and the inner case, and the sleeve with the scale is in rotary engagement with the specified outer groove of the inner case;
where the specified sleeve with a scale is made to rotate with respect to both the outer casing and the inner casing during dose setting and is configured to move both from the outer casing and the inner casing, characterized in that the inner casing contains an internal spiral groove .
2. The dose-setting mechanism according to claim 1, wherein the internal spiral groove is configured to direct the spiral movement of said drive during dose dosing.
3. A dose setting mechanism according to claim 1 or 2, wherein said drive comprises a first drive part and a second drive part, wherein the first or second drive part preferably comprises a plurality of drive components.
4. The dose-setting mechanism according to claim 1, wherein the mechanism further comprises a dose limiter, wherein the dose limiter is in a grooved connection with a spiral groove of the inner case.
5. The dose-setting mechanism according to claim 4, wherein said dose limiter comprises an internal spiral groove that is operatively connected to a spiral groove made on said drive.
6. The dose-setting mechanism according to claim 1, which further comprises an audible warning device.
7. The dose-setting mechanism of claim 6, wherein the audible warning device guides the spiral movement of said actuator and where the audible warning device is located inside the inner case.
8. The dose-setting mechanism according to claim 6, wherein the audible warning device comprises a first part of an audible warning device and a second part of an audible warning device, said first part of an audible warning device comprising a first set of teeth of an audible warning device which are adapted to engage with a second set of teeth of an audible warning device of a second part sound signaling device.
9. The dose-setting mechanism according to claim 6, wherein the audible warning device or the first part of the audible warning device comprises said at least one groove configured to engage with a spiral groove of the inner case.
10. The dose-setting mechanism of claim 6, wherein the audible warning device comprises a first set of teeth of the audible warning device, which is rotationally engaged with the clutch.
11. The dose-setting mechanism according to claim 6, where the audible warning device is mounted on the specified drive in the axial direction.
12. The dose setting mechanism according to claim 6, wherein the audible warning device is rotatable during the dose setting stage and / or rotatable during the dosing stage and / or where the dose setting mechanism containing the resettable dose setting is rotated during the reset stage mechanism.
13. The dose-setting mechanism of claim 1, further comprising a spindle, wherein the spindle is operatively coupled to said drive so that when the inner case guides said drive to distribute said dose given by the specified dose-setting mechanism, the drive pushes the spindle to render impact on the cartridge plug, while the spindle moves in the distal direction in order to push the specified dose out of the cartridge.
14. The dose-setting mechanism of claim 13, wherein said spindle comprises first and second helical grooves.
15. The dose setting mechanism of claim 13, wherein said spindle is configured so as not to rotate during the dose setting stage and / or during the dosing stage and / or during the reset stage.
16. The dose-setting mechanism according to any one of paragraphs. 1-15, where the specified mechanism is configured to set a dose dispensed from a cartridge containing a pharmaceutical composition that contains at least one pharmaceutically active compound.
17. The dose-setting mechanism of claim 16, wherein the pharmaceutically active compound comprises at least one human insulin, or a human insulin analog or derivative, a glucagon-like peptide (GLP-1), or its analog, or derivative, or exedin-3, or exedin-4, or an analog, or a derivative of exedin-3 or exedin-4.
18. A dose-setting mechanism for a drug delivery device, said mechanism comprising: an outer case; an inner case that has an outer groove and a spiral groove, said spiral groove of the inner case being located on an inner surface of the inner case;
sleeve with a scale connected to the specified outer groove of the inner case:
a drive rotatably coupled to a sleeve with a scale during the dose setting step;
a connecting element containing at least one ridge, which is rotatably connected to the spiral groove of the inner housing:
so that when during the indicated dose setting stage the sleeve with the scale and the drive rotate together, while the specified sleeve with the scale follows the outer groove on the inner case, and the specified connector rotates in a spiral groove and can rotate relative to the sleeve with the scale and the drive;
and during the dose distribution step, said drive is rotatably disconnected from the sleeve with a scale and rotatably coupled to said connector,
characterized in that the said connector is made without the possibility of axial movement relative to the inner case and without the possibility of rotation of the specified drive when the dose-setting mechanism moves between the positions of the specified dose setting stage and the specified dose dosage stage or between the positions of the specified dose dosage stage and the specified installation stage doses.
19. The dose-setting mechanism of claim 18, wherein said mechanism is configured to set a dose dispensed from a cartridge containing a pharmaceutical composition that contains at least one pharmaceutically active compound.
20. The dose-setting mechanism of claim 19, wherein the pharmaceutically active compound comprises at least one human insulin, or a human insulin analog or derivative, a glucagon-like peptide (GLP-1), or its analog, or derivative, or exedin-3, or exedin-4, or an analog, or a derivative of exedin-3 or exedin-4.
RU2011154367/14A 2009-06-01 2010-05-28 Internal case of device, possessing spiral slot, for delivery of medication RU2555133C2 (en)
US18286409P true 2009-06-01 2009-06-01
US61/182,864 2009-06-01
PCT/EP2010/057490 WO2010139643A1 (en) 2009-06-01 2010-05-28 Drug delivery device inner housing having helical spline
RU2011154367A RU2011154367A (en) 2013-07-20
RU2555133C2 true RU2555133C2 (en) 2015-07-10
RU2011154367/14A RU2555133C2 (en) 2009-06-01 2010-05-28 Internal case of device, possessing spiral slot, for delivery of medication
US (4) US8257319B2 (en)
EP (2) EP3572109A1 (en)
CN (2) CN103418057A (en)
AU (1) AU2010255818B2 (en)
BR (1) BRPI1014738A2 (en)
DK (1) DK2437828T3 (en)
IL (1) IL216429A (en)
MX (1) MX2011012214A (en)
NZ (1) NZ596706A (en)
SG (2) SG176081A1 (en)
ZA (1) ZA201107728B (en)
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2010-05-27 US US12/788,780 patent/US8257319B2/en active Active
2010-05-28 WO PCT/EP2010/057490 patent/WO2010139643A1/en active Application Filing
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DK2437828T3 (en) 2019-11-11
NZ596706A (en) 2013-10-25
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US20120172809A1 (en) 2012-07-05
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IL216429A (en) 2014-12-31
US8257319B2 (en) 2012-09-04
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EP2437828A1 (en) 2012-04-11
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US20120165750A1 (en) 2012-06-28
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BRPI1014738A2 (en) 2016-04-12
US20190366005A1 (en) 2019-12-05
CN102448526B (en) 2015-08-19 For the resetting-mechanism of drug delivery device
JP5818786B2 (en) 2015-11-18 Drive mechanism for drug delivery device