Preservative free insulin formulations

Abstract

One embodiment describes an insulin formulation that is specifically adapted for aerosolization. The formulation comprises a major amount of water and a minor amount of insulin. Further, the formulation is preservative free, without meta-cresol, cresol or phenol, to permit the formulation to be aerosolized using a vibrating aperture plate without substantial foaming of the insulin formulation.

Claims

1. An insulin formulation specifically adapted for aerosolization, the formulation comprising: a major amount of water; a minor amount of insulin; and 2 to 4 Zn.sup.2+ per insulin hexamer, wherein the formulation is preservative free thereby facilitating aerosolization of the formulation as an aerosolized liquid spray; and wherein the liquid spray is produced-without substantial foaming of the insulin formulation.

2. The insulin formulation of claim 1, wherein the formulation has a concentration of about 100 IU/ml to about 1200 IU/ml of human insulin.

3. The insulin formulation of claim 1, wherein the water comprises in volume about 99.8% to about 97.0%, and the insulin comprises in volume about 0.2% to about 3.0%.

4. The insulin formulation of claim 1, wherein the formulation does not include phenol, metacresol, chloro-cresol, or thymol.

5. The insulin formulation of claim 1, wherein the formulation does not include non-phenol preservatives selected from the group consisting of bicyclic aliphatic alcohols, tricyclic aliphatic alcohols, bicyclic aliphatic purines, and tricyclic aliphatic purines.

6. The insulin formulation of claim 1, wherein the formulation does not include surfactants or detergents.

7. The insulin formulation of claim 1, wherein the formulation comprises glycol.

8. The insulin formulation of claim 1, wherein the formulation is aerosolizable using a vibrating aperture plate without substantial foaming of the formulation.

9. The insulin formulation of claim 8, wherein the vibrating aperture plate has a plurality of apertures and vibrates at a frequency in a range from about 50 kHz to about 150 kHz.

10. A preservative-free insulin formulation comprising: 100 IU/ml to about 1200 IU/ml of human insulin; a minor amount of HCl and NaOH; and 2 to 4 Zn.sup.2+ per insulin hexamer, wherein the formulation does not comprise a preservative.

11. The preservative-free insulin formulation of claim 10, wherein the formulation has a pH of about 7.4.

12. The preservative-free insulin formulation of claim 10, wherein the formulation does not include phenol, metacresol, chloro-cresol, or thymol.

13. The preservative-free insulin formulation of claim 10, wherein the formulation does not include non-phenol preservatives selected from the group consisting of bicyclic aliphatic alcohols, tricyclic aliphatic alcohols, bicyclic aliphatic purines, and tricyclic aliphatic purines.

14. The preservative-free insulin formulation of claim 10, wherein the formulation does not include surfactants or detergents.

15. The preservative-free insulin formulation of claim 10, wherein the formulation comprises glycol.

16. A method for manufacturing a preservative-free insulin formulation comprising: suspending human insulin powder in water, the human insulin powder comprising 2 to 4 Zn.sup.2+ per insulin hexamer; adding a minor amount of HCl to dissolve the human insulin and form an insulin solution; after the human insulin is dissolved, adding a minor amount of NaOH to titrate the insulin solution to a desired pH; and adding additional water to adjust the concentration of the insulin solution to 100 IU/ml to 1200 IU/ml human insulin; wherein the inulin solution is devoid of preservatives.

17. The method of claim 16, wherein the pH is about 3.0 when the HCl is added.

18. The method of claim 16, wherein the insulin solution is titrated to about pH 7.4.

19. The method of claim 16, wherein the formulation does not include phenol, metacresol, chloro-cresol, or thymol.

20. The method of claim 16, wherein the formulation does not include non-phenol preservatives selected from the group consisting of bicyclic aliphatic alcohols, tricyclic aliphatic alcohols, bicyclic aliphatic purines, and tricyclic aliphatic purines.

21. The method of claim 16, wherein the insulin formulation is also devoid of surfactants and detergents.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective, partial cut-away view of one embodiment of a dispensing apparatus according to the invention.

(2) FIG. 2 is a more detailed view of the dispensing apparatus of FIG. 1.

(3) FIG. 3 is a graph illustrating the time required to aerosolize different insulin formulations.

(4) FIG. 4 is a graph illustrating aerosolization times for various insulin formulations as well as for water and saline.

(5) FIG. 5 is a graph illustrating aerosolization times for various insulin formulations, including the formulations of Examples 1-3 when glycol is added.

DETAILED DESCRIPTION OF THE INVENTION

(6) Certain embodiments of the invention provide a preservative free insulin formulation that may be used with an aerosolization device to provide an aerosolized spray of insulin. More specifically, the insulin formulations do not contain any preservatives, including phenol, metacresol, chloro-cresol, thymol and mixtures thereof or the like. The absence of such preservatives enable the formulations to be aerosolized as a liquid spray using a vibrating mesh or aperture plate that operates at high frequencies. The absence of such preservatives permits a dosage of the formulation to come into contact with the vibrating mesh without substantial foaming of the formulation. In turn, the formulation may be aerosolized more quickly. Further, substantially all of the liquid is able to be aerosolized.

(7) The formulations contain water in major and human insulin in minor amount. The formulations may also include various concentrations of human insulin. For example, the concentrations may be in the range from about 100 IU insulin/ml of formulation to about 1200 IU insulin/ml of formulation, and more preferably from about 200 IU insulin/ml of formulation to about 800 IU insulin/ml of formulation.

(8) In addition to water and human insulin, the formulations may also include zinc, acetate, chloride and sodium. The zinc ion and acetate ion come from the drug substance, e.g., the insulin. The chloride ion and sodium ion are added during dissolution of the insulin and adjustment of the pH. Merely by way of example, the NaCl concentration may be about 20 mM for an 800 IU insulin/ml formulation, about 10 mM for a 400 IU insulin/ml formulation, and about 5 mM for a 200 IU insulin/ml formulation.

(9) The following are various non-limiting examples of preservative free formulations that may be used according to the invention:

Example 1800 IU Insulin/ml Formulation

(10) In this example, 50 ml of the 800 IU insulin solution was made by suspending 1400 mg human insulin (with 2 to 4 Zn.sup.2+ per insulin hexamer) in 44 ml water, then dissolved the insulin by adding 1.0 ml 1 N HCl to pH about 3.0. After all of the insulin dissolved, 1.6 ml 1 N NaOH was slowly added to titrate the insulin solution to pH 7.4. Finally, water was added to 50 ml.

Example 2400 IU Insulin/ml Formulation

(11) In this second example, 50 ml of the 400 IU insulin solution was made by suspending 700 mg human insulin (with 2 to 4 Zn.sup.2+ per insulin hexamer) in 44 ml water, then dissolved the insulin by adding 0.5 ml 1 N HCl to pH about 3.0. After all of the insulin dissolved, about 0.8 ml 1 N NaOH was slowly added to titrate the insulin solution to pH 7.4. Finally, water was added to 50 ml.

Example 3200 IU Insulin/ml Formulation

(12) In this third example, 50 ml of the 200 IU insulin solution was made by suspending 350 mg human insulin (with 2 to 4 Zn.sup.2+ per insulin hexamer) in 44 ml water, then dissolved the insulin by adding 0.25 ml 1 N HCl to pH about 3.0. After all of the insulin dissolved, about 0.4 ml 1 N NaOH was slowly added to titrate the insulin solution to pH 7.4. Finally, water was added to 50 ml.

(13) A wide variety of inhalers or aerosolizers may be used to aerosolize the preservative free solution. For example, an aerosolizing apparatus may comprise a housing defining a dispensing outlet, a vibratable membrane having a front face exposed at the outlet and a rear face for receiving a liquid to be dispensed, and a vibrating mechanism connected to the housing and operable to vibrate the membrane to dispense aerosol of the liquid through the membrane. In some cases, a liquid delivery system may also be used to deliver a metered quantity of the liquid from to the rear face of the membrane. In this way, a metered quantity of liquid is dispensable at the outlet by operating the vibrating mechanism for an operating period sufficient to completely aerosolize the metered quantity of the rear face.

(14) Examples of certain types of aerosolizers that may be used are described in U.S. Pat. No. 8,950,394, entitled PRESERVATIVE-FREE SINGLE DOSE INHALER SYSTEMS, filed on Jan. 11, 2011 and issued on Feb. 10, 2015, previously incorporated by reference.

(15) Referring now to FIG. 1, one embodiment of an inhaler will be described. FIG. 1 illustrates a partially cut-away view of an inhaler 100. Inhaler 100 may be used in connection with various containers that supply the liquid insulin. For example, inhaler 100 may be used with a unit dose blister package for supplying a metered quantity of insulin to the inhaler. Inhaler 100 comprises two subassemblies 102 and 112. The first subassembly 102 defines a compartment for the electronic circuitry and the batteries, and the second subassembly 112 defines a housing with a dispensing outlet 105 and contains a vibratable membrane aerosol generator 108 and a lid 104 that may be closed as shown by arrow 115. Aerosol generator 108 has a front face exposed at the outlet duct 111 and a rear face 109 contacted in use by liquid to be dispensed. Aerosol generator 108 is connected to the housing of subassembly 112 and is operable to dispense the active pharmaceutical agent as an aerosol through the mouthpiece 105. Exemplary aerosol generators that may be used are also described in U.S. Pat. Nos. 5,164,740; 6,629,646; 6,926,208; 7,108,197; 5,938,117; 6,540,153; 6,540,154; 7,040,549; 6,921,020; 7,083,112; 7,628,339; 5,586,550; 5,758,637; 6,085,740; 6,467,476; 6,640,804; 7,174,888; 6,014,970; 6,205,999; 6,755,189; 6,427,682; 6,814,071; 7,066,398; 6,978,941; 7,100,600; 7,032,590; 7,195,011, incorporated herein by reference. These references describe exemplary aerosol generators, ways to manufacture such aerosol generators and ways to supply liquid to aerosol generators, and are incorporated by reference for at least these features. The aerosol generators may comprise vibratable membranes having tapered aperture with a size in the range from about 3 m to about 8 m, preferably from about 3 m to about 6 m, and in some cases around 4 m. The membrane may be domed shaped and be vibrated by an annular piezoelectric element that circumscribes the apertures. The diameter of the membrane may be in the range from about 5 mm to about 8 mm. The membrane may also have a thickness in the range from about 50 microns to about 70 microns. Typically, the membrane will be vibrated at a frequency in the range from about 50 kHz to about 150 kHz.

(16) Further, to minimize foaming of the insulin formulations, the membrane may be vibrated at an amplitude that is less than about 4 m, preferably less than 3 m and more preferably less than 2 m.

(17) Each time a metered quantity of liquid is supplied to inhaler 100, it is delivered to the rear face 109 of the aerosol generator. Hence, for each use a metered quantity of aerosolized pharmaceutical agent may be dispensed at the mouthpiece outlet 105 by operation of the aerosol generator.

(18) Inhaler 100 further includes a well 107 to receive the content of a container so that it may be supplied to the aerosol generator 108. The well 107 has a concave shape and defines a fluid passage to the vibrating aerosol generator 108.

(19) FIG. 2 illustrates the vibrating membrane 109 of the aerosol generator 108 in greater detail. When a volume of liquid is dispensed an indicator light 120 starts to blink signaling to the patient that the inhaler 100 is ready for use. At any time shortly thereafter the patient may inhale through the mouthpiece 105. Patient inhalation is detected by a flow sensor which in turn activates the aerosol generator 108 to produce aerosol particles into the duct 111. Aerosol is entrained in the inhalation air flow in the direction shown by arrows 121 and flow via the respiratory system to the lungs of the patient. When the entire dose is aerosolized, which may take one or more breaths, the end-of-dose indicator light 123 lights a second time to signal the patient that the entire dose has been delivered. Delivery of the entire dose is obtained when at least about 95% of the dose is delivered, more preferably 98% and most preferably when more than 99% of the dose is delivered. In one embodiment, the opening funnel to the aerosol generator is sufficiently large such that the liquid delivery to the aerosol generator is delivered in its entirety. To receive the dose, the patient may take several inhalations or a single inhalation depending on the volume delivered to the mesh and the patient's breathing capacity. Each inhalation should be a deep breath to assure that the aerosol reaches deeply to the lungs.

(20) The preservative-free insulin formulations are particularly useful in that they do not have substantial foaming when coming into contact with the vibrating membrane. In turn, this permits the formulation to be rapidly aerosolized. This is a critical feature in that the dosage needs to be quickly aerosolized so that the user can inhale the insulin in a short time frame. In most cases, it is desirable to limit the number of inhalations required to administer the formulation. Depending on the user's ability to inhale, it is desirable to administer the entire dosage in about 1 to 3 breaths. Typical dosage amounts are in the range from about 40 L to about 200 L. Aerosolizing these volumes fast enough to permit them to be inhaled within a few breaths is a critical feature of the invention. It is desirable to aerosolize these volumes in less than about 22 seconds, and more particularly less than about 15 seconds to permit them to be inhaled in about 1 to 3 breaths.

(21) The graphs of FIGS. 3 and 4 illustrate how the insulin formulations of the invention provide this critical feature while commercially available insulin formulations are unable to aerosolize in an acceptable time frame. As shown, the Humalin, Lantus and Humalog formulations took in excess of 30 seconds to aerosolize 100 L of insulin formulation. This is because both of these formulations had significant foaming that prevented the formulation from being ejected as liquid droplets from the front face of the vibrating membrane. Further, with the Lantus formulation, 6.9 L remained at the end of the test. Preferably, substantially all the liquid will be aerosolized, and typically less than about 3 L will remain, corresponding to an aerosolization efficiency of at least about 97% aerosolization.

(22) In contrast to the insulin formulations that contain preservatives, the insulin formulations of the invention (with concentrations of 200 IU, 400 IU and 800 IU, corresponding to Examples 3, 2, and 1, respectively) were each aerosolized in about 10 seconds. With less than 3 ul of formulation remaining, more than about 97% of the formulation was aerosolized. By aerosolizing this volume in around 10 seconds, most individuals, including children, are able to inhale the complete dosage in around 1 to 3 breaths. The insulation formulations of the invention were able to aerosolize at essentially the same rate as water and a saline solution.

(23) One significant reason for the foaming is due to the preservative used in the formulation. For example, many formulations contain the preservative meta-cresol at 2.5-3.15 mgs/ml. However this additive was found to have no effect on foaming FIG. 4. Thus, eliminating such preservatives substantially eliminates foaming and markedly increases aerosolization times.

(24) As one specific example, each milliliter of HUMALOG contains 100 iu lispro, 16 mg glycerin, 1.88 mg dibasic sodium phosphate, 3.15 mg meta-cresol, zinc oxide content adjusted to provide 0.0197 mg zinc ion, trace amounts of phenol, and water for injection. Insulin lispro has a pH of 7.0-7.8, and hydrochloric acid (10%) and/or sodium hydroxide (10%) may be added to adjust pH.

(25) As another example, LANTUS consists of insulin glargine dissolved in a clear aqueous fluid. Each milliliter of LANTUS (insulin glargine injection) contains 100 IU (3.6378 mg) insulin glargine. Inactive ingredients for the 10 mL vial are 30 mcg zinc, 2.7 mg m-cresol, 20 mg glycerol 85%, 20 mcg polysorbate 20, and water for injection. Inactive ingredients for the 3 mL cartridge are 30 mcg zinc, 2.7 mg m-cresol, 20 mg glycerol 85%, and water for injection. The pH is adjusted by addition of aqueous solutions of hydrochloric acid and sodium hydroxide. LANTUS has a pH of approximately 4.

(26) Further, each milliliter of Humulin contains 500 IU of human insulin, 16 mg glycerin, 2.5 mg meta-cresol as a preservative, and zinc-oxide calculated to supplement endogenous zinc to obtain a total zinc content of 0.017 mg/100 units. Sodium hydroxide and/or hydrochloric acid may be added during manufacture to adjust pH.

(27) As yet another example, Humalin R formulation is 100 IU recombinant human insulin, 16 mg (174 mM) glycerin, 2.5 mg metacresol (22.7 mM, 0.25%), HCl and NaOH.

(28) Finally Novolin R formulation is 100 IU recombinant human insulin, glycerin, metacresol, HCl and NaOH.

(29) Other formulations containing preservatives are described in U.S. Pat. Nos. 6,489,292 and 6,211,144, incorporated herein by reference. Such preservatives can include phenol, m-cresol, chloro-cresol, thymol and mixtures thereof. Some similar non-phenol preservatives include bi- or tricyclic aliphatic alcohols and purines, such as a bicyclic aliphatic alcohol, including a monoterpenol, such as isopinocampheol, 2,3-pinandiol, myrtanol, borneol, norborneol or fenchol, a tricyclic aliphatic alcohol, such as 1-adamantanol, and a purine, such as adenine, guanine or hypoxanthine. As described in these patents, such preservatives are included to ensure stability of the insulin. However, the preservatives included in the formulations described in these patents cause the formulations to foam when subjected to vibrating aperture plates, significantly increasing the time to aerosolize.

(30) The formulations of the invention do not contain such preservatives or stabilizers. As such, little or no foaming occurs, allowing substantially all of the aerosol generator to rapidly aerosolize the formulations.

(31) Some insulin formulations also include surfactants or detergents. These also can cause foaming in the presence of a vibrating aperture plate or mesh. The formulations of the invention also avoid the use of such surfactants or detergents.

(32) While the formulations of the invention lack the use of preservatives, the integrity of the formulations can still be maintained by proper packaging and management of shelf life. In this way, the formulations may be preservative free and still commercially viable.

(33) FIG. 5 illustrates what happens when 20 L glycol added per 100 IU (1 ml) was added to the formulations of Examples 1-3. These were then compared to Humalin, Lantus and Humalog, saline and water examples of FIG. 4. As shown, inclusion of glycol had essentially no effect on the aerosolization times of Examples 1-3, confirming that glycol does not contribute to foaming, with the main contributor of foaming being the preservatives as previously described.

(34) The invention has now been described in detail for purposes of clarity and understanding. However, it will be appreciated that certain changes and modifications may be practiced within the scope of the appended claims.