FORM 2
THE PATENTS ACT, 1970
(39 of 1970)
&
The Patent Rules, 2003
COMPLETE SPECIFICATION
{See section 10 and rule 13)
INJECTION SOLUTION
SUN PHARMA ADVANCED RESEARCH COMPANY LTD.
A company incorporated under the laws of India having their office at 17/B, MAHAL INDUSTRIAL ESTATE, MAHAKALI CAVES ROAD, ANDHERI (E), MUMBAI-400093, MAHARASHTRA, INDIA.
The following specification particularly describes the invention and the manner in which it is to be performed.

FIELD OF INVENTION
The present invention relates to stable ready-to-use solution comprising glucagon. The solution is suitable for parenteral administration, particularly suitable for self administration.
BACKGROUND OF THE INVENTION
Glucagon is a polypeptide hormone identical to human glucagon that increases blood glucose and relaxes smooth muscle of the gastrointestinal tract. Glucagon is a single-chain polypeptide that contains 29 amino acid residues. It is insoluble in water but is soluble at a pH of less than 3 or more than 9.5. Due to limitations in both chemical and physical stability of glucagon, it is supplied in the form of a lyophilized powder which must be used immediately following reconstitution with its supplied aqueous diluents. It is available for use intravenously, intramuscularly, or subcutaneously in a kit that contains a vial of sterile glucagon and a syringe of sterile diluent. The vial contains 1 mg (1 unit) of glucagon and 49 mg of lactose or 107mg of lactose monohydrate (Novo nordisk). The diluent syringe contains 12 mg/mL of glycerin, Water For Injection, and hydrochloric acid or only water For Injection. Glucagon is administered as an emergency medication in case of hypoglycemic shocks. Therefore, administration of a ready-to-use aqueous solution that does not require any step of reconstitution may be a better preferred approach, particularly, in emergency cases and when the patient needs to self administer the drug. However, the biggest constraint of glucagon aqueous solution is that it is physically and chemically unstable. This is because of propensity of glucagon to aggregate resulting in the formation of fibrils and gel; a process that can be stimulated by acidic pH, increased ionic strength, peptide concentration, agitation and/or elevated temperatures. The aggregation is particularly unacceptable because aging glucagon solutions prepared at concentrations greater than 2.5 mg/ml for 24 hours have been reported to result in production of cytotoxic amyloidogenic fibrils.(by Kathy L.De Jong, Bev Incledon, Chrostopher M.Yip, Michael R. Defellippis, Biophys J BioFAST, June 9, 2006). It may be inferred from literature reports, that the nature of glucagon, presents a challenge for a formulator to develop glucagon solution, particularly, a ready to use solution.

The prior art references indicate that there are attempts made to tackle the problem generally associated with water insoluble drugs while making a solution. For example, United States Patent Number US 6,217,886 (herein after referred to as '886) disclosed a method of preparing a biologically active micelle product comprising one or more biologically active amphipathic compounds in association with a micelle, said method comprising steps of
a) mixing one or more lipids wherein at least one lipid component is covalently bonded to a water soluble polymer;
b) forming sterically stabilized micelles from lipids;
c) incubating micelles from step(b) with one or more biologically active amphipathic compound (s) under conditions in which said compound(s) becomes associated with said micelles in a more biologically active conformation.
The United States Patent Number US '886 and several other references, for example, Journal of pharmaceutical Sciences, vol. 93, No. 10, October 2004, pp. 2476-2487, teach that DSPE-PEG 2000 is a novel lipid based carrier for water insoluble drugs.
Also the effects of micelles of nonionic, zwitterionic, anionic and cationic surfactants and lipids on the conformation of glucagon and insulin have been investigated by circular dichroism and intrinsic protein fluorescence by Pasta et al [Pasta et al, Biochmica et Biophysica Acta, 953 (1988) 314-320]. Some amphipathic compounds protected glucagon against proteolysis by trypsin and chymotrypsin very markedly, whereas others did not protect at all or only slightly protected the hormone. It is reported in the literature that concentration dependent equilibrium of glucagon in mildly alkaline solution involves the formation of associated forms of higher helicity {W.B. Gratzer and G.H. Beaven, The Journal of Biological Chemistry, vol. 244, No. 24, pp. 6675-6679, 1969). It is also reported that monomeric glucagon in aqueous solution does not have a stable globular structure, the conformation changing continuously with change of temperature or concentration of denaturants added. {Bhinyo Pnajipan and Walter B. Gratzer, European J. Biochemistry, 45, 547-553, (1974).

In attempts to develop a stable, ready-to-use solution of glucagon suitable for self parenteral administration, preferably, in emergency situations where there is no sufficient time for reconstitution, the inventors found that cyclodextrins, sugar alcohols, alcohol, proteins like human serum albumin were incapable of solubilizing the glucagon. The inventors, surprisingly, found out that aqueous solution of glucagon having distearoyl-phosphotidylethanolamine covalently bonded to polyethylene glycol was chemical and physical stability to the solution, particularly in terms of protein conformation, particularly, at a pH between 5 and 7.5.
SUMMARY OF THE INVENTION
The present invention provides a stable, ready-to-use solution which comprises therapeutically effective amounts of glucagon and pharmaceutically acceptable vehicle. The invention can be summarized as follows:
A. A stable, ready-to-use solution which comprises therapeutically effective amounts of
glucagon and pegylated distearoyl-phosphotidylethanolarnine adjusted to a pH of about
5-7.5 and pharmaceutically acceptable vehicle.
B. A stable, ready-to-use solution as described in A wherein glucagon concentration
ranges from 0.5 mg/ml to 5 mg/ml.
C. A stable, ready-to-use solution micellar solution as described in A wherein the
pegylated distearoyl-phosphotidylethanolamine has molecular weight of about 300 to
5000 and is present in amount ranging from 1 mg/ml to 40 mg/ml.
D. A stable, ready-to-use solution as described in A wherein the vehicle comprises a
solvent selected from aqueous or polar aprotic solvents such as dimethyl sulphoxide.
E. A stable, ready-to-use solution as described in D wherein the aprotic solvent is present
in 5 to 15% volume by volume of the solution.
F. A stable, ready-to-use solution as described in A wherein the pH of the solution is
adjusted to about 6.5.
G. A stable, ready-to-use solution as described in A wherein the solution further
comprises a stabilizer is selected from the group consisting of fatty acids or
zwitterionic choline derivatives or mixtures thereof.

H. A stable, ready-to-use solution as described in G wherein choline derivative is
dimyristoyl phosphotidylcholine and is present in concentration of about 1 mg/ml to 2
mg/ml. I. A stable, ready-to-use solution as described in G wherein the fatty acid is caprylic acid
and is present in amount of about 0.1 mg/ml to 3 mg/ml. J. A stable, ready-to-use solution as described in A wherein pharmaceutically acceptable
vehicle comprises one or more acids, buffers, preservatives, tonicity adjusting agents
and mixtures thereof. K. A stable, ready-to-use solution as described in J wherein the buffers are selected from
the group consisting of histidine succinate, phosphate, citrate salts and mixtures
thereof.
DETAILED DESCRIPTION OF THE INVENTION
The term 'stable' as used herein means that the solution remains physically and chemically stable. Particularly, the solution remains clear on long term storage at either 2-8°C or preferably, at room temperature for at least three months, preferably about 6 months to 12 months. The physical stability of the solution of the present invention is determined by recording the percentage transmission at 650 nm & absorbance at 420 run. Further the solution retains potency which is determined by bioassay methods official in pharmacopoeia as well as the chemical assay such as HPLC. The solution is said to be stable when the total impurities do not exceed more than 10 %, preferably more than 10 % when the solution is stored for a period of about three months at room temperature and/ or at 2-8°C for a period of about three month or more. Additionally, the solution is said to be stable when the related substances of glucagon, such as glucagon sulphoxide, D-trp (25)- glucagon or D- phen (22)- glucagon do not exceed 3 % at the end of storage period, such as room temperature for three months or more or when stored at 2-8°C for six months or more.
The term 'ready-to-use' as used herein means that the solution is in the form that can be administered without additional step of reconstitution. For example, product that is available in the market is in the form of a lyophilized form. Glucagon, is a therapeutic substance that is administered as an emergency medication in case of hypoglycemic shocks. Thus, it is always

desirable to have a ready to use solution that is stored in a pre-filled syringe. Depending upon on the emergency situation, the patient can self administer the glucagon solution without any delay in administration. According to one preferred embodiment, the ready-to-use stable, miceliar solution of the present invention is suitable for a single dose parenteral self administration wherein the composition is dispensed in a prefilled syringe. The amount of glucagon per single administration may range from 1 mg to about 5 mg per ml of the solution, preferably, 1 mg per ml. According to another embodiment, the solution is filled in prefilled syringe with an autoinjector. Generally, an autoinjector is spring powered and designed to administer the entire contents of the prefilled syringe in one single dose. It may not have any fluid path and may not have any contact with the drug or biologic contained within the syringe. The components of autoinjector may be made up of plastic and steel. The design and performance features of the autoinjector device may include a safety mechanism to prevent inadvertent activation, automatic sheathing of the used needle, cutout window on the front assembly, locking tabs to prevent disassembly of the auto-injector device once the two sub assemblies have been connected, and self disabling to prevent reuse.
The term 'miceliar' as used herein means that the solution is in the form of micelles which appears to be a clear solution by visual observation. Preferably, the micelles here are stabilized by phospholipids. The miceliar solution is said to be physically stable when there are no signs of conformation changes such as gel formation/aggregation, change in CD spectra showing alpha helix structure and/or the solution is clear in terms of particulate matter immediately after preparation and on storage at various storage conditions such as room temperature, 2-8° C for a period of about 6 months. It is important to note here again that any change in the conformation of hormone is unacceptable as it is found to provide less potent protein or provide less therapeutic effects,, upon administration (See by Kathy L.De Jong, Bev Incledon, Chrostopher M.Yip, Michael R. Defellippis, Biophvs J Biofast, June 9, 2006). The miceliar solution of the present invention is suitable for parenteral administration. By the term 'suitable for parenteral administration' it is meant that the solution comprises the excipients in amounts that are safe and are approved by regulatory authority like USFDA, for parenteral use.

In one embodiment of the present invention, there is provided a micellar solution comprising glucagon in therapeutically effective amounts and distearoyl-phosphatidylethanolamine covaiently bonded to PEG (PEG-DSPE) and, optionally, one or more stabilizers and pharmaceutically acceptable vehicle, wherein the pH of the solution is at about 5-7.5. The ready-to-use solution of the present invention comprises glucagon in the concentration ranging from about 0.5 mg/ml to about 5 mg/ml. Further, it comprises pegylated distearoyl-phosphotidylethanolamine in the concentration ranging from 4 mg/ml to 40 mg/ml. In one preferred embodiment, the molecular weight of pegylated distearoyl-phosphotidylethanolamine ranges from about 300 to 5000 Daltons, particularly, about 2000 & 5000 Daltons.
In one embodiment, ready-to-use glucagons solution of the present invention comprises pegylated distearoyl-phosphotidylethanolamine having molecular weight of about 300 to 5000. It is used in an amount of 1 mg/ml to 8 mg/ml. It was found that addition of a polar aprotic solvent such as dimethyl sulphoxide, allows decrease in the amount of pegylated distearoyl-phosphotidylethanolamine required to solubilize the glucagon. In some embodiment,polar aprotic solvent constitutes 5% to 15% v/v of the total volume.
In one preferred embodiment, the micellar solution further comprises a stabilizer which has a tendency to reside in the hydrophobic portions of the micelle. Preferably, the stabilizer is selected from the group consisting of fatty acid or a zwitterions choline derivative. The term fatty acids includes aliphatic (saturated or unsaturated) monocarboxylic acids derived from or contained in esterified form, in an animal or vegetable fat, oil or wax. Examples of fatty acids or its salts that may be used in the compositions of the present invention include but are not limited to fatty acids or its salts having 'n' number of carbon atoms wherein 'n' ranges from about 4 to about 28. The fatty acid may be a saturated fatty acid or an unsaturated fatty acid, and their salt and combinations thereof. The saturated fatty acid and its salts may be selected from butyric acid, caproic acid, caprylic acid, capric acid, lauric acid, myristic acid, palmitic acid, stearic acid, arachidic acid, behenic acid, sodium caprylate, sodium laurate, sodium myristate, sodium palmitate and the like and/or mixtures thereof. The unsaturated fatty acid and its salts may be selected from myristoleic acid, palmitoleic acid, oleic acid, linoleic acid, alpha linolenic acid, arachidonic acid, eicosapentaenoic acid, erucic acid, docosahexaenoic

acid, sodium oleate, sodium arachidonate and the like and/or mixtures thereof. In an embodiment in which the stabilizer is a zwitterion choline derivative selected from the group consisting of dimyristoyl phosphotidylcholine, egg phosphotidylcholine, dipalmityol phosphotidylcholine, distearoyl phosphotidylcholine, hydrogenated soya phosphotidylcholine, dilauryl phosphotidylcholine, dioleaoyl phosphotidylcholine and their-lyso products. In one embodiment, the solution of the present invention comprises dimyristoyl phosphotidylcholine in the concentration ranging from about 1 mg/ml to 2 mg/ml. In another embodiment, the micellar solution comprises caprylic acid as a stabilizer in the concentration ranging from about 0.1 mg/ml to 3 mg/ml, particularly, 1 mg/ml. Addition of these stabilizers improves the stability of glucagon in that the solution can be stored at room temperature for a period of about six months.
The ready-to-use solution of the present invention further comprises pharmaceutically acceptable vehicle which may comprise one or more acids, buffers, preservatives, tonicity adjusting agents and mixtures thereof. The buffers that may used in the pharmaceutically acceptable vehicle are selected from the group consisting of histidine, succinate, phosphate, citrate and the like and mixtures thereof. The tonicity imparting agents that may be added to the micellar solution may be selected from the group consisting of mono-saccharides like dextrose, sucrose, mannitol, lactose and glycerine and mixtures thereof.
The inventors of the present invention however found surprisingly and unexpectedly, that glucagon was solubilized and stabilized with the help of a pegylated distearoyl-phosphotidylethanolamine alone or in combination with a detergent like dimyristoyl phosphotidylcholine or a fatty acid such as caprylic acid, pH was adjusted to about 5.0 to 7.5, preferably, pH of about 6 to 7.
While the present invention is disclosed generally above, additional aspects are further discussed and illustrated with reference to the examples below. However, the examples are presented merely to illustrate the invention and should not be considered as limitations thereto.

EXAMPLE A
Effect of pH on the glucagon solution was studied. A bulk solution of glucagon (lmg/ml) was prepared using 8mg/ml MPEG-DSPE2K having molecular weight of 2000. This solution was divided in 3 portions & pH was adjusted to 3.0, 6.0, & 9.0. After storage at 40°C/75% RH for 3 days, these solutions were analyzed for assay of glucagon. Table 1 shows the data of the solutions indicating physical and chemical stability.
Table 1: Effect of pH on assay (HPLC) of aqueous glucagon solution after 3 days at 40°C

pH 3.0 6.0 9.0
Appearance Turbid Clear Clear
Assay 73.39 107.30 76.58
From the data, it is evident that glucagon along with MPEG-DSPE is physically unstable at acidic pH (pH 3.0) & chemically unstable at basic pH (pH 9.0). At pH 6.0 (near to the isoelectric point 6.2 of glucagon), the aqueous solution of glucagon was found to be more stable.
Further, the effect of pH was studied in a narrow pH range. A bulk solution of glucagon (lmg/ml) was prepared using 8mg/ml MPEG-DSPE2K. pH was adjusted from 5.5 to 7.5 using citrate buffer & sodium hydroxide solution. After storage at 30°C/65% RH for 1 month, these solutions were analyzed for assay of glucagon & related substances.

Table 2: Effect of pH on physicochemical stability of aqueous glucagon solution

pH Time Physical appearance HPLC Assay Related substance (%)

Glucagon sulphoxide D-trp(25)-glucagon D-phe(22)-glucagon Single max. Total
5.5 Initial Clear 96.31 0.28 ND 0.22 0.68 2.42

1M/30°C Clear 93.77 0.59 0.02 0.04 0.98 5.16
6.0 Initial Clear 95.86 0.26 ND 0.21 0.68 2.50

1M/30°C Clear 91.17 0.64 0.03 0.03 1.01 4.16
6.5 Initial Clear 97.25 0.23 ND 0.20 0.64 2.32

1M/30°C Clear 94.61 0.83 ND 0.2 1.05 4.22
7.0 Initial Clear 96.03 0.27 ND 0.21 0.67 2.46

1M/30°C Clear 92.62 0.91 ND 0.01 1.40 4.93
7.5 Initial Clear 94.91 0.21 ND 0.21 0.67 2.32

1M/30°C Clear 90.35 0.73 ND 0.01 1.52 5.22
The results (Table 2) showed similar physicochemical stability of glucagon from pH 5.5 to pH 7.5 in solution form prepared using mPEG-DSPE2000. Thus it may be concluded from these preliminary findings, that when the glucagons solution is maintained at a pH range of 5.0 to about 7.5 and pegylated distearyl- phosphatidyl ethanolamine, a stable solution is obtained.
EXAMPLE 1-2
An aqueous solution of glucagon was prepared as follows: Table 3: composition of the glucagons solution

Ingredients EXAMPLE 1 EXAMPLE 2

Quantity in milligrams
Glucagon 1 1
mPEG-DSPE 2000 8 8
Sucrose 50 80
Histidine - 1.5
to adjust to pH 6.0
Lactic acid solution (10%) qs to adjust to pH 6.5 -
Sodium bicarbonate (8 mg/ml)

Water for Injection q.s to 1 ml

mPEG-DSPE 2000 and sucrose were dissolved in purified water at room temperature. pH of this solution was adjusted to 6.5 using lactic acid and/or sodium bicarbonate solution (Example 1) or to a pH of 6.0 with histidine
Required amount of glucagon was dissolved in the above solution using magnetic stirrer at room temperature. This solution was filtered through 0.8/0.2µ PVDF filter in aseptic area and packed in 5ml USP-Type I glass vials. The final product was kept for stability study as per ICH guidelines at 2-8°C, 25°C/60%RH & 40°C/75%RH. Results of the stability are given below.
Table 4: Results of the stability testing of composition of example 1.

Stability Condition Time Description Assay in % Related substan ce (%) Absorban ce at 420 nm(AU) % T at 650 nm
Single Total
Initial Clear solution 101.19 0.53 1.40 0.011 99.812
2-8°C 1M Clear solution 102.71 0.59 2.05 0.004 99.947
25°C/60%RH 1M Clear solution 97.57 0.58 4.16 0.005 99.591
40°C/75%RH 1M Clear solution 74.83 2.96 17.49 0.090 97.325
2-8°C 2M Clear solution 94.66 0.52 3.0 0.006 99.927
25°C/60%RH 2M Precipitation. 81.82 1.12 8.36 0.025 97.328
40°C/75%RH 2M Precipitation 66.16 3.82 31.42 0.0570 29.506
2-8°C 3M Clear solution 95.49 0.60 3.24 0.009 99.701
25°C/60%RH 3M Precipitation 85.22 1.09 8.93 0.248 61.279
40°C/75%RH 3M Precipitation 39.36 6.62 31.75 0.636 26.875
2-8°C 6M Precipitation 97.01 0.72 3.21 0.076 92.430
2-8°C 12M Precipitation 80.06 0.59 4.12 0.917 19.258
Composition of Example 2 was found to be not stable at room temperature as turbidity started appearing on 33 day when stored at room temperature. Therefore, it may be concluded that when glucagon was formulated into a solution by use of mPEG-DSPE wherein the pH is adjusted to a specific range of 5 to 7.5, the solution was found to be stable under 2-8°C for a period of three months only, However, the solution was not stable when stored at room temperature. The room temperature stability was further improvised by addition of a stabilizer such as fatty acid or dimyristoyl phosphotidylcholine.

EXAMPLE 3 -5
Table 5: composition of the present invention

Ingredients EXAMPLE

3 4 5
Glucagon lmg 1 mg lmg
mPEG-DSPE 2000 8mg 8mg _
mPEG-DSPE 5000 - 7mg
Sucrose 50 mg 50 mg 50 mg
Dimyristoyl phoshotidylcholine 2mg
Caprylic acid - 1 mg 0.1 mg
Histidine I mg 1 mg lmg
Water for injection q.sto 1 ml q.s to 1 ml q.s to 1 ml
Lactic acid solution (10%) qs to adjust to pH 6.5 qs to adjust to pH 6.5 qs to adjust to pH 6.5
Sodium bicarbonate (8 mg/ml) qs to adjust to pH 6.5 qs to adjust to pH 6.5 qs to adjust to pH 6.5
Example 3: Glucagon and Dimyristoyl phoshotidylcholine (DMPC) were mixed together in water for injection at room temperature, till the mixture becomes translucent. Then specified amount of mPEG-DSPE 2000 was added to this mixture and stirred until it becomes clear. Sucrose and histidine were added and dissolved in solution. pH was adjusted between 6-6.5 and volume was made up with water for injection. This solution was filtered through 0.2µ PVDF filter in aseptic area. The filtered bulk was filled in 1ml pre-filled syringes (with attached needle) & stoppered. The final solution was kept for stability study as per ICH guidelines at 2-8°C & 25°C/60%RH.
Example 4: mPEG-DSPE 2000 was dissolved in WFI. Glucagon was added to this solution & dissolved by continuous stirring at room temperature. Sucrose, histidine & caprylic acid were added one by one & dissolved. pH was adjusted between 6.0-6.5 & volume was made up with WFI. This solution was filtered through 0.2u PVDF filter in aseptic area. The filtered bulk was filled in 1ml pre-filled syringes (with attached needle) & stoppered. The final solution was kept for stability study as per ICH guidelines at 2-8°C& 25°C/60%RH.

Example 5: mPEG-DSPE 5000 was dissolved in purified water at room temperature. Required amount of glucagon was dissolved in the above solution using magnetic stirrer at room temperature. Sucrose, histidine & caprylic acid were added & dissolved one by one in the above solution with continuous stirring. pH of this solution was adjusted to 6,5 using sodium bicarbonate solution and/or lactic acid solution if needed. A clear colourless solution was formed. This solution was filtered through 0.8/0.2µ PVDF filter in aseptic area and packed in 5ml USP-Type I glass vials.
Table 6: Stability results of solution of example 3 and example 4

Example No. Time M (month) RT (Room temperature) Physical appearance
Example 3 1M/RT Clear solution

5M/2-8°C Clear solution

5M/RT Clear solution

6M/RT Clear solution

10M/2-8°C Clear solution
Example 4 RT/1M Clear solution

40°C/1M Clear solution

5M/2-8°C Clear solution

5M/RT Clear solution

6M/2-8°C Clear solution

6M/RT Clear solution

9M/2-8°C Clear solution
Glucagon solution of Examples 3 & 4, were found to be stable. Without wishing to be bound by any theory, this effect said to be due to stabilization of micelles by fatty acid like caprylic acid or zwitterions choline derivative like DMPC in combination with mPEG-DSPE. Histidine is added in this solution to act as buffer. Thus, it may be concluded that mPEG-DSPE can improve physical & chemical stability of glucagon solution. But, precipitation starts appearing in glucagon solution containing mPEG-DSPE alone within 6 months, even when stored at 2-8°C. However, addition of a stabilizer like caprylic acid or DMPC can further improve physical & chemical stability of glucagon solution micellar solution.

Further, the solution similar to example 3 and example 4 were subjected to physical characterization (%Transmittance at 650nm & absorbance at 420nm), bioassay and chemical assay of glucagon as well as content of related substance at initial time point and at various storage conditions such as 2-8°C and 25°C/60%RH for three months. The physical stability of the hormone in the solution form in terms of conformation is confirmed by performing bioassay of the glucagon after the solution is stored at six months at room temperature. The procedure for the bioassay was as per USP monograph for glucagon injection. The results are tabulated in table 7 and table 8, respectively.
Table 7: Chemical and biological stability data for solution as per example 3

Stability Time HPLC
assay of
Glucagon Bioassay
of Glucagon Related substance Absorban
ce at
420nm
(AU) %Trans mittance
at 650nm
Condition


Glucagon sulphoxide D-trp(25)-glucago D-phe(22)-glucagon Single max. Total

INITIAL 106.84 1.194 0.07 ND 0.03 0.86 1.96
25°C/60% RH 1M 98.53 1.145 0.11 ND ND 0.55 2.79 0.096 92.931
25°C/60% RH 2M 103.0 - 0.07 ND 0.02 0.86 5.55 0.246 91.780
2-8°C 3M 105.80 - 0.102 ND 1.132 0.239 1.965 0.045 98.180
25°C/60% RH 3M 91.78 - 0.074 ND 0.304 2.160 8.231 0.206 89.244
2-8°C 6M 104.63 - 0.112 ND 1.025 0.878 4.807 0.06 96.70
Table 8: Chemical and biological stability data for solution as per example 4

Stability Condition Time HPLC
assay of
Glucagon Bioassay
of Glucagon Related substance Absorban
ce at
420nm
(AU) %Trans mittance
at 650nm

Glucagon sulphoxide D-
trp(25) glucagon D-
phe(22)-glucagon Single max. Total

INITIAL 106.70 1.09 0.17 ND 0.17 0.77 2.21
25°C/60% RH 1M 101.05 0.89-1.096 0.21 ND ND 0.96 3.04 0.027 97.218
25°C/60% RH 2M 89.11 1.162 0.89 ND 1.21 1.21 7.02 - -
2-8°C 3M 101.47 1.049-1.068 0.36 ND ND 0.97 3.01 0.027 97.900
25°C/60% 3M 90.98 1.02 1.03 ND 0.33 1.67 7.84 0.025 98.221

Related substance
RH
2-8°C 6M 102.24 1.298-1.409 0.490 ND 1.240 0.490 3.960 0.012 98.682
2-8°C 9M 102.66 0.983-1.013 0.75 0.01 1.19 1.28 5.823 0.02 97.852
EXAMPLE 6
Effect of aprotic solvents like dimethyl sulfoxide: mPEG-DSPE 3 mg/ml was dissolved in water for injection. Glucagon was added to dimethyl sulfoxide (equivalent to 10% of total volume) & dissolved by continuous stirring at room temperature. The solution of glucagon was slowly added to the solution of mPEG-DSPE with continuous stirring. pH was adjusted between 6.0-7.0 & volume was made up with WFI. This solution was filtered through 0.2µ PVDF filter in aseptic area.
Table 9: Stability results of solution of example 6

Time Physical appearance Total Related substances
3M/2-8°C Clear solution -
2M/RT Clear solution 3.656%
3M/RT Clear solution 4.551%
Micellar solution with less mPEG-DSPE with small amount of polar aprotic solvent was found to be chemically stable for three months at room temperature.

We claim:
2. A stable ready-to-use solution as claimed in claim 1 wherein the vehicle comprises
pegylated distearoyl-phosphotidylethanolamine and the pH of the solution is about 5 to about
7.5.
3. A stable ready-to-use solution as claimed in claim 2 wherein glucagon concentration ranges from 0.5 mg/ml to 5 mg/ml.
4. A stable ready-to-use solution as claimed in claim 2 wherein the pegylated distearoyl-phosphotidylethanolamine has molecular weight of 300 to 5000 and is present in amount ranging from 1 mg/ml to 40 mg/ml.
5. A stable ready-to-use solution as claimed in claim 1 wherein the vehicle comprises at least one of a solvent or one or more stabilizers.
6. A stable ready-to-use solution as claimed in claim 5 wherein the solvent is selected from dimethyl sulfoxide, dimethylformamide, dioxane or hexamethylphosphorotriamide.

8. A stable ready-to-use solution as claimed in claim 5 wherein the stabilizer is a fatty acid or zwitterionic choline derivatives dimyristoyl phosphotidylcholine or mixtures thereof.
9. A stable ready-to-use solution as claimed in claim 5 wherein the solution is stable at room temperature for a period of about six months.
10. A stable ready-to-use solution as claimed in claim 1 wherein the solution is stable at 2-8 C
for a period of about three months.