Title of Invention	AN INSULIN ANALOG-PROTAMINE COMPLEX AND PARENTERAL PHARMACEUTICAL FORMULATION
Abstract	The present invention discloses various parenteral pharmaceutical formulations, which comprise: a monomeric insulin analog, zinc, protamine, and phenolic derivative. The analog formulations provide a prolonged duration of action. A process for preparing insulin analog-protamine formulations is also described.

Full Text

Monomeric Insulin Analog Formulations The present invention relates to monomeric analogs of human insulin. More specifically, the present invention relates to various parenteral formulations, which comprise a monomeric insulin analog, zinc, protamine, and a phenolic derivative. The formulations provide a prolonged duration of action. A process for preparing insulin analog-protamine formulations is also described. Since the introduction of insulin in the 1920's, continuous strides have been made to improve the treatment of diabetes mellitus. Major advances have been made in insulin purity and availability with the development of recombinant DNA technology. Various formulations with different time- actions have also been developed. Currently, there are generally seven commercially available insulin formulations: Regular insulin, semilente insulin, globin insulin, isophane insulin, insulin zinc suspension, protamine zinc insulin, and Ultralente insulin. Despite the array of formulations available, subcutaneous injection therapy still falls short of providing a patient with convenient regulation and normalized glycemic control. Frequent excursions from normal glycemia levels over a patient's lifetime lead to hyper-or hypoglycemia, and long term complications including retinopathy, neuropathy, nephropathy, and micro- and macroangiopathy. To help avoid extreme glycemic levels, diabetics often practice multiple injection therapy whereby insulin is administered with each meal. However, this therapy has not yet been optimized. The most rapid-acting insulin commercially available peaks too late after injection and lasts too long to optimally control glucose levels. Therefore, considerable effort has been devoted to create insulin formulations and insulin analog formulations that alter the kinetics of the subcutaneous absorption process. Because all commercial pharmaceutical formulations of insulin contain insulin in the self-associated state and predominately in the hexamer form, it is believed that the rate-limiting step for the absorption of insulin from the subcutaneous injection depot to the bloodstream is the dissociation of the self-aggregated insulin hexamer. Recently, monomeric insulin analogs have been developed that are less prone to association to higher molecular weight forms than human insulin. This lack of self-association is due to modifications in the amino acid sequence of human insulin that decrease association by primarily disrupting the formation of dimers. See, e.g., Brems et al., Protein Engineering, 5_:6, 527-533 (1992) and Brange et al. , Nature, 333:679-682 (1988).. Accordingly, monomeric insulin analogs possess a comparatively more rapid onset of activity while retaining the biological activity of native human insulin. These insulin analogs provide a rapid absorption to place injection time and peak action of insulin into closer proximity with postprandial glucose excursion associated in the response to a meal. The physical properties and characteristics of monomeric analogs are not analogous to insulin. For example, Brems et al. disclose that various monomeric analogs have little, or no, Zn-induced association. Any association that is observed is to a multitude of higher molecular weight forms. This differs dramatically from insulin, which is almost exclusively in an ordered, hexamer conformation in the presence of zinc. Brange et al. Diabetes Care 13: 923-954 (1990). The lack of association attributes to the fast acting characteristics of the analogs. Because the analogs have lower tendency to associate, it is quite surprising that a monomeric insulin analog can be formulated to provide an intermediate duration of action. The present invention provides a monomeric insulin analog formulation that yields upon use an intermediate duration of action. The invention further provides a novel protamine crystal called insulin analog-NPD. The present invention also provides a mixture of insulin analog-NPD and soluble monomeric insulin analog. This mixture provides a rapid onset of action and an intermediate duration of action. Accordingly, the mixture possesses advantages over both insulin and the monomeric analog. The present invention further provides for a process for preparing uniform crystals of insulin analog-NPD. This invention provides an insulin analog-protamine formulation, which comprises: a monomeric insulin analog, protamine, zinc, and a phenolic derivative. The invention further provides a crystalline insulin analog-protamine complex. This complex has been defined as insulin analog-NPD. LysB28ProB29-human insulin- NPD comprises: a LysB28ProB29-human insulin, about 0.27 to about 0.32 mg protamine/100 U of insulin analog, about 0.35 to about 0.9 % zinc by weight, and a phenolic derivative. This invention additionally provides a process for preparing LysB28ProB29-human insulin-NPD, which comprises: combining an aqueous solution of LysB28proB29-human insulin in a hexamer association state, and a protamine solution at a temperature from about 8° to about 22°C; said aqueous solution comprising from about 0.35 to about 0.9% zinc by weight, LysB28ProB29-human insulin, and a phenolic derivative at a pH of about 7.1 to about 7.6; said protamine solution comprising protamine at a pH of about 7.1 to about 7.6 such that the final concentration of protamine is about 0.27 to about 0.32 mg protamine/100 U of insulin analog. The invention also provides formulations that are both rapid and intermediate acting. The formulations are mixtures of monomeric insulin analog and crystalline insulin analog-NPD, wherein the ratio by weight of the two components is about 1-99:99-1. Finally, the invention provides a method of treating a patient suffering from diabetes mellitus, which comprises administering to said patient a pharmaceutical composition containing insulin analog-protamine crystals. FIGURE 1 is a graphical representation of the profile of action of LysB28ProB29-hI-NPD and human insulin- NPH. The graph is µU/ml versus the Time of Infusion. The figure demonstrates the advantages of the present invention. FIGURE 2 presents a picture of AspB28-human insulin-protamine crystals of the present invention. The picture was taken at 1000x magnification with differential phase contrast. FIGURE 3 presents a picture of LysB28ProB29-hi protamine crystals of the present invention. The picture was taken at lOOOx magnification with differential phase contrast. As noted above, the invention provides various formulations of a monomeric insulin analog. The term "monomeric insulin analog" or "insulin analog" as used herein is a fast-acting insulin analog that is less prone to dimerization or self-association. Monomeric insulin analog is human insulin wherein Pro at postion B28 is substituted with Asp, Lys, Leu, Val, or Ala, and Lys at position B29 is Lysine or Proline; des(B28-B30); or des(B27). Monomeric insulin analogs are described in Chance et al., EPO publication number 383 472, and Brange et al., EPO publication 214 82 6, and are herein incorporated by reference. One skilled in the art would recognize that other modifications to the monomeric insulin analog are possible. These modifications are widely accepted in the art and include replacement of the histidine residue at position BIO with aspartic acid; replacement of the phenylalanine residue at position Bl with aspartic acid; replacement of the threonine residue at position B30 with alanine; replacement of the serine residue at position B9 with aspartic acid; deletion of amino acids at position Bl alone or in combination with a deletion at position B2; and deletion of threonine from position B30. All amino acid abbreviations used in this disclosure are those accepted by the United States Patent & Trademark Office as set forth in 37 C.F.R. § 1.822(b)(2). Particularly preferred monomeric insulin analogs are LysB28ProB29-human insulin (B28 is Lys; B29 is Pro) and AspB28-human insulin (B28 is Asp). The term "monomeric insulin analog-NPD" or "insulin analog-NPD" is a suspension of crystalline insulin analog and protamine in a formulation. NPD is Neutral Protamine formulation according to DeFelippis. The composition is prepared in accordance to the claimed process described herein. A related term "insulin analog NPD crystals," "crystalline insulin analog-NPD, " or "LysB28proB29_human insulin-protamine crystals" refer to the insulin analog- protamine crystals in the NPD formulation. The term "treating," as used herein, describes the management and care of a patient for the purpose of combating the disease, condition, or disorder and includes the administration of a compound of present invention to prevent the onset of the symptoms or complications, alleviating the symptoms or complications, or eliminating the disease, condition, or disorder. The term "isotonicity agent" refers to an agent that is physiologically tolerated and embarks a suitable tonicity to the formulation to prevent the net flow of water across the cell membrane. Compounds, such as glycerin, are commonly used for such purposes at known concentrations. The concentration of the isotonicity agent is in the range known in the art for insulin formulations. The term "phenolic derivative" is m-cresol, phenol or preferably a mixture of m-cresol and phenol. The term "free base basis" indicates the amount of protamine in the formulation. Free base basis corrects for the water and salt content of the protamine salts commercially available and commonly used in parenteral formulations. The preferred protamine, protamine sulfate, is approximately 80% protamine. The term "IU" or "U" is international unit. The term "isophane ratio" is the equilibrium amount of protamine necessary to complex with the analog as taught by Krayenbuhl and Rosenberg, Steno Memorial Hospital report (Copenhagen), ,1:60 (1946). The isophane ratio is determined by titration in a manner well known in the art and described in Krayenbuhl, et al. The present invention provides an insulin analog- protamine formulation, which comprises: a monomeric insulin analog, protamine, zinc, and a phenolic derivative. The concentration of protamine is preferably about 0.2 to about 1.5 mg of protamine to 100 U of insulin analog on a free base basis. Most preferably, the range of protamine is about 0.27 mg/100 U to about 0.35 mg/100 U. The concentration of zinc is from about 0.35 to about 0.9 % on a weight basis. Preferably, the concentration of zinc is about 0.7 %. The phenolic derivative is m-cresol, phenol or a mixture of m-cresol and phenol. Preferably the phenolic derivative is m-cresol and phenol. The concentration of the phenolic derivative is known to one skilled in the art. The concentrations must be sufficient to maintain preservative effectiveness, i.e., retard microbial growth. In general, the concentration of phenolic is, for example in the range of 1.0 mg/mL to 6.0 mg/mL; preferably greater than about 2.5 mg/mL. The most preferred concentration is about 3 mg/mL. The presence of a phenolic derivative is critical because it acts to complex the analog, protamine and zinc in addition to serving as a preservative. However, it is believed that only one molecule of phenol per molecule of insulin analog is bound to the crystal structure. Preferably, an isotonicity agent is added to the formulation. The preferred isotonicity agent is glycerin. The concentration of the isotonicity agent is, for example 14 mg/mL to 18 mg/mL, preferably about 16 mg/mL. The pH of the formulation may be buffered with a physiologically tolerated buffer, preferably a phosphate buffer, like dibasic sodium phosphate. Other physiologically tolerated buffers include TRIS, sodium acetate, or sodium citrate. The selection and concentration of buffer is known in the art. Generally, the concentration is, for example, about 1.5 mg/mL to 5.0 mg/mL; preferably 3.8 mg/mL. The present invention further provides specific conditions under which the insulin analog-protamine exists as a stable crystal. Formulations of these crystals are defined as insulin analog-NPD. Insulin analog-NPD is a formulated suspension of insulin analog-NPD crystals and yields upon use an intermediate duration of action. The profile of activity of insulin analog-NPD is quite surprising in view of the lack of self-association of the monomeric analog. The ability to form an intermediate acting formulation with a monomeric analog is demonstrated in FIGURE I. FIGURE I discloses a profile of action for LysB28ProB29- hl-NPD and human insulin-NPH. The NPD profile is similar to insulin-NPH. The duration of action for the NPD formulation and the insulin-NPH formulation are approximately equal. However, most significantly, the present formulation rises more rapidly and remains stable for a longer period than insulin-NPH. This difference is quite unexpected in view of the fast-acting profile of the monomeric analog. A particularly preferred insulin analog-protamine formulation, LysB28ProB29-human insulin-NPD, comprises: LysB28ProB29-human insulin, about 0.27 to about 0.32 mg protamine/100 U of insulin analog, about 0.35 to about 0.9 % zinc by weight, and a phenolic derivative. The concentration of protamine is preferably 0.3 mg/100 U on a free base basis. The invention also provides the process for preparing LysB28ProB29-human insulin-protamine crystals, which comprises: combining an aqueous solution of LysB28ProB29-human insulin in a hexamer association state, and a protamine solution at a temperature from about 8° to about 22°C; said aqueous solution comprising from about 0.35 to about 0.9% zinc by weight, LysB28ProB29-human insulin, and a phenolic derivative at a pH of about 7.1 to about 7.6; said protamine solution comprising protamine at a pH of about 7.1 to about 7.6 such that the final concentration of protamine is about 0.27 to about 0.32 mg protamine/100 U of insulin analog. At the time of invention it was known that monomeric insulin analogs have a lesser tendency to associate and form hexamers. The conditions necessary to cause the monomeric insulin analogs to associate with protamine to form crystals were previously unknown in the art. Previous studies relate to insulin. The teachings regarding the preparation of insulin-NPH (neutral protamine formulation according to Hagedorn) or isophane insulin formulations by Krayenbuhl and Rosenberg, Steno Memorial hospital report (Copenhagen), 1:60 (1946) are not relevant in view of the distinct properties of the monomeric insulin analogs. In fact, the commercial process of producing Humulin-N™ (insulin-NPH), an acid-neutral process, does not produce crystalline insulin analog-NPD. Most significantly, it has been found that the parameters in the present process -- namely, the temperature of the crystallization and the formation of a hexamer complex of the insulin analog, zinc, and the phenolic derivative are critical limitations to the formation of stable, LysB28ProB29-hI-NPD crystals. The temperature of the crystallization must be from about 8°C to about 22°C, preferably from 13°C to 17°C. If the temperature is outside of this range, a largely amorphous insulin analog-protamine formulation results. It is also critical that the insulin analog be transformed to a hexamer state prior to the crystallization. The crystallization results in an amorphous product when the process is carried out with a monomeric association state. Crystals form without agitation in five to thirty-six hours hours. Good quality crystals are generally formed in 24 hours. Soluble monomeric insulin analog is complexed to a hexamer association state by suspending solid monomeric analog in a diluent containing the phenolic derivative and adding zinc until the concentration is from about 0.35 % to about 0.9 % on a weight basis. Zinc is preferably added as a salt. Representative examples of zinc salts include zinc acetate, zinc bromide, zinc chloride, zinc fluoride, zinc iodide and zinc sulfate. The skilled artisan will recognize that there are many other zinc salts that also might be used in the process of the present invention. Preferably, zinc acetate or zinc chloride is used. Dissolution of the insulin analog in the diluent may be aided by what is commonly known as an acid dissolution, In an acid dissolution, the pH is lowered to about 3.0 to 3.5 with a physiologically tolerated acid, preferably HCl, to increase solubility of the analog. Other physiologically tolerated acids include acetic acid, citric acid, and phosphoric acid. The pH is then adjusted with a physiologically tolerated base, preferably NaOH to about 7.1 to 7.6 for the crystallization. Other physiologically tolerated bases include KOH and ammonium hydroxide. Most significantly, the process of producing LysB28ProB29-hI-NPD complex is sensitive to the concentration of NaCl. If the concentration exceeds about 4 mg/mL, the insulin analog-NPD crystals become mixed with amorphous product. Accordingly, it is preferred that the monomeric analog is dissolved at neutral pH to avoid the formation of salt ions. Alternatively, the analog may be dissolved in the diluent at an acid pH prior to the addition of the buffer. This reduces the concentration of salts generated due to the pH adjustment. However, the order that the constituents are added is not critical to the formation of the hexamer or the amorphous formulation. As previously disclosed, an isotonicity agent may be added to the formulations of the present invention. The addition of the isotonicity agent can be to the analog solution, to the protamine solution, or to the final insulin analog-NPD formulation. Likewise, the addition of the physiologically tolerated buffer may be added to the analog solution, to the protamine solution, or to the final insulin analog-NPD formulation. However, it is preferred that both the analog solution and the protamine solution contain the isotonicity agent and the buffer prior to combining the aqueous solution and the protamine. Because of the NaCl effects on the process for producing crystalline insulin- analog-NPD, glycerin is the preferred isotonicity agent. The invention also provides insulin analog formulations, which comprise mixtures of insulin analog-NPD as a crystalline solid and soluble insulin analog. These mixtures are prepared in a range of about 1:99 to 99:1, by volume suspended insulin analog-NPD to soluble insulin analog. The soluble insulin analog is a monomeric insulin analog dissolved in an aqueous diluent comprising: zinc, a phenolic derivative, an isotonicity agent, and buffer. The concentrations described in the diluent are the same as previously disclosed herein. Preferably the ratio of insulin analog-NPD to soluble insulin analog is 25:75 to 75:25; and more preferably, 50:50. The mixtures are readily prepared by mixing the individual constituents. The mixed formulations of the present invention are especially suitable for the treatment of diabetes mellitus because of the combination of a rapid onset of action and prolonged duration. These mixtures allow "fine control" by varying the amount of each individual constituent based on the needs, diet, and physical activity of the patient. The mixture of suspended insulin-analog-NPD and soluble insulin analog are also advantageous because they are homogeneous, i.e., any equilibrium exchange between the suspended crystals and soluble insulin analog is transparent. The insulin analogs of the present invention can be prepared by any of a variety of recognized peptide synthesis techniques including classical (solution) methods, solid phase methods, semi synthetic methods, and more recent recombinant DNA methods. For example, Chance et al., EPO publication number 383 472, and Brange et al., EPO 214 826, disclose the preparation of various monomeric analogs. The following examples are provided merely to further illustrate the preparation of the insulin analogs and the invention. The scope of the invention is not construed as merely consisting of the following examples. Example 1 Preparation of LysB28ProB29-hI-NPD A solution of LysB28proB29-human insulin (LysB28ProB29-hI) at 200 IU/mL (U200) concentration was prepared by dissolving zinc containing crystals of LysB28ProB29-hI in a preservative/buffer system containing: 1.6 mg/mL m-cresol, 0.73 mg/mL phenol (equivalent to 0.65 mg/mL phenol calculated as 89 %), 16 mg/mL glycerin, and 3.78 mg/mL of dibasic sodium phosphate buffer. The endogenous zinc level in the crystals was supplemented by adding an appropriate volume of an acidic ZnO solution (10 mg/mL) to achieve a final concentration of 0.025 mg/100 IU (0.7%). Dissolution of LysB28ProB29-hI was accomplished at ambient temperature by lowering the pH to about 3 with JJ.L volumes of 5 M HC1. After the solution had clarified, the pH was readjusted to 7.5 with µL volumes of 5 M NaOH. A protamine solution was prepared by dissolving enough solid protamine sulfate in the preservative/buffer solution to achieve a final concentration of 0.6 mg/100 IU calculated on a free base basis. The pH of this solution was adjusted to 7.5 and equilibrated at 15°C. Both solutions were diluted to final concentration with water for injection and filtered. 5 mL aliquots of the LysB28ProB29-hI subsection were filled into separate clean glass vials, and the samples were incubated in a water bath at 15 °C. After appropriate time for equilibration (15 minutes), precipitation was induced by rapidly adding 5 mL of the protamine solution to the LysB28ProB29-hI samples. The crystallization was allowed to proceed about 24 hours at 15 °C. Example 2 Preparation of LysB28ProB29-hI-NPD The process is identical to Example 1, except that the dissolution of LysB28proB29-hI occurs at neutral pH. The process was carried out such that the final pH was 7.4. Example 3 Preparation of LysB28ProB29-hI-NPD Insulin analog-NPD was prepared in a manner analogous to Example 1, but the acid dissolution of LySB28proB29_;hi was carried out in the presence of all excipients except the dibasic sodium phosphate buffer. Solid dibasic sodium phosphate is added after the insulin analog solution was returned to pH 7.4. The addition of dibasic sodium phosphate clarified the solution. Example 4 Preparation of insulin analog-NPD mixture formulations Mixtures of intermediate and rapid acting LysB28ProB29-hI formulations are prepared as follows. The intermediate acting, suspension preparation is prepared by the methods described in Example 3 and serves as the intermediate acting section for the mixture. A separate solution of LysB28ProB29-hI (100 IU) is prepared by dissolving zinc-containing LysB28ProB29-hI crystals at ambient temperature in the diluent described in Example 1. The endogenous zinc level of LysB28ProB29-hI in this solution is supplemented by the addition of acidic ZnO solution to match the level in the suspension section (i.e., 0.025 mg/100 IU (0.7%)). Water for injection is used to dilute the solution to final concentration after the pH is adjusted to 7.4 using 10% solutions of HC1 and/or NaOH. This solution is the rapid acting section of the mixtures. The final mixture is prepared by combining appropriate volumes of the intermediate and rapid acting subsections to achieve the desired ratio. A 50/50 mixture is prepared by combining 1 part of the intermediate acting section with 1 part of the rapid acting section by volume. Example 5 Effect of ionic strength on LysB28ProB29-hI protamine crystallization The effect of ionic strength on the crystallization was evaluated by the addition of NaCl to the LysB28ProB29-hI section prior to mixing with protamine. NaCl was added so that the total concentration was 20, 30, and 40 mM (1.2, 1.8, and 2.3 mg/ml). The volume particle size displayed multi- modal behaviour (additional peaks at small particle sizes), as the NaCl concentration was increased. The volume mean particle size decreased as NaCl concentration was increased indicating an increase in amorphous material. Results of particle size vs. NaCl concentration are as follows: The microscope analysis showed that all samples contained a mixture of amorphous and crystalline material. The sample containing 40 mM NaCl had mostly amorphous material and very few crystals. Example 6 Comparative dynamics of LysB28ProB29-hI-NPD and human insulin-NPH This study was carried out in a conscious dog model. Prior to the commencement of the study, three basal samples were taken. An infusion of somatostatin (0.3 µg/Kg- min.) was initiated. After a 10 minute interval, a subcutaneous injection of either NPD or NPH was administered. Frequent monitoring of plasma glucose was initiated and a variable glucose (20%) infusion was given so as to maintain near-normal glycemia. Samples were taken throughout and were analyzed for immunoreactive insulin (Linco antibody) and glucose. The results are illustrated in FIGURE 1. Example 7 Preparation of Asp(B28) Analog-Protamine Crystals A subsection of Asp(B28)-hI at 200 IU/mL (U200) concentration was prepared by dissolving lyophilized bulk (95% purity) in a preservative/buffer system containing: 1.6 mg/mL m-cresol, 0.73 mg/mL phenol (equivalent to 0.65 mg/mL phenol calculated as 89 %), 16 mg/mL glycerin, and 3.78 mg/mL dibasic sodium phosphate. Zinc was added to the system using an appropriate volume of an acidic ZnO solution (10 mg/mL) to obtain a final concentration of 0.025 mg/100 IU. Dissolution of Asp(B28) was achieved at ambient temperature at neutral pH. The final pH of the section was 7.4. A crystallization was carried as described in Example 2. Final protamine concentrations of 0.3 mg/lOOU, 0.35 mg/lOOU, and 0.4 mg/lOOU were investigated. These protamine concentration correspond to 2.9%, 9.3% and 10.5% respectively on a weight/weight basis. Incubation temperatures included 5 °C (0.3 mg/lOOU only), 15 °C and 22 °C. After 24 hr. at these temperatures, samples were analyzed for crystal formation. Results as determined by microscopy illustrate a mixture of a few crystals and amorphous product. Example 8 Preparation of Asp(B28) Analog-Protamine Crystals The crystallization Asp(B28) Protamine was performed as described in Example 7, except that the protein was first dissolved in a buffer-free diluent. The addition of the acidic ZnO stock was sufficient to acidify the sample to pH 2.0-2.5. After the solution had clarified, the pH was readjusted to approximately pH 7 with UL volumes of 5 N NaOH. Sodium phosphate, dibasic, was added using a concentrated stock solution at 47.25 mg/mL to achieve the final concentration of 3.78 mg/mL. The subsection was adjusted to pH 7.4 using UL quantities of HC1. Crystallization was initiated by combining the Asp(B28) and protamine sections, as described in previous examples. Final protamine concentrations of 0.3 mg/lOOU, 0.35 mg/lOOU, and 0.4 mg/lOOU were investigated. Incubation temperatures included 15 °C and 22 °C. After 24 hr. at these temperatures, samples were analyzed for crystal formation. Results as determined by microscopy illustrate a mixture of a crystals and amorphous material. Example 9 Preparation of Leu(B28)Pro(B29) Analog-Protamine Crystals A subsection of Leu(B28)Pro(B29) (93% purity) at 200 IU/mL (U200) concentration was prepared as described in Example 8 using an acid dissolution of the bulk followed by pH adjustment with 5N NaOH to pH 7.4. Crystallization was as described above. Final protamine concentrations of 0.3 mg/lOOU, 0.35 mg/lOOU, and 0.4 mg/lOOU were investigated. Incubation temperatures included 5 °C, 15 °C and 22 °C. After 24 hr. at these temperatures, all samples contain some crystals, but were primarily amorphous as determined by microscopy. Example 10 Des(B27)hI-protamine crystals A subsection of DesThr(B27) (97.37 % purity) at 200 IU/mL (U200) concentration was prepared as described in Example 8 using an acid dissolution of the bulk followed by pH adjustment with 5N NaOH to pH 7.4. A crystallization was carried out as described in Example 8. Final protamine concentrations of 0.3 mg/100U, 0.35 mg/lOOU, and 0.4 mg/100U were investigated. Incubation temperatures included 15 °C and 22 °C. After 24 hr. at these temperatures, all samples were primarily amorphous as determined by microscopy. Qualitatively, crystals were observed. Example 11 Des(B28-B30)hI-protamine A subsection of Des(28-30) (96.3 % purity) at 200 IU/mL (U200) concentration was prepared as described in Example 8 using an acid dissolution of the bulk followed by pH adjustment with 5N NaOH to pH 7.4. A crystallization was attempted using the neutral/neutral combination method of the protein and protamine sections as described above. Final protamine concentrations of 0.3 mg/lOOU, 0.35 mg/lOOU, and 0.4 mg/lOOU were investigated. Incubation temperatures included 15 °C and 22 °C. After 24 hr. at these temperatures, all samples were primarily amorphous as determined by microscopy. Qualitatively, crystals were observed. The crystals were well defined. Example 12 Asp(B28) Analog-Protamine A insulin Asp(B28)-human insulin analog solution was prepared by dissolving 16.6 mg of the protein in 1 mL of a solution containing 3.2 mg/mL m-cresol, 1.3 mg/mL phenol and 32 mg/mL glycerin. A 14.4 (XL aliquot of an acidic zinc stock solution (10 mg/mL in Zn2+, prepared by dissolving 0.311 g of zinc oxide in 5 mL of 10% HCl and diluting to 25 mL with water).. The solution pH was 2.3 which allowed for complete dissolution of the protein. A 10 µL aliquot of 10% NaOH was added to adjust the pH to 7.06. To the solution was added 100 (XL of 0.28 M dibasic sodium phosphate, pH 7.0 which increased the solution pH to 7.27. A 870 µL aliquot of water for injection was added to the solution. Additional 10% HC1 (1 µL) and NaOH (0.7 µL) were added, and the final volume of the solution was brought to 2 mL with water for injection resulting in a final pH of 7.26. The solution was filtered through a 0.2 µm Supor® Acrodisc® 13, Gelman Sciences) filter before use. Protamine stock solutions were prepared by dissolving protamine sulfate in a solution containing 1.6 mg/mL m-cresol, 0.65 mg/mL phenol, 16 mg/mL glycerin and 14 mM dibasic sodium phosphate. The final pH of the solution was adjusted to 7.3. The final protamine concentration was 0.60 mg/100U on a free base basis. Both solutions were filtered through 0.22 [to (Millipore Sterivex™-GV) filter units before use. Crystallization was achieved by mixing the Asp(B28)-human insulin solution in a 1:1 ratio at controlled temperature as outlined in Table 1. The final mixture conditions were 3.94 mg/mL Asp(B28)-human insulin, 0.03 59 mg/mL (0.9%) zinc ions, 1.6 mg/mL m-cresol, 0.65 mg/mL phenol, 16 mg/mL glycerin, 14 mM dibasic sodium phosphate and 0.30 mg/lOOU of protamine at pH 7.3. Specifically, 50-200 µL portions of the AspB28-human insulin solution were transferred to glass vials, and the samples were equilibrated to 4, 8, 15 or 23 (ambient temperature) °C. Portions of both protamine solutions were also equilibrated at these temperatures. After 15-20 minutes, an equivalent volume of either protamine solution was pipetted into the Asp(B28)- human insulin samples. The mixture was gently swirled, capped and then left quiescent at controlled temperature during the crystallization period. All of the samples were examined by microscopy after 24 hours and found to be predominantly amorphous. After 48 hours, the sample containing 0.30 mg/100 U of protamine and incubated at 15 °C showed extensive amounts of needle-like crystals and some amorphous material. Example 13 A insulin Asp(B28)-human insulin analog solution was prepared by dissolving 10.62 mg of the protein in 0.71 mL of a solution containing 3.2 mg/mL m-cresol, 1.3 mg/mL phenol and 32 mg/mL glycerin. A 10.2 |1L aliquot of an acidic zinc stock solution (10 mg/mL in Zn2+, prepared by dissolving 0.311 g of zinc oxide in 5 mL of 10% HC1 and diluting to 25 mL with water)/. The solution pH was 2.3 which allowed for complete dissolution of the protein. A 6.5 µL aliquot of 10% NaOH was added to adjust the pH to 7.00. To the solution was added 71 µL of 0.28 M dibasic sodium phosphate, pH 7.0 which increased the solution pH to 7.26. A 620 µL aliquot of water for injection was added to the solution. Additional 10% HC1 (0.2 µL) and NaOH (0.6 µL) were added, and the final volume of the solution was brought to 1.42 mL with water for injection resulting in a final pH of 7.42. The solution was filtered through a 0 . 2 µm Supor® Acrodisc® 13, Gelman Sciences) filter before use. A protamine stock solution was prepared by dissolving protamine sulfate in a solution containing 1.6 mg/mL m-cresol, 0.65 mg/mL phenol, 16 mg/mL glycerin and 14 mM dibasic sodium phosphate. The final pH of the solution was adjusted to 7.4, and the final protamine concentration was 0.60 mg/100U on a free base basis. The solution was filtered through a 0.22 |im (Millipore Sterivex™-GV) filter unit before use. Crystallization was achieved by mixing the Asp(B28)-human insulin solution in a 1:1 ratio with the protamine solution as described in Example 12 at controlled temperatures 13°C, 15°C, 17°C and 23°C. The results are presented in Table 1. The final mixture conditions were 3.74 mg/mL Asp(B28)-human insulin, 0.0359 mg/mL (0.9%) zinc ions, 1.6 mg/mL m-cresol, 0.65 mg/mL phenol, 16 mg/mL glycerin, 14 mM dibasic sodium phosphate and 0.30 mg/lOOU of protamine at pH 7.4. Four different crystallization temperatures were evaluated. A 1 mL aliquot of the AspB28-human insulin equilibrated at 15 °C was mixed with 1 mL of the protamine solution adjusted to the same temperature. After gentle swirling the preparation was left quiescent at 15 °C. Another sample was prepared by equilibrating 100 p.L of the Asp(B28)-human insulin solution to 13 °C, and then combining with 100 µL of the protamine solution adjusted to the same temperature. The final mixture was incubated at 13 °C. The third sample was prepared in a similar manner except that the two 100 µL aliquots were equilibrated, combined and then incubated at 17 °C. The final solution was prepared by mixing ambient temperature equilibrated, 80 µL aliquots of the Asp(B28)-human insulin and protamine solutions and incubating at ambient temperature (23 °C) . All samples were evaluated by microscopy after 24 hours and other time intervals thereafter as listed in Table 1. a All solutions also contained 0.9% zinc ions, 1.6 mg/mL m- cresol, 0.65 mg/mL phenol, 16 mg/mL glycerin and 14 mM dibasic sodium phosphate, pH 7.4. b Crystallization outcome was evaluated by microscopy at 600X (Nikon Optiphot 66 microscope) or 1000X (Zeiss Axioplan microscope with differential interface contrast) magnification. Both microscopes were equipped with accessories for photography. Crystals prepared in accordance with the above examples are illustrated in Figure 2 and Figure 3. 'VE CLAIM: 1. An insulin analog-protamine complex, which comprises: LysB28ProB29-human insulin; protamine; zinc; and a phenolic derivative. 2. The complex of Claim 1, which is LysB28ProB29-human insulin, about 0.27 to about 0.32 mg protamine/100 IU of insulin analog, about 0.35 to about 0.9 % zinc by weight, and a phenolic derivative. 3. The complex of Claim 1 or Claim 2 in which the complex is crystalline. 4. A parenteral pharmaceutical Lys Pro -human insulin-protamine formulation, which comprises the complex of claim 1, 2, or 3. 5. A formulation of Claim 4, which further comprises about 0.2 to about 1.5 mg protamine/100 IU insulin analog; about 0.35 to about 0.9% zinc by weight; and a phenolic derivative. 6. A parenteral pharmaceutical formulation of Claim 5, which comprises: LysB28ProB29 human insulin, about 0.27 to about 0.32 mg protamine/100 IU insulin analog, and about 0.35 to about 0.9% zinc by weight. 7. A parenteral pharmaceutical formulation, which comprises: LysB28ProB29 -human insulin, about 0.3 mg protamine/100 IU of insulin analog, about 0.7% zinc by weight, about 1.7 mg/mL m-cresol, about 0.7 mg/mL phenol, about 16mg/mL glycerin and about 3.78 mg/mL dibasic sodium phosphate. 8. A parenteral pharmaceutical formulation as claimed in any of claims 4 through 7, which further comprises soluble insulin analog. 9. A parenteral pharmaceutical formulation, which comprises: a mixture of soluble LysB28ProB29-human insulin and LysB28ProB29-human insulin-protamine crystals; wherein the ratio by weight of the two components is about 1:99 to 99:1 LysB28ProB29-human insulin to LysB28ProB29-human insulin-protamine crystals. 10. A parenteral pharmaceutical formulation of Claim 9, wherein the ratio by weight of the two components is about 75:25 to 25:75. 11. A parenteral pharmaceutical formulation of Claim 10, wherein the ratio by weight of the two components is 50:50, 75:25, or 25:75. 12. A process for preparing the complex in any one of claims 1 to 3, which comprises: combining LysB28ProB29 -human insulin, protamine, zinc and a phenolic derivative in an aqueous solvent and allowing the complex to form. 13. A process for preparing LysB28ProB29-human insulin-protamine crystals, which comprises: combining an aqueous solution of LysB28ProB29-human insulin in a hexamer association state, and a protamine solution at a temperature from about 8° to about 22°C; said aqueous solution comprising from about 0.35 to about 0.9% zinc by weig ht, LysB28ProB29- human insulin, and a phenolic derivative at a pH of about 7.1 to about 7.6; said protamine solution comprising protamine at a pH of about 7.1 to about 7.6 such that the final concentration of protamine is about 0.27 to about 0.32 mg protamine/100 IU of insulin analog. 14. The process of Claim 13, wherein the temperature is 15°C; the zinc concentration is 0.7% to 0.9%; and the protamine concentration is 0.3 mg/100 IU of insulin analog. 15. A process of preparing a parenteral pharmaceutical formulation as claimed in any of claims 4 through 11, which comprises: suspending LysB28ProB29 -human insulin-protamine crystals in a pharmaceutically acceptable diluent. 16. Insulin analog-protamine crystals whenever prepared by a process according to any one of Claims 12, 13, or 14. 17. An insulin analog-protamine complex, a parenteral pharmaceutical formulation, a process and an insulin analog-protamine crystal, substantially as hereindescribed with reference to the accompanying examples and drawings. The present invention discloses various parenteral pharmaceutical formulations, which comprise: a monomeric insulin analog, zinc, protamine, and phenolic derivative. The analog formulations provide a prolonged duration of action. A process for preparing insulin analog-protamine formulations is also described.

Documents:

677-CA-1995-(01-07-2014)CORRESPONDENCE.pdf

677-CAL-1995-(07-08-2014)-OPPOSITION UNDER SECTION 25(1).pdf

677-CAL-1995-(15-10-2014)-CLAIMS.pdf

677-CAL-1995-(15-10-2014)-CORRESPONDENCE.pdf

677-CAL-1995-(15-10-2014)-OTHERS.pdf

677-CAL-1995-(18-10-2012)-CORRESPONDENCE.pdf

677-CAL-1995-(23-07-2014)-CORRESPONDENCE.pdf

677-CAL-1995-(23-07-2014)-PA.pdf

677-CAL-1995-(25-10-2012)-CORRESPONDENCE.pdf

677-cal-1995-abstract.pdf

677-cal-1995-claims.pdf

677-CAL-1995-CORRESPONDENCE 1.1.pdf

677-CAL-1995-CORRESPONDENCE 1.2.pdf

677-CAL-1995-CORRESPONDENCE 1.4.pdf

677-CAL-1995-CORRESPONDENCE 1.5.pdf

677-CAL-1995-CORRESPONDENCE-1.3.pdf

677-CAL-1995-CORRESPONDENCE-1.6.pdf

677-CAL-1995-CORRESPONDENCE.pdf

677-cal-1995-description (complete).pdf

677-cal-1995-drawings.pdf

677-cal-1995-examination report.pdf

677-cal-1995-form 1.pdf

677-cal-1995-form 13.pdf

677-cal-1995-form 19.pdf

677-cal-1995-form 2.pdf

677-cal-1995-form 26.pdf

677-cal-1995-form 3.pdf

677-cal-1995-form 5.pdf

677-cal-1995-gpa.pdf

677-CAL-1995-OTHERS PATENT DOCUMENTS.pdf

677-cal-1995-pa.pdf

677-CAL-1995-PRE GRANT OPPOSITION 1.1.pdf

677-CAL-1995-PRE GRANT OPPOSITION-1.2.pdf

677-CAL-1995-Pre Grant Opposition.pdf

677-cal-1995-reply to examination report.pdf

677-cal-1995-specification.pdf

677-CAL-2011-(21-12-2011)-1995-CORRESPONDENCE.pdf