JP6403026B2 - Liposomes, formulations containing liposomes, and methods for producing formulations - Google Patents

Description

FIELD OF THE INVENTION The present invention relates to a novel liposome, a formulation containing a liposome , and a method for producing a liposome formulation.

[Background of the invention]
In the art, liposomes are known to function as carriers in delivering therapeutic agents to target cells to treat a variety of medical conditions. For some applications, liposomes can be formulated with drugs encapsulated in a manner that is selectively phagocytosed by macrophages. Phagocytosed liposomes release drugs into cells, inter alia, inhibiting the inflammatory function of macrophages.

Several methods for the production of such liposomes have been described in the art (eg, Monkkonen, J. et al., 1994, J. Drug Target, 2: 299-308; Monkkonen, J. et al., 1993, Calcif. Tissue Int., 53: 139-145; Classic DD., Liposomes Technology Inc., Elsevier, 1993, 63-105. (Chapter 3); Winterhalter M, Classic DD, Chem 93, 1953; 3): see 35-43). In one of these methods, in the formation of liposomes, a laminate of two liquid crystal layers is formed, which is hydrated into a hydrated lipid sheet, and is further self-closed by being agitated to break up large multilayer vesicles (large multilamellar vesicles (MLV). This method is known as a lipid thin film hydration method. When such particles are formed, the particle size of the particles varies depending on the method (sonic energy (sonication), mechanical energy (extrusion)) used in the subsequent steps of the method. In the case of sonication, small unilamellar vesicles (SUVs) are usually generated and a bath and / or probe tip sonicator is required. On the other hand, lipid extrusion methods that force the lipid suspension through a series of polycarbonate filters (usually 0.8, 0.4, 0.2, and 0.1 μm membranes are used at high pressure (500 psi or less) ) Produces particles having a diameter close to the pore size of the filter used. Such a method is limited to small batch production mainly used for research purposes, and the high pressure extrusion method has a problem that the operation cost is higher and time is required. Thus, in this technology, there is a reproducible method for producing liposomes that can cope with problems such as quality control, stability, possibility of expansion of production scale, and sterilization in liposome production and can be used for industrial scale production. is necessary.

In addition, liposome formulations known in the art are substantially uniform in particle size and shape essential for pharmaceutical compositions to produce sterile products and prevent the possibility of harmful side effects caused by unusually large liposomes. It does not have sex. At present, it is difficult to produce a liposome formulation having a uniform particle size. Extrusion methods that extrude multilamellar vesicles through a series of filters (eg, including a polycarbonate filter with a pore size of 100 nm) cannot stably produce a formulation containing substantially uniform liposomes with a particle size of 100 nm. Indeed, depending on the physical properties of the liposomes such as compressibility and / or stability, the average vesicle size of the extruded vesicles will vary considerably depending on the type of filter used and the pore size. Thus, there is a need for a production method that can produce liposomes with substantially uniform particle size and shape.

Furthermore, many physical properties of liposome formulations affect the cellular response to the liposomes and influence the effectiveness of the liposomes as a pharmaceutical composition. The physical properties of liposome formulations are affected in many ways by the manufacturing process. However, this technique has not shown a method for controlling the characteristics of liposomes in the production process and manipulating the production efficiency and the stability of the liposomes. Therefore, there is a need for a method that can produce substantially uniform liposomes that are cost-effective and that can be used for large-scale production with controllable properties of liposome formulations and that are suitable for clinical use. .

SUMMARY OF THE INVENTION In the present invention, a novel liposome encapsulating a therapeutic agent is described. The present invention also relates to liposome formulations with high particle size uniformity, fewer side effects, and improved sterilization process reliability. The present invention also describes an efficient and cost-effective production method for producing liposomes under low pressure extrusion conditions. Liposomes formulated in this way have desirable and effective therapeutic properties.

Liposome formulations are characterized in that the liposomes have the desired composition and physical properties. Liposomes are composed of lipid components encapsulating therapeutic agents. In one aspect of the present invention, the lipid component comprises distearoyl phosphatidylcholine (DSPC), distearoyl phosphatidylglycerol (DSPG), cholesterol in a 3: 1: 2 molar ratio (DSPC: DSPG: chol).

Liposomes are composed of a lipid component and a therapeutic agent, wherein the ratio of the mass of therapeutic agent, called drug: lipid ratio, to the mass of the lipid component is about 1: 5 to 1: 8, preferably 1: 6 to 1: 7. When the drug: lipid ratio is in this range, stability and efficiency are enhanced, and drug release and liposome integrity are also increased. These structural properties have realized the unexpected advantages of the formulations of the present invention.

The particle size range of the liposome of the present invention is 30 to 500 nm, preferably 70 to 120 nm, 100 to 300 nm, 100 to 180 nm, 70 to 150 nm, depending on the type of therapeutic agent and / or excipient used. It is. In a preferred embodiment, the liposome particle size can be 80 ± 5 nm.

Other physical properties of the liposome composition also contribute significantly to stability and effectiveness. For example, the conductivity of liposomes may affect selective uptake into phagocytic cells. In one aspect, the conductivity is in the range of 13.5 to 17.5 ms / cm. Similarly, external and internal osmolality of the formulation affects stability and effectiveness. The external osmolality is preferably matched with the osmolality in the human body, and the internal osmolality is preferably sufficiently low to stabilize the formulation. In one aspect of the invention, the internal osmolality is in the range of 340 to 440 mOsm / kg. Another preferred variable is the pH of the liposome and / or liposome formulation. For example, an internal pH of the liposome formulation of about 6.9 has a beneficial effect on long-term stability as well as drug leakage and encapsulation capacity.

The liposomes of the present invention are relatively rigid compared to liposomes in the art, as also characterized by having a liposome membrane that is difficult to compress. The liposome of the present invention has a compressibility of less than 0.7 ml / g. As such, the liposome of the present invention has improved stability and storage stability.

This liposome formulation also has new and useful features. The liposome formulation of the present invention consists of liposomes that are not only rigid but also have a substantially uniform particle size and shape distribution. This formulation has almost no variation in particle size between liposomes. Liposome homogeneity as measured by Poly Diversity Index (PDI) is less than 0.075, preferably in the range of about 0.02 to 0.05, which is also a highly uniform composition It is shown that. Therefore, the liposome formulation of the present invention is preferable because it reduces the number of undesirable events that accompany large liposomes and allows efficient filtration with a sterile filter.

Another aspect of the present invention is a method for producing a liposome formulation. This manufacturing method consists of (1) mixing a therapeutic agent with a preselected lipid to create vesicles, (2) extruding the vesicles through a single size filter in a single stage, and (3) limiting Filtering. After ultrafiltration, the product may be standardized to the desired final concentration as needed. Since the extrusion step (2) is performed by extrusion in a single stage under low pressure, the method of the present invention can save operating cost and time and yield as compared with extrusion in a multi-stage process at high pressure. Can be mentioned. Such a manufacturing process can also be adapted for large scale manufacturing.

In one embodiment of the manufacturing method, the prescription agent is mixed with a lipid containing (1) a therapeutic agent in a molar ratio of DSPC, DSPG, cholesterol at a molar ratio of about 3: 1: 2, and the mass ratio of the therapeutic agent to the lipid is about 1 The vesicles are formed to have a ratio of 5 to 1: 8, (2) the vesicles are extruded through a filter having a pore size of about 100 nm in a single stage, and (3) ultrafiltration is performed.

Yet another aspect of the present invention is a liposome formulation manufactured according to the above-described manufacturing process. This formulation consists of a plurality of liposomes composed of a certain amount of therapeutic agent encapsulated lipid component. For example, the lipid component can include DSPC, DSPG, cholesterol in a molar ratio of about 3: 1: 2 and the mass ratio of therapeutic agent to lipid component can be about 1: 5 to 1: 8. The formulation consists of the following steps: (1) mixing the therapeutic agent with a preselected lipid to create vesicles, (2) extruding the vesicles through a single size filter in a single stage, (3) Manufactured by ultrafiltration. After ultrafiltration, the product may be standardized to the desired final concentration as needed. Preferably, the formulation prepared according to this method has a PDI in the range of less than 0.075, more preferably 0.02-0.05. This method produces liposome formulations with novel and useful characteristics such as the above-described 3: 1: 2 ratio of lipid components, drug: lipid ratio, PDI, stiffness, pH, osmolality, and conductivity.

It is a flowchart of the liposome formulation manufacturing method of this invention. It is the flowchart which put together the manufacturing method of 1 liter liposome encapsulated alendronate (capacity strength, 5 mg / ml) and process control variables based on one viewpoint of this invention. 1 is a TEM image of liposome-encapsulated alendronate according to one aspect of the present invention. It is a graph which compares the specific compression rate of various liposome formulations. It is a graph of the particle size distribution of the liposome formulation of this invention. It is a graph of the particle size distribution of the liposome formulation of a prior art.

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a novel liposome formulation used for the treatment of various diseases and a method for producing the same. This formulation consists of a plurality of therapeutic agent-encapsulated liposomes, ie, a plurality of liposomes that contain “encapsulated therapeutic agents”. Depending on the physical properties of each liposome, the stability and effectiveness of the liposome formulation is realized. The formulation is characterized in that the liposome particle size and shape are substantially uniform. The present invention also describes a method for producing liposome formulations that is efficient, cost-effective and meets the demands of large-scale production. The present invention also relates to a formulation having new and useful properties produced by this production method.

A. The present invention relates to a new and useful form of liposomes. In producing the liposome of the present invention, various liposome components can be used. Preferably, the lipid component is a non-toxic, biocompatible lipid, such as a lipid made from phosphatidylcholine, phosphoglycerol, and / or cholesterol. In one form of the invention, the lipid component comprises distearoylphosphatidylcholine (DSPC), distearoylphosphatidylglycerol (DSPG), and cholesterol, preferably about 3: 1: 2 molar (DSPC: DSPG: chol). Contains.

  The lipid component encapsulates the therapeutic agent, where both components have a predetermined mass. As used herein, “drug to lipid ratio” (ie, drug: lipid ratio) refers to the relative mass ratio of drug to lipid components that make up the liposome and / or formulation. In one aspect of the invention, the liposome has a drug: lipid weight ratio of about 1: 5 to 1: 8, preferably 1: 6 to 1: 7.

B. Physical properties of liposomes Various physical variables and properties of liposomes can affect homogeneity, stability, and formulation effectiveness. These physical properties include: (1) osmolarity within and outside the liposome, (2) conductivity (inside and outside the liposome), (3) drug: lipid ratio, (4) (inside and outside the liposome) pH, (5) Types of lipids and drugs used in the composition.

  Osmolality is a measure for the concentration of solutes in the liposome formulation. As used herein, the term “osmolarity” is a measure for the concentration of solute as defined by the number of solute molecules in osmoles per kilogram of solvent (mOsm) (mOsm / kg). The internal osmolarity is the concentration of the solute within the liposome, and the external osmolarity is the concentration of the solute outside the liposome. In one aspect of the invention, the liposomes have a low liposome internal osmolarity. The internal osmolarity can be adjusted by changing the amount of drug encapsulated in the liposome. Liposomes described in the art are liposomes that encapsulate as many drugs as possible, resulting in high osmolarity (high encapsulation ratio). However, the liposome disclosed in the present invention is a liposome having a lower osmolarity (or a lower encapsulation ratio) than a liposome used in the art. Using lower osmolality as disclosed herein, ie, about 340-440 mOsm / kg, improves liposome stability in the formulation and liposome uniformity. One method for reducing the internal osmolarity is to reduce the amount of therapeutic agent encapsulated in the liposome formulation. Another method for reducing the internal osmolarity that does not require changing the drug: lipid ratio includes the use of uncharged substances such as certain polysaccharides or saccharides known in the art.

  The external osmolarity is preferably isotonic with the osmolarity in the body, and in the case of a prescription for injection, it is preferably isotonic with the osmolarity in the body. Therefore, it is preferable that the external osmolarity is relatively constant. The internal and external osmolarity of the present invention achieves high stability, low drug leakage rate, and proper drug encapsulation ability of liposomes.

  The term “conductive” as used herein is the electrical conductivity of liposomes based on the ionic content of the solution. The conductivity is related to the ionic content of the liposome and affects the stability of the liposome formulation, the drug leakage rate, and the drug encapsulation ability. The conductivity of the liposome is in the range of about 13.5 to 17.5 ms / cm. In one embodiment of the present invention, the encapsulated drug is charged. Charged drugs have a one-to-one correlation with liposome conductivity and osmolarity. Therefore, if the amount of charged substance to be encapsulated is changed, both of these characteristics will be affected in a proportional manner. In another embodiment, neutral (non-electrically resistant) drug substances can be used. When a substance such as a polysaccharide is used as a neutral substance for adjusting conductivity, it is independent of the concentration of the osmolarity drug and can be controlled in a manner independent of the drug concentration.

  Another novel aspect of the liposomes of the present invention is the relative stiffness of the composition, i.e., the stability of the liposomes under different conditions in the environment and the body, and fragility. Liposome stiffness is a measure of the liposome membrane strength as well as the resistance to shear forces and pressures that lead to improved shelf stability of the liposomes. Liposome stiffness is inversely proportional to compressibility. Liposomes with low compressibility have high rigidity. An example of a method for measuring the rigidity of the liposome uses ultrasonic velocimetry and densitometry. Methods for measuring the stiffness of liposomes are well known in the art. , Et al. , “Compressibility study of quarterly phospholipid blend monomers”, Colloids and Surfaces B: Biointerfaces 85 (2011) 153-160; and Hianik, Tibor. , “Specific volume and Complicability of bilayer lipid membrane with incorporated Na, K-ATPase”, General Physiology and Biophysics, 30-15 (11). All of which are hereby incorporated by reference herein.

  Regarding liposomes, there are a pH for a solvent outside the liposome (external pH) and a pH for an encapsulated portion inside the liposome (internal pH). The pH affects the stability, the rate of drug leakage from the liposome, and the drug encapsulation ability of the liposome formulation. In one embodiment of the formulation, the internal pH is in the range of about 6.8 to 7.0. An internal pH of 6.8-7.0 is advantageous for the stability of the formulation. The pH of the solvent of the therapeutic agent is, for example, maintained at a pH range of 6.8 to 7.0 while continuously titrating the solution, or when the therapeutic agent is dissolved using a known buffer solution. It can be maintained by maintaining the pH, for example, about pH 6.9. The internal pH of the liposome may be different from the external pH of the liposome. In order to make the pH different, the pH of the solution constituting the internal and external environments of the liposome may be changed.

C. Formulation The liposome formulation of the present invention is composed of a plurality of liposomes having the characteristics as described above, substantially uniform in particle size and shape, that is, having almost no variation in particle size between liposomes. Formulation uniformity is measured by the polydispersity index (PDI). PDI is measured on a non-linear scale from 0 to 1 (value 0 is a perfectly uniform formulation, compositions with a PDI of 1 are highly diverse (non-uniform)). The PDI of the formulation of the present invention is less than 0.075, preferably in the range of 0.02-0.05.
The value of PDI is described in Zetasizer nano series user manual, 2003, Malvern Instruments, pp. 5.5-5.6 and Kazuba M. , Nano Series and HPPS Training Manual Chapter 1, 2003, Malvern Instruments, pp. 9, the contents of these documents are hereby incorporated by reference into the present invention. In fact, the PDI of this formulation is similar to a particle size measurement standard with a PDI of less than 0.02. Formulations known in the art have a PDI typically on the order of 0.3 and a uniformity that is substantially different from the uniformity of the present invention. Because PDI is a non-linear scale, the PDI of the present invention is substantially different from the PDI of prescriptions in the industry. In fact, the low PDI of the present invention is advantageous because it prevents harmful effects associated with large liposomes and can produce a formulation suitable for sterilization by filters.

  The formulation of the present invention comprises liposomes with increased stiffness and uniformity, thus improving stability and shelf life. The formulation of the present invention is also considered effective. . (Banai, Shmuel, et al, "Targeted anti-inflammatory systemic therapy for restenosis: The Biorest Liposomeal Alendronate with Stent study (BLAST) - a double blind, randomized Clinical trial", Am Heart J. (2013) 165 (2) : 234-40.)

  The liposome of this formulation has a specific particle size so that it can be taken up by macrophages and monocytes. Liposomes can have a particle size in the range of 30-500 nm. However, the range of the particle size of the liposome can be 70 to 120 nm, 100 to 500 nm, 100 to 300 nm, 100 to 180 nm, and 80 to 120 nm depending on the type of drug or carrier used. However, these ranges are given by way of example, and other specific particle sizes suitable for uptake by phagocytic cells could be found without departing from the spirit and scope of the present invention. In one preferred aspect, the liposome particle size of the formulation is about 80 ± 5 nm.

  Various therapeutic agents can be encapsulated in the liposome of the present invention. A therapeutic agent is a substance that can reduce or inhibit activity and / or reduce the amount of phagocytic cells in a patient when liposomes are taken up. The therapeutic agent can be any chemical substance, such as a large or small molecule, a mixture of chemical compounds, inorganic or organic compounds, biological macromolecules such as proteins, carbohydrates, peptides, antibodies, nucleic acids, etc. Can do. The therapeutic agent may be a natural product derived from a known organism or a synthetic compound.

  One type of therapeutic agent useful in the present invention is bisphosphonate. Bisphosphonate (formerly phosphonate) is a compound characterized by having two CP bonds. Bisphosphonates are called geminal bisphosphonates when two bonds are present on the same carbon atom (P-C-P). Bisphosphonates are analogs of endogenous inorganic pyrophosphate that are involved in the regulation of bone formation and resorption. Bisphosphonates may form polymer chains in some cases. Since bisphosphonates are highly hydrophilic and negatively charged, in their intact free form it is almost impossible to cross the cell membrane.

  As used herein, the term bisphosphonate refers to both geminal and non-geminal bisphosphonates. Suitable bisphosphonates have the following formula (I):

Where R1 is H, OH or a halogen atom and R2 is required for halogen, heteroaryl or heterocyclic C1-C10 alkylamino or C3-C8 cycloalkylamino (amino is primary, secondary or tertiary) Linear or branched C1-C10 alkyl or C2-C10 alkenyl, depending on the formula, —NHY (where Y is hydrogen), C3-C8 cycloalkyl, aryl or heteroaryl, or —SZ (wherein Z is chloro-substituted phenyl or pyridinyl).

  An example of a bisphosphonate agent is alendronate having the following formula (II).

  Many bisphosphonates have similar activity to alendronate and are useful as therapeutic agents of the present invention. These bisphosphonates can be chosen in terms of how close they are to the biological activity of alendronate. The biological activity of alendronate includes, for example, in vitro activity that inhibits the activity of phagocytic cells, such as macrophages and fibroblasts, inhibiting the activity of those cells, IL-1 from macrophages and / or Inhibition of IL-6 and / or TNF-α secretion, in vitro activity, e.g. the ability of the tested formulation to deplete or disable blood monocytes in animal models or humans, or treat myocardial infarction Mention the ability to reduce the area of infarction.

  Bisphosphonates applicable in the present invention include clodronate, tiludronate, 3- (N, N-dimethylamino) -1-hydroxypropane-1,1-diphosphonic acid, such as dimethyl-APD; 1-hydroxy-ethylidene-1, 1-bisphosphonic acid, such as etidronate; 1-hydroxy-3 (methylpentylamino) -propylidene-bisphosphonic acid, (ibandronic acid), such as ibandronate; 6-amino-1-hydroxyhexane-1,1-diphosphonic acid, For example amino-hexyl-BP; 3- (N-methyl-N-pentylamino) -1-hydroxypropane-1,1-diphosphonic acid, such as methyl-pentyl-APD; 1-hydroxy-2- (imidazole-1- Yl) ethane-1,1-diphosphonic acid, and Zoledronic acid; 1-hydroxy-2- (3-pyridyl) ethane-1,1-diphosphonic acid (risedronic acid), such as risedronate; 3- [N- (2-phenylthioethyl) -N-methylamino]- 1-hydroxypropane-1,1-bisphosphonic acid; 1-hydroxy-3- (pyrrolidin-1-yl) propane-1,1-bisphosphonic acid, 1- (N-phenylaminothiocarbonyl) methane-1,1- Diphosphonic acids such as FR 78844 (Fujisawa); 5-benzoyl-3,4-dihydro-2H-pyrazole-3,3-diphosphonic acid tetraethyl ester such as U81581 (Upjohn); and 1-hydroxy-2- (imidazo [1 , 2-a] pyridine-3-yl) ethane-1,1-diphosphonic acid, such as YM 529, but is not limited thereto.

  In certain embodiments, for example, where sodium alendronate is encapsulated in DSPC, DSPG, and cholesterol, a 1: 5.7 drug: lipid mass ratio (about 1 for sodium alendronate : Equivalent to a molar ratio of 3). When another therapeutic agent, disodium clodronate, is encapsulated in the same lipid component, a mass ratio of about 1: 5.4 (equivalent to a molar ratio of 1: 3) can be used. The invention may encapsulate other therapeutic agents that inhibit or reduce phagocytic cells by inhibiting or delaying proliferation and / or down-regulating phagocytic activity. Specific therapeutic agents can include any agent that is cytotoxic or cytostatic, such as gallium, gold, silica, 5-fluorouracil, cisplatin, alkylating agents, mitramycin, paclitaxol. However, it is not limited to these. In any of the above therapeutic agents, the liposome drug: lipid ratio (by weight) is about 1: 5 to 1: 8, preferably 1: 6 to 1: 7.

  In one embodiment, the formulation comprises a therapeutic agent encapsulated in liposomes that enters the cell through phagocytosis and targets macrophages and monocytes without affecting other than phagocytic cells. Since normal state macrophages and monocytes are induced in the damaged area of the cells and promote inflammation beyond the level of inflammation caused by the disease or condition, monocyte / macrophage inhibition and / or deficiency can be damaged. Suppresses adverse effects on the affected area. When taken inside phagocytic cells, the drug is released, including ischemia reperfusion injury or inflammatory disorders such as myocardial infarction, reduction of the final area of the infarct, cardiac repair and improvement of outcome after acute myocardial infarction Monocytes and / or macrophages are inhibited, inactivated, dysfunctional, killed, and / or depleted to treat various conditions associated with phagocytic immune responses. The liposomes of the formulation have specific properties such as particle size, charge, pH, conductivity, particle size, charge, pH, conductivity, osmolality, etc. that promote uptake mainly through phagocytosis.

  After being taken up by monocytes / macrophages, the formulation exerts a sustained inhibitory activity against monocytes / macrophages. This sustained activity is sufficient to attenuate the inflammatory effects of monocytes / macrophages, and therefore it is not necessary to release the formulation continuously to retain the inhibitory effect. Thus, a method of treating a disease by inhibiting monocytes / macrophages using, for example, a formulation encapsulated in liposomes is a systemic approach that targets the monocytes and macrophages to which the formulation circulates. Treatment is preferred. Depending on the type of therapeutic agent encapsulated, the phagocytic response may vary. For example, alendronate encapsulated liposomes cause apoptosis, whereas clodronate encapsulated liposomes cause necrosis. Cells other than phagocytic cells are relatively less likely to be taken up due to the physiological and scientific properties inherent in liposome formulations.

  In addition, the liposome of the present invention not only retains the therapeutic agent for a sufficient period of time so that the therapeutic agent is not released in the body fluid, but also efficiently releases the formulation in the target cell. The liposomes of the present invention deliver an effective amount of the formulation to target cells. The term “effective amount” is a prescription that is effective in achieving the desired therapeutic outcome, eg, treatment of endometriosis, restenosis, ischemia-reperfusion injury (IRI), myocardial infarction or related symptoms. It means the amount. For example, if the disorder is related to myocardial damage, a reduction in the number and / or activity of activated macrophages and monocytes will reduce the area of the infarct and / or improve repair. The effective amount depends on a number of factors such as the weight and sex of the patient to be treated, the dosage form of the formulation (ie, systemic or direct administration to the site), the treatment plan (eg, 1 day of administration of the therapeutic agent). Multiple doses, several doses per day, doses every other day, single dose, etc.), clinical indicators of inflammation, clinical factors that affect the rate of deterioration of the symptoms being treated, the presence or absence of smoking, hypercholesterolemia Although it depends on pro-inflammatory state, renal disease, dosage form of the composition, etc., the factors are not limited to these. Whether the liposome formulation is successfully delivered depends on the stability and effectiveness of the liposome formulation. The number of therapeutic molecules encapsulated in each liposome (payload), the size of the vesicles, and the level of free non-encapsulated material are important variables that determine the therapeutic index of the product.

D. Dosage and Administration The liposomal formulation can be administered by any route that allows the liposomes to be effectively delivered to the appropriate or desired site of action. Suitable dosage forms include intravenous (IV) administration and intraarterial (IA) administration (particularly suitable for in-line administration). Other suitable administration forms can include intramuscular (IM) administration, subcutaneous (SC) administration, and intraperitoneal (IP) administration. Such administration can be accomplished by rapid injection or infusion. Another form of administration can include perivascular delivery. The formulation may be administered directly or after dilution. Any combination of the above routes of administration may be used in accordance with the present invention. Any route of administration can be used as long as the particles are in contact with phagocytic cells (circulating monocytes or peritoneal macrophages).

  The pharmaceutical composition used in accordance with the present invention is a physiologically acceptable carrier comprising excipients and auxiliaries known in the art that facilitates the processing of the active ingredient into a formulation and can be used pharmaceutically. It can be prescribed by using the above.

  Dosage amount and interval can be adjusted individually to ensure that the level of plasma formulation is sufficient (minimum effective concentration, MEC) to induce or suppress biological effects. . The MEC will vary for each formulation but can be determined from in vitro data. The volume required to achieve MEC will depend on individual characteristics and route of administration. Various detection assays can be used to measure plasma concentrations.

  Depending on the degree and responsiveness of the condition to be treated, the administration can be single or multiple administrations, and the treatment period can be several hours to several weeks or until the treatment is completed. The frequency of administration can also be changed according to symptoms and degree. In one aspect, the formulation can be administered periodically. The dose can be formulated in any amount or volume required by the desired treatment. For example, a 1 microgram or 10 microgram dose may be administered to a patient undergoing endovascular treatment, eg, stenting, to reduce the subsequent occurrence or severity of in-stent late loss. Can be prevented. In another example, the dose can be 100 micrograms or more. In this sense, the formulation can be administered in a single dose, multiple doses, and / or in the form of a continuous infusion for a predetermined period of time, for example. For example, the capacity is described in Banai, Am Heart J., supra. (2013) can be administered according to the description.

E. Method for Producing Liposomes Another aspect of the present invention is a method for producing liposomes and liposome formulations suitable for commercial production of products. This manufacturing method can manipulate the physical properties as described above: water: solvent ratio, solvent composition and solvent ratio, vesicle preparation temperature, vesicle preparation shear rate, extrusion temperature, extrusion pressure. It is also possible to control certain process variables such as extruded membrane particle size, membrane type.

  The production of liposome formulations consists of (1) mixing the therapeutic agent with a preselected lipid to form vesicles, (2) extruding the vesicles through a single size filter in a single stage. Process, (3) The process of ultrafiltration is included. Here, the expression “process for extruding using a filter in a single stage” means that “in the extruding process, a filtration process with a single pore diameter” is used. That is, a single size filter may be passed multiple times, but different size filters as known in the prior art must be passed multiple times and / or sequentially (eg, 1.. 0, 0.8, 0.6, 0.4, 0.2 micrometer membranes). After ultrafiltration, the product can be standardized to the desired final concentration. Since the extrusion of step (2) is performed by single-stage extrusion at low pressure, the use of the method of the present invention reduces operating costs and time and increases the yield compared to high-pressure extrusion in multiple stages. . FIG. 1 illustrates each step of the manufacturing method.

  The first step consists of the step of mixing the therapeutic agent and a preselected lipid component in solution to form vesicles. In many cases, the therapeutic agent and lipid component are solubilized in the form of a therapeutic agent solution and a lipid component solution, and then both solutions are mixed. In this embodiment, the therapeutic agent solution has certain physical properties including pH, osmolarity, and conductivity. The therapeutic agent solution forms the internal environment of the liposome formulation. Thus, the pH, conductivity, osmolarity of the therapeutic agent solution affects the internal pH, conductivity, osmolarity of the liposome formulation. The internal osmolality of the liposome is preferably in the range of 340 to 440 mOsm / kg, while the external osmolality of the liposome is in the range of 270 to 340 mOsm / kg. The pH of the solution is such that the therapeutic agent solution is in the desired pH range. Therefore, when using an acidic therapeutic agent, such as a bisphosphonate, a basic pH solution is used to keep the pH of the solution in the range of 6.8-7.0. For example, the therapeutic agent solution can be prepared from a solution of alendronate sodium in NaOH solution, and the resulting alendronate solution has a pH of about 6.8 and a conductivity of about 18.0 ms / cm. The solution may be heated during this process if necessary. In another aspect, sodium clodronate or alendronate monohydrate can be used. The solution can be heated to a temperature of 55-75 ° C., such as 70 ° C., which promotes solubilization of the bisphosphonate in a basic solvent. Depending on the amount of therapeutic agent and other excipients dissolved, the solution can have an osmolality of 340 to 400 mOsm / kg, which becomes the internal osmolality. The solution may have conductivity in the range of 14.0 to 21.0 ms / cm depending on the amount of the therapeutic agent and excipient, and this conductivity becomes the internal conductivity. Internal pH, osmolality, and conductivity are factors that are related to the stability and effectiveness of liposome formulations. In one aspect, the concentration of the therapeutic agent solution in step (1) of the manufacturing process can be 20 to 120 g / L. The therapeutic agent solution can be prepared separately from and / or prior to the manufacturing process discussed herein.

  The lipid component can be in the form of a solution containing a desired starting amount of the lipid component in one or more lipid solvents. Any suitable lipid component and lipid solvent can be used. For example, the lipid component can consist of DSPC, DSPG, and cholesterol in a molar ratio of 3: 1: 2 prior to liposome formation. Liposomes obtained by using lipids in this combination may also have a molar ratio of DSPC, DSPG, cholesterol of 3: 1: 2. Furthermore, the lipid solvent can be composed of, for example, t-butanol, ethanol, and water having a v / v / v ratio of 77/77/6. Other lipid solvents that can be used when formulating the liposomes of the present invention include chloroform or methanol. The lipid component is dissolved in the lipid solvent. The lipid solvent can be heated to a temperature that promotes solubilization of the lipid component in the range of 55-75 ° C., for example, 70 ° C., to form a lipid solution. The concentration of the dissolved lipid solution can be in the range of 50 to 350 g / L. The lipid solution can be prepared separately from and / or prior to the manufacturing process discussed herein.

  Multilayer vesicles (MLV) are formed by mixing the therapeutic agent solution and the lipid solution. The drug: lipid ratio can be controlled by varying the amount of lipid solution or therapeutic agent solution. For the purpose of promoting the mixing of the solutions, the two solutions may be gently heated as necessary. This process allows the therapeutic agent to be efficiently encapsulated in the multilayer vesicle. In one example, the lipid solution can be added to the therapeutic agent solution in a ratio of 5.3 parts lipid to 1 part therapeutic agent. This lipid to drug (weight) ratio increases the stability of the liposomal formulation without significantly sacrificing delivery. Indeed, the drug: lipid ratio in this process can be varied in a range of 1: 4 to 1: 8, preferably 1: 5 to 1: 6 by weight. Also, the solvent concentration can be adjusted prior to the extrusion step without sacrificing liposome integrity.

  The next step in the formulation manufacturing process involves extruding vesicles through a single size filter in a single step. When the vesicles are extruded, the particle size of the multilayer vesicles described above is reduced. This method uses a single extrusion process and low pressure, resulting in liposomes with high particle size and shape uniformity. In the process of extrusion, a microfluidizer or other conventional homogenizer can be used. Homogenizers use shear energy to break up large liposomes into small liposomes. Homogenizers suitable for use in the present invention can include microfluidizers manufactured by various manufacturers, such as Microfluidics, Inc. of Boston, Massachusetts, USA. The particle size distribution can be monitored by particle size discrimination with a normal laser beam. Filtration of liposomes through polycarbonate membranes or asymmetric ceramic membranes is an effective way to limit liposome particle size to a relatively well-defined particle size distribution. In order to reduce the particle size, the extrusion temperature is preferably higher than the transition phase temperature of the liposome. For example, when DSPG, DSPC, or cholesterol is used, the temperature is preferably about 55 ° C. Other lipids can be used, and a known transition phase temperature can be used as an indicator of the desired temperature in the extrusion process. Multiple passes may be required to achieve the desired vesicle particle size and uniformity and homogeneity. During this process, the sample can be analyzed in real time to assess vesicle particle size and bacterial count.

  The extrusion process is performed by a single stage low pressure extrusion process. In the process of extrusion, small unilamellar liposomes are formed by multi-stage extrusion in which large liposomes are sequentially passed from a large pore membrane to a small membrane using a high pressure extruder (as has been practiced in the prior art). Rather, it is processed in a single step by extruding the MLV directly through a single membrane under low pressure. In one aspect, the single-stage extrusion process is performed directly using a polycarbonate or ceramic membrane with a pore size of 0.1 micrometers, applying a low pressure of 60-90 psi to obtain liposomes having a particle size of 100 nm. In this process, a low pressure of 60 to 90 psi is used as opposed to a high pressure (500 psi) in high pressure extrusion.

  The process of the present invention that extrudes at low pressure so that no multilayer is produced has several advantages. First, a single-stage extrusion process can be performed in a shorter time than a multi-stage process. In addition, since the need for high-pressure extrusion is eliminated, high costs associated with extrusion equipment can be avoided. Low pressure extruders are significantly less expensive. An example of a suitable extruder of the present invention is LIPEX® Extruder sold by Northern Lipids, Inc. In addition, materials used in low pressure extruders, such as compressed air, are generally less expensive than materials used in high pressure extruders, such as nitrogen. Furthermore, by changing the multi-stage extrusion to a single-stage extrusion, waste was similarly reduced and the yield was increased.

  The final step of the present invention consists of ultrafiltration of the extruded vesicles into a buffer. Liposomes produced in the process of extrusion have a uniform particle size and shape, but in ultrafiltration, pressure is applied to the formulation to pass through the membrane, and the encapsulated liposomes are not encapsulated in the therapeutic agent or solvent. Separate from lipids. This step is preferably carried out at a temperature below the transition phase temperature of the lipid used in the formulation, for example typically below 45 ° C. Various filtration membranes can be used in the process of ultrafiltration. In one aspect of ultrafiltration, a relatively large liposome remains in the fiber by using a hollow fiber membrane and applying pressure to pass the formulation through the inner hollow portion of the fiber, whereas small molecules ( That is, the solvent, unencapsulated bisphosphonate, lipid) is filtered through the membrane outside the fiber. By this ultrafiltration, a formulation in which 96% or more of the therapeutic agent is encapsulated is obtained.

  The ultrafiltration step may further include a dialysis step of dialyzing the formulation against a specific amount of buffer. An example of a buffer is phosphate buffered saline (PBS), but any buffer kept at physiological osmotic pressure that contains a balance of positive and negative ions can be used. Other buffer additives are known in the art and may contain, for example, sucrose, glycine, sodium succinate, and / or albumin. The buffer should preferably carefully monitor the pH and conductivity of the solution to reflect the external environment of the final formulation. The buffer is preferably isotonic and non-toxic to cells. The buffer can be filtered to further reduce contaminants or prepared prior to the manufacturing process. The final point of dialysis is when the desired pH and conductivity of the formulation is reached.

  At the end of the ultrafiltration step, the formulation may be filtered if necessary for sterilization, i.e. to control biological contamination. In one aspect of this process, the sterile filter is connected to a pressure vessel containing a liposome formulation, and the sterile filter is further connected to a sterilized receiving tank. When pressure is applied to the liposome formulation, the formulation passes through a sterile filter. In this step, another sample can be taken to examine the bacterial content. The pore size of the sterilizing filter can be in the range of 0.2 to 0.45 micrometers. Since the liposomes of the formulation are substantially uniform and do not contain large liposomes, sterile filtration can be carried out without any particular complications.

  After manufacture, the formulation can be standardized. Final standardization results in a liposome formulation having a standard concentration. Standardization analyzes for yield, particle size, lipid composition, drug and free drug content, and product concentration. Concentration analysis can be performed by methods known in the art, for example, analysis of phosphate using HPLC, a spectrophotometer. Once the ultrafiltration product concentration is confirmed, the formulation is diluted to a standard concentration using a specific amount of buffer. Final standardization also includes sterile filtration of the liposomal product. For example, the encapsulated bisphosphonate formulation after ultrafiltration can be diluted with an appropriate amount of buffer to a final concentration. Similarly, different final concentrations can be used by dividing the ultrafiltration product into multiple batches and using different amounts of buffer as diluent in each batch. A sample may be obtained and the concentration of the formulation at that time may be measured.

  This production method has the advantage that the physiological and chemical characteristics of the liposome can be controlled, monitored and reproduced. For example, the internal pH of the liposome can be controlled by the composition of the solution in which the therapeutic agent is dissolved. The internal osmolality can be similarly manipulated by changing the amount of therapeutic agent, for example, depending on whether the therapeutic agent is charged. The drug: lipid ratio can be managed by selecting the amount of lipid component that makes up the liposome, ie, the amount of lipid added to the dissolved active therapeutic agent. Increasing the amount of lipid component decreases the drug: lipid ratio and vice versa. Also, a low drug: lipid ratio reduces the internal osmolality of the liposome formulation. The external pH and external osmolarity of the composition are influenced in part by the composition of the buffer containing the final product. The conductivity can be controlled by the nature of the therapeutic agent and other excipients encapsulated in the liposomes. Other factors such as viscosity, excipient quality, sterility, saline solution, infusion kit, compatibility with syringes (in the case of injectable formulations), and compatibility with processing equipment are also provided by the method of the present invention. Each can be controlled independently.

  In view of the above description, in one preferred embodiment of the production method, the formulation is mixed with (1) a solution containing a therapeutic agent and a solution containing DSPC, DSPG, cholesterol at a molar ratio of about 3: 1: 2, Forming vesicles such that the mass ratio of the therapeutic agent to lipid is about 1: 5 to 1: 8, (2) extruding the vesicles through a filter with a pore size of about 100 nm in a single step, and (3) limiting Manufactured by external filtration.

  Another aspect of the present invention is a liposomal formulation manufactured according to the manufacturing process described above, wherein the formulation comprises DSPC, DSPG, cholesterol in a molar ratio of about 3: 1: 2, and the therapeutic agent to lipid The mass ratio of the components can be about 1: 5 to 1: 8, and the following steps: (1) A solution containing a therapeutic agent and a solution containing a lipid component are mixed to form vesicles; (2) Manufactured by extruding vesicles through a single size filter in a single stage and (3) ultrafiltration. After ultrafiltration, the product can be standardized to the desired final concentration. Formulations prepared according to this method have a PDI in the range of less than 0.075, preferably 0.02-0.05. This method produces a liposomal formulation having novel and useful characteristics as described above, including a lipid component ratio of 3: 1: 2 and a drug: lipid ratio of 1: 5 to 1: 8. Furthermore, individual liposome properties including pH, osmolarity, conductivity, and stiffness can be controlled separately as described above.

  The following examples are for illustrating and illustrating various viewpoints in carrying out the present invention, and are not intended to limit the present invention. In the following embodiments, the present invention will be described by way of example only with reference to the drawings. Specifically referring to the drawings, the details of each part shown in the drawings are only for the purpose of carrying out the preferred embodiment of the present invention, and the principle and conceptual aspects of the present invention are described. In explaining, it was presented by showing specifically what seems to be the most useful and easy to understand. For purposes of explanation, consider together with the drawings, which have become apparent to those skilled in the art how some aspects of the present invention may be embodied.

Example 1 Batch Preparation of Liposome Formulation A test batch was prepared according to the method described above. Of course, the particle size of the batch can be varied as desired for commercial production. In this example, a 1 liter batch of phosphate buffered saline in which liposomes containing alendronate were encapsulated in liposomes containing cholesterol, DSPC, DSPG were produced. Liposome-encapsulated alendronate can be produced as a cloudy liposome dispersion sterilized at two concentrations of 5 mg / ml and 0.5 mg / ml in view of clinical convenience. About these density | concentrations, it can prescribe further suitably and can obtain a specific quantity of a desired amount of therapeutic agents. The lipid component was composed of cholesterol, DSPC, DSPG. The dispersion liquid also contained a phosphate buffer solution in order to control pH, perform infusion in an appropriate manner, and maintain isotonicity. More than 96% of the drug in the final product was encapsulated in the liposomes. For administration, the contents of the vial (or part of it if necessary) were diluted with saline and administered by infusion.

  Table 1 shows the batch formulation including the amount and quality of the components used in the manufacturing process. The quantity indicates the quantity per liter of batch.

  Table 2 below shows the content and quantitative composition of the liposome-encapsulated alendronate for intravenous injection produced in the 1-liter batch of Table 1. In this batch, the DSPC: DSPG: cholesterol molar ratio was 3: 1: 2. The drug: lipid ratio was calculated to be about 1: 5.7 ± 1.5 (w: w).

  Intravenous liposome-encapsulated alendronate formulations actually produced by the novel production method described herein are shown in Table 3 below.

  FIG. 2 is a flow chart summarizing a method for producing 1 liter of liposome-encapsulated alendronate for intravenous injection having an active ingredient content of 5 mg / ml and process control parameters. The process for producing an active ingredient content of 0.5 mg / ml is the same as that used for an active ingredient content of 5 mg / ml. Only the final standardization step is different in that it provides different final formulation concentrations for administration. One skilled in the art will appreciate that other doses can be produced in this manner without undue experimentation.

  A therapeutic solution (alendronate solution) and a lipid solution were prepared as follows.

  Alendronate solution NaOH (6.8-8.0 g) was weighed and dissolved in 850 ml of water for injection (WFI). It was confirmed by visual observation that it was completely dissolved. Alendronate sodium (68-80.75 g) was dissolved in the NaOH solution while stirring at 600 ± 150 RPM at a temperature of 70 ± 3 ° C. Visual confirmation of complete dissolution (ie clear solution), conductivity and pH measurements were confirmed (pH = 6.8 ± 0.3, conductivity = 18.0 ± 1 ms / cm) .

Lipid solution Weighing lipid consisting of 30 g DSPC (37.9 mmoles), 10 g DSPG (12.5 mmoles), 10 g cholesterol (25.8 mmoles) (DSPC / DSPG / Cholesterol; 3/1/2 mol / mol / mol) The sample was dissolved in 160 ml of t-butanol / EtOH / H ₂ O (77/77/6, v / v / v) at a temperature of 70 ± 3 ° C. in a 250 ml beaker using a heated magnetic stirrer. A lipid solution with a concentration of 312 mg / ml was formed. A clear yellow solution was formed when the temperature was in range.

Formation of MLV The lipid solution was added to the alendronate solution (1 part drug: 5.3 parts lipid) while mixing at 600 + 150 RPM and keeping the temperature at 70 ± 3 ° C. After 5 minutes or more, 100 ml of water for injection (10% of the total volume) was added, and the solvent concentration was lowered before extrusion. The formulation was mixed for an additional 10 minutes.

Extrusion 1.2L heated stainless steel loaded with a 0.14 micrometer ceramic membrane or two polycarbonate membranes (eg 0.2 micrometer prefilter and 0.1 micrometer membrane) Extrusion was performed using an extruder, and the vesicle particle size was reduced and the vesicle homogeneity was increased at a pressure of 90 ± 15 psi and a temperature of 68 ± 5 ° C. In this process, 12-18 passages were required to make the vesicles 80-100 nm. The extrudate was subjected to ultrafiltration after a sample was collected on the spot and the particle size of the vesicles was confirmed. The particle size of the liposome formulation was analyzed using a Malvern Nano ZS analyzer (acceptance limit: 95 ± 20 nm). Extruded samples were also counted for the number of aerobic bacteria (control of biological contamination). The pass limit was less than 100 CFU / ml.

Ultrafiltration and diafiltration First, before performing ultrafiltration, the formulation was allowed to cool to less than 45 ° C. Ultrafiltration was performed using an Amersham QuixStand system equipped with a 500K hollow fiber membrane. The formulation was concentrated so that the inlet pressure was 25 psi or less. When the minimum volume was reached, the formulation was dialyzed against 10 times the initial volume (about 7 L) of phosphate buffered saline (PBS) solution. A PBS solution was prepared by dissolving 145 mM NaCl, 13 mM Na ₂ HPO ₄ , 7 mM NaH ₂ PO ₄ in 10 L of water for injection. The pH of PBS was about 6.9, and the conductivity was about 16.9 ms / cm. PBS was filtered through a 0.2 micrometer filter. The end point of diafiltration was determined by measuring the pH and conductivity of the dialyzed formulation. Formulations that did not exceed 120% of the initial volume (about 1.2 liters) were discharged from the ultrafiltration system. Samples were taken for general analysis and aerobic bacterial count (biological contamination control). The pass limit was less than 1,000 CFU / ml.

  Upon completion of dialysis, the formulation was filtered through a 0.2 micron filter to maintain a controlled state for biological contamination. The pressure vessel containing the formulation was connected to a sterile 0.2 micrometer filter (Sartorius Sartobran P). The filter was previously connected to the sterilization recipient tank. Filtration was performed by applying a pressure of 5-30 psi to the pressure vessel. Samples were taken for general analysis and aerobic bacterial count (biological contamination control). The pass limit was less than 1,000 CFU / ml.

Final standardization Formulation particle size, liposomal lipid / therapeutic agent composition, drug and free therapeutic agent content were analyzed by HPLC. The expected yield in this example was that 1 liter of formulation contains about 6 mg / ml liposome encapsulated alendronate and 35 mg / ml lipid. Based on the results for alendronate concentration, the dilution required to achieve a final formulation concentration of about 1 liter to 5 mg / ml or 0.5 mg / ml was calculated. To prepare a 5 mg / ml formulation, after ultrafiltration, about 900 ml of liposome-encapsulated alendronate was diluted with about 100 ml of PBS prepared as described above. In addition, in order to prepare a 0.5 mg / ml formulation, after ultrafiltration, about 100 ml of liposome-encapsulated alendronate was diluted with about 900 ml of PBS to a concentration of 0.5 mg / ml. A sample was taken to determine the actual concentration of alendronate.

  After preparing the standard concentration formulation, connect the bottle with the formulation to two 0.2 micrometer sterile filters (Sartorius Sartobran P) placed in series in a class 100 room or sterile biological hood. did. The filter was previously connected to a sterile disposable receiving bag or bottle. Filtration was performed using a peristaltic pump or pressurized nitrogen. The pressure should not exceed 10 psi. At the end of filtration, the filter was tested for integrity.

  Intravenous liposome-encapsulated alendronate produced in the above examples has several desired properties, for example: (i) at least 3 alendronate and lipid for 3 years storage at 5 ° C. (range 2-8 ° C.) (Ii) mean vesicle diameter 80 ± 5 (no particulate matter), (iii) sodium alendronate concentration in the range of 5 mg / ml or less (0.1-5.0 mg / ml), (iv) 96% Aldronate encapsulation rate, (v) 3/1/2 (mol / mol / mol) distearoylphosphatidylcholine / diastearoylphosphatidylglycerol / cholesterol (DSPC / DSPG / CHOL) lipid composition, (vi) 270-340 mOsm (Vii) viscosity similar to water, ie 1.0 mPa.s at 20 ° C. s kinematic viscosity, (viii) pH 6.8 (range 6.8-7.0), (ix) globally acceptable US or European Pharmacopoeia compliant excipient quality, (x) US Pharmacopoeia Sterilization conditions and pyrogens that meet the guidelines of USP 24-NF19, (xi) salt solutions, infusion kits, compatibility with syringes (use), (xii) filters, stainless steel and glass tubing It was compatible (method).

  FIG. 3 is a TEMS image of the alendronate of the liposome produced in the above example. Good homogeneity and uniformity were observed for the liposome group, and the particle size of the liposomes in the image was in the range of 40-120 nm.

Example 2 Test for Liposome Stiffness Four types of large unilamellar liposomes (about 100 nm in diameter) were examined for rigidity. That is, the PBS suspension of hollow liposomes produced according to the present invention was designated LPO, and the liposome formulation containing 5.0 mg / ml alendronate produced according to the present invention was designated LSA. Two other liposome samples (KS and HU) dissolved in HEPES are described in Epstein-Barash, Hila, et al. “Physicochemical parameters effecting liposomal biphosphonates bioactivity for restenosis therapies: Internalization, Cell inhibition and Activation of Cytokines. Controlled Release 146 (2010) 182-195 was prepared according to the prior art method.

  Each sample was examined for specific volumetric compressibility of the liposomes. Using the ultrasonic velocity measurement, the elastic properties of the liposomes were evaluated based on the following relational expression.

ΒS, ρ, and u in the formula are the adiabatic compressibility, density, and speed of sound of the suspension, respectively. Hianik T. , Haburcak M .; Lohner K .; , Prenner E .; , Paltauf F. , Hermetter A. (1998): Compressibility and density of lipid bilayers Composited of polyphosphorylated phospholipids and Cholesterol, Coll. Surf. A 139, 189-197; Hianik T .; Rybar P .; , Krivanek R .; Petrikova M. , Milena Roudna M. Hans-Jurgen Appell, HJ. (2011): Specific volume and compressibility of bilayer lipid membrane with integrated Na, K-ATPase. Gen. Physiol. Biophys. 30, 145-153. Therefore, by measuring the change in sound speed and density, the change in compression rate can also be determined.

  Supersonic velocity was measured using a fixed-path differential velocimeter consisting of two nearly identical acoustic cavity resonators operating at a frequency of about 7.2 MHz (Sarvazan AP (1991): Ultrasonic velocimetry compounds). , Annu Rev. Biophys Biophys Chem 20, 321-342; Sarvazyan A.P., Chalikian T.V. (1991):.... Theoretical analysis of an ultrasonic interferometer for precise measurements at high pressures, Ultrasonics 29, 119- 124). The resonant frequency of the cell was measured (USAT, USA) using a computer controlled network analyzer (USAT, USA). The sample volume was 0.7 ml. The resonator cell was equipped with a magnetic stirrer so that the sample was homogeneously dispersed during the measurement. One resonator contained the liposome solution at a concentration of 10 mg / ml relative to the phospholipid and the other was filled with the same buffer without vesicles (PBS or HEPES) as a control. . At the start of a series of measurements, the resonant frequencies of both resonators were first compared by measuring both cells using the same reference liquid. Since the energy density of the sonic signal was small throughout (the ultrasonic pressure amplitude was less than 103 Pa), any effect of the sonic wave on the structural characteristics of the vesicles was prevented. In general, as shown in the following equation, the velocity of sound [u], or rather, the concentration-dependent increment of the velocity of sound [u] can be measured by performing ultrasonic velocity measurement. (Sarvazan AP (1982): Development of methods of precision measurements in liquids of liquids, Ultrasonics 20, 151-154).

Here, c is the solute concentration (mg / ml), and the subscript “0” relates to the solvent (buffer solution). The value [u] is the change in the resonance frequencies f and f _{0 of} both resonators (f is the resonance frequency of the sample and f ₀ is the resonance frequency of the reference buffer):

(This coefficient satisfies the condition of γ << 1 and can be ignored in the calculation)
Can be determined directly from

  The density (ρ) of the vesicle solution is determined by the vibration tube principle (Kratky O., Leopold H., Stabinger H. (1973): The determination of the biochemical of the biochemicals by the biochemicals. Ed. E. Gell), vol. 27, pp. 98-110, Academic Press, London), a high-precision densitometer system (DMA60, two sample chambers of DMA602M, Anton Paar KG, Graz, Austria) Was measured using. The apparent specific partial volume (φV) was calculated from the density data using the following formula.

Here, the subscript 0 refers to the reference solvent, and [ρ] = (ρ−ρ0) / (ρ0c) is the density concentration increment. The temperature of the cells was controlled in the range of ± 0.02 ° C. using Lauda RK 8 CS ultra-thermostat (Lauda, Germany).

  By determining the specific volume in addition to the increment of the sonic velocity concentration, it was possible to predict φK / β0 of the apparent specific compression ratio of the vesicles reduced based on the following formula.

In the equation, β ₀ is a coefficient of compressibility, and ρ ₀ is the density of the buffer solution (Sarvazan 1991). The value of φK / β0 indicates the volume compressibility of the liposome buffer. The higher the value of φK / β0, the higher the compression ratio of the liposome (that is, the lower the rigidity).

  That is, in order to determine the specific volume compressibility of the liposome, the ultrasonic velocity concentration increment [u] and the density ρ are measured, and then the specific volume φV and the apparent specific compressibility φK / β0 are expressed by the formula (4, 4). 5).

  FIG. 4 shows that the liposome of the present invention is substantially rigid as compared with other liposome formulations and hollow liposomes. As shown in FIG. 4, the specific compression ratio (inversely proportional to the stiffness) of LSA liposomes is significantly lower than that of hollow liposomes produced with normal prior art formulations. The specific compression ratio of the hollow liposome is about 0.90, while the compression ratio of the LSA liposome is about 0.70. The specific compressibility of KS and HU liposomes is significantly different at 0.75. From this example, it can be seen that the mechanical properties depend on the formulation and the presence or absence of the drug inside the liposome.

Example 3: Analysis of liposome stability Tables 4 and 5 show the stability of liposome formulations prepared according to Example 1. As shown in Table 4, the liposomes of the present invention are stable for at least 36 months when stored at 4 ° C., and the formulation meets all required specifications.

  As shown in Table 5, the liposomes of the present invention are stable for at least 7 months when stored at 25 ° C., and the formulation meets all required specifications.

Example 4: Analysis for liposome homogeneity The homogeneity of the liposome formulation was measured using a Malvern Nano zs particle size analyzer. In this method, the uniformity of the particle size of the liposome formulation vesicles is measured by dynamic light scattering (DLS), and the particle size distribution of the particles suspended in the liquid medium is examined. This technique can measure particle size distributions in the range of 10-1000 nm and is useful for particle groups such as liposomal emulsions, nanoparticles, synthetic polymers. This technique can be used to obtain an indication of the average diameter of a homogeneous liposomal formulation as well as the heterogeneity of the formulation. After standardizing the measurement results with the Malvern Nano-zs particle size measuring apparatus according to the operating instructions, a 0.5 mg / ml liposome sample was first diluted 1/3 with PBS. The UV λmax 600 nm of the diluted solution was confirmed with an Ultraspec 2100pro UV / VIS spectrophotometer. The liposome sample was diluted again until the optical density (OD) value was 0.10 ± 0.02. Again, it was confirmed that the UV λmax 600 nm of the second diluted solution was 0.10 ± 0.02 in terms of optical density. Next, 1.0 to 1.5 ml of a diluted sample was placed in a culture tube, and the particle size of the vesicles was measured using a Malvern Nano-zs particle size measuring apparatus. The analysis is performed at ambient temperature (23 ° C. ± 2 ° C.) with a fixed angle of 173 ° and a laser wavelength of 633 nm. Data was accumulated to 150-500 Kcps (kilocounts / second).

  Table 6 shows the measurement results for the formulations prepared according to the present invention. The average particle size of the liposomes was 80.41 nm and the PDI was 0.04.

  The homogeneity of HU liposomes and the prior art liposomes of Example 2 above was analyzed according to the procedure described above. The Z average particle diameter of the HU liposome was 176.5 nm.

  Figures 5A and 5B show the particle size distributions of liposomes and HU liposomes produced according to the present invention, respectively. From FIG. 5A, it can be seen that the liposome preparation of the present invention has an average diameter of about 88 nm and a particle diameter of 69 to 107 nm. On the other hand, from FIG. 5B, it can be seen that the average diameter of the HU liposome formulation is about 201 nm, and the diameter of the liposome extends from a small diameter of 80 nm to a large diameter of 500 nm. The PDI of the formulation of FIG. 5A was 0.025. The PDI of the HU formulation of FIG. 5B was 0.118.

  In order to more fully describe the current state of the technology related to the present invention, all published articles, books, reference manuals and abstracts cited in this specification are hereby incorporated herein by reference. It shall be incorporated into the book.

  Since various modifications can be made to the subject matter described above without departing from the scope or spirit of the invention, all the subject matter included in the above description and defined in the claims describes the invention. Should be construed as illustrative. Many modifications and variations can be made to the present invention in light of the above teachings.

Claims (26)

Use of liposomes for the manufacture of a pharmaceutical composition for use in the treatment of symptoms by inhibiting monocytes or macrophages,
Have therapeutic agent encapsulated with the lipid components, Osamu療剤weight ratio of to lipid of about 1: 5 to 1: 8, the lipid component is DSPC, DSPG, molar cholesterol ratio of about 3: 1: containing 2 and, the use of liposomes compression ratio of the liposomes is less than 0.70 ml / g. Use of liposomes according to claim 1, wherein the liposome is negatively charged. The use of a liposome according to claim 1, wherein the liposome has an internal osmolarity of 340 to 440 mOsm / kg. The use of a liposome according to claim 1, wherein the liposome has an internal conductivity of 13.5 to 17.5 ms / cm. The use of a liposome according to claim 1, wherein the therapeutic agent is a bisphosphonate. The use of liposome according to claim 5, wherein the concentration range of bisphosphonate in the liposome is in the range of 0.5 to 5 mg / ml. The use of a liposome according to claim 1, wherein the internal pH of the liposome is about 6.9. A formulation comprising a plurality of liposomes and used for treating symptoms by inhibiting monocytes or macrophages, wherein the liposome has a lipid component and a therapeutic agent, and the lipid component has a molar ratio of DSPC, DSPG, and cholesterol. A formulation containing about 3: 1: 2 and having a PDI of less than 0.07.   The formulation according to claim 8, wherein the liposome is negatively charged.   The formulation according to claim 8, wherein the liposome has an internal osmolarity of 340 to 440 mOsm / kg.   The formulation according to claim 8, wherein the liposome internal conductivity is in the range of 13.5 to 17.5 ms / cm.   The prescription according to claim 8, wherein the therapeutic agent is a bisphosphonate.   The formulation according to claim 12, wherein the concentration range of the bisphosphonate in the liposome is in the range of 0.5 to 5 mg / ml.   The formulation according to claim 8, wherein the internal pH of the liposome is about 6.9.   9. The formulation according to claim 8, wherein the average particle size of the liposome is 80 ± 5 nm.   The prescription according to claim 8, wherein 96% or more of the therapeutic agent in the prescription is encapsulated.   The formulation of claim 8, wherein the mass ratio of therapeutic agent to lipid component is about 1: 5 to 1: 8.   The prescription according to claim 8, wherein the compression rate of the liposome is 0.70 ml / g or less.   The prescription according to claim 8, wherein PDI is 0.02 to 0.05. A method for producing a formulation comprising a plurality of liposomes containing a certain amount of a lipid component and a therapeutic agent and used to treat a symptom by inhibiting monocytes or macrophages, wherein the lipid component is DSPC, DSPG, cholesterol In a molar ratio of about 3: 1: 2 and a therapeutic agent to lipid mass ratio in the range of about 1: 5 to 1: 8,
(A) A solution containing a therapeutic agent is mixed with a lipid solution containing DSPC, DSPG, and cholesterol in a molar ratio of about 3: 1: 2, so that the mass ratio of therapeutic agent to lipid is about 1: 5 to 1: 8. Forming a vesicle so that
(B) substantially extruding a vesicle by repeatedly extruding through a single filter having a pore diameter of about 100 nm multiple times;
(C) ultrafiltration of vesicles;
A method comprising the steps of:   21. The method of claim 20, further comprising the step of (d) diluting the formulation with a phosphate buffer to a final therapeutic agent concentration of the formulation.   The process according to claim 20, wherein the extrusion in step (b) is carried out in the range of 55C to 75C.   21. The method of claim 20, wherein the extrusion of step (b) is performed at a pressure in the range of 60 to 90 psi.   The method according to claim 20, wherein the ultrafiltration is carried out after repeating the extrusion in the step (b) 10 to 18 times.   21. The method of claim 20, wherein the formulation has a liposome internal pH of about 6.9. 21. The method of claim 20, wherein the prescription PDI is less than 0.07.